Hugging Face's logo

Datasets:
ArkaAcharya
/
MM_Retriever_Dataset

Dataset card Files Community
MM_Retriever_Dataset
File size: 219,798 Bytes 
694fde3
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
 
fig_num,image_path,image_caption,golden_corpus,positive_corpus
Figure 7.3,cardio/images/Figure 7.3.jpg,Figure 7.3: Timeline of cardiac biomarkers after a myocardial infarction.,"With non-ST segment elevation myocardial infarction (NSTEMI), there is necrosis of the myocardium. Although, as the name suggests, there is no consistent ST segment elevation in a NSTEMI, other ECG changes may be seen. These include transient ST elevation, ST depression, or new T-wave inversions. The lysing myocytes release their contents including enzymes that can be used as biomarkers of the necrotic event. Presence of elevated cardiac enzymes distinguishes NSTEMI from unstable angina, but denotes myocardial damage and a poorer prognosis. There are several cardiac enzymes that can be detected (myoglobin, creatine kinase, and troponin I), and each has a different timeline from onset of infarction (figure 7.3). But because of improvements in test sensitivity, the test enzyme of choice is troponin I.","{'2395eb07-d28a-4e14-983c-126fe6e1985e': 'With non-ST segment elevation myocardial infarction (NSTEMI), there is necrosis of the myocardium. Although, as the name suggests, there is no consistent\xa0ST segment elevation in a NSTEMI, other ECG\xa0changes may be seen. These include\xa0transient ST elevation, ST depression, or new T-wave inversions.\xa0The lysing myocytes release their contents including enzymes that can be used as biomarkers of the necrotic event. Presence of elevated\xa0cardiac enzymes distinguishes NSTEMI from unstable angina, but denotes myocardial damage\xa0and a poorer prognosis. There are several cardiac enzymes that can be detected (myoglobin, creatine kinase, and troponin I), and each has a different timeline from onset of infarction (figure 7.3). But because of improvements in test sensitivity, the test\xa0enzyme of choice is troponin I.'}"
Figure 7.4,cardio/images/Figure 7.4.jpg,Figure 7.4: Comparison of audible and inaudible S4 sounds.,"The physical examination findings may include elevated heart rate and blood pressure due to increased sympathetic tone. However, if cardiac function is severely impacted because of the size or location of the infarction, cardiogenic shock may result with a fall in blood pressure. The insufficient ATP production in the ischemic region means the interaction of actin and myosin in the cardiac myocytes cannot be broken and the muscle cannot relax. An S4 heart sound (figure 7.4) occurs when the noncompliant, stiffened left ventricle vibrates when blood enters from the atrium. The S4 sound is also known as an atrial gallop—not because the sound comes from the ventricle, but because it is associated with atrial contraction (and ventricular filling). If the infarction involves an impact of the papillary muscle function, the associated valve will fail and the regurgitation will cause a holosystolic murmur. A STEMI in the left ventricle sufficient to cause congestion and a rise in left-ventricular and end-diastolic pressure can lead to rises in left atrial and pulmonary pressure; this may be heard on the lung exam as rales due to the transient pulmonary edema.","{'99654ea9-1084-45f3-8c5b-2479b32f7b8e': 'The physical examination findings may include elevated\xa0heart rate and blood pressure due to increased sympathetic tone. However, if cardiac function is severely impacted because of the size or location of the infarction,\xa0cardiogenic shock may result with a fall in blood pressure. The insufficient\xa0ATP\xa0production in the ischemic region means the interaction of actin and myosin in the cardiac myocytes cannot be broken and the muscle cannot relax. An S4 heart sound\xa0(figure 7.4)\xa0occurs when the noncompliant, stiffened left ventricle\xa0vibrates\xa0when blood enters from the atrium. The S4 sound is also known as an atrial gallop—not because\xa0the sound comes from the ventricle, but because\xa0it is associated with atrial contraction (and ventricular filling).\xa0If the infarction involves an\xa0impact\xa0of the\xa0papillary muscle function, the associated valve will fail and the\xa0regurgitation\xa0will cause\xa0a holosystolic murmur. A STEMI in the left ventricle sufficient to cause congestion and a rise in left-ventricular and end-diastolic pressure can lead to rises in left atrial and pulmonary pressure; this may be heard\xa0on the lung exam as rales due to the transient pulmonary edema.', 'd23a054f-12c2-4916-b9b0-6ca0f924a9fa': 'As mentioned above the two most important tools for diagnosing a STEMI are the ECG and the presence of cardiac enzymes that have been released into the bloodstream. Figure 7.4 shows the time line of myoglobin, creatine kinase, and troponin elevations after an infarction. Using the values of all three enzymes\xa0allowed the history of an infarction to be generated, but amazing\xa0improvements in the sensitivity of the troponin I\xa0test\xa0have allowed it to become the gold standard because of its specificity to the myocardium.'}"
Figure 7.4,cardio/images/Figure 7.4.jpg,Figure 7.4: Comparison of audible and inaudible S4 sounds.,"The physical examination findings may include elevated heart rate and blood pressure due to increased sympathetic tone. However, if cardiac function is severely impacted because of the size or location of the infarction, cardiogenic shock may result with a fall in blood pressure. The insufficient ATP production in the ischemic region means the interaction of actin and myosin in the cardiac myocytes cannot be broken and the muscle cannot relax. An S4 heart sound (figure 7.4) occurs when the noncompliant, stiffened left ventricle vibrates when blood enters from the atrium. The S4 sound is also known as an atrial gallop—not because the sound comes from the ventricle, but because it is associated with atrial contraction (and ventricular filling). If the infarction involves an impact of the papillary muscle function, the associated valve will fail and the regurgitation will cause a holosystolic murmur. A STEMI in the left ventricle sufficient to cause congestion and a rise in left-ventricular and end-diastolic pressure can lead to rises in left atrial and pulmonary pressure; this may be heard on the lung exam as rales due to the transient pulmonary edema.","{'99654ea9-1084-45f3-8c5b-2479b32f7b8e': 'The physical examination findings may include elevated\xa0heart rate and blood pressure due to increased sympathetic tone. However, if cardiac function is severely impacted because of the size or location of the infarction,\xa0cardiogenic shock may result with a fall in blood pressure. The insufficient\xa0ATP\xa0production in the ischemic region means the interaction of actin and myosin in the cardiac myocytes cannot be broken and the muscle cannot relax. An S4 heart sound\xa0(figure 7.4)\xa0occurs when the noncompliant, stiffened left ventricle\xa0vibrates\xa0when blood enters from the atrium. The S4 sound is also known as an atrial gallop—not because\xa0the sound comes from the ventricle, but because\xa0it is associated with atrial contraction (and ventricular filling).\xa0If the infarction involves an\xa0impact\xa0of the\xa0papillary muscle function, the associated valve will fail and the\xa0regurgitation\xa0will cause\xa0a holosystolic murmur. A STEMI in the left ventricle sufficient to cause congestion and a rise in left-ventricular and end-diastolic pressure can lead to rises in left atrial and pulmonary pressure; this may be heard\xa0on the lung exam as rales due to the transient pulmonary edema.', 'd23a054f-12c2-4916-b9b0-6ca0f924a9fa': 'As mentioned above the two most important tools for diagnosing a STEMI are the ECG and the presence of cardiac enzymes that have been released into the bloodstream. Figure 7.4 shows the time line of myoglobin, creatine kinase, and troponin elevations after an infarction. Using the values of all three enzymes\xa0allowed the history of an infarction to be generated, but amazing\xa0improvements in the sensitivity of the troponin I\xa0test\xa0have allowed it to become the gold standard because of its specificity to the myocardium.'}"
Figure 7.5,cardio/images/Figure 7.5.jpg,Figure 7.5: Hyperacute T-waves associated with an early myocardial infarction.,"The first ECG sign to arise during a STEMI are “hyperacute T-waves” (figure 7.5). These T-waves are taller than normal and caused by the release of intracellular potassium from lysing cells and the consequent hyperkalemia in the surrounding tissue. Hyperacute T-waves are not often seen clinically because they occur so early in the event and prior to the patient’s arrival in the hospital. Subsequent ECG stages are more commonly observed, and these include the ST elevation.","{'72ffb72c-4a64-4cc6-873f-de27f4b99bc8': 'The first ECG sign to arise during a STEMI are\xa0“hyperacute T-waves” (figure 7.5). These T-waves are taller than normal and caused by the release of intracellular potassium from lysing cells and the consequent hyperkalemia in the surrounding tissue. Hyperacute T-waves are not often seen clinically because they occur so early in the event and prior to the patient’s arrival in the hospital. Subsequent ECG stages are more commonly observed, and these include the ST elevation.', '88db4132-68ca-4549-89a2-924cf9f900ea': 'Determining which ECG\xa0leads show the ST elevation allow for the\xa0location of the infarcted tissue to be determined\xa0and provide insight into which coronary vessel is effected. How the leads of a twelve-lead ECG\xa0relate to the coronary vessels is summarized in figure 7.6. The following looks at the characteristic ECG changes in relation to location in a bit more detail (tip: relate back to figure 7.6\xa0as you read the next sections).'}"
Figure 7.6,cardio/images/Figure 7.6.jpg,"Figure 7.6: Which leads look at which coronary vessels? LCx = left circumflex, LAD = left anterior descending, RCA = right coronary artery.",Determining which ECG leads show the ST elevation allow for the location of the infarcted tissue to be determined and provide insight into which coronary vessel is effected. How the leads of a twelve-lead ECG relate to the coronary vessels is summarized in figure 7.6. The following looks at the characteristic ECG changes in relation to location in a bit more detail (tip: relate back to figure 7.6 as you read the next sections).,"{'72ffb72c-4a64-4cc6-873f-de27f4b99bc8': 'The first ECG sign to arise during a STEMI are\xa0“hyperacute T-waves” (figure 7.5). These T-waves are taller than normal and caused by the release of intracellular potassium from lysing cells and the consequent hyperkalemia in the surrounding tissue. Hyperacute T-waves are not often seen clinically because they occur so early in the event and prior to the patient’s arrival in the hospital. Subsequent ECG stages are more commonly observed, and these include the ST elevation.', '88db4132-68ca-4549-89a2-924cf9f900ea': 'Determining which ECG\xa0leads show the ST elevation allow for the\xa0location of the infarcted tissue to be determined\xa0and provide insight into which coronary vessel is effected. How the leads of a twelve-lead ECG\xa0relate to the coronary vessels is summarized in figure 7.6. The following looks at the characteristic ECG changes in relation to location in a bit more detail (tip: relate back to figure 7.6\xa0as you read the next sections).'}"
Figure 7.7,cardio/images/Figure 7.7.jpg,Figure 7.7: An ECG showing an anterior wall infarction with the characteristic “tombstoning” of the T-wave.,"The anterior wall is affected when the left anterior descending coronary artery becomes occluded. Additional involvement of lateral and septal regions is indicative of the left main coronary artery being involved. Inclusion of these regions is termed an extensive anterior infarction. The ECG shows ST segment elevation in leads V3 and V4 (the anterior leads), seen as a raised J-point (see figure 7.7). A reciprocal ST depression will be seen in leads II, III, and aVF (the inferior leads). If the extent of the infarction is large, the elevated ST segment may been seen in the lateral and septal leads. The elevated ST segment is also associated in a change in shape of the T-wave as it becomes broader and loses its concave shape on the downward section. This broad T-wave can be higher as well as the ST elevation progresses, and its height can surpass the R-wave. These morphological changes result in a T-wave that looks like a tombstone (see figure 7.7).","{'49edadfd-c220-471a-a2a7-98961115d828': 'The anterior wall is affected when the left anterior descending coronary artery becomes occluded. Additional involvement of\xa0lateral and septal regions is indicative of the left main coronary artery being involved. Inclusion of these regions is termed an extensive anterior infarction. The ECG shows\xa0ST segment elevation\xa0in\xa0leads V3 and V4\xa0(the anterior leads), seen as a raised\xa0J-point (see figure 7.7).\xa0A\xa0reciprocal ST depression will be seen in leads\xa0II, III, and aVF (the inferior leads). If the extent of the infarction is large, the elevated ST segment may been seen in\xa0the lateral and septal leads.\xa0The elevated ST segment is also associated in a change in shape of the T-wave as it becomes broader and loses its concave shape on the downward section. This broad\xa0T-wave can be higher as well as the ST elevation progresses, and its height can surpass the R-wave. These morphological changes result in a T-wave that looks like a tombstone (see figure 7.7).'}"
Figure 7.9,cardio/images/Figure 7.9.jpg,Figure 7.9: IWMI.,"Occlusion of the right coronary artery is the usual culprit for an inferior wall myocardial infarction (IWMI), which may be severe enough to extend to posterior regions.  The ECG findings of an acute inferior myocardial infarction (figure 7.9) will be an ST segment elevation in leads II, III, and aVF (the inferior leads) and reciprocal depression in lead aVL (a lateral lead); without the reciprocal depression in aVL, alternative causes of ST segment elevation in the inferior leads should be considered (e.g., pericarditis). Because the right coronary artery perfuses the SA node, bradycardia may occur. An inferior MI can have multiple potential complications, including cardiogenic shock, atrioventricular block, or ventricular fibrillation, and can be fatal.","{'6bffe156-b418-440d-b656-519ab719029a': 'Occlusion of the right coronary artery is the usual culprit for an inferior wall myocardial infarction (IWMI), which may be severe enough to extend to posterior regions. \xa0The ECG findings of an acute inferior myocardial infarction (figure 7.9) will be an\xa0ST segment elevation in leads\xa0II, III, and aVF\xa0(the inferior leads) and reciprocal depression in lead\xa0aVL\xa0(a\xa0lateral lead); without the reciprocal depression in aVL,\xa0alternative causes of ST segment elevation in the inferior leads\xa0should be considered (e.g., pericarditis). Because the right coronary artery\xa0perfuses the SA node, bradycardia may occur.\xa0An inferior MI can have multiple potential complications, including cardiogenic shock, atrioventricular block, or ventricular fibrillation, and can be fatal.'}"
Figure 7.11,cardio/images/Figure 7.11.jpg,Figure 7.11: Posterior wall MI.,"Most posterior myocardial infarctions occur with occlusion of the posterior descending artery (which in most people is a branch of the right coronary artery); because of the shared supply, a posterior infarction is often accompanied by an IWMI. The ECG findings include ST segment elevation in V7–V9 (the posterior leads that are placed on the posterior axillary line, not shown in figure 7.11) and ST depression in V1–V4 (the septal and anterior leads, shown in figure 7.10). If an IWMI is also present then there will be an ST elevation in leads II, III, and aVF (the inferior leads). A twelve-lead ECG showing a posterior wall infarction is shown in figure 7.11.","{'efe18db6-82d6-407b-ac2b-58efb88e6c6d': 'Most posterior myocardial infarctions occur with occlusion of the posterior descending artery (which in most people is a branch of the right coronary artery); because of the shared supply, a posterior infarction is often accompanied by an IWMI. The ECG findings include ST segment elevation in V7–V9 (the posterior leads that are placed on the posterior axillary line, not shown in figure 7.11) and ST depression in V1–V4 (the septal and anterior leads, shown in\xa0figure 7.10). If an IWMI\xa0is also present then there will be an ST elevation in leads II, III, and aVF (the inferior leads). A\xa0twelve-lead ECG showing a posterior wall infarction is shown in figure 7.11.', 'c3555430-b628-4c1d-a1b4-ea3410d63415': 'The location of the infarction, leads showing ST elevation\xa0and depression, and the involved coronary artery are summarized in table 7.1.', 'fad9a2c1-10a1-4b64-b8df-f054450efa3c': 'Table 7.1: Location of the infarction, leads showing ST elevation and depression, and the involved coronary artery.'}"
Figure 7.1,cardio/images/Figure 7.1.jpg,,Figure 7.1: Sequences in progression of atherosclerosis.,"{'8c6e0429-e47f-4997-a67a-ddf069d958f5': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Ischemic Heart Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 6. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'f418f90a-4b61-47fe-9986-92500c9a8db6': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Acute Coronary Syndromes.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 7. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0d5c9a9d-0b35-43ee-a67d-f78f5b489c22': 'Surawicz, Borys, Rory Childers, Barbara J. Deal, and Leonard S. Gettes. “AHA/ACCF/HRS Recommendations for the Standardization and Interpretation of the Electrocardiogram.” Circulation 119, no. 10 (2009): e235–e240.', '60ff9e9a-c126-471e-99f6-c12310ca27fc': 'Surawicz, Borys, and Timothy Knilans. Chou’s Electrocardiography in Practice, 6th ed. Philadelphia: Saunders, 2008.', '338365cf-229f-462a-a031-98082c43433e': 'Bhansali, Suneet, and Colin Phoon.\xa0Truncus Arteriosis. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK534774/,\xa0CC BY 4.0.', '995ee375-aece-4390-b26d-9b4c9f312271': 'Cunningham, Jonathan W., and David W. Brown. “Congenital Heart Disease.” In\xa0Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, edited by Leonard S. Lilly, Chapter 16. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2012.', '840aca0a-c487-491a-b695-a8457d2cbc98': 'Dakkak, Wael, and Tony I. Oliver.\xa0Ventricular Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK470330/,\xa0CC BY 4.0.', '51d7dd59-efef-49b1-b87a-858bd257fe67': 'Diaz-Frias, Josua, and Melissa Guillaume.\xa0Tetralogy of Fallot. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK513288/,\xa0CC BY 4.0.', 'c7943f22-f9f3-4d59-b486-0d892d7fc01d': 'Gillam-Krakauer, Maria, and Kunal Mahajan.\xa0Patent Ductus Ateriosus. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', 'eb6a5536-2fab-49e9-8fea-fb6dfd90ac7e': 'Law, Mark A., and Vijai\xa0 S. Tivakaran.\xa0Coarctation of the Aorta. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430913/,\xa0CC BY 4.0.', '7dab3894-5603-4e66-a595-a4a501477845': 'Menillo, Alexandra M., Lawrence S. Lee, and Anthony L. Pearson-Shaver.\xa0Atrial Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK535440/,\xa0CC BY 4.0.', '477bb241-ffa8-4452-b076-05fd90b9111e': 'Szymanski, Michael W., Sheila M. Moore, Stacy M. Kritzmire, and Amandeep Goyal.\xa0Transposition of the Great Arteries. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', '740f1bed-fa6b-4651-a963-90a31353aa51': 'Umapathi, Krishna Kishore, and Pradyumna Agasthi.\xa0Atrioventricular Canal Defects.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK557511/,\xa0CC BY 4.0.', 'ade10988-52d5-40bb-a747-06d819e62b55': 'Dornbush, Sean, and Andre E. Turnquest. Physiology, Heart Sounds. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK541010, CC BY 4.0.', '1d13203a-5404-4ba4-abaa-6b5f3df36f97': 'Kulkarni, Vivek T., and Leonard S. Lilly. “The Cardiac Cycle: Mechanisms of Heart Sounds and Murmurs.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 2. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '3f337c79-9677-4c2d-8bca-e53e383a902f': 'Thomas, Seth L., Joseph Heaton, and Amgad N. Makaryus. Physiology, Cardiovascular Murmurs. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK525958, CC BY 4.0.', '79ed1809-c439-4208-b3fb-eabdea6a3c5c': 'Table 5.5: Classifications of heart murmurs. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/5.5_20220113', '0d9a3874-61bf-4706-bc3b-cd7d9ea2021c': 'Abnormalities of valvular structure and/or function can either be congenital or acquired. Acquired valvular disease is by far the most common and is most prevalent in the elderly. The high blood flow and pressures that valves are exposed to make them particularly susceptible to other risk factors that promote valvular damage (see table 4.1). Congenital valvular defects arise from disrupted heart development, about 50 percent\xa0of which involve the valves. The impact of congenital defects has diminished with the advent of advanced detection techniques.\xa0What we will spend time on in this chapter is the main instigating factors and pathologies that result\xa0in acquired valvular defects.', 'ccc9c78e-3005-40ab-baac-35ac9036e771': 'Table 4.1: Risk factors for acquired valvular damage.', '9098edeb-f4b5-4b10-aa41-7ecc7e039310': 'The constant stress of facing high flow and pressure over thirty to forty\xa0million cardiac contractions a year is not without its consequences, and the most common valvular disorder is calcification that comes with “wear-and-tear”\xa0and aging. The presence of other factors such as hyperlipidemia, hypertension, and inflammation accelerate this process and promote the deposition of hydroxyapatite (a form of calcium phosphate), and the valve structure contains cells that resemble osteoblasts (figure 4.1).', '8e9c7284-ff78-4170-bdb5-1bb9aa034b4b': 'As they face the most pressure, the aortic and mitral valves are more prone to calcification. The most common pattern of calcification in the aortic valve is mounded masses within the cusps of the valve (see table\xa04.2) that eventually fuse and stop the valve from opening fully.\xa0Calcification in the mitral valve\xa0tends to start in the fibrous annulus, which does not\xa0impact valvular function to the same extent, but in exceptional cases can cause regurgitation or stenosis, or even arrhythmias as calcium deposits impinge on the atrioventricular conduction system (see table\xa04.2).', '56ee9369-4764-475a-bf47-8192d06fa092': 'Table 4.2: Location of calcium deposits on aortic and mitral valves and their pathological consequences.', '87a6622f-680a-4032-acf2-22d1a3d06a57': 'Dass, Clarissa, and Arun Kanmanthareddy. Rheumatic Heart Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK538286/, CC BY 4.0.', '01571255-0baf-4ad1-abdb-c3c38901b4f1': 'Douedi, Steven, and Hani Douedi. Mitral Regurgitation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK553135/, CC BY 4.0.', '7f9e8792-d353-4380-b72b-10095d2e32d2': 'Lopez, Diana M., Patrick T. O’Gara, and Leonard S. Lilly. “Valvular Heart\xa0 Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 8. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0b92e173-7511-4e4f-a01c-46a261d63327': 'Wenn, Peter, and Roman Zeltser. Aortic Valve Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK542205/, CC BY 4.0.', '1ae0ec16-694d-4b2e-9c46-4f16ca1187bc': 'Table 4.1: Location of calcium deposits on aortic and mitral valves and their pathological consequences. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/4.2a_20220113', '36cfa87f-cb4a-40da-be59-3fe09efefb82': 'The current guidelines (JNC 8, 2017) list the following pressures and categories to define hypertension:', '043d0a6c-c109-49d3-864d-1049ae0bab92': 'Brown, Jenifer M., Gordon H. Williams, and Leonard S. Lilly. “Hypertension.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 13. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '6a1b6fe6-83fe-406c-9e01-1a06a4791350': 'Hajar, Rachel. “Framingham Contribution to Cardiovascular Disease.” Heart Views 17, no. 2 (April–June 2016): 78–81. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4966216.', 'b09e6339-ed87-40ae-b475-924c98e1a575': 'Iqbal, Arshad Muhammad, and Syed F. Jaml. Essential Hypertension. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK539859/, CC BY 4.0.', 'df8f6825-cd8d-4f33-a3b6-3aa95e2b7231': 'Page, Michael R. “The JNC 8 Hypertension Guidelines: An In-Depth Guide.” Evidence-Based Diabetes Management 20, no. SP1\xa0 (January 2014). https://www.ajmc.com/view/the-jnc-8-hypertension-guidelines-an-in-depth-guide.', '542c40cb-0157-4bdb-8e18-253f38324396': 'For whichever reason the end effect of the failure is a decline in blood flow out of the heart, and consequently congestion on the way in.', '7793dbfa-5e5b-4555-9631-e10c6b1d4a99': 'Table 2.1: Changes in cardiac function in different disease states.', '810dee93-c004-4109-b99d-0c58c90f8bc4': 'Impediments to emptying the heart during systole (i.e., a reduced contractility or increased afterload) were\xa0referred to as systolic heart failure. Similarly, problems with filling the ventricle during diastole were referred to as diastolic heart failure (figure 2.1).', '9d443965-9456-4656-a0f9-1e1e37fce404': 'In reality there is a great deal of overlap between these forms of heart failure, and elements of both can be present in the same patient. Similarly, as both forms result in congestion before the heart and reduced flow after it, they are hard to immediately distinguish. Consequently the type and degree of failure is now categorized by the effect on ejection fraction that can help distinguish the source of the problem.', '33c5d98f-6bcc-40b2-9a97-f4a5cf465f1c': 'Let us quickly remind ourselves of what ejection fraction is. Ejection fraction is the proportion of blood volume that the left ventricle ejects in one beat. It is mathematically described as the starting volume (i.e., end-diastolic volume, EDV) minus the finishing volume (i.e., end-systolic volume, ESV) as a proportion of the starting volume (figure 2.2)—in simpler terms, what percentage of the ventricular blood volume was pushed out during a contraction.', '0dade292-7120-4fea-a845-e26eeb3159a3': 'Eberly, Lauren A., Eldrin F. Lewis, and Leonard S. Lilly. “Heart Failure.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 9. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'd3239a6f-3c3d-4562-9ca8-835f21d500e2': 'Malik, Ahmad, Daniel Brito, Sarosh Vaqar, and Lovely Chhabra. Congestive Heart Failure. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK430873/, CC BY 4.0.', '25e09e1a-9d83-488d-ad5f-1fbe028f8fb0': 'Burns, Ed, and Robert Buttner. Hypercalcaemia. Lift in the Fast Lane, 2021. https://litfl.com/hypercalcaemia-ecg-library/, CC BY 4.0.', '98b0eb2b-328b-4f37-95d0-4a1d717348c2': 'Burns, Ed, and Robert Buttner. Hypocalcaemia. Life in the Fast Lane, 2021. https://litfl.com/hypocalcaemia-ecg-library/, CC BY 4.0.', '924eb71e-f15c-45cf-a207-17b43a28255e': 'Buttner, Robert, and Ed Burns. Hyperkalaemia. Life in the Fast Lane. https://litfl.com/hyperkalaemia-ecg-library/, CC BY 4.0.', '3f6b51a5-0594-4ad0-aff0-def446f6da9d': 'Buttner, Robert, and Ed Burns. Hypokalaemia. Life in the Fast Lane, 2021. https://litfl.com/hypokalaemia-ecg-library/, CC BY 4.0.', 'c2ec9ebd-39e6-4027-8d33-99309d013968': 'Chhabra, Lovely, Amandeep Goyal, and Michael D. Benham. Wolff Parkinson White Syndrome. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK554437/, CC BY 4.0.', 'de0f5e7f-54b2-4ef7-80ca-92553b8b6171': 'Custer, Adam M., Varun S. Yelamanchili, and Sarah L. Lappin. Multifocal Atrial Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459152/, CC BY 4.0.', '3e262579-d93b-409b-983d-96ddc6f0517c': 'Farzam, Khashayar, and John R. Richards. Premature Ventricular Contraction. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532991/, CC BY 4.0.', '7328f663-c5ef-4e2f-ade4-a4211caf5868': 'Foth, Christopher, Manesh Kumar Gangwani, and Heidi Alvey. Ventricular Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532954/, CC BY 4.0.', 'fc065c88-8e7e-4e26-a309-85650123fb33': 'Hafeez, Yamama, and Shamai A. Grossman. Sinus Bradycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK493201/, CC BY 4.0.', 'f1595d60-c9c3-4d6b-ba3b-44af48991758': 'Harkness, Weston T., and Mary Hicks. Right Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK507872/, CC BY 4.0.', 'd2624d0f-ba5a-421e-b634-e2a663b7ab7e': 'Heaton, Joseph, and Srikanth Yandrapalli. Premature Atrial Contractions. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK559204/, CC BY 4.0.', 'dcf93591-9453-4b52-a6ad-1aca2b965dd9': 'Kashou, Anthony H., Amandeep Goyal, Tran Nguyen, and Lovely Chhabra. Atrioventricular Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459147/, CC BY 4.0.', '54fd1955-7dcf-474e-a1c7-48be82daaf68': '“Learn the Heart.” Healio. https://www.healio.com/cardiology/learn-the-heart.', 'd631c93d-f5f0-400a-84c4-7fbe032819dc': 'Ludhwani, Dipesh, Amandeep Goyal, and Mandar Jagtap. Ventricular Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK537120/, CC BY 4.0.', '23d28e5a-2755-4f59-a997-fe25fb642627': 'Nesheiwat, Zeid, Amandeep Goyal, and Mandar Jagtap. Atrial Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK526072/, CC BY 4.0.', 'c652c067-fadb-4dcb-b5b7-c4507437ffd4': 'Pipilas, Daniel C., Bruce A. Koplan, and Leonard S. Lilly. “The Electrocardiogram.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 4. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '7c80cf5c-7fd6-4813-bb3d-279ddffa421e': 'Rodriguez Ziccardi, Mary, Amandeep Goyal, and Christopher V. Maani. Atrial Flutter. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK540985/, CC BY 4.0.', '9c33cea2-2522-4f34-b5de-1bb5ae1c0182': 'Scherbak, Dmitriy, and Gregory J. Hicks. Left Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK482167/, CC BY 4.0.'}"
Figure 6.1,cardio/images/Figure 6.1.jpg,Figure 6.1: Schematic of ASD showing left–right shunt. Thicker lines indicate the presence of volume overload.,"ASDs allow blood flow between the atria. As the pressure in the left atria is higher than that in the left, blood flows from left to right (figure 6.1). This causes volume overload of the right side of the heart. This excessive load may lead to right ventricular compliance being reduced as remodeling takes place. The reduced compliance can elevate right-side pressure and thereby reduce the left–right shunt.","{'0ca2e9a4-4235-43f9-ab0c-905df40a4de4': 'ASDs allow blood flow between the atria. As the pressure in the left atria is higher than that in the left, blood flows from left to right (figure 6.1). This causes volume overload of the right side of the heart. This excessive load may lead to right ventricular compliance being reduced as remodeling takes place. The reduced compliance can elevate right-side pressure and thereby reduce the left–right shunt.'}"
Figure 6.2,cardio/images/Figure 6.2.jpg,"Figure 6.2: Schematic of VSD showing left–right shunt that can lead to volume overload in the RV, LA, LV, and pulmonary circulation. Dotted lines show the recirculation of blood back through the pulmonary circulation. Thicker lines denote volume overload.","The manifestations of a VSD depend on the VSD size and the relative resistance of the pulmonary and systemic circulations—all of which will determine the direction of blood flow. During fetal development, the pulmonary and systemic circulations have equivalent resistances, so there may be very little shunting through the VSD, particularly if it is small. After birth, however, the resistance of the pulmonary system falls dramatically, so right ventricular pressure is lower and below left ventricular pressure (which still has to contend with systemic resistance)—consequently a left–right shunt is established. If this shunt is large (depending on the size of the defect), then blood returning from the pulmonary circulation to the left atrium can pass into the left ventricle, through the VSD into the right ventricle and head back into pulmonary circulation to start this loop again (figure 6.2).","{'2207e1e4-c6bd-4d7f-942d-aba1814d1dac': 'Most ventricular septal defects arise from membraneous portion of the septum (70 percent), while others form in the muscular portion (20 percent); less frequently they occur near the aortic or AV valves.', '905a0d96-2952-42f9-8fba-fd4f61c9a889': 'The manifestations of a VSD depend on the VSD size and the relative resistance of the pulmonary and systemic circulations—all of which will determine the direction of blood flow. During fetal development, the pulmonary and systemic circulations have equivalent resistances, so there may be very little shunting through the VSD, particularly if it is small. After birth, however, the resistance of the pulmonary system falls dramatically, so right ventricular pressure is lower and below left ventricular pressure (which still has to contend with systemic resistance)—consequently a left–right shunt is established. If this shunt is large (depending on the size of the defect), then blood returning from the pulmonary circulation to the left atrium can pass into the left ventricle, through the VSD into the right ventricle and head back into pulmonary circulation to start this loop again (figure 6.2).', 'aa70f67a-58aa-47d6-848c-2372e6335b6d': 'When a large VSD is present, the recirculated blood causes volume overload of the\xa0right ventricle and\xa0the pulmonary circulation and subsequently\xa0both chambers of the left heart (figure 6.2). This can eventually cause chamber dilation and lead to heart failure. The extra volume load in the pulmonary circulation can also lead to early onset of pulmonary vascular disease.'}"
Figure 6.3,cardio/images/Figure 6.3.jpg,Figure 6.3: Coarctation of the aorta (circled).,"Coarctation of the aorta (figure 6.3) is a constriction of the aortic lumen, usually close to the ductus. The cause is unclear, but low flow through the left heart and aorta flow during development may cause the defect (no flow, no grow).","{'baf51c4b-f19b-4d5a-97c8-2f134e75f7fc': 'Coarctation of the aorta (figure 6.3) is a constriction of the aortic lumen, usually close to the ductus. The cause is unclear, but low flow through the left heart and aorta flow during development may cause the defect (no flow, no grow).', '2b7ddeef-3daa-4e16-996a-9128398cd540': 'The diminished lumen causes increased afterload on the left ventricle. Vessels branching off the aorta before the coarctation can receive normal blood flow, so the head (carotid) and upper extremities (subclavian) are usually properly perfused whereas branching arteries after the coarctation may be underperfused. Consequently, differential cyanosis is a possible manifestation.'}"
Figure 6.4,cardio/images/Figure 6.4.jpg,"Figure 6.4: Tetralogy of Fallot with 1) pulmonic stenosis, 2) RV hypertrophy, 3) VSD, and 4) overriding aorta.","The high resistance of the stenosed pulmonic valve (#1, figure 6.4) causes the blood in the right ventricle to exit through VSD (#3, figure 6.4) and enter the left ventricle forming a right-left shunt, bypassing the pulmonary circulation. Consequently blood with venous PO2 enters the systemic circulation and hypoxemia/cyanosis results. The degree of hypoxemia/cyanosis that occurs depends on the degree of pulmonic stenosis.","{'7a4760f4-973c-4a6a-8a2b-28a1f5d1c029': 'In Tetralogy of Fallot (ToF) the outflow tract (infundibular) portion of the interventricular septum is displaced. This single defect leads to four defects:', '93e3f0c6-c5f9-413c-b352-7115cb701e96': 'Other defects can be associated with ToF, but the defects listed above lead this to be the most common form of cyanotic congenital heart disease.', 'af60813e-aa12-41db-9727-78873b12e12e': 'The high resistance of the stenosed pulmonic valve (#1, figure 6.4) causes the blood in the right ventricle to exit through VSD (#3, figure 6.4) and enter the left ventricle forming a right-left shunt, bypassing the pulmonary circulation. Consequently blood with venous PO2 enters the systemic circulation and hypoxemia/cyanosis results. The degree of hypoxemia/cyanosis that occurs\xa0depends\xa0on the degree of pulmonic stenosis.'}"
Figure 6.5,cardio/images/Figure 6.5.jpg,"Figure 6.5: Schematic of transposition of the great vessels (aorta off of the right, pulmonary artery off of the left) forming two separate, looped circulations.","The placement of the pulmonary artery on the left means left ventricular blood is pumped up to pulmonary circulation, only to return to the left side of the heart via the pulmonary veins. Similarly, the aorta on the right forms a closed-system with the right ventricle pumping into the systemic circulation, only for it to return to the right atrium via the vena cava (see figure 6.5). So how is this compatible with life? In short, it is not. Embryonic development can continue because the two looped circulations can mix at the ductus arteriosus and foramen ovale of the fetal circulation. But after birth these shunts between the two circulations MUST be artificially maintained, or the patient must be “fortunate” enough to also have a VSD for mixing to take place.","{'236b9e5b-579c-4497-81b7-5d66ab40a6f8': 'Although not completely understood, it is thought that failure of the aortic-pulmonary septum to spiral during development results in the great vessels coming off the wrong ventricles—the aorta exits the right, and the pulmonary artery exits the left. Other theories exist.', '895cbe7b-7f2f-4641-a6fa-539f64d1cd91': 'The placement of the pulmonary artery on the left means left ventricular blood is pumped up to pulmonary circulation, only to return to the left side of the heart via the pulmonary veins. Similarly, the aorta on the right forms a closed-system with the right ventricle pumping into the systemic circulation, only for it to return to the right atrium via the vena cava (see figure 6.5). So how is this compatible with life? In short, it is not. Embryonic development can continue because the two looped circulations can mix at the ductus arteriosus and foramen ovale of the fetal circulation. But after birth these shunts between the two circulations MUST be artificially maintained, or the patient must be “fortunate” enough to also have a VSD for mixing to take place.'}"
Figure 6.6,cardio/images/Figure 6.6.jpg,Figure 6.6: Schematic of PDA with flow from the aorta to the pulmonary artery. Thicker lines denote volume overload.,"In utero, the high resistance of the pulmonary circulation ensures that blood is diverted through the ductus arteriosis into the aorta. However, at birth there is a dramatic fall in the resistance of the pulmonary circulation as the lungs inflate. The pressure gradient across the ductus is consequently reversed (low on the pulmonary side, high on the systemic), so if the ductus remains open blood will flow from the aorta to the pulmonary artery (i.e., the opposite direction to fetal circulation) (figure 6.6).","{'cb3ec1c2-1b92-4d52-a7bf-705e9bf6c4ef': 'The ductus arteriosus is part of the fetal circulation allowing blood in the pulmonary artery to bypass the nonfunctional, high resistance lungs and instead traverse into the aorta and systemic circulation. The ductus should close at birth, and failure to do so leaves a patent ductus arteriosus (PDA).', 'd331685f-470c-41e0-978f-1aeb22b0fb60': 'In utero, the high resistance of the pulmonary circulation ensures that blood is diverted through the ductus arteriosis into the aorta. However, at birth there is a dramatic fall in the resistance of the pulmonary circulation as the lungs inflate. The pressure gradient across the ductus is consequently reversed (low on the pulmonary side, high on the systemic), so if the ductus remains open blood will flow from the aorta to the pulmonary artery (i.e., the opposite direction to fetal circulation) (figure 6.6).', 'e3219b6e-0643-4242-8ce2-be68ebbccf30': 'The consequences of this are that a greater volume of blood reenters the pulmonary circulation, the left atria, and the left ventricle. Consequently the compartments of the left heart can eventually fail through volume overload. When the left heart fails, the shunt through the PDA can be reversed, and desaturated blood destined for the pulmonary circulation can end up passing through the PDA to the aorta instead—this reversal later in life is called Eisenmenger syndrome. In Eisenmenger’s the upper extremities receive uncontaminated, saturated blood, as their branching arteries are upstream of the desaturated blood entering the aorta at the PDA. Not so for the lower extremities whose arteries branch after the PDA and so receive low oxygen blood. Hence in Eisenmenger syndrome patients, only the feet are cyanosed.'}"
Figure 6.7,cardio/images/Figure 6.7.jpg,"Figure 6.7: AV Canal with 1) ASD, 2&3) AV valve defects, and 4) VSD.","Complete AV canal defect is a result of complete failure of fusion between endocardial cushions. It is characterized by a primum atrial septal defect (#1, figure 6.7) that is contiguous with a ventricular septal defect (#4 in figure 6.7) and a malformed or common AV valve. Although several forms of this defect exist, this complete form is effectively a single chambered heart.","{'c2876a14-af63-464b-bdaf-f313627386d0': 'Complete AV canal defect is a result of complete failure of fusion between endocardial cushions. It is characterized by a primum atrial septal defect (#1, figure 6.7) that is contiguous with a ventricular septal defect (#4 in figure 6.7) and a malformed or common AV valve. Although several forms of this defect exist, this complete form is effectively a single chambered heart.', '974946a0-a10f-48d8-b255-5854625a572b': 'The malformed valves allow regurgitation, and the unrestricted interventricular communication allow a profound left–right shunt. This leads to volume overload in the pulmonary circulation, and heart failure will be produced if there is no correction. Pulmonary artery hypertension (PAH) and premature development of pulmonary vascular obstructive disease are other common outcomes.'}"
Figure 6.8,cardio/images/Figure 6.8.jpg,Figure 6.8: Truncus arteriosus.,Failed development of the truncoconal septum that normally leads to separation of the pulmonary artery and aorta leads to truncus arteriosus (TA). This condition leads to a single vessel with a single (often incompetent) valve positioned above the ventricular septum (see figure 6.8).,"{'38f7669b-8f52-4a28-859d-6bcf408a76ba': 'Failed development of the truncoconal septum that normally leads to separation of the pulmonary artery and aorta leads to truncus arteriosus (TA). This condition leads to a single vessel with a single (often incompetent) valve positioned above the ventricular septum (see figure 6.8).', 'a4208a50-27fd-43a0-abb7-f887dba520fb': 'The underlying issues with TA are 1) mixing of blood from the left (saturated) and right heart (unsaturated), and 2) the common valve can allow regurgitation. In utero the high pulmonary vascular resistance means most blood exiting the heart goes through the aorta and cardiac output is rarely affected. At birth mild cyanosis can be produced by the mixing of blood from the left and right heart, but as pulmonary vascular resistance remains high in the first few days of life, cardiac output my be maintained. As pulmonary vascular resistance continues to fall in the first few weeks of life, a significant left–right shunt can become established as more left ventricular blood finds it “easier” to ascend up the pulmonary artery. Similar to a VSD, this leads to volume overload in the pulmonary circulation and eventually heart failure. The heart failure has a more rapid onset in TA than VSD if the common valve allows regurgitation. The regurgitation lowers end-diastolic ventricular volumes, so cardiac work to maintain cardiac output increases and promotes myocardial ischemia. Add to this the left–right shunt (as seen in VSD) and heart failure is more likely.'}"
Figure 5.1,cardio/images/Figure 5.1.jpg,Figure 5.1: Normal and abnormal differences in the components of S1 (M1 and T1).,"S1 occurs at the beginning of isovolumetric contraction. The ventricle is beginning to contract, so ventricular pressure quickly rises above atrial pressure and the atrioventricular (tricuspid and mitral) valves close, producing the S1 sound. The mitral valve normally closes slightly (0.04 seconds) before the tricuspid, causing S1 to be “split” (i.e., actually being two sounds, M1 and T1 (figure 5.1)), but the time gap is too short with a normal heart to be detectable with a stethoscope. The reasons for M1 preceding T1 are not clear, but may be due to the force generation of the left ventricle being slightly faster than that of the right ventricle. The splitting of S1 can be more pronounced and audible in the presence of a right bundle branch block (figure 5.1) that causes left ventricular contraction (and mitral valve closure) to markedly precede contraction of the right ventricle. Conversely, in the case of a left bundle branch block, the normal splitting of S1 may be absent (figure 5.1) as M1 is delayed and so occurs in synchrony with T1.","{'5ffbc2bb-1935-4280-878f-182fffd98c9a': 'The first and second sounds (S1 and S2) are the fundamental heart sounds.', '334f25ea-7306-46ac-9e69-58e46df94d20': 'S1 occurs at the beginning of isovolumetric contraction. The ventricle is beginning to contract, so ventricular pressure quickly rises above atrial pressure and the atrioventricular (tricuspid and mitral) valves close,\xa0producing the S1 sound. The mitral valve normally closes slightly (0.04 seconds) before the tricuspid, causing S1 to be “split”\xa0(i.e., actually being two sounds, M1 and T1 (figure 5.1)), but the time gap is too short with a normal heart to be detectable with a stethoscope. The reasons for M1 preceding T1 are not clear, but may be due to the force generation of the left ventricle being slightly faster than that of the right ventricle.\xa0The splitting of S1 can be more pronounced and audible in the presence of a right bundle branch block (figure 5.1) that causes left ventricular contraction (and mitral valve closure) to markedly precede contraction of the right ventricle. Conversely, in the case of a left bundle branch block, the normal splitting of S1 may be absent (figure 5.1) as M1 is delayed and so occurs in synchrony with T1.', '724a9152-0b3a-4764-ba81-4c3120c38cff': 'S2 is caused by closure of the aortic and pulmonic valves at the beginning of isovolumetric ventricular relaxation when ventricular pressure falls below pulmonary and aortic pressure. As aortic pressure (80 mmHg) is far greater than pulmonary artery pressure (10 mmHg), S2 is normally split with two components (A2 and P2) relating to the closure of the aortic and pulmonic valves, respectively. How split A2 and P2 are depend on physiological conditions, primarily the phase of breathing that influences the pulmonary artery pressure. In expiration pulmonary artery pressure is higher, so the pulmonic valve closes earlier and P2 occurs closer to A2. Conversely, during inspiration pulmonary artery pressure falls, so pulmonic valve closing occurs later and A2 and P2 occur further apart (figure 5.2). This physiological splitting can be heard with a stethoscope, but can be further influenced by diseases as listed in table 5.1.', '4d7c531a-16ee-4653-afbd-f021fd27c395': 'Table 5.1: Changes in S2 splitting and possible underlying causes.', 'b85a54b0-6aea-444b-b9c5-1b982105fbc8': 'S3 is associated with the rapid filling phase of the ventricle (when the AV valves open), about 0.14 to 0.16 seconds after S2 (closure of the aortic and pulmonic valves). The exact cause of the sound is unclear, but a normal S3 occurs as a brief, low-frequency vibration. Previously thought to be an intracardiac sound arising from vibrations in the valve cusps or ventricular wall, more recent studies suggest the sound may be due to the filling ventricular wall hitting the inner chest wall, or it may arise from the ventricular apex as it hits a limitation of its longitudinal expansion.', '41134bf7-67fa-419e-b65e-355eba0c75ce': 'Table 5.2: Common causes of abnormal S3.', 'b6f4bdf6-2cdb-4402-978e-0d2c0f12ef68': 'As S3 is a filling sound, an abnormal S3 (higher pitch and referred to as a ventricular gallop) is an important clue to heart failure or volume overload (see table 5.2). The absence of an abnormal S3 does not rule out heart failure, but its presence is a sensitive indicator of ventricular dysfunction. Constriction around the heart (e.g., constrictive pericarditis) may cause an early S3, or “pericardial knock.”', '8e78b9d6-934e-48c2-8d8e-2a605bc52c8b': 'S4 is abnormal and is associated with poor ventricular compliance (e.g., ventricular hypertrophy). It occurs during atrial contraction and is associated with the atrial pressure pulse. The sound is thought to be caused by reverberation of the stiffened ventricular wall as blood is propelled into the ventricle from the atrium (hence it is also known as an atrial gallop). S4 and raised end-diastolic ventricular pressure (EDVP)\xa0commonly occur together as both are\xa0caused by poor ventricular compliance, so S4 tends to be associated with conditions that cause pressure overload (see table 5.3).', '862d6bb6-963f-4074-bc42-16be655a662e': 'Table 5.3: Common causes of abnormal S4.', '1f6b22d4-bf70-4b81-afa4-729a627cdae7': 'As S1 and S2 occur during closure of heart valves, pathological conditions can lead to the valves producing a high-frequency “clicking”\xa0sound when they open during chamber ejection—hence they can be referred to as ejection sounds and they are pathological.', 'a2f5be91-51f5-4d63-bf3e-f8125ee88346': 'Aortic ejection sounds usually occur 0.12–0.14 seconds after the Q-wave of the ECG (i.e., after ventricular pressure has risen to exceed aortic pressure). Because of its timing, the “click” produced can be misinterpreted as a split S1. The abnormal opening of the aortic valve is usually caused by a deformed but mobile valve leaflet or aortic root dilation that may be caused by the conditions listed in table 5.4.', '7e8d8d0a-4d81-4e44-982a-bcec6f5b34c6': 'Pulmonary ejection sounds occur a little earlier (0.09–0.11 seconds) after the Q-wave as the pulmonary valve opens a little earlier (figure 5.1). It can also be distinguished by the fact that its\xa0intensity is diminished during inspiration as increased venous return during inspiration augments the effect of atrial contraction and causes a “gentler” opening of the valve. As with the aortic ejection sounds, pulmonary ejection sounds are associated with deformed valves or pulmonary arterial dilation.', '1b153493-e775-4028-9b43-5efb5d11fad0': 'A click occurring in diastole is associated with abnormal opening of either the mitral or tricuspid valve. Similar to systolic clicks, a diastolic click can be misinterpreted as a split S2. The most common cause of diastolic clicks is valvular stenosis of an AV valve.', '1615eacf-7f87-43a8-b7b5-a3cb428b9d53': 'Table 5.4: Common causes of ejection ""clicks.""'}"
Figure 5.2,cardio/images/Figure 5.2.jpg,Figure 5.2: Normal splitting of S2 with inspiration.,"S2 is caused by closure of the aortic and pulmonic valves at the beginning of isovolumetric ventricular relaxation when ventricular pressure falls below pulmonary and aortic pressure. As aortic pressure (80 mmHg) is far greater than pulmonary artery pressure (10 mmHg), S2 is normally split with two components (A2 and P2) relating to the closure of the aortic and pulmonic valves, respectively. How split A2 and P2 are depend on physiological conditions, primarily the phase of breathing that influences the pulmonary artery pressure. In expiration pulmonary artery pressure is higher, so the pulmonic valve closes earlier and P2 occurs closer to A2. Conversely, during inspiration pulmonary artery pressure falls, so pulmonic valve closing occurs later and A2 and P2 occur further apart (figure 5.2). This physiological splitting can be heard with a stethoscope, but can be further influenced by diseases as listed in table 5.1.","{'5ffbc2bb-1935-4280-878f-182fffd98c9a': 'The first and second sounds (S1 and S2) are the fundamental heart sounds.', '334f25ea-7306-46ac-9e69-58e46df94d20': 'S1 occurs at the beginning of isovolumetric contraction. The ventricle is beginning to contract, so ventricular pressure quickly rises above atrial pressure and the atrioventricular (tricuspid and mitral) valves close,\xa0producing the S1 sound. The mitral valve normally closes slightly (0.04 seconds) before the tricuspid, causing S1 to be “split”\xa0(i.e., actually being two sounds, M1 and T1 (figure 5.1)), but the time gap is too short with a normal heart to be detectable with a stethoscope. The reasons for M1 preceding T1 are not clear, but may be due to the force generation of the left ventricle being slightly faster than that of the right ventricle.\xa0The splitting of S1 can be more pronounced and audible in the presence of a right bundle branch block (figure 5.1) that causes left ventricular contraction (and mitral valve closure) to markedly precede contraction of the right ventricle. Conversely, in the case of a left bundle branch block, the normal splitting of S1 may be absent (figure 5.1) as M1 is delayed and so occurs in synchrony with T1.', '724a9152-0b3a-4764-ba81-4c3120c38cff': 'S2 is caused by closure of the aortic and pulmonic valves at the beginning of isovolumetric ventricular relaxation when ventricular pressure falls below pulmonary and aortic pressure. As aortic pressure (80 mmHg) is far greater than pulmonary artery pressure (10 mmHg), S2 is normally split with two components (A2 and P2) relating to the closure of the aortic and pulmonic valves, respectively. How split A2 and P2 are depend on physiological conditions, primarily the phase of breathing that influences the pulmonary artery pressure. In expiration pulmonary artery pressure is higher, so the pulmonic valve closes earlier and P2 occurs closer to A2. Conversely, during inspiration pulmonary artery pressure falls, so pulmonic valve closing occurs later and A2 and P2 occur further apart (figure 5.2). This physiological splitting can be heard with a stethoscope, but can be further influenced by diseases as listed in table 5.1.', '4d7c531a-16ee-4653-afbd-f021fd27c395': 'Table 5.1: Changes in S2 splitting and possible underlying causes.', 'b85a54b0-6aea-444b-b9c5-1b982105fbc8': 'S3 is associated with the rapid filling phase of the ventricle (when the AV valves open), about 0.14 to 0.16 seconds after S2 (closure of the aortic and pulmonic valves). The exact cause of the sound is unclear, but a normal S3 occurs as a brief, low-frequency vibration. Previously thought to be an intracardiac sound arising from vibrations in the valve cusps or ventricular wall, more recent studies suggest the sound may be due to the filling ventricular wall hitting the inner chest wall, or it may arise from the ventricular apex as it hits a limitation of its longitudinal expansion.', '41134bf7-67fa-419e-b65e-355eba0c75ce': 'Table 5.2: Common causes of abnormal S3.', 'b6f4bdf6-2cdb-4402-978e-0d2c0f12ef68': 'As S3 is a filling sound, an abnormal S3 (higher pitch and referred to as a ventricular gallop) is an important clue to heart failure or volume overload (see table 5.2). The absence of an abnormal S3 does not rule out heart failure, but its presence is a sensitive indicator of ventricular dysfunction. Constriction around the heart (e.g., constrictive pericarditis) may cause an early S3, or “pericardial knock.”', '8e78b9d6-934e-48c2-8d8e-2a605bc52c8b': 'S4 is abnormal and is associated with poor ventricular compliance (e.g., ventricular hypertrophy). It occurs during atrial contraction and is associated with the atrial pressure pulse. The sound is thought to be caused by reverberation of the stiffened ventricular wall as blood is propelled into the ventricle from the atrium (hence it is also known as an atrial gallop). S4 and raised end-diastolic ventricular pressure (EDVP)\xa0commonly occur together as both are\xa0caused by poor ventricular compliance, so S4 tends to be associated with conditions that cause pressure overload (see table 5.3).', '862d6bb6-963f-4074-bc42-16be655a662e': 'Table 5.3: Common causes of abnormal S4.'}"
Figure 5.1,cardio/images/Figure 5.1.jpg,Figure 5.1: Normal and abnormal differences in the components of S1 (M1 and T1).,"S1 occurs at the beginning of isovolumetric contraction. The ventricle is beginning to contract, so ventricular pressure quickly rises above atrial pressure and the atrioventricular (tricuspid and mitral) valves close, producing the S1 sound. The mitral valve normally closes slightly (0.04 seconds) before the tricuspid, causing S1 to be “split” (i.e., actually being two sounds, M1 and T1 (figure 5.1)), but the time gap is too short with a normal heart to be detectable with a stethoscope. The reasons for M1 preceding T1 are not clear, but may be due to the force generation of the left ventricle being slightly faster than that of the right ventricle. The splitting of S1 can be more pronounced and audible in the presence of a right bundle branch block (figure 5.1) that causes left ventricular contraction (and mitral valve closure) to markedly precede contraction of the right ventricle. Conversely, in the case of a left bundle branch block, the normal splitting of S1 may be absent (figure 5.1) as M1 is delayed and so occurs in synchrony with T1.","{'5ffbc2bb-1935-4280-878f-182fffd98c9a': 'The first and second sounds (S1 and S2) are the fundamental heart sounds.', '334f25ea-7306-46ac-9e69-58e46df94d20': 'S1 occurs at the beginning of isovolumetric contraction. The ventricle is beginning to contract, so ventricular pressure quickly rises above atrial pressure and the atrioventricular (tricuspid and mitral) valves close,\xa0producing the S1 sound. The mitral valve normally closes slightly (0.04 seconds) before the tricuspid, causing S1 to be “split”\xa0(i.e., actually being two sounds, M1 and T1 (figure 5.1)), but the time gap is too short with a normal heart to be detectable with a stethoscope. The reasons for M1 preceding T1 are not clear, but may be due to the force generation of the left ventricle being slightly faster than that of the right ventricle.\xa0The splitting of S1 can be more pronounced and audible in the presence of a right bundle branch block (figure 5.1) that causes left ventricular contraction (and mitral valve closure) to markedly precede contraction of the right ventricle. Conversely, in the case of a left bundle branch block, the normal splitting of S1 may be absent (figure 5.1) as M1 is delayed and so occurs in synchrony with T1.', '724a9152-0b3a-4764-ba81-4c3120c38cff': 'S2 is caused by closure of the aortic and pulmonic valves at the beginning of isovolumetric ventricular relaxation when ventricular pressure falls below pulmonary and aortic pressure. As aortic pressure (80 mmHg) is far greater than pulmonary artery pressure (10 mmHg), S2 is normally split with two components (A2 and P2) relating to the closure of the aortic and pulmonic valves, respectively. How split A2 and P2 are depend on physiological conditions, primarily the phase of breathing that influences the pulmonary artery pressure. In expiration pulmonary artery pressure is higher, so the pulmonic valve closes earlier and P2 occurs closer to A2. Conversely, during inspiration pulmonary artery pressure falls, so pulmonic valve closing occurs later and A2 and P2 occur further apart (figure 5.2). This physiological splitting can be heard with a stethoscope, but can be further influenced by diseases as listed in table 5.1.', '4d7c531a-16ee-4653-afbd-f021fd27c395': 'Table 5.1: Changes in S2 splitting and possible underlying causes.', 'b85a54b0-6aea-444b-b9c5-1b982105fbc8': 'S3 is associated with the rapid filling phase of the ventricle (when the AV valves open), about 0.14 to 0.16 seconds after S2 (closure of the aortic and pulmonic valves). The exact cause of the sound is unclear, but a normal S3 occurs as a brief, low-frequency vibration. Previously thought to be an intracardiac sound arising from vibrations in the valve cusps or ventricular wall, more recent studies suggest the sound may be due to the filling ventricular wall hitting the inner chest wall, or it may arise from the ventricular apex as it hits a limitation of its longitudinal expansion.', '41134bf7-67fa-419e-b65e-355eba0c75ce': 'Table 5.2: Common causes of abnormal S3.', 'b6f4bdf6-2cdb-4402-978e-0d2c0f12ef68': 'As S3 is a filling sound, an abnormal S3 (higher pitch and referred to as a ventricular gallop) is an important clue to heart failure or volume overload (see table 5.2). The absence of an abnormal S3 does not rule out heart failure, but its presence is a sensitive indicator of ventricular dysfunction. Constriction around the heart (e.g., constrictive pericarditis) may cause an early S3, or “pericardial knock.”', '8e78b9d6-934e-48c2-8d8e-2a605bc52c8b': 'S4 is abnormal and is associated with poor ventricular compliance (e.g., ventricular hypertrophy). It occurs during atrial contraction and is associated with the atrial pressure pulse. The sound is thought to be caused by reverberation of the stiffened ventricular wall as blood is propelled into the ventricle from the atrium (hence it is also known as an atrial gallop). S4 and raised end-diastolic ventricular pressure (EDVP)\xa0commonly occur together as both are\xa0caused by poor ventricular compliance, so S4 tends to be associated with conditions that cause pressure overload (see table 5.3).', '862d6bb6-963f-4074-bc42-16be655a662e': 'Table 5.3: Common causes of abnormal S4.', '1f6b22d4-bf70-4b81-afa4-729a627cdae7': 'As S1 and S2 occur during closure of heart valves, pathological conditions can lead to the valves producing a high-frequency “clicking”\xa0sound when they open during chamber ejection—hence they can be referred to as ejection sounds and they are pathological.', 'a2f5be91-51f5-4d63-bf3e-f8125ee88346': 'Aortic ejection sounds usually occur 0.12–0.14 seconds after the Q-wave of the ECG (i.e., after ventricular pressure has risen to exceed aortic pressure). Because of its timing, the “click” produced can be misinterpreted as a split S1. The abnormal opening of the aortic valve is usually caused by a deformed but mobile valve leaflet or aortic root dilation that may be caused by the conditions listed in table 5.4.', '7e8d8d0a-4d81-4e44-982a-bcec6f5b34c6': 'Pulmonary ejection sounds occur a little earlier (0.09–0.11 seconds) after the Q-wave as the pulmonary valve opens a little earlier (figure 5.1). It can also be distinguished by the fact that its\xa0intensity is diminished during inspiration as increased venous return during inspiration augments the effect of atrial contraction and causes a “gentler” opening of the valve. As with the aortic ejection sounds, pulmonary ejection sounds are associated with deformed valves or pulmonary arterial dilation.', '1b153493-e775-4028-9b43-5efb5d11fad0': 'A click occurring in diastole is associated with abnormal opening of either the mitral or tricuspid valve. Similar to systolic clicks, a diastolic click can be misinterpreted as a split S2. The most common cause of diastolic clicks is valvular stenosis of an AV valve.', '1615eacf-7f87-43a8-b7b5-a3cb428b9d53': 'Table 5.4: Common causes of ejection ""clicks.""'}"
Figure 4.1,cardio/images/Figure 4.1.jpg,Figure 4.1: Histological view of the ossification of valve tissue with osteoblast-like cells clustered in the center of the field of view. These cells are responsible for the calcification and consequent stiffening of the valve leaflet.,"The constant stress of facing high flow and pressure over thirty to forty million cardiac contractions a year is not without its consequences, and the most common valvular disorder is calcification that comes with “wear-and-tear” and aging. The presence of other factors such as hyperlipidemia, hypertension, and inflammation accelerate this process and promote the deposition of hydroxyapatite (a form of calcium phosphate), and the valve structure contains cells that resemble osteoblasts (figure 4.1).","{'8c6e0429-e47f-4997-a67a-ddf069d958f5': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Ischemic Heart Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 6. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'f418f90a-4b61-47fe-9986-92500c9a8db6': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Acute Coronary Syndromes.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 7. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0d5c9a9d-0b35-43ee-a67d-f78f5b489c22': 'Surawicz, Borys, Rory Childers, Barbara J. Deal, and Leonard S. Gettes. “AHA/ACCF/HRS Recommendations for the Standardization and Interpretation of the Electrocardiogram.” Circulation 119, no. 10 (2009): e235–e240.', '60ff9e9a-c126-471e-99f6-c12310ca27fc': 'Surawicz, Borys, and Timothy Knilans. Chou’s Electrocardiography in Practice, 6th ed. Philadelphia: Saunders, 2008.', '338365cf-229f-462a-a031-98082c43433e': 'Bhansali, Suneet, and Colin Phoon.\xa0Truncus Arteriosis. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK534774/,\xa0CC BY 4.0.', '995ee375-aece-4390-b26d-9b4c9f312271': 'Cunningham, Jonathan W., and David W. Brown. “Congenital Heart Disease.” In\xa0Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, edited by Leonard S. Lilly, Chapter 16. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2012.', '840aca0a-c487-491a-b695-a8457d2cbc98': 'Dakkak, Wael, and Tony I. Oliver.\xa0Ventricular Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK470330/,\xa0CC BY 4.0.', '51d7dd59-efef-49b1-b87a-858bd257fe67': 'Diaz-Frias, Josua, and Melissa Guillaume.\xa0Tetralogy of Fallot. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK513288/,\xa0CC BY 4.0.', 'c7943f22-f9f3-4d59-b486-0d892d7fc01d': 'Gillam-Krakauer, Maria, and Kunal Mahajan.\xa0Patent Ductus Ateriosus. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', 'eb6a5536-2fab-49e9-8fea-fb6dfd90ac7e': 'Law, Mark A., and Vijai\xa0 S. Tivakaran.\xa0Coarctation of the Aorta. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430913/,\xa0CC BY 4.0.', '7dab3894-5603-4e66-a595-a4a501477845': 'Menillo, Alexandra M., Lawrence S. Lee, and Anthony L. Pearson-Shaver.\xa0Atrial Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK535440/,\xa0CC BY 4.0.', '477bb241-ffa8-4452-b076-05fd90b9111e': 'Szymanski, Michael W., Sheila M. Moore, Stacy M. Kritzmire, and Amandeep Goyal.\xa0Transposition of the Great Arteries. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', '740f1bed-fa6b-4651-a963-90a31353aa51': 'Umapathi, Krishna Kishore, and Pradyumna Agasthi.\xa0Atrioventricular Canal Defects.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK557511/,\xa0CC BY 4.0.', 'ade10988-52d5-40bb-a747-06d819e62b55': 'Dornbush, Sean, and Andre E. Turnquest. Physiology, Heart Sounds. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK541010, CC BY 4.0.', '1d13203a-5404-4ba4-abaa-6b5f3df36f97': 'Kulkarni, Vivek T., and Leonard S. Lilly. “The Cardiac Cycle: Mechanisms of Heart Sounds and Murmurs.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 2. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '3f337c79-9677-4c2d-8bca-e53e383a902f': 'Thomas, Seth L., Joseph Heaton, and Amgad N. Makaryus. Physiology, Cardiovascular Murmurs. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK525958, CC BY 4.0.', '79ed1809-c439-4208-b3fb-eabdea6a3c5c': 'Table 5.5: Classifications of heart murmurs. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/5.5_20220113', '0d9a3874-61bf-4706-bc3b-cd7d9ea2021c': 'Abnormalities of valvular structure and/or function can either be congenital or acquired. Acquired valvular disease is by far the most common and is most prevalent in the elderly. The high blood flow and pressures that valves are exposed to make them particularly susceptible to other risk factors that promote valvular damage (see table 4.1). Congenital valvular defects arise from disrupted heart development, about 50 percent\xa0of which involve the valves. The impact of congenital defects has diminished with the advent of advanced detection techniques.\xa0What we will spend time on in this chapter is the main instigating factors and pathologies that result\xa0in acquired valvular defects.', 'ccc9c78e-3005-40ab-baac-35ac9036e771': 'Table 4.1: Risk factors for acquired valvular damage.', '9098edeb-f4b5-4b10-aa41-7ecc7e039310': 'The constant stress of facing high flow and pressure over thirty to forty\xa0million cardiac contractions a year is not without its consequences, and the most common valvular disorder is calcification that comes with “wear-and-tear”\xa0and aging. The presence of other factors such as hyperlipidemia, hypertension, and inflammation accelerate this process and promote the deposition of hydroxyapatite (a form of calcium phosphate), and the valve structure contains cells that resemble osteoblasts (figure 4.1).', '8e9c7284-ff78-4170-bdb5-1bb9aa034b4b': 'As they face the most pressure, the aortic and mitral valves are more prone to calcification. The most common pattern of calcification in the aortic valve is mounded masses within the cusps of the valve (see table\xa04.2) that eventually fuse and stop the valve from opening fully.\xa0Calcification in the mitral valve\xa0tends to start in the fibrous annulus, which does not\xa0impact valvular function to the same extent, but in exceptional cases can cause regurgitation or stenosis, or even arrhythmias as calcium deposits impinge on the atrioventricular conduction system (see table\xa04.2).', '56ee9369-4764-475a-bf47-8192d06fa092': 'Table 4.2: Location of calcium deposits on aortic and mitral valves and their pathological consequences.', '87a6622f-680a-4032-acf2-22d1a3d06a57': 'Dass, Clarissa, and Arun Kanmanthareddy. Rheumatic Heart Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK538286/, CC BY 4.0.', '01571255-0baf-4ad1-abdb-c3c38901b4f1': 'Douedi, Steven, and Hani Douedi. Mitral Regurgitation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK553135/, CC BY 4.0.', '7f9e8792-d353-4380-b72b-10095d2e32d2': 'Lopez, Diana M., Patrick T. O’Gara, and Leonard S. Lilly. “Valvular Heart\xa0 Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 8. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0b92e173-7511-4e4f-a01c-46a261d63327': 'Wenn, Peter, and Roman Zeltser. Aortic Valve Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK542205/, CC BY 4.0.', '1ae0ec16-694d-4b2e-9c46-4f16ca1187bc': 'Table 4.1: Location of calcium deposits on aortic and mitral valves and their pathological consequences. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/4.2a_20220113', '36cfa87f-cb4a-40da-be59-3fe09efefb82': 'The current guidelines (JNC 8, 2017) list the following pressures and categories to define hypertension:', '043d0a6c-c109-49d3-864d-1049ae0bab92': 'Brown, Jenifer M., Gordon H. Williams, and Leonard S. Lilly. “Hypertension.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 13. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '6a1b6fe6-83fe-406c-9e01-1a06a4791350': 'Hajar, Rachel. “Framingham Contribution to Cardiovascular Disease.” Heart Views 17, no. 2 (April–June 2016): 78–81. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4966216.', 'b09e6339-ed87-40ae-b475-924c98e1a575': 'Iqbal, Arshad Muhammad, and Syed F. Jaml. Essential Hypertension. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK539859/, CC BY 4.0.', 'df8f6825-cd8d-4f33-a3b6-3aa95e2b7231': 'Page, Michael R. “The JNC 8 Hypertension Guidelines: An In-Depth Guide.” Evidence-Based Diabetes Management 20, no. SP1\xa0 (January 2014). https://www.ajmc.com/view/the-jnc-8-hypertension-guidelines-an-in-depth-guide.', '542c40cb-0157-4bdb-8e18-253f38324396': 'For whichever reason the end effect of the failure is a decline in blood flow out of the heart, and consequently congestion on the way in.', '7793dbfa-5e5b-4555-9631-e10c6b1d4a99': 'Table 2.1: Changes in cardiac function in different disease states.', '810dee93-c004-4109-b99d-0c58c90f8bc4': 'Impediments to emptying the heart during systole (i.e., a reduced contractility or increased afterload) were\xa0referred to as systolic heart failure. Similarly, problems with filling the ventricle during diastole were referred to as diastolic heart failure (figure 2.1).', '9d443965-9456-4656-a0f9-1e1e37fce404': 'In reality there is a great deal of overlap between these forms of heart failure, and elements of both can be present in the same patient. Similarly, as both forms result in congestion before the heart and reduced flow after it, they are hard to immediately distinguish. Consequently the type and degree of failure is now categorized by the effect on ejection fraction that can help distinguish the source of the problem.', '33c5d98f-6bcc-40b2-9a97-f4a5cf465f1c': 'Let us quickly remind ourselves of what ejection fraction is. Ejection fraction is the proportion of blood volume that the left ventricle ejects in one beat. It is mathematically described as the starting volume (i.e., end-diastolic volume, EDV) minus the finishing volume (i.e., end-systolic volume, ESV) as a proportion of the starting volume (figure 2.2)—in simpler terms, what percentage of the ventricular blood volume was pushed out during a contraction.', '0dade292-7120-4fea-a845-e26eeb3159a3': 'Eberly, Lauren A., Eldrin F. Lewis, and Leonard S. Lilly. “Heart Failure.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 9. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'd3239a6f-3c3d-4562-9ca8-835f21d500e2': 'Malik, Ahmad, Daniel Brito, Sarosh Vaqar, and Lovely Chhabra. Congestive Heart Failure. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK430873/, CC BY 4.0.', '25e09e1a-9d83-488d-ad5f-1fbe028f8fb0': 'Burns, Ed, and Robert Buttner. Hypercalcaemia. Lift in the Fast Lane, 2021. https://litfl.com/hypercalcaemia-ecg-library/, CC BY 4.0.', '98b0eb2b-328b-4f37-95d0-4a1d717348c2': 'Burns, Ed, and Robert Buttner. Hypocalcaemia. Life in the Fast Lane, 2021. https://litfl.com/hypocalcaemia-ecg-library/, CC BY 4.0.', '924eb71e-f15c-45cf-a207-17b43a28255e': 'Buttner, Robert, and Ed Burns. Hyperkalaemia. Life in the Fast Lane. https://litfl.com/hyperkalaemia-ecg-library/, CC BY 4.0.', '3f6b51a5-0594-4ad0-aff0-def446f6da9d': 'Buttner, Robert, and Ed Burns. Hypokalaemia. Life in the Fast Lane, 2021. https://litfl.com/hypokalaemia-ecg-library/, CC BY 4.0.', 'c2ec9ebd-39e6-4027-8d33-99309d013968': 'Chhabra, Lovely, Amandeep Goyal, and Michael D. Benham. Wolff Parkinson White Syndrome. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK554437/, CC BY 4.0.', 'de0f5e7f-54b2-4ef7-80ca-92553b8b6171': 'Custer, Adam M., Varun S. Yelamanchili, and Sarah L. Lappin. Multifocal Atrial Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459152/, CC BY 4.0.', '3e262579-d93b-409b-983d-96ddc6f0517c': 'Farzam, Khashayar, and John R. Richards. Premature Ventricular Contraction. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532991/, CC BY 4.0.', '7328f663-c5ef-4e2f-ade4-a4211caf5868': 'Foth, Christopher, Manesh Kumar Gangwani, and Heidi Alvey. Ventricular Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532954/, CC BY 4.0.', 'fc065c88-8e7e-4e26-a309-85650123fb33': 'Hafeez, Yamama, and Shamai A. Grossman. Sinus Bradycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK493201/, CC BY 4.0.', 'f1595d60-c9c3-4d6b-ba3b-44af48991758': 'Harkness, Weston T., and Mary Hicks. Right Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK507872/, CC BY 4.0.', 'd2624d0f-ba5a-421e-b634-e2a663b7ab7e': 'Heaton, Joseph, and Srikanth Yandrapalli. Premature Atrial Contractions. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK559204/, CC BY 4.0.', 'dcf93591-9453-4b52-a6ad-1aca2b965dd9': 'Kashou, Anthony H., Amandeep Goyal, Tran Nguyen, and Lovely Chhabra. Atrioventricular Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459147/, CC BY 4.0.', '54fd1955-7dcf-474e-a1c7-48be82daaf68': '“Learn the Heart.” Healio. https://www.healio.com/cardiology/learn-the-heart.', 'd631c93d-f5f0-400a-84c4-7fbe032819dc': 'Ludhwani, Dipesh, Amandeep Goyal, and Mandar Jagtap. Ventricular Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK537120/, CC BY 4.0.', '23d28e5a-2755-4f59-a997-fe25fb642627': 'Nesheiwat, Zeid, Amandeep Goyal, and Mandar Jagtap. Atrial Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK526072/, CC BY 4.0.', 'c652c067-fadb-4dcb-b5b7-c4507437ffd4': 'Pipilas, Daniel C., Bruce A. Koplan, and Leonard S. Lilly. “The Electrocardiogram.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 4. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '7c80cf5c-7fd6-4813-bb3d-279ddffa421e': 'Rodriguez Ziccardi, Mary, Amandeep Goyal, and Christopher V. Maani. Atrial Flutter. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK540985/, CC BY 4.0.', '9c33cea2-2522-4f34-b5de-1bb5ae1c0182': 'Scherbak, Dmitriy, and Gregory J. Hicks. Left Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK482167/, CC BY 4.0.'}"
Figure 4.2,cardio/images/Figure 4.2.jpg,Figure 4.2Mitral valve prolapse.,"A prolapsed mitral valve is one where one or both leaflets have become floppy and capable of ballooning back into the left atrium during systole (figure 4.2). The condition is more common in women, affects 2–3 percent of adults in the United States, and can be a secondary effect of mitral valve regurgitation.","{'25e1bb25-ef77-49ee-becc-697b567b01d0': 'A prolapsed mitral valve is one where one or both leaflets have become floppy and\xa0capable of ballooning back into the left atrium during systole (figure 4.2). The condition is more common in women, affects 2–3 percent of adults in the United States,\xa0and can be a secondary effect of mitral valve regurgitation.', '83ad3463-bd48-4a5d-9550-96ee5e4586ac': 'The causes of MVP are usually unidentified, but a few cases can be attributed to inherited connective tissue disorders such as Marfan syndrome. The prolapsed valve leaflet composition is enlarged and thickened with deposition of myxomatous material rich in proteoglycans, and a reduction in the structurally critical fibrosa layer where a higher prevalence of type III collagen (a more stretchy than structural form of collagen) is found.', '3830bcdf-10ca-46bc-b1c6-da084e9eb154': 'The flapping valve structure can cause secondary fibrosis on the structures it strikes, such as the leaflet edges or the endocardium where the abnormally elongated cords rub. The agitation may also promote thrombus formation in the atrium.', '071facc2-9ef2-4958-bb2d-ef391a7e20cf': 'The resultant floppy leaflet can be detected by a midsystolic click,\xa0and any associated incompetence may produce a late-systolic murmur (summary in figure 4.2). MVP is usually asymptomatic, but potential complications include:'}"
Figure 4.3,cardio/images/Figure 4.3.jpg,Figure 4.3: Pathophysiology of rheumatic heart disease.,"The chronic effects involve an immune cross-reaction between the antibodies and CD4+ T-cells directed against the streptococcal M proteins and cardiac self-antigens. Antibody binding and T-cell activity toward the cardiac antigens activate complement and recruit neutrophils and macrophages toward the valve tissue. The damage they produce includes histologically distinct lesions called Aschoff bodies (figure 4.3), and plump activated macrophages called Anitschkow cells (or caterpillar cells) appear in the effected areas (figure 4.3). All layers of the myocardium can be effected, but the valves can show leaflet thickening and fusion as well as shortened, thickened cords. Vegetative verrucae are associated with the necrotic fibrinoid foci, making RHD one of the vegetative forms of valvular disease.","{'2093f797-eecd-4860-b20e-322f80a0b697': 'Rheumatic heart disease (RHD) is virtually the only cause of mitral valve stenosis. It arises after a group A streptococcal infection that often originates in the upper airway and leads to rheumatic fever (a multisystem, immune-mediated disease). The incidence in developed countries is relatively low because of rapid diagnosis and treatment of the instigating pharyngitis, but in poor, crowed, urban areas RHD remains an important health issue.', '360fb267-07a9-402e-9a7e-438c6986ea70': 'The acute results of rheumatic fever occur days to weeks after the streptococcal infection, and while the initial pharyngeal infection may have cleared and the test results have become\xa0negative, the antibodies to the streptococcal enzymes (Streptolysin O and DNase B) can still be detected. The initial cardiac effects include carditis, pericardial rubs, tachycardia, and arrhythmias. However, the chronic effects may arise years or even decades later.', 'e933abed-192e-441f-b157-fbf11ce31326': 'The chronic effects involve an immune cross-reaction between the antibodies and CD4+ T-cells directed against the streptococcal M proteins and cardiac self-antigens. Antibody binding and T-cell activity toward the cardiac antigens activate complement and recruit neutrophils and macrophages toward\xa0the valve tissue. The damage they produce includes histologically distinct lesions called Aschoff bodies (figure 4.3), and plump activated macrophages called Anitschkow cells (or caterpillar cells) appear in the effected areas (figure 4.3). All layers of the myocardium can be effected, but the valves can show leaflet thickening and fusion as well as shortened, thickened cords. Vegetative verrucae are associated with the necrotic fibrinoid foci,\xa0making RHD one\xa0of the vegetative forms of valvular disease.', 'fabf8aa6-13d8-4527-8773-5aaca4242bc6': 'As the valve thickens it can become calcified as well, and the adhered leaflets produce a “fish-mouth”\xa0or “button hole”\xa0appearance \xa0that causes the valve to narrow. The damage is cumulative with the increased turbulence through a stenosed valve perpetuating the fibrotic process (see summary in figure 4.3).'}"
Figure 4.4,cardio/images/Figure 4.4.jpg,Figure 4.4: Vegetative lesions (in white box) associated with IE.,"Most incidence of IE start with fever, but it can also manifest as nonspecific fatigue, weight loss, or flu-like symptoms in older adults. The infection leads to vegetations on the valve that are the hallmark of IE (figure 4.4). These lesions contain fibrin, inflammatory cells, and bacteria.","{'4d708ee1-4455-43f5-bbcf-2b98b7d02e96': 'Infective endocarditis (IE) is divided into acute and subacute forms, depending on the virulence of the causal pathogen. Acute IE is rapid in onset and involves highly destructive pathogens that cause necrosis and significant lesions that can lead to death in a matter of days. Subacute IE, alternatively,\xa0can deform the valves over weeks to months and generally involves a much less destructive pathogen.', 'b4efabae-c886-41e7-afdd-30e3c3e1fde1': 'Acute cases tend to involve healthy individuals and are responsible for 20 to 30 percent\xa0of cases, whereas the less virulent pathogens that cause subacute IE tend to need a foothold and only affect previously damaged or deformed valves.', '208863b0-d700-491e-a56c-57d15fcf0459': 'Most incidence of IE start with fever, but it can also manifest as nonspecific fatigue, weight loss, or flu-like symptoms in older adults.\xa0The infection leads to vegetations on the valve that are the hallmark of IE (figure 4.4). These lesions contain fibrin, inflammatory cells, and bacteria.'}"
Figure 4.5,cardio/images/Figure 4.5.jpg,"Figure 4.5: Signs of IE include Janeway lesions (left), Osler nodes (middle), and Roth spots (right).","After a few weeks, complications arise that are the product of immune complex deposition or emboli. They can include glomerulonephritis as immune complexes become embedded in the glomerular basement membrane. Other later complications are now rare due to early detection and effective treatment but can include microthromboemboli that produce splinter or subungual lesions. Other hemorrhagic signs include Janeway lesions on the palms or soles, Osler nodes on the fingers, or Roth spots on the retina (figure 4.5).","{'2ada3b7c-1dd9-4458-a070-a1cf8b01ba05': 'After a few weeks, complications arise that are the product of immune complex deposition or emboli. They can include glomerulonephritis as immune complexes become embedded in the glomerular basement membrane. Other later complications are now rare due to early detection and effective treatment but can include microthromboemboli that produce splinter or subungual lesions. Other hemorrhagic signs include Janeway lesions on the palms or soles, Osler nodes on the fingers, or Roth spots on the retina (figure 4.5).'}"
Figure 4.6,cardio/images/Figure 4.6.jpg,Figure 4.6: NBTE with small thrombi binding to valve leaflets.,"Often coinciding with emboli in other sites, NBTE occurs in states of hypercoagulability, such as in cancer or sepsis. The small thrombi (1–5 mm) bind to the valve leaflets (figure 4.6), but do not illicit an inflammatory response nor are they invasive. Often the local consequences are trivial, but they can be the source of emboli that lead to infarcts in the brain, heart, or elsewhere.","{'d7a40cbf-0c72-4cc8-9b48-8f359276ee39': 'Some vegetations are sterile\xa0(i.e., occur in the absence of infection). There are two main examples of this—nonbacterial thrombotic endocarditis (NBTE) and the systemic lupus erythematosus (SLE).', '9735b804-9384-4972-8801-65b4137d8a8a': 'Often coinciding with emboli in other sites, NBTE occurs in states of hypercoagulability, such as in cancer or sepsis. The small thrombi (1–5 mm) bind to the valve leaflets (figure 4.6), but do not illicit an inflammatory response nor are they invasive. Often the local consequences are trivial, but they can be the source of emboli that lead to\xa0infarcts in the brain, heart, or elsewhere.', 'fc5b8240-74d4-4363-8ff2-89da75b67d46': 'In SLE, the vegetations are again sterile and small (1–4\xa0mm) with a pink, wart-like appearance that are composed of eosinophilic material, granular material, and cellular debris. They tend to adhere to the undersurfaces of the atrioventricular valves, the valvular endocardium, and the cords (figure 4.7). Unlike NBTE, the vegetations can instigate complement and Fc-bearing cells that cause intense valvulitis. The end product of this is referred to as Libman Sacks disease.'}"
Figure 4.7,cardio/images/Figure 4.7.jpg,Figure 4.7: Small “wart-like vegetations” in the cords of a valve.,"In SLE, the vegetations are again sterile and small (1–4 mm) with a pink, wart-like appearance that are composed of eosinophilic material, granular material, and cellular debris. They tend to adhere to the undersurfaces of the atrioventricular valves, the valvular endocardium, and the cords (figure 4.7). Unlike NBTE, the vegetations can instigate complement and Fc-bearing cells that cause intense valvulitis. The end product of this is referred to as Libman Sacks disease.","{'d7a40cbf-0c72-4cc8-9b48-8f359276ee39': 'Some vegetations are sterile\xa0(i.e., occur in the absence of infection). There are two main examples of this—nonbacterial thrombotic endocarditis (NBTE) and the systemic lupus erythematosus (SLE).', '9735b804-9384-4972-8801-65b4137d8a8a': 'Often coinciding with emboli in other sites, NBTE occurs in states of hypercoagulability, such as in cancer or sepsis. The small thrombi (1–5 mm) bind to the valve leaflets (figure 4.6), but do not illicit an inflammatory response nor are they invasive. Often the local consequences are trivial, but they can be the source of emboli that lead to\xa0infarcts in the brain, heart, or elsewhere.', 'fc5b8240-74d4-4363-8ff2-89da75b67d46': 'In SLE, the vegetations are again sterile and small (1–4\xa0mm) with a pink, wart-like appearance that are composed of eosinophilic material, granular material, and cellular debris. They tend to adhere to the undersurfaces of the atrioventricular valves, the valvular endocardium, and the cords (figure 4.7). Unlike NBTE, the vegetations can instigate complement and Fc-bearing cells that cause intense valvulitis. The end product of this is referred to as Libman Sacks disease.'}"
Figure 4.8,cardio/images/Figure 4.8.jpg,Figure 4.8: Release of inflammatory mediators from neuroendocrine tumors leading to carcinoid heart disease.,"Lastly, carcinoid heart disease is the cardiac manifestation of carcinoid syndrome. Carcinoid tumors are neuroendocrine tumors that usually arise in the gastrointestinal tract or lungs, and they secrete a number of mediators (figure 4.8) that can give rise to carcinoid heart disease.","{'4951a27c-fe47-412b-a160-ced605a85c96': 'Lastly, carcinoid heart disease is the cardiac manifestation of carcinoid syndrome. Carcinoid tumors are neuroendocrine tumors that usually arise in the gastrointestinal\xa0tract or lungs, and they secrete a number of mediators (figure 4.8) that can give rise to carcinoid heart disease.', 'f5fc14dc-e762-4dc2-9c28-aefe679a91e4': 'The liver normally metabolizes these circulating mediators, but when the metastatic burden overwhelms hepatic clearance, the right heart is exposed to their effects (the left heart is somewhat protected by the degradation performed by the pulmonary circulation).', '66efaec5-1124-469a-b63e-a04259cca668': 'Of all these released mediators, serotonin is the most likely candidate for causing cardiac effects, although the mechanism is not\xa0clear. Once established, carcinoid lesions are distinctive white intimal thickenings (figure 4.8) composed of smooth muscle cells and collagen embedded in a mucopolysaccharide matrix. The most common manifestations are tricuspid insufficiency and pulmonary stenosis.'}"
Figure 3.1,cardio/images/Figure 3.1.jpg,Figure 3.1: Potential sources of essential hypertension.,"Hypertension can be categorized as either essential or secondary. Secondary is much less common and a consequence of another condition (e.g., renal or endocrine disease). Essential hypertension (EH), despite being the prevalent form, is poorly understood but can be attributed to a problem with either cardiac output or peripheral resistance (i.e., the components of blood pressure regulation). Because multiple factors contribute to these components AND there is evidence of some genetic component to hypertension AND due to the contribution from environmental factors, essential hypertension can be considered a “description” rather than a “diagnosis.” Primary abnormalities that may contribute to essential hypertension are shown in figure 3.1.","{'17c3cb39-d548-4da3-b59e-211a3acb1f40': 'Hypertension can be categorized as either essential or secondary. Secondary is much less common and a consequence of another condition (e.g., renal or endocrine disease). Essential hypertension (EH), despite being the prevalent form, is poorly understood but can be attributed to a problem\xa0with\xa0either cardiac output or peripheral resistance (i.e., the components of blood pressure regulation). Because\xa0multiple factors contribute to these components AND there is evidence of some genetic component to hypertension AND due to the contribution from environmental factors, essential hypertension can be considered a “description”\xa0rather than a “diagnosis.” Primary abnormalities that may contribute to essential hypertension are shown in figure 3.1.', 'ade4db08-4c80-4062-a00a-d762ac4f1a0f': 'Since Blood Pressure\xa0= Cardiac Output\xa0x Peripheral Resistance, it should be easy to imagine why aberrant rises in cardiac output (e.g., increased sympathetic tone) or peripheral resistance (e.g., low levels of vasodilators) would cause a rise in blood pressure (BP). Some of those aberrations of the acute BP control mechanisms are in figure 3.1, but this is clearly half the story as there are chronic control mechanisms that should surely compensation for loss of acute control. What this means is, for hypertension to be sustained, the kidney must be “in on the hypertension act.”\xa0While the kidney itself can be responsible for volume-based hypertension (dysregulated renal blood flow, ion channels defects, etc.), there are deficits in renal control in hypertension. Renin levels are normal or high in 70 to 75 percent\xa0of EH patients—and of course they should be low as elevated\xa0BP should suppress renin secretion. So while this begins a chicken-and-egg scenario, for hypertension to be sustained, both acute and chronic control mechanisms must\xa0fail.'}"
Figure 3.1,cardio/images/Figure 3.1.jpg,Figure 3.1: Potential sources of essential hypertension.,"Hypertension can be categorized as either essential or secondary. Secondary is much less common and a consequence of another condition (e.g., renal or endocrine disease). Essential hypertension (EH), despite being the prevalent form, is poorly understood but can be attributed to a problem with either cardiac output or peripheral resistance (i.e., the components of blood pressure regulation). Because multiple factors contribute to these components AND there is evidence of some genetic component to hypertension AND due to the contribution from environmental factors, essential hypertension can be considered a “description” rather than a “diagnosis.” Primary abnormalities that may contribute to essential hypertension are shown in figure 3.1.","{'17c3cb39-d548-4da3-b59e-211a3acb1f40': 'Hypertension can be categorized as either essential or secondary. Secondary is much less common and a consequence of another condition (e.g., renal or endocrine disease). Essential hypertension (EH), despite being the prevalent form, is poorly understood but can be attributed to a problem\xa0with\xa0either cardiac output or peripheral resistance (i.e., the components of blood pressure regulation). Because\xa0multiple factors contribute to these components AND there is evidence of some genetic component to hypertension AND due to the contribution from environmental factors, essential hypertension can be considered a “description”\xa0rather than a “diagnosis.” Primary abnormalities that may contribute to essential hypertension are shown in figure 3.1.', 'ade4db08-4c80-4062-a00a-d762ac4f1a0f': 'Since Blood Pressure\xa0= Cardiac Output\xa0x Peripheral Resistance, it should be easy to imagine why aberrant rises in cardiac output (e.g., increased sympathetic tone) or peripheral resistance (e.g., low levels of vasodilators) would cause a rise in blood pressure (BP). Some of those aberrations of the acute BP control mechanisms are in figure 3.1, but this is clearly half the story as there are chronic control mechanisms that should surely compensation for loss of acute control. What this means is, for hypertension to be sustained, the kidney must be “in on the hypertension act.”\xa0While the kidney itself can be responsible for volume-based hypertension (dysregulated renal blood flow, ion channels defects, etc.), there are deficits in renal control in hypertension. Renin levels are normal or high in 70 to 75 percent\xa0of EH patients—and of course they should be low as elevated\xa0BP should suppress renin secretion. So while this begins a chicken-and-egg scenario, for hypertension to be sustained, both acute and chronic control mechanisms must\xa0fail.'}"
Figure 3.2,cardio/images/Figure 3.2.jpg,Figure 3.2: Consequences of hypertension.,"The retinal circulation provides a direct window into the state of the vasculature. Rapid onset and severe hypertension may burst small retinal vessels and produce local infarctions. In more chronic cases, arterial narrowing and medial hypertrophy of the retinal vessel can be seen. As the chronic hypertension worsens, arterial sclerosis is evident. While these chronic effects may not produce functional issues, they are at least an accessible indicator of the vascular status. The consequences of hypertension are summarized in figure 3.2.","{'af882988-7ccc-462e-9505-98fd0bd3263c': 'As most hypertensive patients are asymptomatic, the condition can be left unmanaged and allowed to produce significant chronic effects. Most of these effects are caused by the extra work placed on the heart with the increased afterload and the damage to the interior of the vasculature.', 'd283f412-2185-450b-9f1e-c9490be56efa': 'The excess afterload can lead to systolic dysfunction and eventually heart failure with reduced ejection fraction (HFREF). In response to the excessive afterload the left ventricle can hypertrophy, causing a loss of compliance diastolic dysfunction and eventually heart failure with normal ejection fraction (HFNEF). The increased workload and muscle mass also increase\xa0the myocardial oxygen demand. This increase in demand often occurs at the same time that blood supply is diminished by concurrent atherosclerosis that is accelerated by the hypertension-induced\xa0arterial damage. Consequently,\xa0with high demand and low supply, the patient is prone to ischemia and myocardial infarction.', 'c1ed34a9-7d84-4ac5-9417-1199bdbf9872': 'The arterial damage will also promote thrombosis and atheroemboli, so risk of embolic stroke is raised. Risk of hemorrhagic stroke is also increased as the vessel ways become weak. The large vessels are also at risk of being unable to counteract raised pressure\xa0(remember Laplace’s\xa0law?), so aortic aneurysm and dissection can also occur.', 'a8286b9f-39dc-4ddd-a8c6-737c69993a46': 'High pressures entering the renal circulation can lead to nephrosclerosis. As renal function declines,\xa0a vicious cycle forms with renal failure exacerbating hypertension that exacerbates renal failure.', '020ddd29-fe19-4942-a12e-51cb278a5826': 'The retinal circulation\xa0provides a direct window into the state of the vasculature. Rapid onset and severe hypertension may burst small retinal vessels and produce local infarctions. In more chronic cases, arterial narrowing and medial hypertrophy of the retinal vessel can be seen. As the chronic hypertension worsens,\xa0arterial sclerosis is evident. While\xa0these chronic effects may not produce functional issues, they are at least an accessible indicator of the vascular status. The consequences of hypertension are summarized in figure 3.2.'}"
Figure 2.1,cardio/images/Figure 2.1.jpg,Figure 2.1: Overly simplified schema of heart failure. Systolic = cannot get the blood out; Diastolic = cannot get the blood in.,"Impediments to emptying the heart during systole (i.e., a reduced contractility or increased afterload) were referred to as systolic heart failure. Similarly, problems with filling the ventricle during diastole were referred to as diastolic heart failure (figure 2.1).","{'8c6e0429-e47f-4997-a67a-ddf069d958f5': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Ischemic Heart Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 6. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'f418f90a-4b61-47fe-9986-92500c9a8db6': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Acute Coronary Syndromes.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 7. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0d5c9a9d-0b35-43ee-a67d-f78f5b489c22': 'Surawicz, Borys, Rory Childers, Barbara J. Deal, and Leonard S. Gettes. “AHA/ACCF/HRS Recommendations for the Standardization and Interpretation of the Electrocardiogram.” Circulation 119, no. 10 (2009): e235–e240.', '60ff9e9a-c126-471e-99f6-c12310ca27fc': 'Surawicz, Borys, and Timothy Knilans. Chou’s Electrocardiography in Practice, 6th ed. Philadelphia: Saunders, 2008.', '338365cf-229f-462a-a031-98082c43433e': 'Bhansali, Suneet, and Colin Phoon.\xa0Truncus Arteriosis. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK534774/,\xa0CC BY 4.0.', '995ee375-aece-4390-b26d-9b4c9f312271': 'Cunningham, Jonathan W., and David W. Brown. “Congenital Heart Disease.” In\xa0Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, edited by Leonard S. Lilly, Chapter 16. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2012.', '840aca0a-c487-491a-b695-a8457d2cbc98': 'Dakkak, Wael, and Tony I. Oliver.\xa0Ventricular Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK470330/,\xa0CC BY 4.0.', '51d7dd59-efef-49b1-b87a-858bd257fe67': 'Diaz-Frias, Josua, and Melissa Guillaume.\xa0Tetralogy of Fallot. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK513288/,\xa0CC BY 4.0.', 'c7943f22-f9f3-4d59-b486-0d892d7fc01d': 'Gillam-Krakauer, Maria, and Kunal Mahajan.\xa0Patent Ductus Ateriosus. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', 'eb6a5536-2fab-49e9-8fea-fb6dfd90ac7e': 'Law, Mark A., and Vijai\xa0 S. Tivakaran.\xa0Coarctation of the Aorta. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430913/,\xa0CC BY 4.0.', '7dab3894-5603-4e66-a595-a4a501477845': 'Menillo, Alexandra M., Lawrence S. Lee, and Anthony L. Pearson-Shaver.\xa0Atrial Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK535440/,\xa0CC BY 4.0.', '477bb241-ffa8-4452-b076-05fd90b9111e': 'Szymanski, Michael W., Sheila M. Moore, Stacy M. Kritzmire, and Amandeep Goyal.\xa0Transposition of the Great Arteries. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', '740f1bed-fa6b-4651-a963-90a31353aa51': 'Umapathi, Krishna Kishore, and Pradyumna Agasthi.\xa0Atrioventricular Canal Defects.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK557511/,\xa0CC BY 4.0.', 'ade10988-52d5-40bb-a747-06d819e62b55': 'Dornbush, Sean, and Andre E. Turnquest. Physiology, Heart Sounds. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK541010, CC BY 4.0.', '1d13203a-5404-4ba4-abaa-6b5f3df36f97': 'Kulkarni, Vivek T., and Leonard S. Lilly. “The Cardiac Cycle: Mechanisms of Heart Sounds and Murmurs.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 2. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '3f337c79-9677-4c2d-8bca-e53e383a902f': 'Thomas, Seth L., Joseph Heaton, and Amgad N. Makaryus. Physiology, Cardiovascular Murmurs. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK525958, CC BY 4.0.', '79ed1809-c439-4208-b3fb-eabdea6a3c5c': 'Table 5.5: Classifications of heart murmurs. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/5.5_20220113', '0d9a3874-61bf-4706-bc3b-cd7d9ea2021c': 'Abnormalities of valvular structure and/or function can either be congenital or acquired. Acquired valvular disease is by far the most common and is most prevalent in the elderly. The high blood flow and pressures that valves are exposed to make them particularly susceptible to other risk factors that promote valvular damage (see table 4.1). Congenital valvular defects arise from disrupted heart development, about 50 percent\xa0of which involve the valves. The impact of congenital defects has diminished with the advent of advanced detection techniques.\xa0What we will spend time on in this chapter is the main instigating factors and pathologies that result\xa0in acquired valvular defects.', 'ccc9c78e-3005-40ab-baac-35ac9036e771': 'Table 4.1: Risk factors for acquired valvular damage.', '9098edeb-f4b5-4b10-aa41-7ecc7e039310': 'The constant stress of facing high flow and pressure over thirty to forty\xa0million cardiac contractions a year is not without its consequences, and the most common valvular disorder is calcification that comes with “wear-and-tear”\xa0and aging. The presence of other factors such as hyperlipidemia, hypertension, and inflammation accelerate this process and promote the deposition of hydroxyapatite (a form of calcium phosphate), and the valve structure contains cells that resemble osteoblasts (figure 4.1).', '8e9c7284-ff78-4170-bdb5-1bb9aa034b4b': 'As they face the most pressure, the aortic and mitral valves are more prone to calcification. The most common pattern of calcification in the aortic valve is mounded masses within the cusps of the valve (see table\xa04.2) that eventually fuse and stop the valve from opening fully.\xa0Calcification in the mitral valve\xa0tends to start in the fibrous annulus, which does not\xa0impact valvular function to the same extent, but in exceptional cases can cause regurgitation or stenosis, or even arrhythmias as calcium deposits impinge on the atrioventricular conduction system (see table\xa04.2).', '56ee9369-4764-475a-bf47-8192d06fa092': 'Table 4.2: Location of calcium deposits on aortic and mitral valves and their pathological consequences.', '87a6622f-680a-4032-acf2-22d1a3d06a57': 'Dass, Clarissa, and Arun Kanmanthareddy. Rheumatic Heart Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK538286/, CC BY 4.0.', '01571255-0baf-4ad1-abdb-c3c38901b4f1': 'Douedi, Steven, and Hani Douedi. Mitral Regurgitation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK553135/, CC BY 4.0.', '7f9e8792-d353-4380-b72b-10095d2e32d2': 'Lopez, Diana M., Patrick T. O’Gara, and Leonard S. Lilly. “Valvular Heart\xa0 Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 8. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0b92e173-7511-4e4f-a01c-46a261d63327': 'Wenn, Peter, and Roman Zeltser. Aortic Valve Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK542205/, CC BY 4.0.', '1ae0ec16-694d-4b2e-9c46-4f16ca1187bc': 'Table 4.1: Location of calcium deposits on aortic and mitral valves and their pathological consequences. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/4.2a_20220113', '36cfa87f-cb4a-40da-be59-3fe09efefb82': 'The current guidelines (JNC 8, 2017) list the following pressures and categories to define hypertension:', '043d0a6c-c109-49d3-864d-1049ae0bab92': 'Brown, Jenifer M., Gordon H. Williams, and Leonard S. Lilly. “Hypertension.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 13. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '6a1b6fe6-83fe-406c-9e01-1a06a4791350': 'Hajar, Rachel. “Framingham Contribution to Cardiovascular Disease.” Heart Views 17, no. 2 (April–June 2016): 78–81. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4966216.', 'b09e6339-ed87-40ae-b475-924c98e1a575': 'Iqbal, Arshad Muhammad, and Syed F. Jaml. Essential Hypertension. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK539859/, CC BY 4.0.', 'df8f6825-cd8d-4f33-a3b6-3aa95e2b7231': 'Page, Michael R. “The JNC 8 Hypertension Guidelines: An In-Depth Guide.” Evidence-Based Diabetes Management 20, no. SP1\xa0 (January 2014). https://www.ajmc.com/view/the-jnc-8-hypertension-guidelines-an-in-depth-guide.', '542c40cb-0157-4bdb-8e18-253f38324396': 'For whichever reason the end effect of the failure is a decline in blood flow out of the heart, and consequently congestion on the way in.', '7793dbfa-5e5b-4555-9631-e10c6b1d4a99': 'Table 2.1: Changes in cardiac function in different disease states.', '810dee93-c004-4109-b99d-0c58c90f8bc4': 'Impediments to emptying the heart during systole (i.e., a reduced contractility or increased afterload) were\xa0referred to as systolic heart failure. Similarly, problems with filling the ventricle during diastole were referred to as diastolic heart failure (figure 2.1).', '9d443965-9456-4656-a0f9-1e1e37fce404': 'In reality there is a great deal of overlap between these forms of heart failure, and elements of both can be present in the same patient. Similarly, as both forms result in congestion before the heart and reduced flow after it, they are hard to immediately distinguish. Consequently the type and degree of failure is now categorized by the effect on ejection fraction that can help distinguish the source of the problem.', '33c5d98f-6bcc-40b2-9a97-f4a5cf465f1c': 'Let us quickly remind ourselves of what ejection fraction is. Ejection fraction is the proportion of blood volume that the left ventricle ejects in one beat. It is mathematically described as the starting volume (i.e., end-diastolic volume, EDV) minus the finishing volume (i.e., end-systolic volume, ESV) as a proportion of the starting volume (figure 2.2)—in simpler terms, what percentage of the ventricular blood volume was pushed out during a contraction.', '0dade292-7120-4fea-a845-e26eeb3159a3': 'Eberly, Lauren A., Eldrin F. Lewis, and Leonard S. Lilly. “Heart Failure.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 9. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'd3239a6f-3c3d-4562-9ca8-835f21d500e2': 'Malik, Ahmad, Daniel Brito, Sarosh Vaqar, and Lovely Chhabra. Congestive Heart Failure. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK430873/, CC BY 4.0.', '25e09e1a-9d83-488d-ad5f-1fbe028f8fb0': 'Burns, Ed, and Robert Buttner. Hypercalcaemia. Lift in the Fast Lane, 2021. https://litfl.com/hypercalcaemia-ecg-library/, CC BY 4.0.', '98b0eb2b-328b-4f37-95d0-4a1d717348c2': 'Burns, Ed, and Robert Buttner. Hypocalcaemia. Life in the Fast Lane, 2021. https://litfl.com/hypocalcaemia-ecg-library/, CC BY 4.0.', '924eb71e-f15c-45cf-a207-17b43a28255e': 'Buttner, Robert, and Ed Burns. Hyperkalaemia. Life in the Fast Lane. https://litfl.com/hyperkalaemia-ecg-library/, CC BY 4.0.', '3f6b51a5-0594-4ad0-aff0-def446f6da9d': 'Buttner, Robert, and Ed Burns. Hypokalaemia. Life in the Fast Lane, 2021. https://litfl.com/hypokalaemia-ecg-library/, CC BY 4.0.', 'c2ec9ebd-39e6-4027-8d33-99309d013968': 'Chhabra, Lovely, Amandeep Goyal, and Michael D. Benham. Wolff Parkinson White Syndrome. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK554437/, CC BY 4.0.', 'de0f5e7f-54b2-4ef7-80ca-92553b8b6171': 'Custer, Adam M., Varun S. Yelamanchili, and Sarah L. Lappin. Multifocal Atrial Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459152/, CC BY 4.0.', '3e262579-d93b-409b-983d-96ddc6f0517c': 'Farzam, Khashayar, and John R. Richards. Premature Ventricular Contraction. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532991/, CC BY 4.0.', '7328f663-c5ef-4e2f-ade4-a4211caf5868': 'Foth, Christopher, Manesh Kumar Gangwani, and Heidi Alvey. Ventricular Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532954/, CC BY 4.0.', 'fc065c88-8e7e-4e26-a309-85650123fb33': 'Hafeez, Yamama, and Shamai A. Grossman. Sinus Bradycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK493201/, CC BY 4.0.', 'f1595d60-c9c3-4d6b-ba3b-44af48991758': 'Harkness, Weston T., and Mary Hicks. Right Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK507872/, CC BY 4.0.', 'd2624d0f-ba5a-421e-b634-e2a663b7ab7e': 'Heaton, Joseph, and Srikanth Yandrapalli. Premature Atrial Contractions. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK559204/, CC BY 4.0.', 'dcf93591-9453-4b52-a6ad-1aca2b965dd9': 'Kashou, Anthony H., Amandeep Goyal, Tran Nguyen, and Lovely Chhabra. Atrioventricular Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459147/, CC BY 4.0.', '54fd1955-7dcf-474e-a1c7-48be82daaf68': '“Learn the Heart.” Healio. https://www.healio.com/cardiology/learn-the-heart.', 'd631c93d-f5f0-400a-84c4-7fbe032819dc': 'Ludhwani, Dipesh, Amandeep Goyal, and Mandar Jagtap. Ventricular Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK537120/, CC BY 4.0.', '23d28e5a-2755-4f59-a997-fe25fb642627': 'Nesheiwat, Zeid, Amandeep Goyal, and Mandar Jagtap. Atrial Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK526072/, CC BY 4.0.', 'c652c067-fadb-4dcb-b5b7-c4507437ffd4': 'Pipilas, Daniel C., Bruce A. Koplan, and Leonard S. Lilly. “The Electrocardiogram.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 4. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '7c80cf5c-7fd6-4813-bb3d-279ddffa421e': 'Rodriguez Ziccardi, Mary, Amandeep Goyal, and Christopher V. Maani. Atrial Flutter. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK540985/, CC BY 4.0.', '9c33cea2-2522-4f34-b5de-1bb5ae1c0182': 'Scherbak, Dmitriy, and Gregory J. Hicks. Left Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK482167/, CC BY 4.0.'}"
Figure 2.2,cardio/images/Figure 2.2.jpg,Figure 2.2: Calculation for ejection fraction.,"Let us quickly remind ourselves of what ejection fraction is. Ejection fraction is the proportion of blood volume that the left ventricle ejects in one beat. It is mathematically described as the starting volume (i.e., end-diastolic volume, EDV) minus the finishing volume (i.e., end-systolic volume, ESV) as a proportion of the starting volume (figure 2.2)—in simpler terms, what percentage of the ventricular blood volume was pushed out during a contraction.","{'8c6e0429-e47f-4997-a67a-ddf069d958f5': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Ischemic Heart Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 6. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'f418f90a-4b61-47fe-9986-92500c9a8db6': 'Rhee, June-Wha, Sabatine, Marc S., and Leonard S. Lilly. “Acute Coronary Syndromes.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 7. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0d5c9a9d-0b35-43ee-a67d-f78f5b489c22': 'Surawicz, Borys, Rory Childers, Barbara J. Deal, and Leonard S. Gettes. “AHA/ACCF/HRS Recommendations for the Standardization and Interpretation of the Electrocardiogram.” Circulation 119, no. 10 (2009): e235–e240.', '60ff9e9a-c126-471e-99f6-c12310ca27fc': 'Surawicz, Borys, and Timothy Knilans. Chou’s Electrocardiography in Practice, 6th ed. Philadelphia: Saunders, 2008.', '338365cf-229f-462a-a031-98082c43433e': 'Bhansali, Suneet, and Colin Phoon.\xa0Truncus Arteriosis. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK534774/,\xa0CC BY 4.0.', '995ee375-aece-4390-b26d-9b4c9f312271': 'Cunningham, Jonathan W., and David W. Brown. “Congenital Heart Disease.” In\xa0Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, edited by Leonard S. Lilly, Chapter 16. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2012.', '840aca0a-c487-491a-b695-a8457d2cbc98': 'Dakkak, Wael, and Tony I. Oliver.\xa0Ventricular Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK470330/,\xa0CC BY 4.0.', '51d7dd59-efef-49b1-b87a-858bd257fe67': 'Diaz-Frias, Josua, and Melissa Guillaume.\xa0Tetralogy of Fallot. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK513288/,\xa0CC BY 4.0.', 'c7943f22-f9f3-4d59-b486-0d892d7fc01d': 'Gillam-Krakauer, Maria, and Kunal Mahajan.\xa0Patent Ductus Ateriosus. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', 'eb6a5536-2fab-49e9-8fea-fb6dfd90ac7e': 'Law, Mark A., and Vijai\xa0 S. Tivakaran.\xa0Coarctation of the Aorta. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430913/,\xa0CC BY 4.0.', '7dab3894-5603-4e66-a595-a4a501477845': 'Menillo, Alexandra M., Lawrence S. Lee, and Anthony L. Pearson-Shaver.\xa0Atrial Septal Defect.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK535440/,\xa0CC BY 4.0.', '477bb241-ffa8-4452-b076-05fd90b9111e': 'Szymanski, Michael W., Sheila M. Moore, Stacy M. Kritzmire, and Amandeep Goyal.\xa0Transposition of the Great Arteries. Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK430758/,\xa0CC BY 4.0.', '740f1bed-fa6b-4651-a963-90a31353aa51': 'Umapathi, Krishna Kishore, and Pradyumna Agasthi.\xa0Atrioventricular Canal Defects.\xa0Treasure Island, FL: StatPearls Publishing, 2022.\xa0https://www.ncbi.nlm.nih.gov/books/NBK557511/,\xa0CC BY 4.0.', 'ade10988-52d5-40bb-a747-06d819e62b55': 'Dornbush, Sean, and Andre E. Turnquest. Physiology, Heart Sounds. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK541010, CC BY 4.0.', '1d13203a-5404-4ba4-abaa-6b5f3df36f97': 'Kulkarni, Vivek T., and Leonard S. Lilly. “The Cardiac Cycle: Mechanisms of Heart Sounds and Murmurs.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 2. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '3f337c79-9677-4c2d-8bca-e53e383a902f': 'Thomas, Seth L., Joseph Heaton, and Amgad N. Makaryus. Physiology, Cardiovascular Murmurs. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK525958, CC BY 4.0.', '79ed1809-c439-4208-b3fb-eabdea6a3c5c': 'Table 5.5: Classifications of heart murmurs. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/5.5_20220113', '0d9a3874-61bf-4706-bc3b-cd7d9ea2021c': 'Abnormalities of valvular structure and/or function can either be congenital or acquired. Acquired valvular disease is by far the most common and is most prevalent in the elderly. The high blood flow and pressures that valves are exposed to make them particularly susceptible to other risk factors that promote valvular damage (see table 4.1). Congenital valvular defects arise from disrupted heart development, about 50 percent\xa0of which involve the valves. The impact of congenital defects has diminished with the advent of advanced detection techniques.\xa0What we will spend time on in this chapter is the main instigating factors and pathologies that result\xa0in acquired valvular defects.', 'ccc9c78e-3005-40ab-baac-35ac9036e771': 'Table 4.1: Risk factors for acquired valvular damage.', '9098edeb-f4b5-4b10-aa41-7ecc7e039310': 'The constant stress of facing high flow and pressure over thirty to forty\xa0million cardiac contractions a year is not without its consequences, and the most common valvular disorder is calcification that comes with “wear-and-tear”\xa0and aging. The presence of other factors such as hyperlipidemia, hypertension, and inflammation accelerate this process and promote the deposition of hydroxyapatite (a form of calcium phosphate), and the valve structure contains cells that resemble osteoblasts (figure 4.1).', '8e9c7284-ff78-4170-bdb5-1bb9aa034b4b': 'As they face the most pressure, the aortic and mitral valves are more prone to calcification. The most common pattern of calcification in the aortic valve is mounded masses within the cusps of the valve (see table\xa04.2) that eventually fuse and stop the valve from opening fully.\xa0Calcification in the mitral valve\xa0tends to start in the fibrous annulus, which does not\xa0impact valvular function to the same extent, but in exceptional cases can cause regurgitation or stenosis, or even arrhythmias as calcium deposits impinge on the atrioventricular conduction system (see table\xa04.2).', '56ee9369-4764-475a-bf47-8192d06fa092': 'Table 4.2: Location of calcium deposits on aortic and mitral valves and their pathological consequences.', '87a6622f-680a-4032-acf2-22d1a3d06a57': 'Dass, Clarissa, and Arun Kanmanthareddy. Rheumatic Heart Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK538286/, CC BY 4.0.', '01571255-0baf-4ad1-abdb-c3c38901b4f1': 'Douedi, Steven, and Hani Douedi. Mitral Regurgitation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK553135/, CC BY 4.0.', '7f9e8792-d353-4380-b72b-10095d2e32d2': 'Lopez, Diana M., Patrick T. O’Gara, and Leonard S. Lilly. “Valvular Heart\xa0 Disease.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 8. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '0b92e173-7511-4e4f-a01c-46a261d63327': 'Wenn, Peter, and Roman Zeltser. Aortic Valve Disease. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK542205/, CC BY 4.0.', '1ae0ec16-694d-4b2e-9c46-4f16ca1187bc': 'Table 4.1: Location of calcium deposits on aortic and mitral valves and their pathological consequences. Grey, Kindred. 2022. CC BY 4.0. https://archive.org/details/4.2a_20220113', '36cfa87f-cb4a-40da-be59-3fe09efefb82': 'The current guidelines (JNC 8, 2017) list the following pressures and categories to define hypertension:', '043d0a6c-c109-49d3-864d-1049ae0bab92': 'Brown, Jenifer M., Gordon H. Williams, and Leonard S. Lilly. “Hypertension.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 13. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '6a1b6fe6-83fe-406c-9e01-1a06a4791350': 'Hajar, Rachel. “Framingham Contribution to Cardiovascular Disease.” Heart Views 17, no. 2 (April–June 2016): 78–81. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4966216.', 'b09e6339-ed87-40ae-b475-924c98e1a575': 'Iqbal, Arshad Muhammad, and Syed F. Jaml. Essential Hypertension. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK539859/, CC BY 4.0.', 'df8f6825-cd8d-4f33-a3b6-3aa95e2b7231': 'Page, Michael R. “The JNC 8 Hypertension Guidelines: An In-Depth Guide.” Evidence-Based Diabetes Management 20, no. SP1\xa0 (January 2014). https://www.ajmc.com/view/the-jnc-8-hypertension-guidelines-an-in-depth-guide.', '542c40cb-0157-4bdb-8e18-253f38324396': 'For whichever reason the end effect of the failure is a decline in blood flow out of the heart, and consequently congestion on the way in.', '7793dbfa-5e5b-4555-9631-e10c6b1d4a99': 'Table 2.1: Changes in cardiac function in different disease states.', '810dee93-c004-4109-b99d-0c58c90f8bc4': 'Impediments to emptying the heart during systole (i.e., a reduced contractility or increased afterload) were\xa0referred to as systolic heart failure. Similarly, problems with filling the ventricle during diastole were referred to as diastolic heart failure (figure 2.1).', '9d443965-9456-4656-a0f9-1e1e37fce404': 'In reality there is a great deal of overlap between these forms of heart failure, and elements of both can be present in the same patient. Similarly, as both forms result in congestion before the heart and reduced flow after it, they are hard to immediately distinguish. Consequently the type and degree of failure is now categorized by the effect on ejection fraction that can help distinguish the source of the problem.', '33c5d98f-6bcc-40b2-9a97-f4a5cf465f1c': 'Let us quickly remind ourselves of what ejection fraction is. Ejection fraction is the proportion of blood volume that the left ventricle ejects in one beat. It is mathematically described as the starting volume (i.e., end-diastolic volume, EDV) minus the finishing volume (i.e., end-systolic volume, ESV) as a proportion of the starting volume (figure 2.2)—in simpler terms, what percentage of the ventricular blood volume was pushed out during a contraction.', '0dade292-7120-4fea-a845-e26eeb3159a3': 'Eberly, Lauren A., Eldrin F. Lewis, and Leonard S. Lilly. “Heart Failure.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e, edited by Leonard S. Lilly, Chapter 9. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', 'd3239a6f-3c3d-4562-9ca8-835f21d500e2': 'Malik, Ahmad, Daniel Brito, Sarosh Vaqar, and Lovely Chhabra. Congestive Heart Failure. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK430873/, CC BY 4.0.', '25e09e1a-9d83-488d-ad5f-1fbe028f8fb0': 'Burns, Ed, and Robert Buttner. Hypercalcaemia. Lift in the Fast Lane, 2021. https://litfl.com/hypercalcaemia-ecg-library/, CC BY 4.0.', '98b0eb2b-328b-4f37-95d0-4a1d717348c2': 'Burns, Ed, and Robert Buttner. Hypocalcaemia. Life in the Fast Lane, 2021. https://litfl.com/hypocalcaemia-ecg-library/, CC BY 4.0.', '924eb71e-f15c-45cf-a207-17b43a28255e': 'Buttner, Robert, and Ed Burns. Hyperkalaemia. Life in the Fast Lane. https://litfl.com/hyperkalaemia-ecg-library/, CC BY 4.0.', '3f6b51a5-0594-4ad0-aff0-def446f6da9d': 'Buttner, Robert, and Ed Burns. Hypokalaemia. Life in the Fast Lane, 2021. https://litfl.com/hypokalaemia-ecg-library/, CC BY 4.0.', 'c2ec9ebd-39e6-4027-8d33-99309d013968': 'Chhabra, Lovely, Amandeep Goyal, and Michael D. Benham. Wolff Parkinson White Syndrome. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK554437/, CC BY 4.0.', 'de0f5e7f-54b2-4ef7-80ca-92553b8b6171': 'Custer, Adam M., Varun S. Yelamanchili, and Sarah L. Lappin. Multifocal Atrial Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459152/, CC BY 4.0.', '3e262579-d93b-409b-983d-96ddc6f0517c': 'Farzam, Khashayar, and John R. Richards. Premature Ventricular Contraction. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532991/, CC BY 4.0.', '7328f663-c5ef-4e2f-ade4-a4211caf5868': 'Foth, Christopher, Manesh Kumar Gangwani, and Heidi Alvey. Ventricular Tachycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK532954/, CC BY 4.0.', 'fc065c88-8e7e-4e26-a309-85650123fb33': 'Hafeez, Yamama, and Shamai A. Grossman. Sinus Bradycardia. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK493201/, CC BY 4.0.', 'f1595d60-c9c3-4d6b-ba3b-44af48991758': 'Harkness, Weston T., and Mary Hicks. Right Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK507872/, CC BY 4.0.', 'd2624d0f-ba5a-421e-b634-e2a663b7ab7e': 'Heaton, Joseph, and Srikanth Yandrapalli. Premature Atrial Contractions. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK559204/, CC BY 4.0.', 'dcf93591-9453-4b52-a6ad-1aca2b965dd9': 'Kashou, Anthony H., Amandeep Goyal, Tran Nguyen, and Lovely Chhabra. Atrioventricular Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK459147/, CC BY 4.0.', '54fd1955-7dcf-474e-a1c7-48be82daaf68': '“Learn the Heart.” Healio. https://www.healio.com/cardiology/learn-the-heart.', 'd631c93d-f5f0-400a-84c4-7fbe032819dc': 'Ludhwani, Dipesh, Amandeep Goyal, and Mandar Jagtap. Ventricular Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK537120/, CC BY 4.0.', '23d28e5a-2755-4f59-a997-fe25fb642627': 'Nesheiwat, Zeid, Amandeep Goyal, and Mandar Jagtap. Atrial Fibrillation. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK526072/, CC BY 4.0.', 'c652c067-fadb-4dcb-b5b7-c4507437ffd4': 'Pipilas, Daniel C., Bruce A. Koplan, and Leonard S. Lilly. “The Electrocardiogram.” In Pathophysiology of Heart Disease: A Collaborative Project of Medical Students and Faculty, 5e edited by Leonard S. Lilly, Chapter 4. Philadelphia: Lippincott Williams & Wilkins, a Wolters Kluwer Business, 2010.', '7c80cf5c-7fd6-4813-bb3d-279ddffa421e': 'Rodriguez Ziccardi, Mary, Amandeep Goyal, and Christopher V. Maani. Atrial Flutter. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK540985/, CC BY 4.0.', '9c33cea2-2522-4f34-b5de-1bb5ae1c0182': 'Scherbak, Dmitriy, and Gregory J. Hicks. Left Bundle Branch Block. Treasure Island, FL: StatPearls Publishing, 2022. https://www.ncbi.nlm.nih.gov/books/NBK482167/, CC BY 4.0.'}"
Figure 2.3,cardio/images/Figure 2.3.jpg,"Figure 2.3: Pathophysiological sequence of left ventricular failure. Whether through lowered ejection fraction (HFREF, a.k.a. systolic failure) or through poor ventricular filling (heart failure with a normal ejection fraction, or HFNEF, a.k.a. diastolic failure), the end point of pulmonary congestion is the same.","Let us look at the pathophysiological consequences of HFREF. With a poor ejection fraction blood will begin to accumulate in the ventricle, and EDV will begins to rise and consequently so will the ventricular pressure. The raised pressure will impede venous return and promote venous congestion as blood struggles to enter the heart, and in the case of left ventricular failure the congestion will occur first in the left atrium and then in the pulmonary system (figure 2.3).","{'8313e09f-8062-4d5c-992f-418a2f86e873': 'Let us\xa0first relate this to systolic failure by looking at what happens when the contractility of the myocardium is reduced. In systolic failure, there is a problem getting blood out of the heart, so the volume of blood coming out of the heart per beat (EDV-ESV) is reduced. However, the end diastolic volume will remain the same, or more likely rise. So our ejection fraction is reduced. Consequently, if you have a reduced ejection fraction you know you have a systolic failure. So to improve diagnosis, systolic failure is now referred to as heart failure with a reduced ejection fraction (HFREF).', 'bb4d5498-c998-405e-bfe2-bdc0fdb98ee3': 'Let us\xa0look at the pathophysiological consequences of HFREF. With a poor ejection fraction blood will begin to accumulate in the ventricle, and EDV will begins to rise and consequently so will the ventricular pressure. The raised pressure will impede venous return\xa0and promote venous congestion as blood struggles to enter the heart, and in the case of left ventricular\xa0failure the congestion will occur first in the left atrium and then in the pulmonary system (figure 2.3).', 'a6ecac52-4f7f-4f9a-959c-73163b2c45e2': 'So systolic failure is referred to as HFREF, but what started as a problem emptying the heart has led to congestion and has produced a problem getting blood into the heart. Let us compare this with diastolic failure.', '4a4369ee-b8dd-4481-b713-a6c69f9c6ce7': 'Remember that in diastolic failure there is a problem relaxing/filling the ventricle. Consequently EDV tends to be lower than normal, and this lower volume of blood in the chamber is relatively easy for the heart to expel. So proportionately, the ejection fraction can be maintained, even if the absolute stroke volume may be low. This is now classified as heart failure with a normal ejection fraction (HFNEF).', '3c7cd1cb-4846-4b2e-a25f-4cab6021fbc9': 'The pathophysiological consequences of HFNEF stem from the poor relaxation of the ventricle and/or ability to accept blood. When the ventricle is noncompliant during diastole (i.e., does not relax properly), it does not\xa0take much blood volume to enter the chamber before the ventricle pressure begins to rise. This rise in ventricular pressure opposes the entry of more blood, so it accumulates in the atrium. Atrial pressure rises and venous return is impeded, so blood becomes congested in the venous system.', '41492948-d42e-48d2-8d92-5f2fa12f7f3f': 'If you compare this sequence of events in HFREF\xa0and HFNEF\xa0in figure 2.3 the end point is the same—congestion in the venous system, hence the difficulty in distinguishing “systolic” and “diastolic” failure and the need to measure ejection fraction and the newer categories of HFREF and HFNEF.\xa0In summary, HFREF starts with a problem getting blood out, that leads to a problem getting blood in, whereas HFNEF starts with a problem getting blood in that leads to a problem getting blood out. Both produce congestion, and both result in a diminished cardiac output.', '7c1b6d8d-ee1a-4cfe-be3e-3be6c7664e69': 'Acute Responses to Reduced Cardiac Output in Heart Failure: Good or Bad?', 'e63043fd-51c9-4f41-a0c6-e96a7748fc36': 'Initial responses to the diminished cardiac output include the acute compensatory responses to low blood pressure, myocardial stretch, or changes in renal perfusion. Let us\xa0do a quick review.', '2457bc27-6e6b-4146-8364-866cf6245fb9': 'The reduced cardiac output leads to a reduced arterial blood pressure, which, in combination with low volume exiting the heart, results in lower blood flow. With less blood exiting the heart, more remains in the chamber, particularly with systolic failure, so the myocardium is stretched. These three factors (pressure, flow, and myocardial stretch) elicit mechanical, neural, and hormone responses intended to correct the fall in pressure, resume flow, and clear the heart of congestion—but these responses are intended for a normal heart, not one undergoing failure.', '827a6f0f-2995-441d-a84f-1326feff6ad8': 'First, the extended myocardium elicits the Frank-Starling mechanism to increase contractility, while the release of ANP and BNP induces sodium and fluid loss at the kidney. Conversely, reduced renal blood flow instigates the RAAS system to cause salt and fluid retention and vasoconstriction aided by the release of Endothelin-1 from the endothelium of flow-deprived vessels. Finally, the reduced arterial pressure prompts the baroreceptor reflex that increases\xa0sympathetic tone to increase rate and contractility, and antidiuretic hormone causes fluid retention. See the summary in figure 2.4.', 'f4564ed9-680a-4eb9-98a0-9300621443d8': 'These compensatory effects are all attempts to improve cardiac output and blood pressure, but the failing heart is being forced to work harder against an increased afterload and move more volume. Consequently, but for the natriuretic peptides, these responses are maladaptive in the long term, and chronic changes to the heart are instigated.'}"
Figure 2.3,cardio/images/Figure 2.3.jpg,"Figure 2.3: Pathophysiological sequence of left ventricular failure. Whether through lowered ejection fraction (HFREF, a.k.a. systolic failure) or through poor ventricular filling (heart failure with a normal ejection fraction, or HFNEF, a.k.a. diastolic failure), the end point of pulmonary congestion is the same.","Let us look at the pathophysiological consequences of HFREF. With a poor ejection fraction blood will begin to accumulate in the ventricle, and EDV will begins to rise and consequently so will the ventricular pressure. The raised pressure will impede venous return and promote venous congestion as blood struggles to enter the heart, and in the case of left ventricular failure the congestion will occur first in the left atrium and then in the pulmonary system (figure 2.3).","{'8313e09f-8062-4d5c-992f-418a2f86e873': 'Let us\xa0first relate this to systolic failure by looking at what happens when the contractility of the myocardium is reduced. In systolic failure, there is a problem getting blood out of the heart, so the volume of blood coming out of the heart per beat (EDV-ESV) is reduced. However, the end diastolic volume will remain the same, or more likely rise. So our ejection fraction is reduced. Consequently, if you have a reduced ejection fraction you know you have a systolic failure. So to improve diagnosis, systolic failure is now referred to as heart failure with a reduced ejection fraction (HFREF).', 'bb4d5498-c998-405e-bfe2-bdc0fdb98ee3': 'Let us\xa0look at the pathophysiological consequences of HFREF. With a poor ejection fraction blood will begin to accumulate in the ventricle, and EDV will begins to rise and consequently so will the ventricular pressure. The raised pressure will impede venous return\xa0and promote venous congestion as blood struggles to enter the heart, and in the case of left ventricular\xa0failure the congestion will occur first in the left atrium and then in the pulmonary system (figure 2.3).', 'a6ecac52-4f7f-4f9a-959c-73163b2c45e2': 'So systolic failure is referred to as HFREF, but what started as a problem emptying the heart has led to congestion and has produced a problem getting blood into the heart. Let us compare this with diastolic failure.', '4a4369ee-b8dd-4481-b713-a6c69f9c6ce7': 'Remember that in diastolic failure there is a problem relaxing/filling the ventricle. Consequently EDV tends to be lower than normal, and this lower volume of blood in the chamber is relatively easy for the heart to expel. So proportionately, the ejection fraction can be maintained, even if the absolute stroke volume may be low. This is now classified as heart failure with a normal ejection fraction (HFNEF).', '3c7cd1cb-4846-4b2e-a25f-4cab6021fbc9': 'The pathophysiological consequences of HFNEF stem from the poor relaxation of the ventricle and/or ability to accept blood. When the ventricle is noncompliant during diastole (i.e., does not relax properly), it does not\xa0take much blood volume to enter the chamber before the ventricle pressure begins to rise. This rise in ventricular pressure opposes the entry of more blood, so it accumulates in the atrium. Atrial pressure rises and venous return is impeded, so blood becomes congested in the venous system.', '41492948-d42e-48d2-8d92-5f2fa12f7f3f': 'If you compare this sequence of events in HFREF\xa0and HFNEF\xa0in figure 2.3 the end point is the same—congestion in the venous system, hence the difficulty in distinguishing “systolic” and “diastolic” failure and the need to measure ejection fraction and the newer categories of HFREF and HFNEF.\xa0In summary, HFREF starts with a problem getting blood out, that leads to a problem getting blood in, whereas HFNEF starts with a problem getting blood in that leads to a problem getting blood out. Both produce congestion, and both result in a diminished cardiac output.', '7c1b6d8d-ee1a-4cfe-be3e-3be6c7664e69': 'Acute Responses to Reduced Cardiac Output in Heart Failure: Good or Bad?', 'e63043fd-51c9-4f41-a0c6-e96a7748fc36': 'Initial responses to the diminished cardiac output include the acute compensatory responses to low blood pressure, myocardial stretch, or changes in renal perfusion. Let us\xa0do a quick review.', '2457bc27-6e6b-4146-8364-866cf6245fb9': 'The reduced cardiac output leads to a reduced arterial blood pressure, which, in combination with low volume exiting the heart, results in lower blood flow. With less blood exiting the heart, more remains in the chamber, particularly with systolic failure, so the myocardium is stretched. These three factors (pressure, flow, and myocardial stretch) elicit mechanical, neural, and hormone responses intended to correct the fall in pressure, resume flow, and clear the heart of congestion—but these responses are intended for a normal heart, not one undergoing failure.', '827a6f0f-2995-441d-a84f-1326feff6ad8': 'First, the extended myocardium elicits the Frank-Starling mechanism to increase contractility, while the release of ANP and BNP induces sodium and fluid loss at the kidney. Conversely, reduced renal blood flow instigates the RAAS system to cause salt and fluid retention and vasoconstriction aided by the release of Endothelin-1 from the endothelium of flow-deprived vessels. Finally, the reduced arterial pressure prompts the baroreceptor reflex that increases\xa0sympathetic tone to increase rate and contractility, and antidiuretic hormone causes fluid retention. See the summary in figure 2.4.', 'f4564ed9-680a-4eb9-98a0-9300621443d8': 'These compensatory effects are all attempts to improve cardiac output and blood pressure, but the failing heart is being forced to work harder against an increased afterload and move more volume. Consequently, but for the natriuretic peptides, these responses are maladaptive in the long term, and chronic changes to the heart are instigated.'}"
Figure 2.4,cardio/images/Figure 2.4.jpg,Figure 2.4: Compensatory responses to reduced cardiac output.,"First, the extended myocardium elicits the Frank-Starling mechanism to increase contractility, while the release of ANP and BNP induces sodium and fluid loss at the kidney. Conversely, reduced renal blood flow instigates the RAAS system to cause salt and fluid retention and vasoconstriction aided by the release of Endothelin-1 from the endothelium of flow-deprived vessels. Finally, the reduced arterial pressure prompts the baroreceptor reflex that increases sympathetic tone to increase rate and contractility, and antidiuretic hormone causes fluid retention. See the summary in figure 2.4.","{'4a4369ee-b8dd-4481-b713-a6c69f9c6ce7': 'Remember that in diastolic failure there is a problem relaxing/filling the ventricle. Consequently EDV tends to be lower than normal, and this lower volume of blood in the chamber is relatively easy for the heart to expel. So proportionately, the ejection fraction can be maintained, even if the absolute stroke volume may be low. This is now classified as heart failure with a normal ejection fraction (HFNEF).', '3c7cd1cb-4846-4b2e-a25f-4cab6021fbc9': 'The pathophysiological consequences of HFNEF stem from the poor relaxation of the ventricle and/or ability to accept blood. When the ventricle is noncompliant during diastole (i.e., does not relax properly), it does not\xa0take much blood volume to enter the chamber before the ventricle pressure begins to rise. This rise in ventricular pressure opposes the entry of more blood, so it accumulates in the atrium. Atrial pressure rises and venous return is impeded, so blood becomes congested in the venous system.', '41492948-d42e-48d2-8d92-5f2fa12f7f3f': 'If you compare this sequence of events in HFREF\xa0and HFNEF\xa0in figure 2.3 the end point is the same—congestion in the venous system, hence the difficulty in distinguishing “systolic” and “diastolic” failure and the need to measure ejection fraction and the newer categories of HFREF and HFNEF.\xa0In summary, HFREF starts with a problem getting blood out, that leads to a problem getting blood in, whereas HFNEF starts with a problem getting blood in that leads to a problem getting blood out. Both produce congestion, and both result in a diminished cardiac output.', '7c1b6d8d-ee1a-4cfe-be3e-3be6c7664e69': 'Acute Responses to Reduced Cardiac Output in Heart Failure: Good or Bad?', 'e63043fd-51c9-4f41-a0c6-e96a7748fc36': 'Initial responses to the diminished cardiac output include the acute compensatory responses to low blood pressure, myocardial stretch, or changes in renal perfusion. Let us\xa0do a quick review.', '2457bc27-6e6b-4146-8364-866cf6245fb9': 'The reduced cardiac output leads to a reduced arterial blood pressure, which, in combination with low volume exiting the heart, results in lower blood flow. With less blood exiting the heart, more remains in the chamber, particularly with systolic failure, so the myocardium is stretched. These three factors (pressure, flow, and myocardial stretch) elicit mechanical, neural, and hormone responses intended to correct the fall in pressure, resume flow, and clear the heart of congestion—but these responses are intended for a normal heart, not one undergoing failure.', '827a6f0f-2995-441d-a84f-1326feff6ad8': 'First, the extended myocardium elicits the Frank-Starling mechanism to increase contractility, while the release of ANP and BNP induces sodium and fluid loss at the kidney. Conversely, reduced renal blood flow instigates the RAAS system to cause salt and fluid retention and vasoconstriction aided by the release of Endothelin-1 from the endothelium of flow-deprived vessels. Finally, the reduced arterial pressure prompts the baroreceptor reflex that increases\xa0sympathetic tone to increase rate and contractility, and antidiuretic hormone causes fluid retention. See the summary in figure 2.4.', 'f4564ed9-680a-4eb9-98a0-9300621443d8': 'These compensatory effects are all attempts to improve cardiac output and blood pressure, but the failing heart is being forced to work harder against an increased afterload and move more volume. Consequently, but for the natriuretic peptides, these responses are maladaptive in the long term, and chronic changes to the heart are instigated.'}"
Figure 2.5,cardio/images/Figure 2.5.jpg,Figure 2.5: The effects of volume and pressure overload on the morphology of the heart and cardiac myocytes.,"But the two forms of overload (volume and pressure) lead to different patterns of hypertrophy. In volume overload the myocytes add more sarcomeres in series, so they elongate and contribute to the dilation of the chamber while there is a proportional increase in wall thickness. This is referred to as eccentric hypertrophy (figure 2.5).","{'38a6b3ec-f8b6-41bd-a4dc-855ba9398345': 'The long-term structural changes begin with additional wall stress in the failing heart interacting with neurohormonal and cytokine alterations, but the wall stress seems to be an important instigator of hypertrophy and remodeling.\xa0Stress can be placed on the chamber walls in two major ways.', '3d505d61-d695-4456-81c2-16b0858e0ef1': 'But the two forms of overload (volume and pressure) lead to different patterns of hypertrophy. In volume overload the myocytes add more sarcomeres in series, so they elongate and contribute to the dilation of the chamber while there is a proportional increase in wall thickness. This is referred to as eccentric hypertrophy (figure 2.5).', 'cf5247ca-13e8-49ce-a929-e13d964bdeee': 'Pressure loading, on the other hand, leads to the synthesis of new sarcomeres that are formed in parallel to the old ones, causing an increase in wall thickness\xa0without any dilation of the chamber. This is referred to as concentric hypertrophy (figure 2.5).', 'af81a211-a1f5-4981-aeb8-b5e176b28af0': 'These adaptations are accompanied by increased deposition of connective tissue that may have conductive or contractive ramifications. The difference in myocytic arrangement and presence of connective tissue is clear in the histological views of normal myocardium and myocardium chronically exposed\xa0to valvular disease in figure 2.6.', '1688bd5c-bfae-42ba-abd9-825ce316194a': 'Myocytes may also be lost through either apoptosis or necrosis. As hypertrophy occurs the blood supply to the thickening wall becomes inadequate so infarction and consequent necrosis are more likely. Factors that promote myocyte apoptosis are all present during heart failure and include\xa0elevated catecholamines, Angiotensin II, inflammatory cytokines, and wall stress.', 'bb79e7cd-ae7b-4e7e-9b25-d6a2a2fa57c2': 'These same factors also disrupt gene expression in myocytes and cause intracellular deficits, including loss of Ca++\xa0homeostasis and production of high-energy phosphates. While the mechanisms of these intracellular effects is still being heavily researched, the inability to control calcium or regulate high-energy phosphates obviously has implications of excitation–contraction coupling.', '384bc000-79c1-4a05-be16-e91fa7cc8b07': 'So while hypertrophy may seem a sensible response in the failing heart, the patterns and inflammation and stress-driven changes are eventually maladaptive and lead to a progressive decline in cardiac function.'}"
Figure 2.6,cardio/images/Figure 2.6.jpg,Figure 2.6: Normal myocardial (A) and myocardium exposed to valvular disease (B).,These adaptations are accompanied by increased deposition of connective tissue that may have conductive or contractive ramifications. The difference in myocytic arrangement and presence of connective tissue is clear in the histological views of normal myocardium and myocardium chronically exposed to valvular disease in figure 2.6.,"{'38a6b3ec-f8b6-41bd-a4dc-855ba9398345': 'The long-term structural changes begin with additional wall stress in the failing heart interacting with neurohormonal and cytokine alterations, but the wall stress seems to be an important instigator of hypertrophy and remodeling.\xa0Stress can be placed on the chamber walls in two major ways.', '3d505d61-d695-4456-81c2-16b0858e0ef1': 'But the two forms of overload (volume and pressure) lead to different patterns of hypertrophy. In volume overload the myocytes add more sarcomeres in series, so they elongate and contribute to the dilation of the chamber while there is a proportional increase in wall thickness. This is referred to as eccentric hypertrophy (figure 2.5).', 'cf5247ca-13e8-49ce-a929-e13d964bdeee': 'Pressure loading, on the other hand, leads to the synthesis of new sarcomeres that are formed in parallel to the old ones, causing an increase in wall thickness\xa0without any dilation of the chamber. This is referred to as concentric hypertrophy (figure 2.5).', 'af81a211-a1f5-4981-aeb8-b5e176b28af0': 'These adaptations are accompanied by increased deposition of connective tissue that may have conductive or contractive ramifications. The difference in myocytic arrangement and presence of connective tissue is clear in the histological views of normal myocardium and myocardium chronically exposed\xa0to valvular disease in figure 2.6.', '1688bd5c-bfae-42ba-abd9-825ce316194a': 'Myocytes may also be lost through either apoptosis or necrosis. As hypertrophy occurs the blood supply to the thickening wall becomes inadequate so infarction and consequent necrosis are more likely. Factors that promote myocyte apoptosis are all present during heart failure and include\xa0elevated catecholamines, Angiotensin II, inflammatory cytokines, and wall stress.', 'bb79e7cd-ae7b-4e7e-9b25-d6a2a2fa57c2': 'These same factors also disrupt gene expression in myocytes and cause intracellular deficits, including loss of Ca++\xa0homeostasis and production of high-energy phosphates. While the mechanisms of these intracellular effects is still being heavily researched, the inability to control calcium or regulate high-energy phosphates obviously has implications of excitation–contraction coupling.', '384bc000-79c1-4a05-be16-e91fa7cc8b07': 'So while hypertrophy may seem a sensible response in the failing heart, the patterns and inflammation and stress-driven changes are eventually maladaptive and lead to a progressive decline in cardiac function.'}"
Figure 2.7,cardio/images/Figure 2.7.jpg,Figure 2.7: Consequences of right- and left-sided heart failure.,The clinical manifestations arise as fluid begins to move from the blood to the interstitium due to congestion (see summary in figure 2.7).,"{'8eedeb9c-8875-4207-8dc0-63d9714411a6': 'The clinical manifestations arise as fluid begins to move from the blood to the interstitium due to congestion (see summary in figure 2.7).', 'cd53d0f7-ff4a-4644-bb06-f1b12dd8d8d7': 'If the right heart fails, there is a rise in systemic venous pressure and peripheral edema arises. There may be abdominal discomfort as the liver becomes engorged and a loss of appetite or nausea as gastrointestinal edema arises. If the left heart fails, then the pulmonary circulation is exposed to the congestion and pulmonary edema arises.', 'f01b9785-90a8-4f1f-9af6-b2abdb605faa': 'Low cardiac output\xa0reduces renal filtration, so urine formation maybe impaired. Similarly cerebral blood flow may be compromised, causing dulled mental status.', 'aae92405-fd79-4bad-b17c-3704ca13b242': 'Orthopnea\xa0arises when the patient lays down and venous return toward the failing left ventricle increases, compounding the pulmonary congestion. Patients often sleep propped up on pillows to elevate the heart and lungs. In severe cases the patient may only be able to sleep upright in a chair.'}"
Figure 1.1,cardio/images/Figure 1.1.jpg,Figure 1.1: An ECG of atrial fibrillation showing lack of P-waves and low-amplitude fibrillation waves between QRS complexes.,"Atrial fibrillation is the most common cardiac arrhythmia and is caused by rapidly firing potentials in the atrial myocardium. These aberrant depolarizations are often the result of myocardial remodeling and frequently originate within the muscular sleeves that extend into the pulmonary veins from the atria. Causes include hypertension, valvular and ischemic heart disease, and genetics (e.g., mutation of 10q22–q24 on chromosome 10). The rapid depolarizations result in a very fast atrial rate from 400 to 600 bpm. Because the atrial rate is so fast, the ECG shows “coarse fibrillatory waves” (figure 1.1); the action potentials produced are low amplitude, and P-waves will not be seen.","{'77eb1c38-43b0-47d4-96c7-3a2c17c4056c': 'Atrial fibrillation is the most common cardiac arrhythmia and is\xa0caused by rapidly firing\xa0potentials in the atrial myocardium. These aberrant depolarizations are often the result of myocardial remodeling and frequently\xa0originate within the muscular sleeves that extend into the pulmonary veins from the atria. Causes include hypertension, valvular and ischemic heart disease, and genetics (e.g., mutation of\xa010q22–q24 on chromosome 10).\xa0The rapid depolarizations result in a very fast atrial rate from 400 to 600 bpm. Because the atrial rate is so fast, the ECG shows “coarse fibrillatory waves”\xa0(figure 1.1);\xa0the action potentials produced are\xa0low amplitude, and P-waves will not be seen.'}"
Figure 1.2,cardio/images/Figure 1.2.jpg,"Figure 1.2: Comparison of atrial arrhythmias, including atrial fibrillation (left), atrial flutter (middle), and multifocal atrial tachycardia (MAT) (right).","The rapid atrial depolarizations are transmitted to the atrioventricular (AV) node, but far from all are conducted through to the ventricle because of the node’s long refractory period. This means the ventricular rate does not rise to 400–600 bpm (which would be catastrophic), but some of the atrial fibrillation activity can be “lucky” and reach the AV node when it is not in a refractory period. When this occurs, the ventricular rate rises to 100–200 bpm, and QRS complexes can be “irregularly irregular” with a varying R-R interval (left panel, figure 1.2).","{'3aee9c75-9844-4eed-9724-f09cc605c6ca': 'The rapid atrial depolarizations are transmitted to the atrioventricular (AV) node, but far from all are conducted through to the ventricle because of the node’s long refractory period. This means the ventricular rate does not rise to 400–600 bpm (which would be catastrophic), but some of the atrial fibrillation activity can be “lucky” and reach the AV node when it is not in a refractory period. When this occurs, the ventricular rate rises to 100–200 bpm, and QRS complexes can be “irregularly irregular” with a varying R-R interval (left panel, figure 1.2).', '639d540a-0158-4f7d-9820-e67b5789ff80': 'Table 1.1: Atrial fibrillation summary.'}"
Figure 1.3,cardio/images/Figure 1.3.jpg,Figure 1.3: Atrial flutter — “sawtooth” P-waves with lower frequency than the fibrillation waves of atrial fibrillation.,"Atrial flutter is caused by a macroreentrant current, rather than the multiple sites of aberrant depolarization seen in fibrillation. The cavotricuspid isthmus (CTI) usually provides the circuit for the slower reentrant current to become established (typical atrial flutter), but other sites of reentry and slow conducting circuits are possible (atypical atrial flutter) and are usually associated with structural heart disease or sites of previous surgical or ablations procedures. The slower reentry current produces an atrial rate of 250–350 bpm (compared to the 400–600 of atrial flutter), and P-waves are present but have a characteristic “sawtooth” pattern (figure 1.3 and middle panel figure 1.2).","{'818acd74-546e-4e12-9767-de1f0f024d58': 'Atrial flutter is caused by a macroreentrant current, rather than the\xa0multiple sites of aberrant depolarization seen in fibrillation. The cavotricuspid isthmus (CTI) usually provides the circuit for the slower reentrant current to become established (typical atrial flutter), but other sites of reentry and slow conducting circuits are possible (atypical atrial flutter) and are usually associated with structural heart disease or sites of previous surgical or ablations procedures. The slower reentry current produces an atrial rate of 250–350 bpm (compared to the 400–600 of atrial flutter), and P-waves are present but have a characteristic “sawtooth” pattern (figure 1.3 and middle panel figure 1.2).'}"
Figure 1.4,cardio/images/Figure 1.4.jpg,Figure 1.4: Three distinct P-wave morphologies in a case of MAT.,"Multifocal atrial tachycardia (MAT) is caused by the presence of multiple ectopic foci. The multiple foci result in P-waves with multiple morphologies and irregular intervals (see figure 1.4). The pathophysiology of MAT is not clear, although several theories exists (e.g., triggered activity, reentry, or abnormal automaticity). The multiple foci within the atrium generate consecutive action potentials that are all conducted to the ventricles. Thus, each QRS complex will be preceded by a P-wave; however, each P-wave will have a different morphology because they originate from different areas. By definition, MAT must have at least three distinctly different P-wave morphologies (figure 1.4) and a ventricular rate of greater than 100 bpm.","{'af0d299e-2b3f-4089-b62a-9764b4a18f71': 'Multifocal atrial tachycardia (MAT)\xa0is caused by the presence of\xa0multiple\xa0ectopic foci. The multiple foci result in\xa0P-waves with multiple morphologies and irregular intervals (see figure 1.4).\xa0The pathophysiology of MAT is not clear, although several\xa0theories exists (e.g., triggered activity,\xa0reentry,\xa0or abnormal automaticity). The multiple\xa0foci\xa0within the atrium generate consecutive action potentials that are all conducted to the ventricles. Thus, each QRS complex will be preceded by a P-wave; however, each P-wave will have a different morphology because they originate from different areas. By definition, MAT\xa0must have at least three distinctly different P-wave morphologies (figure 1.4) and a ventricular rate of greater than 100 bpm.', '69d51e67-954b-4217-ad36-a22a50989d54': 'MAT\xa0frequently occurs in the setting of severe lung disease and, more specifically, during an exacerbation of lung disease. This rhythm is benign, and once the underlying lung disease is treated, it should resolve.', '98afd1fa-85df-4d62-a0c1-9e9c898401fe': 'Table 1.3: MAT summary.'}"
Figure 1.5,cardio/images/Figure 1.5.jpg,Figure 1.5: Atrial bigeminy in PAC with ECG complexes appearing in pairs.,"The premature complex may also upset the timing of the SA node, placing it back into a refractory period when it should be depolarizing for its next scheduled beat. This means that a PAC may cause a “compensatory pause” as the SA node restarts its pacemaker depolarization. Consequently the ECG can show “atrial bigeminy” where complexes appear to be in pairs with a normal complex followed by a complex driven by the atrial ectopic activity, then a pause while the SA node begins its depolarization again (see figure 1.5).","{'8bb9a3f4-eda3-41e3-bdac-aecaedc793cd': 'A premature atrial contraction (PAC) is generated by a depolarization instigated outside of the SA node. This produces an extra P-wave, and consequently\xa0a shortening from previous P-P intervals is seen. The aberrant P-wave also has a different morphology from\xa0a sinus P-wave because of its different anatomical origin.', '7d84a37a-b966-4fe7-808c-348e93346e99': 'The premature complex may also upset the timing of the SA\xa0node,\xa0placing it back into a\xa0refractory period when it should be depolarizing for its next scheduled beat. This means that a PAC\xa0may cause a “compensatory pause” as the SA node restarts its pacemaker depolarization. Consequently the ECG can show “atrial bigeminy”\xa0where complexes appear to be in pairs with a normal complex followed by a complex driven by the atrial ectopic activity, then a pause while the SA node begins\xa0its depolarization again (see figure 1.5).', '37713deb-c7b3-4fbc-b01c-3eb0aaa9d84c': 'If a PAC occurs when the AV node has not yet recovered from its refractory period, the PAC will fail to conduct to the ventricles; meaning the PAC will not be followed by a QRS complex or the ectopic P-R interval will be prolonged. The ECG will show a premature, ectopic P-wave and then no QRS complex afterward. When this occurs along with bigeminy, the ECG can appear as if there is sinus bradycardia.', '2b9aed14-4aa1-4521-9f3c-275cf0a91144': 'Table 1.4: PAC summary.'}"
Figure 1.6,cardio/images/Figure 1.6.jpg,Figure 1.6: PVCs have a wider complex and are followed by a compensatory pause.,"Similar to a PAC, a premature ventricular contraction (PVC) occurs when a focus in the ventricle generates an action potential before the pacemaker cells in the SA node depolarize. This early depolarization is out of rhythm with the normal R-R interval, and because it starts outside of the normal conduction pathways, it has a very different shape from a normal, scheduled QRS complex (figure 1.6). The PVC is wider as it has to travel from myocyte to myocyte, so it is much slower than a normal SA node–driven depolarization that travels through the faster conduction network fibers. There is also a compensatory pause following the PVC as the unscheduled depolarization puts the ventricular myocardium into refractory state, forcing it to “skip a beat” (figure 1.6).","{'dc9ee840-69de-4976-87b6-7abde5e38a90': 'Similar to a PAC, a premature ventricular contraction (PVC) occurs when a focus in the ventricle generates an action potential before the pacemaker cells in the SA node\xa0depolarize.\xa0This early depolarization\xa0is out of rhythm with the normal R-R interval, and because it starts outside of the normal conduction pathways, it has a very different shape from\xa0a normal, scheduled QRS complex (figure 1.6). The PVC is wider as it has to travel from myocyte to myocyte, so it is much slower than a normal SA node–driven depolarization that travels through the faster conduction network fibers. There is also a compensatory pause following the PVC as the unscheduled depolarization puts the ventricular myocardium into refractory state, forcing it to “skip a beat” (figure 1.6).', '23079878-bc12-424c-9e14-a9826f400b5b': 'Table 1.7: PVC summary.'}"
Figure 1.7,cardio/images/Figure 1.7.jpg,Figure 1.7: Monomorphic and polymorphic VT.,VT can be monomorphic or polymorphic (figure 1.7). The QRS complexes in monomorphic VT have the same shape and are symmetrical because they start in the same place in the myocardium. Polymorphic VT has a variable QRS shape because the depolarizations are instigated at multiple points. An electrophysiologist can describe the location(s) within the ventricles from where the VT originates using the shape(s) of the QRS complexes.,"{'0ee66a98-cebd-476f-99fb-3bd440a76037': 'Ventricular tachycardia (VT) is caused by reentry currents being established in the ventricular myocardium or groups of ventricular myocytes that have aberrant electrical behavior. As such, VT is usually caused by underlying cardiac disease.', 'c446e254-69fd-477f-b95e-d85d69a4a7bc': 'Like a PVC, the aberrant depolarizations do not follow the normal conduction pathways so are wide (>120 msecs), but unlike a PVC, VT involves a ventricular rate >100 bpm. With disorganized contractility and reduced filling time, VT can lead to hemodynamic instability and severe hypotension—hence it is life threatening.', '740e2583-adaa-4879-9900-42e40e3469ca': 'The QRS morphology in VT is highly variable between patients and depends on where the arrhythmia originates. Consequently there are several ways to classify VT based on duration, symptoms, QRS morphology, rate, and origin.', 'c3cb9d9f-2d2b-4cfe-8810-58f2fa676d70': 'Sustained VT is any VT\xa0that lasts for more than 30 seconds or is symptomatic. Nonsustained VT lasts for less than 30 seconds and is asymptomatic.', '404d4366-865a-4d38-8585-bbc56474a36d': 'VT can be monomorphic or polymorphic (figure 1.7). The QRS complexes in monomorphic VT have the same shape and are symmetrical because they start in the same place in the myocardium. Polymorphic VT has a variable QRS shape because the depolarizations are instigated at multiple points. An electrophysiologist\xa0can describe the location(s) within the ventricles from where the VT originates\xa0using the shape(s) of the QRS complexes.', '4e92395d-61e7-40e7-b3bd-de21c9a0c006': 'Torsades de pointes (twist of peaks) is a form of VT with multiple QRS morphologies. The twist references\xa0the undulating amplitude of the QRS complexes that twist around the isoelectric line, giving the ECG the appearance of a twisted ribbon (figure 1.8).', '4165fe0e-c783-42fb-9b63-edc7c4a8c906': 'Torsades de pointes is associated with a prolonged QT interval (>600 msecs) that helps distinguish it from other forms of polymorphous VT. The longer QT interval can be caused by ionic abnormalities that reduce the repolarizing current of Phase 3 of the cardiac action potential. This makes the myocardium susceptible to early after-depolarizations—the trigger for torsades de pointes. These after-depolarizations do not happen uniformly across the myocardium and are more common in endocardial tissue where the repolarization currents are slower. So torsades de pointes arises from the after-depolarizations causing reentry currents in neighboring tissue.', '44532f18-cc77-412b-9a9f-8e896baa0e7c': 'Both common garden variety VTs\xa0and torsades de pointes can progress to ventricular fibrillation.', 'f04b8ce2-30d4-4391-bb46-71176695b350': 'Table 1.8: VT summary.'}"
Figure 1.8,cardio/images/Figure 1.8.jpg,Figure 1.8: Torsades de pointes.,"Torsades de pointes (twist of peaks) is a form of VT with multiple QRS morphologies. The twist references the undulating amplitude of the QRS complexes that twist around the isoelectric line, giving the ECG the appearance of a twisted ribbon (figure 1.8).","{'0ee66a98-cebd-476f-99fb-3bd440a76037': 'Ventricular tachycardia (VT) is caused by reentry currents being established in the ventricular myocardium or groups of ventricular myocytes that have aberrant electrical behavior. As such, VT is usually caused by underlying cardiac disease.', 'c446e254-69fd-477f-b95e-d85d69a4a7bc': 'Like a PVC, the aberrant depolarizations do not follow the normal conduction pathways so are wide (>120 msecs), but unlike a PVC, VT involves a ventricular rate >100 bpm. With disorganized contractility and reduced filling time, VT can lead to hemodynamic instability and severe hypotension—hence it is life threatening.', '740e2583-adaa-4879-9900-42e40e3469ca': 'The QRS morphology in VT is highly variable between patients and depends on where the arrhythmia originates. Consequently there are several ways to classify VT based on duration, symptoms, QRS morphology, rate, and origin.', 'c3cb9d9f-2d2b-4cfe-8810-58f2fa676d70': 'Sustained VT is any VT\xa0that lasts for more than 30 seconds or is symptomatic. Nonsustained VT lasts for less than 30 seconds and is asymptomatic.', '404d4366-865a-4d38-8585-bbc56474a36d': 'VT can be monomorphic or polymorphic (figure 1.7). The QRS complexes in monomorphic VT have the same shape and are symmetrical because they start in the same place in the myocardium. Polymorphic VT has a variable QRS shape because the depolarizations are instigated at multiple points. An electrophysiologist\xa0can describe the location(s) within the ventricles from where the VT originates\xa0using the shape(s) of the QRS complexes.', '4e92395d-61e7-40e7-b3bd-de21c9a0c006': 'Torsades de pointes (twist of peaks) is a form of VT with multiple QRS morphologies. The twist references\xa0the undulating amplitude of the QRS complexes that twist around the isoelectric line, giving the ECG the appearance of a twisted ribbon (figure 1.8).', '4165fe0e-c783-42fb-9b63-edc7c4a8c906': 'Torsades de pointes is associated with a prolonged QT interval (>600 msecs) that helps distinguish it from other forms of polymorphous VT. The longer QT interval can be caused by ionic abnormalities that reduce the repolarizing current of Phase 3 of the cardiac action potential. This makes the myocardium susceptible to early after-depolarizations—the trigger for torsades de pointes. These after-depolarizations do not happen uniformly across the myocardium and are more common in endocardial tissue where the repolarization currents are slower. So torsades de pointes arises from the after-depolarizations causing reentry currents in neighboring tissue.', '44532f18-cc77-412b-9a9f-8e896baa0e7c': 'Both common garden variety VTs\xa0and torsades de pointes can progress to ventricular fibrillation.', 'f04b8ce2-30d4-4391-bb46-71176695b350': 'Table 1.8: VT summary.'}"
Figure 1.9,cardio/images/Figure 1.9.jpg,Figure 1.9: Example of VF with no recognizable P-waves or QRS complexes.,"There are a number of instigating events, but coronary artery disease and resultant myocardial ischemia or tissue scarring are the most common. The onset of VF may be preceded by other changes in the myocardial rhythmicity, such as PVCs, ST changes, VT, or QT prolongation. The tissue damage allows formation of reentry patterns that cause the chaotic ventricular depolarization. These reentry patterns break up into multiple smaller wavelets that cause high-frequency activation of the myocytes. The result is an ECG that is chaotic (figure 1.9) and consequently a heart that has little output.","{'33e8af1d-efa7-4fd2-98e0-85c264cccead': 'Ventricular fibrillation (VF) occurs when the ventricular rate exceeds 400 bpm. The disorganized and uncoordinated contraction of the myocardium causes cardiac output to fall to catastrophic levels. Rates of survival for out-of-hospital VF are low.', '01764ee2-2aa5-4abb-899c-572d11954a23': 'There are a number of instigating events, but coronary artery disease and resultant myocardial ischemia or tissue scarring are the most common. The onset of VF may be preceded by other changes in the myocardial rhythmicity, such as PVCs, ST changes, VT, or QT prolongation. The tissue damage allows formation of reentry patterns that cause the chaotic ventricular depolarization. These reentry patterns break up into multiple smaller wavelets that cause high-frequency activation of the myocytes. The result is an ECG that is chaotic (figure 1.9) and consequently a heart that has little output.', '21fd698f-b39d-40ea-9c6a-ae7c5d2c7faf': 'Table 1.9: VF summary.'}"
Figure 1.10,cardio/images/Figure 1.10.jpg,Figure 1.10: Example of first-degree block with P-R interval >0.2 seconds.,"A first-degree atrioventricular node block results from slow action potential conduction through the AV node conduction. The slowing can be due to changes in vagal tone or structural changes associated with damage or disease affecting the conductive tissue of the atria, AV node (most common), bundle of His or bundle branches, and Purkinje system. It takes longer for the action potential to reach the ventricles, so P and R appear further apart. The P-R interval is normally between 0.12 and 0.20 seconds, but in first-degree block it exceeds 0.20 seconds (>5 small boxes; figure 1.10).","{'26fd284b-1d08-488e-addc-2f1d278c835d': 'A first-degree atrioventricular node block results from slow action potential conduction through the\xa0AV node\xa0conduction. The slowing can be due to changes in vagal tone or structural changes associated with damage or disease affecting the conductive tissue of the atria, AV node (most common), bundle of His or bundle branches, and Purkinje system. It\xa0takes longer for the action potential\xa0to reach the ventricles, so P and R appear further apart. The P-R interval is normally between 0.12 and 0.20 seconds, but in first-degree block\xa0it exceeds\xa00.20 seconds (>5 small boxes;\xa0figure 1.10).', 'c0c80220-7953-4f14-aa25-f18009fc23d1': 'In first-degree block each P-wave is accompanied by a QRS complex\xa0(i.e.,\xa0“they all get through”) (figure 1.10), which is not the case in second-degree and third-degree blocks (see below). Generally a first-degree block is asymptomatic and does not require any treatment, but long-term monitoring for worsening conduction is advisable.', 'c743fff8-73b7-4075-a969-1feae0d8a568': 'Table 1.10: First-degree block summary.'}"
Figure 1.11,cardio/images/Figure 1.11.jpg,Figure 1.11: Mobitz I (second-degree block) with P-R intervals shown in seconds.,Mobitz I (or Wenckebach)—The P-R interval progressively lengthens until a P-wave is missed and then goes back to its original length (figure 1.11). So P-R is longest before the dropped QRS complex and shortest immediately after it. This progressive difficulty in traversing the AV node is reflective of the node becoming increasingly refractory.,"{'df09dbda-3d2e-4c9b-8b12-c7c7c05b4acb': 'A second-degree atrioventricular block also has changes in P-R interval, but it starts to show failure of the P-wave to propagate a QRS complex every time (i.e., intermittently the depolarization fails to reach the ventricles). The pattern of missed ventricular depolarizations, or blocked P-waves, is often very regular and described as a ratio of P-waves to QRS complex. The way in which the P-R interval changes in relation to the blocked P-waves produces subclassifications of second-degree blocks, Mobitz I and II.', 'f9d26c65-3284-41a0-b2ad-4b66547da199': 'Mobitz I (or Wenckebach)—The P-R interval progressively lengthens until a P-wave is missed and then goes back to its original length (figure 1.11).\xa0So P-R is longest before the dropped QRS complex and shortest immediately after it. This progressive difficulty in traversing the AV node is reflective of the node becoming increasingly refractory.', '48fe1443-e99b-4d7a-ad87-78d36e7557b0': 'Mobitz II has blocked P-waves as well, but the P-R interval remains unchanged, and the P:QRS ratio\xa0appears in a fixed pattern (figure 1.12). This is a rarer and more serious condition and usually involves problems with the conduction system below the AV node, most commonly in the bundle branches. What can frequently been seen is a widening of the QRS complex that are generated.', 'a1642ccd-4cff-4d8a-9308-edf4c700436d': 'Table 1.11: Second-degree block summary.'}"
Figure 1.12,cardio/images/Figure 1.12.jpg,"Figure 1.12: Mobitz II (second-degree block) with arrows showing P-waves. The P-R interval is stable, and the ratio is 3:1.","Mobitz II has blocked P-waves as well, but the P-R interval remains unchanged, and the P:QRS ratio appears in a fixed pattern (figure 1.12). This is a rarer and more serious condition and usually involves problems with the conduction system below the AV node, most commonly in the bundle branches. What can frequently been seen is a widening of the QRS complex that are generated.","{'df09dbda-3d2e-4c9b-8b12-c7c7c05b4acb': 'A second-degree atrioventricular block also has changes in P-R interval, but it starts to show failure of the P-wave to propagate a QRS complex every time (i.e., intermittently the depolarization fails to reach the ventricles). The pattern of missed ventricular depolarizations, or blocked P-waves, is often very regular and described as a ratio of P-waves to QRS complex. The way in which the P-R interval changes in relation to the blocked P-waves produces subclassifications of second-degree blocks, Mobitz I and II.', 'f9d26c65-3284-41a0-b2ad-4b66547da199': 'Mobitz I (or Wenckebach)—The P-R interval progressively lengthens until a P-wave is missed and then goes back to its original length (figure 1.11).\xa0So P-R is longest before the dropped QRS complex and shortest immediately after it. This progressive difficulty in traversing the AV node is reflective of the node becoming increasingly refractory.', '48fe1443-e99b-4d7a-ad87-78d36e7557b0': 'Mobitz II has blocked P-waves as well, but the P-R interval remains unchanged, and the P:QRS ratio\xa0appears in a fixed pattern (figure 1.12). This is a rarer and more serious condition and usually involves problems with the conduction system below the AV node, most commonly in the bundle branches. What can frequently been seen is a widening of the QRS complex that are generated.', 'a1642ccd-4cff-4d8a-9308-edf4c700436d': 'Table 1.11: Second-degree block summary.'}"
Figure 1.13,cardio/images/Figure 1.13.jpg,Figure 1.13: Third-degree block with P-waves (black arrows) having an SA node rate of 100 bpm and the ventricles depolarizing (blue arrows) at 33 bpm.,"A third-degree atrioventricular block is where no action potentials pass through the AV node, hence it is often called “complete heart block”. This is usually because of damage (e.g., ischemia) or disease (e.g., Lyme disease, sarcoidosis) affecting the AV node. In a third-degree atrioventricular block, no P-waves have associated QRS complexes. Without any descending control by the SA node pacemakers, the ventricular pacemaker cells are finally free to rule the ventricles (insert maniacal laughter). Consequently P-waves and QRS complexes are completely unrelated to each other, and this is termed “AV dissociation.” The ECG (figure 1.13) reflects this with P-waves occurring at an SA node rate (~75 bpm with parasympathetic tone) and the ventricles depolarizing at between thirty and fifty times per minute, depending on which ventricular tissue acts as pacemaker.","{'61b944f1-ad84-4652-aadc-89ed8cf18352': 'A third-degree atrioventricular block is where\xa0no action potentials\xa0pass\xa0through the AV node, hence it is often called “complete heart block”. This is usually because of damage (e.g., ischemia) or disease (e.g., Lyme disease, sarcoidosis) affecting the AV node. In a third-degree atrioventricular\xa0block, no P-waves have associated QRS complexes. Without any descending control by the SA node pacemakers, the ventricular pacemaker cells\xa0are finally free to rule the ventricles\xa0(insert maniacal laughter). Consequently P-waves and QRS complexes are completely unrelated to each other, and this is termed “AV dissociation.”\xa0The ECG (figure 1.13) reflects this with P-waves occurring at an SA node rate (~75 bpm with parasympathetic tone) and the ventricles depolarizing at between thirty and fifty\xa0times per minute, depending on which ventricular tissue acts as pacemaker.', '190d3598-0b72-47c6-9ef7-0547c20cfca4': 'Table 1.12: Third-degree block summary.'}"
Figure 1.14,cardio/images/Figure 1.14.jpg,Figure 1.14: Example of LBBB with defining features labeled.,"Because the normal route through conductive tissue is impaired or blocked, the depolarization has to travel through myocytes, which takes more time. Consequently, the QRS complex is wider (figure 1.14) (i.e., has a duration >120 msecs, with 80–100 msecs being normal). The slower conduction through the left ventricle means the right ventricle depolarizes first and the left last. This means the depolarization has a prominent right-then-left direction and will be moving away from lead V1, causing that lead to have a deep downward S-wave (figure 1.14).","{'7d8c7572-df90-4f8b-9ce4-756804698c77': 'A left bundle branch block (LBBB) is generated when the conductivity of the His-Purkinje system in the left ventricle is compromised, either through damage or disease. The ECG changes, and criteria for LBBB relate to these changes in conductivity and the left-side\xa0location.', 'd816de31-6a21-4de3-a05e-28301d77ae86': 'Because the normal route through conductive tissue is impaired or blocked, the depolarization has to travel through myocytes,\xa0which takes more time. Consequently, the QRS complex is wider (figure 1.14) (i.e., has a duration >120 msecs, with 80–100 msecs being normal).\xa0The slower conduction through the left ventricle means the right ventricle depolarizes first and the left last. This means the depolarization has a prominent right-then-left direction and will be moving away from lead V1, causing that lead to have a deep downward S-wave\xa0(figure 1.14).', 'ea861933-f312-44a7-b370-ce8f7bcfde6d': 'The lateral leads (I, V5, and V6) normally show a downward deflecting Q-wave as normal septal deflection initially occurs left-to-right (i.e., away from the lateral leads). In LBBB the change in direction to right-to-left, plus the longer duration, eliminates the Q-wave from the lateral leads, and Q-waves will be small in aVL.', '2080c0ff-56d1-4e29-8db3-51cc8f868100': 'The R-wave in the lateral leads may also change morphology when there is a distinct separation of right and then left ventricular depolarization. This manifests as an M-shaped R-wave (figure 1.15) or a notched R-wave in the lateral leads (figure 1.14).', 'a1da0307-b435-4784-be2c-4eac84a16ecc': 'Conversely a W-shaped R-wave may occur in leads facing the opposite direction\xa0(e.g., aVR) (figure 1.14).', 'e92edea7-e190-4049-ba98-e1f1633e591f': 'Table 1.13: LBBB summary.'}"
Figure 1.15,cardio/images/Figure 1.15.jpg,Figure 1.15: Changes in R-wave morphology as differences in left and right depolarization produce an M-shaped wave.,The R-wave in the lateral leads may also change morphology when there is a distinct separation of right and then left ventricular depolarization. This manifests as an M-shaped R-wave (figure 1.15) or a notched R-wave in the lateral leads (figure 1.14).,"{'7d8c7572-df90-4f8b-9ce4-756804698c77': 'A left bundle branch block (LBBB) is generated when the conductivity of the His-Purkinje system in the left ventricle is compromised, either through damage or disease. The ECG changes, and criteria for LBBB relate to these changes in conductivity and the left-side\xa0location.', 'd816de31-6a21-4de3-a05e-28301d77ae86': 'Because the normal route through conductive tissue is impaired or blocked, the depolarization has to travel through myocytes,\xa0which takes more time. Consequently, the QRS complex is wider (figure 1.14) (i.e., has a duration >120 msecs, with 80–100 msecs being normal).\xa0The slower conduction through the left ventricle means the right ventricle depolarizes first and the left last. This means the depolarization has a prominent right-then-left direction and will be moving away from lead V1, causing that lead to have a deep downward S-wave\xa0(figure 1.14).', 'ea861933-f312-44a7-b370-ce8f7bcfde6d': 'The lateral leads (I, V5, and V6) normally show a downward deflecting Q-wave as normal septal deflection initially occurs left-to-right (i.e., away from the lateral leads). In LBBB the change in direction to right-to-left, plus the longer duration, eliminates the Q-wave from the lateral leads, and Q-waves will be small in aVL.', '2080c0ff-56d1-4e29-8db3-51cc8f868100': 'The R-wave in the lateral leads may also change morphology when there is a distinct separation of right and then left ventricular depolarization. This manifests as an M-shaped R-wave (figure 1.15) or a notched R-wave in the lateral leads (figure 1.14).', 'a1da0307-b435-4784-be2c-4eac84a16ecc': 'Conversely a W-shaped R-wave may occur in leads facing the opposite direction\xa0(e.g., aVR) (figure 1.14).', 'e92edea7-e190-4049-ba98-e1f1633e591f': 'Table 1.13: LBBB summary.'}"
Figure 1.16,cardio/images/Figure 1.16.jpg,Figure 1.16: Typical RSR’ pattern (upper) and slurred S-wave pattern (lower) of RBBB.,"Again the QRS complex becomes broad (>120 msecs) because of the slower conduction through ventricular myocytes. However, the delayed activation of the right ventricle causes a secondary R-wave (RSR’) to occur in the right precordial leads (V1–V3) and a slurred S-wave in the lateral leads (I, aVL, and frequently V5 and V6) (figure 1.16).","{'205b49ac-17ce-43c1-aacd-68e3d026a96b': 'The causes and manifestations of a right bundle branch block (RBBB) bear some similarities to those described for LBBB, but of course this time its depolarization of the right ventricle\xa0is\xa0delayed. Causes of RBBB include ischemic heart disease again as well as other myocardial diseases, but pulmonary issues such as pulmonary embolism and cor pulmonale can be added to the list.', '421580b1-f84f-4e74-96ce-fc2031991d9d': 'Again the QRS complex becomes broad (>120 msecs) because of the slower conduction through ventricular myocytes. However, the delayed activation of the right ventricle causes a secondary R-wave (RSR’) to occur in the right precordial leads (V1–V3) and a slurred S-wave in the lateral leads (I, aVL, and frequently V5 and V6) (figure 1.16).', 'fe029546-fd85-41f4-8858-24dfa01f1d67': 'Table 1.14: RBBB summary.'}"
Figure 1.17,cardio/images/Figure 1.17.jpg,Figure 1.17: Schematics of normal WPW syndrome conductivity pathways.,"The accessory pathway provides a second route (figure 1.17) for normal sinus rhythm to pass from atrium to ventricle much more quickly (there is no AV node delay), thus the P-R interval is shortened. Because of this “preexcitation” through the accessory pathway, the ECG shows a slurring of the onset of the QRS complex, referred to as a delta wave because of its triangular shape (figure 1.18).","{'330caca1-1db9-4ae4-9ff4-9452e5516814': 'Normally the only electrical connection between the atria and the ventricles is the AV node. Otherwise the fibrous skeleton of the heart electrically\xa0insulates the atria from the ventricles. In Wolff-Parkinson-White (WPW)\xa0syndrome, that insulation is incomplete, and an “accessory pathway” connects the electrical system of the atria directly to the ventricles. If you think of the AV node as a\xa0bridge over the fibrous wall with regulated\xa0access, the accessory pathway is like a pathological tunnel under it with no regulation.', '2e85d51e-4ad4-4591-8ff6-5d386e5cced4': 'The accessory pathway provides a second route (figure 1.17) for normal sinus rhythm to pass from atrium to ventricle much more quickly (there is\xa0no AV node\xa0delay), thus the P-R interval is shortened. Because of this “preexcitation” through the accessory pathway, the ECG\xa0shows a slurring of the onset of the QRS complex, referred to as a delta wave because of its triangular shape (figure 1.18).', 'cb95c23f-df1f-4ad6-9ae3-5dcf0a4ade4d': 'WPW syndrome is often asymptomatic, and patients do not require immediate treatment. However, if atrial fibrillation occurs in a WPW\xa0patient, the accessory pathway can allow the atrial\xa0fibrillation waves through to the ventricle (with no AV\xa0nodal refractory period to prevent them).\xa0Consequently a high ventricular rate is seen, and the risk of ventricular fibrillation being established means immediate clinical attention is required.'}"
Figure 1.19,cardio/images/Figure 1.19.jpg,Figure 1.19: Changes in QT interval in moderate hypercalcemia and hypocalcemia.,"Moderate rises in extracellular levels of Ca++ (3.0–3.4 mmol/L, normal = 2.1–2.6 mmol/L) block the movement of sodium through voltage-gated sodium channels. This results in a reduced depolarization of myocytes, and consequently repolarization time is less. Raised extracellular Ca++ also changes the closing kinetics of the L-type Ca++ channels such that the plateau phase of the cardiac action potential is shortened and repolarization occurs earlier. These two effects manifest as the most common ECG finding of short QT intervals, mainly through shortening of the ST segment (figure 1.19).","{'38c72953-09f5-4d7b-8d42-b09066da831a': 'Moderate rises in extracellular levels of Ca++ (3.0–3.4 mmol/L, normal = 2.1–2.6 mmol/L) block the\xa0movement of sodium\xa0through voltage-gated sodium channels. This results in a reduced depolarization of myocytes, and consequently repolarization time is\xa0less. Raised extracellular\xa0Ca++\xa0also\xa0changes the\xa0closing kinetics of the L-type Ca++ channels such that the plateau phase of the cardiac action potential\xa0is shortened and repolarization occurs earlier.\xa0These two\xa0effects manifest as the most common ECG finding of short QT intervals,\xa0mainly through shortening of the ST segment (figure 1.19).', '63b671b1-8b99-4cdb-b28f-24b3e8fc25b8': 'If hypercalcemia becomes severe (>3.4 mmol/L) then Osborne waves (or J-waves) may be seen—an extra wave seen at the J-point of the ECG (the R-ST junction). The pathophysiology of the J-wave (figure 1.20) is poorly understood, but it is likely caused by an early repolarization of the epicardium—think of it as a chunk of early T-wave. (The other common cause of J-waves is hypothermia.)\xa0During hypocalcemia (<2.2 mmol/L) the opposite changes are seen in the ECG—the QT interval is prolonged, primarily due to a lengthened ST segment (figure 1.19).', 'fefcffa4-b8dc-4ef8-a8c2-701e5e9afbe3': 'Table 1.16: Hyper- and hypocalcemia summary.'}"
Figure 1.20,cardio/images/Figure 1.20.jpg,Figure 1.20: J-waves arise during hypothermia but can also be caused by hypercalcemia.,"If hypercalcemia becomes severe (>3.4 mmol/L) then Osborne waves (or J-waves) may be seen—an extra wave seen at the J-point of the ECG (the R-ST junction). The pathophysiology of the J-wave (figure 1.20) is poorly understood, but it is likely caused by an early repolarization of the epicardium—think of it as a chunk of early T-wave. (The other common cause of J-waves is hypothermia.) During hypocalcemia (<2.2 mmol/L) the opposite changes are seen in the ECG—the QT interval is prolonged, primarily due to a lengthened ST segment (figure 1.19).","{'38c72953-09f5-4d7b-8d42-b09066da831a': 'Moderate rises in extracellular levels of Ca++ (3.0–3.4 mmol/L, normal = 2.1–2.6 mmol/L) block the\xa0movement of sodium\xa0through voltage-gated sodium channels. This results in a reduced depolarization of myocytes, and consequently repolarization time is\xa0less. Raised extracellular\xa0Ca++\xa0also\xa0changes the\xa0closing kinetics of the L-type Ca++ channels such that the plateau phase of the cardiac action potential\xa0is shortened and repolarization occurs earlier.\xa0These two\xa0effects manifest as the most common ECG finding of short QT intervals,\xa0mainly through shortening of the ST segment (figure 1.19).', '63b671b1-8b99-4cdb-b28f-24b3e8fc25b8': 'If hypercalcemia becomes severe (>3.4 mmol/L) then Osborne waves (or J-waves) may be seen—an extra wave seen at the J-point of the ECG (the R-ST junction). The pathophysiology of the J-wave (figure 1.20) is poorly understood, but it is likely caused by an early repolarization of the epicardium—think of it as a chunk of early T-wave. (The other common cause of J-waves is hypothermia.)\xa0During hypocalcemia (<2.2 mmol/L) the opposite changes are seen in the ECG—the QT interval is prolonged, primarily due to a lengthened ST segment (figure 1.19).', 'fefcffa4-b8dc-4ef8-a8c2-701e5e9afbe3': 'Table 1.16: Hyper- and hypocalcemia summary.'}"
Figure 1.21,cardio/images/Figure 1.21.jpg,Figure 1.21: A prominent U-wave and inverted T-wave associated with hypokalemia.,"Your intuition may lead you to think that hypokalemia (<2.7 mmol/L) would increase K+ conductances because there is a greater gradient from inside to outside the cell, but that is not the case. Instead hypokalemia suppresses K+ channel conductances by destabilizing K+ channels. With low K+ conductance, the ECG changes reflect problems with repolarization. The T-wave is flattened and can be inverted, and a prominent U-wave may be seen in the precordial leads (figure 1.21). ST depression may also be apparent.","{'a06e32f7-e9ee-43af-9582-869eb8490ff4': 'The pathophysiology is not as simple as changes in extracellular K+ changing the electrochemical gradient for K+. Because of potassium’s role in maintaining the resting membrane potential, shifts in extracellular potassium can also influence the activity of Na+ and Ca++ channels.', '2667f29a-a755-4a38-985d-d706f37adaba': 'Your intuition may lead you to think that hypokalemia (<2.7 mmol/L) would increase K+ conductances because there is a greater gradient from inside to outside the cell, but that is not the case. Instead hypokalemia suppresses K+ channel conductances by destabilizing K+ channels. With low K+ conductance, the ECG changes reflect problems with repolarization. The T-wave is flattened and can be inverted, and a prominent U-wave may be seen in the precordial leads (figure 1.21). ST depression may also be apparent.', '37c842fb-78a5-4e08-a063-339d8ef14949': 'As hypokalemia also inhibits Na+-K+ ATPase, Na+ accumulates inside the cell. This in turn leads to an accumulation of Ca++ because of a subsequent failure of the Na+-Ca++ exchanger. Extended presence of these two positive ions inside the myocyte\xa0prolongs the\xa0action potential\xa0and may manifest as an increased width and amplitude of the P-wave.', '76f1e8bf-2c73-4b0a-89b6-b9ba772253a5': 'As hypokalemia worsens, the problems with K+ conductance and repolarization increase, and the myocardium becomes susceptible to early after-depolarization (EAD) arrhythmias.', 'a52d120f-fd2e-4cd2-b407-63069bdc1796': 'As K+\xa0is retained in the myocyte (due to the poor K+ conductance)\xa0and elevated\xa0intracellular\xa0Na+ and Ca++ results in\xa0the myocyte\xa0being\xa0more capable of depolarizing again.\xa0\xa0Because these after-depolarizations (figure 1.22) may not be uniform across the whole myocardium, an arrhythmia can be established. Potential arrhythmias include life-threatening forms, such as VT, VF, or torsades de pointes.', 'fbfd6120-fe57-4551-99a2-1931c696dee2': 'Hyperkalaemia produces different changes in myocardial excitability depending on the degree of excess potassium. Again the changes in excitability do not\xa0necessarily follow an intuitive logic of the change in the electrochemical gradient of K+.\xa0Mild hyperkalemia (5.5–6.5 mEq/L) causes peaked T-waves (figure 1.23)—the first sign of raised extracellular potassium. The excess potassium allosterically interferes with K+ channels\xa0and, inverse to hypokalemia, causes an increase in K+ conductance (despite the lower transmembrane gradient).', 'b8e21e93-ae09-4953-9220-de2a123f5fc4': 'Moderate hyperkalemia (5.5–6.5 mEq/L) raises the membrane potential closer to the threshold of voltage-gated Na+ channels (-70 mV) and voltage-gated Ca++channels. Consequently these channels are more likely to fire and cause depolarization, hence the myocardium is initially more excitable. However, this persistent depolarization leaves the slow deactivation (h)\xa0gates on Na+ channels closed for longer, and the ECG manifestations soon reflect a decreased excitability. The P-wave is longer but has low amplitude (and may eventually disappear), the QT interval is prolonged, and there is a decreased R-wave amplitude (figure 1.24). In simpler terms, the overstimulation of Na+ channels causes them to “lock up.”', '97d5700a-306c-4745-90d8-94d723590dea': 'Severe hyperkalemia (>7.0 mEq/L) sees a worsening of the unresponsiveness of the myocardium, and the SA node rhythm is slowed, producing sinus bradycardia until there is no P-wave. Conductive issues arise, and a high-grade atrioventricular\xa0block is likely, allowing ventricular pacemakers to take over, but the ventricular myocardium is also unresponsive, so the QRS complex becomes broad and sine wave–like on the ECG (figure 1.25); this is\xa0a preterminal rhythm. At this point cardiovascular collapse and death are imminent, often through a VF finale.', '2f0edb5d-c677-4289-bf39-55bb65e19c52': 'Table 1.17: Hypo- and hyperkalemia summary.'}"
Figure 1.22,cardio/images/Figure 1.22.jpg,Figure 1.22: Early after-depolarizations occurring in a cardiac action potential due to poor K+ conductance in hypokalemia.,"As K+ is retained in the myocyte (due to the poor K+ conductance) and elevated intracellular Na+ and Ca++ results in the myocyte being more capable of depolarizing again.  Because these after-depolarizations (figure 1.22) may not be uniform across the whole myocardium, an arrhythmia can be established. Potential arrhythmias include life-threatening forms, such as VT, VF, or torsades de pointes.","{'a06e32f7-e9ee-43af-9582-869eb8490ff4': 'The pathophysiology is not as simple as changes in extracellular K+ changing the electrochemical gradient for K+. Because of potassium’s role in maintaining the resting membrane potential, shifts in extracellular potassium can also influence the activity of Na+ and Ca++ channels.', '2667f29a-a755-4a38-985d-d706f37adaba': 'Your intuition may lead you to think that hypokalemia (<2.7 mmol/L) would increase K+ conductances because there is a greater gradient from inside to outside the cell, but that is not the case. Instead hypokalemia suppresses K+ channel conductances by destabilizing K+ channels. With low K+ conductance, the ECG changes reflect problems with repolarization. The T-wave is flattened and can be inverted, and a prominent U-wave may be seen in the precordial leads (figure 1.21). ST depression may also be apparent.', '37c842fb-78a5-4e08-a063-339d8ef14949': 'As hypokalemia also inhibits Na+-K+ ATPase, Na+ accumulates inside the cell. This in turn leads to an accumulation of Ca++ because of a subsequent failure of the Na+-Ca++ exchanger. Extended presence of these two positive ions inside the myocyte\xa0prolongs the\xa0action potential\xa0and may manifest as an increased width and amplitude of the P-wave.', '76f1e8bf-2c73-4b0a-89b6-b9ba772253a5': 'As hypokalemia worsens, the problems with K+ conductance and repolarization increase, and the myocardium becomes susceptible to early after-depolarization (EAD) arrhythmias.', 'a52d120f-fd2e-4cd2-b407-63069bdc1796': 'As K+\xa0is retained in the myocyte (due to the poor K+ conductance)\xa0and elevated\xa0intracellular\xa0Na+ and Ca++ results in\xa0the myocyte\xa0being\xa0more capable of depolarizing again.\xa0\xa0Because these after-depolarizations (figure 1.22) may not be uniform across the whole myocardium, an arrhythmia can be established. Potential arrhythmias include life-threatening forms, such as VT, VF, or torsades de pointes.', 'fbfd6120-fe57-4551-99a2-1931c696dee2': 'Hyperkalaemia produces different changes in myocardial excitability depending on the degree of excess potassium. Again the changes in excitability do not\xa0necessarily follow an intuitive logic of the change in the electrochemical gradient of K+.\xa0Mild hyperkalemia (5.5–6.5 mEq/L) causes peaked T-waves (figure 1.23)—the first sign of raised extracellular potassium. The excess potassium allosterically interferes with K+ channels\xa0and, inverse to hypokalemia, causes an increase in K+ conductance (despite the lower transmembrane gradient).', 'b8e21e93-ae09-4953-9220-de2a123f5fc4': 'Moderate hyperkalemia (5.5–6.5 mEq/L) raises the membrane potential closer to the threshold of voltage-gated Na+ channels (-70 mV) and voltage-gated Ca++channels. Consequently these channels are more likely to fire and cause depolarization, hence the myocardium is initially more excitable. However, this persistent depolarization leaves the slow deactivation (h)\xa0gates on Na+ channels closed for longer, and the ECG manifestations soon reflect a decreased excitability. The P-wave is longer but has low amplitude (and may eventually disappear), the QT interval is prolonged, and there is a decreased R-wave amplitude (figure 1.24). In simpler terms, the overstimulation of Na+ channels causes them to “lock up.”', '97d5700a-306c-4745-90d8-94d723590dea': 'Severe hyperkalemia (>7.0 mEq/L) sees a worsening of the unresponsiveness of the myocardium, and the SA node rhythm is slowed, producing sinus bradycardia until there is no P-wave. Conductive issues arise, and a high-grade atrioventricular\xa0block is likely, allowing ventricular pacemakers to take over, but the ventricular myocardium is also unresponsive, so the QRS complex becomes broad and sine wave–like on the ECG (figure 1.25); this is\xa0a preterminal rhythm. At this point cardiovascular collapse and death are imminent, often through a VF finale.', '2f0edb5d-c677-4289-bf39-55bb65e19c52': 'Table 1.17: Hypo- and hyperkalemia summary.'}"
Figure 1.23,cardio/images/Figure 1.23.jpg,Figure 1.23: Peaked T-waves with mild hyperkalemia.,"Hyperkalaemia produces different changes in myocardial excitability depending on the degree of excess potassium. Again the changes in excitability do not necessarily follow an intuitive logic of the change in the electrochemical gradient of K+. Mild hyperkalemia (5.5–6.5 mEq/L) causes peaked T-waves (figure 1.23)—the first sign of raised extracellular potassium. The excess potassium allosterically interferes with K+ channels and, inverse to hypokalemia, causes an increase in K+ conductance (despite the lower transmembrane gradient).","{'a06e32f7-e9ee-43af-9582-869eb8490ff4': 'The pathophysiology is not as simple as changes in extracellular K+ changing the electrochemical gradient for K+. Because of potassium’s role in maintaining the resting membrane potential, shifts in extracellular potassium can also influence the activity of Na+ and Ca++ channels.', '2667f29a-a755-4a38-985d-d706f37adaba': 'Your intuition may lead you to think that hypokalemia (<2.7 mmol/L) would increase K+ conductances because there is a greater gradient from inside to outside the cell, but that is not the case. Instead hypokalemia suppresses K+ channel conductances by destabilizing K+ channels. With low K+ conductance, the ECG changes reflect problems with repolarization. The T-wave is flattened and can be inverted, and a prominent U-wave may be seen in the precordial leads (figure 1.21). ST depression may also be apparent.', '37c842fb-78a5-4e08-a063-339d8ef14949': 'As hypokalemia also inhibits Na+-K+ ATPase, Na+ accumulates inside the cell. This in turn leads to an accumulation of Ca++ because of a subsequent failure of the Na+-Ca++ exchanger. Extended presence of these two positive ions inside the myocyte\xa0prolongs the\xa0action potential\xa0and may manifest as an increased width and amplitude of the P-wave.', '76f1e8bf-2c73-4b0a-89b6-b9ba772253a5': 'As hypokalemia worsens, the problems with K+ conductance and repolarization increase, and the myocardium becomes susceptible to early after-depolarization (EAD) arrhythmias.', 'a52d120f-fd2e-4cd2-b407-63069bdc1796': 'As K+\xa0is retained in the myocyte (due to the poor K+ conductance)\xa0and elevated\xa0intracellular\xa0Na+ and Ca++ results in\xa0the myocyte\xa0being\xa0more capable of depolarizing again.\xa0\xa0Because these after-depolarizations (figure 1.22) may not be uniform across the whole myocardium, an arrhythmia can be established. Potential arrhythmias include life-threatening forms, such as VT, VF, or torsades de pointes.', 'fbfd6120-fe57-4551-99a2-1931c696dee2': 'Hyperkalaemia produces different changes in myocardial excitability depending on the degree of excess potassium. Again the changes in excitability do not\xa0necessarily follow an intuitive logic of the change in the electrochemical gradient of K+.\xa0Mild hyperkalemia (5.5–6.5 mEq/L) causes peaked T-waves (figure 1.23)—the first sign of raised extracellular potassium. The excess potassium allosterically interferes with K+ channels\xa0and, inverse to hypokalemia, causes an increase in K+ conductance (despite the lower transmembrane gradient).', 'b8e21e93-ae09-4953-9220-de2a123f5fc4': 'Moderate hyperkalemia (5.5–6.5 mEq/L) raises the membrane potential closer to the threshold of voltage-gated Na+ channels (-70 mV) and voltage-gated Ca++channels. Consequently these channels are more likely to fire and cause depolarization, hence the myocardium is initially more excitable. However, this persistent depolarization leaves the slow deactivation (h)\xa0gates on Na+ channels closed for longer, and the ECG manifestations soon reflect a decreased excitability. The P-wave is longer but has low amplitude (and may eventually disappear), the QT interval is prolonged, and there is a decreased R-wave amplitude (figure 1.24). In simpler terms, the overstimulation of Na+ channels causes them to “lock up.”', '97d5700a-306c-4745-90d8-94d723590dea': 'Severe hyperkalemia (>7.0 mEq/L) sees a worsening of the unresponsiveness of the myocardium, and the SA node rhythm is slowed, producing sinus bradycardia until there is no P-wave. Conductive issues arise, and a high-grade atrioventricular\xa0block is likely, allowing ventricular pacemakers to take over, but the ventricular myocardium is also unresponsive, so the QRS complex becomes broad and sine wave–like on the ECG (figure 1.25); this is\xa0a preterminal rhythm. At this point cardiovascular collapse and death are imminent, often through a VF finale.', '2f0edb5d-c677-4289-bf39-55bb65e19c52': 'Table 1.17: Hypo- and hyperkalemia summary.'}"
Figure 1.24,cardio/images/Figure 1.24.jpg,"Figure 1.24: Big T, and little p and r of moderate hyperkalemia.","Moderate hyperkalemia (5.5–6.5 mEq/L) raises the membrane potential closer to the threshold of voltage-gated Na+ channels (-70 mV) and voltage-gated Ca++channels. Consequently these channels are more likely to fire and cause depolarization, hence the myocardium is initially more excitable. However, this persistent depolarization leaves the slow deactivation (h) gates on Na+ channels closed for longer, and the ECG manifestations soon reflect a decreased excitability. The P-wave is longer but has low amplitude (and may eventually disappear), the QT interval is prolonged, and there is a decreased R-wave amplitude (figure 1.24). In simpler terms, the overstimulation of Na+ channels causes them to “lock up.”","{'a06e32f7-e9ee-43af-9582-869eb8490ff4': 'The pathophysiology is not as simple as changes in extracellular K+ changing the electrochemical gradient for K+. Because of potassium’s role in maintaining the resting membrane potential, shifts in extracellular potassium can also influence the activity of Na+ and Ca++ channels.', '2667f29a-a755-4a38-985d-d706f37adaba': 'Your intuition may lead you to think that hypokalemia (<2.7 mmol/L) would increase K+ conductances because there is a greater gradient from inside to outside the cell, but that is not the case. Instead hypokalemia suppresses K+ channel conductances by destabilizing K+ channels. With low K+ conductance, the ECG changes reflect problems with repolarization. The T-wave is flattened and can be inverted, and a prominent U-wave may be seen in the precordial leads (figure 1.21). ST depression may also be apparent.', '37c842fb-78a5-4e08-a063-339d8ef14949': 'As hypokalemia also inhibits Na+-K+ ATPase, Na+ accumulates inside the cell. This in turn leads to an accumulation of Ca++ because of a subsequent failure of the Na+-Ca++ exchanger. Extended presence of these two positive ions inside the myocyte\xa0prolongs the\xa0action potential\xa0and may manifest as an increased width and amplitude of the P-wave.', '76f1e8bf-2c73-4b0a-89b6-b9ba772253a5': 'As hypokalemia worsens, the problems with K+ conductance and repolarization increase, and the myocardium becomes susceptible to early after-depolarization (EAD) arrhythmias.', 'a52d120f-fd2e-4cd2-b407-63069bdc1796': 'As K+\xa0is retained in the myocyte (due to the poor K+ conductance)\xa0and elevated\xa0intracellular\xa0Na+ and Ca++ results in\xa0the myocyte\xa0being\xa0more capable of depolarizing again.\xa0\xa0Because these after-depolarizations (figure 1.22) may not be uniform across the whole myocardium, an arrhythmia can be established. Potential arrhythmias include life-threatening forms, such as VT, VF, or torsades de pointes.', 'fbfd6120-fe57-4551-99a2-1931c696dee2': 'Hyperkalaemia produces different changes in myocardial excitability depending on the degree of excess potassium. Again the changes in excitability do not\xa0necessarily follow an intuitive logic of the change in the electrochemical gradient of K+.\xa0Mild hyperkalemia (5.5–6.5 mEq/L) causes peaked T-waves (figure 1.23)—the first sign of raised extracellular potassium. The excess potassium allosterically interferes with K+ channels\xa0and, inverse to hypokalemia, causes an increase in K+ conductance (despite the lower transmembrane gradient).', 'b8e21e93-ae09-4953-9220-de2a123f5fc4': 'Moderate hyperkalemia (5.5–6.5 mEq/L) raises the membrane potential closer to the threshold of voltage-gated Na+ channels (-70 mV) and voltage-gated Ca++channels. Consequently these channels are more likely to fire and cause depolarization, hence the myocardium is initially more excitable. However, this persistent depolarization leaves the slow deactivation (h)\xa0gates on Na+ channels closed for longer, and the ECG manifestations soon reflect a decreased excitability. The P-wave is longer but has low amplitude (and may eventually disappear), the QT interval is prolonged, and there is a decreased R-wave amplitude (figure 1.24). In simpler terms, the overstimulation of Na+ channels causes them to “lock up.”', '97d5700a-306c-4745-90d8-94d723590dea': 'Severe hyperkalemia (>7.0 mEq/L) sees a worsening of the unresponsiveness of the myocardium, and the SA node rhythm is slowed, producing sinus bradycardia until there is no P-wave. Conductive issues arise, and a high-grade atrioventricular\xa0block is likely, allowing ventricular pacemakers to take over, but the ventricular myocardium is also unresponsive, so the QRS complex becomes broad and sine wave–like on the ECG (figure 1.25); this is\xa0a preterminal rhythm. At this point cardiovascular collapse and death are imminent, often through a VF finale.', '2f0edb5d-c677-4289-bf39-55bb65e19c52': 'Table 1.17: Hypo- and hyperkalemia summary.'}"
Figure 1.25,cardio/images/Figure 1.25.jpg,Figure 1.25: Preterminal ECG of severe hyperkalemia.,"Severe hyperkalemia (>7.0 mEq/L) sees a worsening of the unresponsiveness of the myocardium, and the SA node rhythm is slowed, producing sinus bradycardia until there is no P-wave. Conductive issues arise, and a high-grade atrioventricular block is likely, allowing ventricular pacemakers to take over, but the ventricular myocardium is also unresponsive, so the QRS complex becomes broad and sine wave–like on the ECG (figure 1.25); this is a preterminal rhythm. At this point cardiovascular collapse and death are imminent, often through a VF finale.","{'a06e32f7-e9ee-43af-9582-869eb8490ff4': 'The pathophysiology is not as simple as changes in extracellular K+ changing the electrochemical gradient for K+. Because of potassium’s role in maintaining the resting membrane potential, shifts in extracellular potassium can also influence the activity of Na+ and Ca++ channels.', '2667f29a-a755-4a38-985d-d706f37adaba': 'Your intuition may lead you to think that hypokalemia (<2.7 mmol/L) would increase K+ conductances because there is a greater gradient from inside to outside the cell, but that is not the case. Instead hypokalemia suppresses K+ channel conductances by destabilizing K+ channels. With low K+ conductance, the ECG changes reflect problems with repolarization. The T-wave is flattened and can be inverted, and a prominent U-wave may be seen in the precordial leads (figure 1.21). ST depression may also be apparent.', '37c842fb-78a5-4e08-a063-339d8ef14949': 'As hypokalemia also inhibits Na+-K+ ATPase, Na+ accumulates inside the cell. This in turn leads to an accumulation of Ca++ because of a subsequent failure of the Na+-Ca++ exchanger. Extended presence of these two positive ions inside the myocyte\xa0prolongs the\xa0action potential\xa0and may manifest as an increased width and amplitude of the P-wave.', '76f1e8bf-2c73-4b0a-89b6-b9ba772253a5': 'As hypokalemia worsens, the problems with K+ conductance and repolarization increase, and the myocardium becomes susceptible to early after-depolarization (EAD) arrhythmias.', 'a52d120f-fd2e-4cd2-b407-63069bdc1796': 'As K+\xa0is retained in the myocyte (due to the poor K+ conductance)\xa0and elevated\xa0intracellular\xa0Na+ and Ca++ results in\xa0the myocyte\xa0being\xa0more capable of depolarizing again.\xa0\xa0Because these after-depolarizations (figure 1.22) may not be uniform across the whole myocardium, an arrhythmia can be established. Potential arrhythmias include life-threatening forms, such as VT, VF, or torsades de pointes.', 'fbfd6120-fe57-4551-99a2-1931c696dee2': 'Hyperkalaemia produces different changes in myocardial excitability depending on the degree of excess potassium. Again the changes in excitability do not\xa0necessarily follow an intuitive logic of the change in the electrochemical gradient of K+.\xa0Mild hyperkalemia (5.5–6.5 mEq/L) causes peaked T-waves (figure 1.23)—the first sign of raised extracellular potassium. The excess potassium allosterically interferes with K+ channels\xa0and, inverse to hypokalemia, causes an increase in K+ conductance (despite the lower transmembrane gradient).', 'b8e21e93-ae09-4953-9220-de2a123f5fc4': 'Moderate hyperkalemia (5.5–6.5 mEq/L) raises the membrane potential closer to the threshold of voltage-gated Na+ channels (-70 mV) and voltage-gated Ca++channels. Consequently these channels are more likely to fire and cause depolarization, hence the myocardium is initially more excitable. However, this persistent depolarization leaves the slow deactivation (h)\xa0gates on Na+ channels closed for longer, and the ECG manifestations soon reflect a decreased excitability. The P-wave is longer but has low amplitude (and may eventually disappear), the QT interval is prolonged, and there is a decreased R-wave amplitude (figure 1.24). In simpler terms, the overstimulation of Na+ channels causes them to “lock up.”', '97d5700a-306c-4745-90d8-94d723590dea': 'Severe hyperkalemia (>7.0 mEq/L) sees a worsening of the unresponsiveness of the myocardium, and the SA node rhythm is slowed, producing sinus bradycardia until there is no P-wave. Conductive issues arise, and a high-grade atrioventricular\xa0block is likely, allowing ventricular pacemakers to take over, but the ventricular myocardium is also unresponsive, so the QRS complex becomes broad and sine wave–like on the ECG (figure 1.25); this is\xa0a preterminal rhythm. At this point cardiovascular collapse and death are imminent, often through a VF finale.', '2f0edb5d-c677-4289-bf39-55bb65e19c52': 'Table 1.17: Hypo- and hyperkalemia summary.'}"