Title
stringlengths 0
69
| Video ID
stringlengths 0
11
|
|---|---|
Indirect and Sandwich ELISA | MzrJ35aQPMo |
Western Blotting | 8F_SFymyMCw |
Solid-Phase Synthesis of Proteins | ISjHVbG5CTE |
Introduction to Nucleic Acids | 1Wc4jTH2v_w |
Composition of Nucleic Acids | Ux1tAy1Jb_I |
Nucleosides and Nucleotides | GgQrEJaEH0U |
Watson-Crick Model of DNA | VLD9VLxN3PI |
Meselson and Stahl Experiment | _GN4F-PaAWA |
Melting and Annealing of DNA | OblPqlOOgew |
Stem-Loop Structure of RNA | g_pwHZZ0oSo |
DNA Polymerase and Catalysis of Phosphodiester Bond | wvaBZSQzGVY |
Circular DNA, RNA Genes and Viruses | TEfHW21ZIoc |
Types of RNA | ruIIccU32nU |
RNA Polymerase | 1bAhZayllHc |
Promoter and Termination Sites | a9ZMTVlrLY0 |
Central Dogma and Genetic Code | 0t5eVgtrdWg |
Start and Stop Codons | HxOGxj2jEfA |
Exons and Introns of Eukaryotic mRNA | B8gnuhvnfUs |
Introduction to Biotechnology | FlsD__uCRws |
Restriction Enzymes and Palindromic Sequences | GDIu_t_SUTY |
Southern and Northern Blotting | EoTq-Ql_Zzc |
Sanger Sequencing of DNA | IAf_6TZ6BYc |
Sanger Sequencing of DNA (Part II) | Kw2-LKRzRMM |
Amplifying DNA with Polymerase Chain Reaction | uHKiohWvY_0 |
Plasmids and Recombinant DNA technology | 2YxTcBimxlw |
Lambda Phages as Vectors | 0Mw-0G2m6uE |
Building and Screening Genomic Libraries | 2ikPiR0-rnc |
Cassette Mutagenesis and Gene Deletions | EpQB06gRoLg |
Site-Directed Mutagenesis | cCUKopDvTks |
Synthesizing cDNA with Reverse Transcriptase | EU39PDzz9co |
Gene Transfection | oj_h06k9z0g |
Heme Group of Hemoglobin and Myoglobin | L6vhDsi8O_g |
Oxygen Binding Curve for Myoglobin and Hemoglobin | Y3hRYzEmKrc |
Hemoglobin vs Myoglobin as Oxygen Carrier | XUI5vGfNYZY |
T-state and R-state of Hemoglobin | LKvQLasB6jw |
Concerted and Sequential Model for Hemoglobin | VNln4wn7_f4 |
Effect of 2,3-BPG on Hemoglobin | 20HfkCZy0dI |
Fetal Hemoglobin and 2,3 BPG | WMArOG94H3E |
The Bohr Effect and Hemoglobin | vwdT15oc3IE |
The Bohr Effect and Hemoglobin (Part II) | J7Wjq5YiJhs |
Transport of Carbon Dioxide and Chloride Shift | 7l-WHYD_uYE |
Haldane Effect | NN60olUJu1I |
High Altitude and 2,3 BPG | tTtbU8KD5JM |
Alpha Hemoglobin and Stabilizing Protein | -vpde5PGMX8 |
Sickle-Cell Anemia | e67ZP2C3Pr4 |
Properties of Enzymes | Gy3fEdy9cCA |
Enzymes’ Effect on Activation Energy and Free Energy | tPCOEUo6J8s |
Gibbs Free Energy and Spontaneity | u_IQu7h6xfo |
Enzymes Stabilize Transition State | NEQ9WS8w-2I |
Properties of Active Sites, Lock-and-Key Model and Induced Fit Model | xzeg7ult6pM |
Effect of Enzymes on Rate Law and Rate Constant | htZgbALo8uE |
Effect of Enzymes on Rate Law and Rate Constant (Part II) | yD6CTA-tT6A |
Derivation of Michaelis-Menten Equation | NVDxNal06zM |
Derivation of Michaelis Menten-Equation Part II | OOzj_dFzPH4 |
Michaelis menten Equation | ALwziZSRiqM |
Michaelis Constant | ZU2EAZQ6Mok |
Maximal Velocity and Turnover Number of Enzymes | KM2Kq9L_V4M |
Catalytic Efficiency of Enzymes | EUunw7voY-o |
Catalytic Efficiency of Enzymes Part II | 5dhAuaZMCUg |
Sequential and Ping Pong Reactions | pWURzs8GiB4 |
Mechanisms of Enzyme Catalysis | 0vvUIIulzMk |
Introduction to Proteases | Y9VgJw4w69Q |
Chymotrypsin and Covalent Catalysis | TXSZMLvqx-A |
Reaction Mechanism of Chymotrypsin | OY1WsqlcUdo |
Specificity of Serine Proteases | 4iJY90Fxj7c |
Cysteine, Apsratyl and metalloproteases | n8NFSMfV9dc |
Carbonic Anhyrdase | W5nLcHtuBvM |
NMP Kinases | z-sII0ooX3g |
Irreversible and Reversible Inhibition | 0ZiCqwtFMTs |
Irreversibile and Reversible Inhibition Part II | RouBlFpd_mk |
Enzyme Kinetics of Reversible Inhibition | rNBEUGYu034 |
Enzyme Kinetics of Reversible Inhibition (Part II) | OfjuWqtC51o |
Lineweaver Burke Plot and Reversible Inhibition | GVUkZL1jCw0 |
Lineweaver Burke Plot and REversible Inhibition Part II | md9QC5oQmLY |
Group Specific Affinity Labels and Suicide Inhibitors | K1uq9AXwo5Q |
Transition State Analogs and Catalytic Antibodies | Q1nUbwJ6wF8 |
Structure and Function of Penicillin | JZPo_iXiGuA |
Enzyme Regulation | I82orkqyOEY |
ATCase Allosteric Regulation | Z2ZN_9nFl1E |
Structure of ATCase | zSAABNvECGI |
Structure of ATCase Part II | m-SxOxZ0PwA |
Cooperatively and Allosteric Effectors of ATCase | gZmlhlK9lTQ |
Covalent Modification and Phosphorylation | zHJexIQbHvc |
Covalent Modification and Phosphorylation Part II | 0l924_AJ-iA |
Protein Kinase A | jwp5vwnTyPc |
Proteolytic Activation | Jrp7T9-fMcM |
Proteolytic Activation of Digestive Enzymes | zPX_RGh3Ho0 |
Inhibition of Digestive Enzymes | Brx4S1L6NOY |
Inhibition of Digestive Enzymes | bg0K9U5d0xU |
Activation of Coagulation Cascade | fcvhf9vmj5U |
Factor VIII and Hemophilia A | LbbzuBN2Eao |
Inhibition of Coagulation Cascade | jUs6eGbRrfk |
Isozymes | pzdjg3iG4oM |
Introduction to Carbohydrates | OBP8ltttH5U |
Aldoses, Ketoses Fischer Projections and Epimers | ECKrQu0Y2PI |
Cyclic Form of Carbohydrates | H7z1vNc1jos |
Stability of Glucose Anomie’s | MaY1UOYRFMo |
Modification of Carbohydrates | qrvlx5zD4Vc |
Disaccharides (maltose, lactose, and sucrose) | Kj15mH5zB6Y |
Polysaccharides | e0ijBDroE48 |