Media Storage Type : 64 GB USB Stick
NPTEL Subject Matter Expert : Prof. Mithun Mitra
NPTEL Co-ordinating Institute : IIT Bombay
NPTEL Lecture Count : 62
NPTEL Course Size : 40 GB
NPTEL PDF Text Transcription : Available and Included
NPTEL Subtitle Transcription : Available and Included (SRT)
Lecture Titles:
Lecture 1 - Introduction
Lecture 2 - DNA packing and structure
Lecture 3 - Shape and function
Lecture 4 - Numbers and sizes
Lecture 5 - Spatial scales and System variation
Lecture 6 - Timescales in Biology
Lecture 7 - Random walks and Passive diffusion
Lecture 8 - Random walks to model Biology
Lecture 9 - Derivation of FRAP equations
Lecture 10 - Drift-diffusion equations
Lecture 11 - Solutions of the drift-diffusion equations
Lecture 12 - The cell signaling problem
Lecture 13 - Cell Signalling and Capture Probability of absorbing sphere
Lecture 14 - Capture probability of reflecting sphere
Lecture 15 - Mean capture time
Lecture 16 - Introduction to fluids, viscosity and reynolds number
Lecture 17 - Introduction to the navier stokes equation
Lecture 18 - Understanding reynolds number
Lecture 19 - Life at low reynolds number
Lecture 20 - Various phenomena at low reynolds number
Lecture 21 - Bacterial flagellar motion
Lecture 22 - Rotating flagellum
Lecture 23 - Energy and equilibrium
Lecture 24 - Binding problems
Lecture 25 - Transcription and translation
Lecture 26 - Internal states of macromolecules
Lecture 27 - Protein modification problem
Lecture 28 - Haemoglobin-Oxygen binding problem
Lecture 29 - Freely jointed polymer model
Lecture 30 - Entropic springs and persistence length
Lecture 31 - Freely rotating chain model and radius of gyration
Lecture 32 - The hierarchical chromatin packing model
Lecture 33 - FISH and DNA looping
Lecture 34 - Nucleosomes as barriers, Hi-C, and contact probabilities
Lecture 35 - Deriving the full force extension curve
Lecture 36 - Random walk models for proteins
Lecture 37 - Hydrophobic polar protein model
Lecture 38 - Diffusion in crowded environments
Lecture 39 - Depletion interactions
Lecture 40 - Examples and implications of depletion interactions
Lecture 41 - Introduction to Biological dynamics
Lecture 42 - Introduction to rate equations
Lecture 43 - Separation of timescales in enzyme kinetics
Lecture 44 - Structure and treadmilling of actins and microtubules
Lecture 45 - Average length of polymers in equilibrium
Lecture 46 - Growth rate of polymers
Lecture 47 - Dynamic treadmilling in microtubules
Lecture 48 - Introduction to molecular motors
Lecture 49 - Force generation by molecular motors
Lecture 50 - Models of motor motion
Lecture 51 - molecular motors
Lecture 52 - Free energies of motor for stepping
Lecture 53 - Two state models
Lecture 54 - cooperative transport of cargo
Lecture 55 - Cytoskeleton as a motor
Lecture 56 - translocation ratchet
Lecture 57 - Spatial pattern in biology
Lecture 58 - Some common spatial patterns in biology
Lecture 59 - reaction diffusion and spatial pattern
Lecture 60 - Pattern formation in reaction diffusion system with stability
Lecture 61 - Condition for destablization in pattern formation
Lecture 62 - Schnakenberg kinetics