Modules / Lectures


Sl.No Chapter Name MP4 Download
1Lecture 1: IntroductionDownload
2Lecture 2: DNA packing and structureDownload
3Lecture 3: Shape and functionDownload
4Lecture 4: Numbers and sizesDownload
5Lecture 5: Spatial scales and System variationDownload
6Lecture 6: Timescales in BiologyDownload
7Lecture 7: Random walks and Passive diffusionDownload
8Lecture 8: Random walks to model BiologyDownload
9Lecture 9: Derivation of FRAP equationsDownload
10Lecture 10: Drift-diffusion equationsDownload
11Lecture 11: Solutions of the drift-diffusion equationsDownload
12Lecture 12: The cell signaling problemDownload
13Lecture 13: Cell Signalling and Capture Probability of absorbing sphereDownload
14Lecture 14: Capture probability of reflecting sphereDownload
15Lecture 15: Mean capture timeDownload
16Lecture 16: Introduction to fluids, viscosity and reynolds numberDownload
17Lecture 17: Introduction to the navier stokes equationDownload
18Lecture 18: Understanding reynolds number Download
19Lecture 19: Life at low reynolds numberDownload
20Lecture 20: Various phenomena at low reynolds numberDownload
21Lecture 21: Bacterial flagellar motionDownload
22Lecture 22: Rotating flagellumDownload
23Lecture 23: Energy and equilibriumDownload
24Lecture 24: Binding problemsDownload
25Lecture 25: Transcription and translationDownload
26Lecture 26: Internal states of macromoleculesDownload
27Lecture 27: Protein modification problemDownload
28Lecture 28: Haemoglobin-Oxygen binding problemDownload
29Lecture 29: Freely jointed polymer modelDownload
30Lecture 30: Entropic springs and persistence lengthDownload
31Lecture 31: Freely rotating chain model and radius of gyrationDownload
32Lecture 32: The hierarchical chromatin packing modelDownload
33Lecture 33: FISH & DNA loopingDownload
34Lecture 34: Nucleosomes as barriers, Hi-C, and contact probabilitiesDownload
35Lecture 35: Deriving the full force extension curveDownload
36Lecture 36: Random walk models for proteinsDownload
37Lecture 37: Hydrophobic polar protein modelDownload
38Lecture 38: Diffusion in crowded environmentsDownload
39Lecture 39: Depletion interactionsDownload
40Lecture 40: Examples & implications of depletion interactionsDownload
41Lecture 41: Introduction to Biological dynamicsDownload
42Lecture 42: Introduction to rate equationsDownload
43Lecture 43: Separation of timescales in enzyme kineticsDownload
44Lecture 44: Structure and treadmilling of actins and microtubulesDownload
45Lecture 45: Average length of polymers in equilibriumDownload
46Lecture 46: Growth rate of polymersDownload
47Lecture 47: Dynamic treadmilling in microtubulesDownload
48Lecture 48: Introduction to molecular motorsDownload
49Lecture 49: Force generation by molecular motorsDownload
50Lecture 50: Models of motor motionDownload
51Lecture 51: molecular motorsDownload
52Lecture 52: Free energies of motor for steppingDownload
53Lecture 53: Two state modelsDownload
54Lecture 54: cooperative transport of cargoDownload
55Lecture 55: Cytoskeleton as a motorDownload
56Lecture 56: translocation ratchetDownload
57Lecture 57: Spatial pattern in biologyDownload
58Lecture 58: Some common spatial patterns in biologyDownload
59Lecture 59: reaction diffusion and spatial patternDownload
60Lecture 60: Pattern formation in reaction diffusion system with stabilityDownload
61Lecture 61: Condition for destablization in pattern formationDownload
62Lecture 62: Schnakenberg kineticsDownload

Sl.No Chapter Name English
1Lecture 1: IntroductionDownload
Verified
2Lecture 2: DNA packing and structureDownload
Verified
3Lecture 3: Shape and functionDownload
Verified
4Lecture 4: Numbers and sizesDownload
Verified
5Lecture 5: Spatial scales and System variationDownload
Verified
6Lecture 6: Timescales in BiologyDownload
Verified
7Lecture 7: Random walks and Passive diffusionDownload
Verified
8Lecture 8: Random walks to model BiologyDownload
Verified
9Lecture 9: Derivation of FRAP equationsDownload
Verified
10Lecture 10: Drift-diffusion equationsDownload
Verified
11Lecture 11: Solutions of the drift-diffusion equationsDownload
Verified
12Lecture 12: The cell signaling problemDownload
Verified
13Lecture 13: Cell Signalling and Capture Probability of absorbing sphereDownload
Verified
14Lecture 14: Capture probability of reflecting sphereDownload
Verified
15Lecture 15: Mean capture timeDownload
Verified
16Lecture 16: Introduction to fluids, viscosity and reynolds numberDownload
Verified
17Lecture 17: Introduction to the navier stokes equationDownload
Verified
18Lecture 18: Understanding reynolds number Download
Verified
19Lecture 19: Life at low reynolds numberDownload
Verified
20Lecture 20: Various phenomena at low reynolds numberDownload
Verified
21Lecture 21: Bacterial flagellar motionDownload
Verified
22Lecture 22: Rotating flagellumDownload
Verified
23Lecture 23: Energy and equilibriumDownload
Verified
24Lecture 24: Binding problemsDownload
Verified
25Lecture 25: Transcription and translationDownload
Verified
26Lecture 26: Internal states of macromoleculesDownload
Verified
27Lecture 27: Protein modification problemDownload
Verified
28Lecture 28: Haemoglobin-Oxygen binding problemDownload
Verified
29Lecture 29: Freely jointed polymer modelDownload
Verified
30Lecture 30: Entropic springs and persistence lengthDownload
Verified
31Lecture 31: Freely rotating chain model and radius of gyrationDownload
Verified
32Lecture 32: The hierarchical chromatin packing modelDownload
Verified
33Lecture 33: FISH & DNA loopingDownload
Verified
34Lecture 34: Nucleosomes as barriers, Hi-C, and contact probabilitiesDownload
Verified
35Lecture 35: Deriving the full force extension curveDownload
Verified
36Lecture 36: Random walk models for proteinsDownload
Verified
37Lecture 37: Hydrophobic polar protein modelDownload
Verified
38Lecture 38: Diffusion in crowded environmentsDownload
Verified
39Lecture 39: Depletion interactionsDownload
Verified
40Lecture 40: Examples & implications of depletion interactionsDownload
Verified
41Lecture 41: Introduction to Biological dynamicsDownload
Verified
42Lecture 42: Introduction to rate equationsDownload
Verified
43Lecture 43: Separation of timescales in enzyme kineticsDownload
Verified
44Lecture 44: Structure and treadmilling of actins and microtubulesDownload
Verified
45Lecture 45: Average length of polymers in equilibriumDownload
Verified
46Lecture 46: Growth rate of polymersDownload
Verified
47Lecture 47: Dynamic treadmilling in microtubulesDownload
Verified
48Lecture 48: Introduction to molecular motorsDownload
Verified
49Lecture 49: Force generation by molecular motorsDownload
Verified
50Lecture 50: Models of motor motionDownload
Verified
51Lecture 51: molecular motorsDownload
Verified
52Lecture 52: Free energies of motor for steppingDownload
Verified
53Lecture 53: Two state modelsDownload
Verified
54Lecture 54: cooperative transport of cargoDownload
Verified
55Lecture 55: Cytoskeleton as a motorDownload
Verified
56Lecture 56: translocation ratchetDownload
Verified
57Lecture 57: Spatial pattern in biologyDownload
Verified
58Lecture 58: Some common spatial patterns in biologyDownload
Verified
59Lecture 59: reaction diffusion and spatial patternDownload
Verified
60Lecture 60: Pattern formation in reaction diffusion system with stabilityDownload
Verified
61Lecture 61: Condition for destablization in pattern formationDownload
Verified
62Lecture 62: Schnakenberg kineticsDownload
Verified


Sl.No Language Book link
1EnglishDownload
2BengaliNot Available
3GujaratiNot Available
4HindiNot Available
5KannadaNot Available
6MalayalamNot Available
7MarathiNot Available
8TamilNot Available
9TeluguNot Available