Modules / Lectures

Module Name | Download |
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Sl.No | Chapter Name | MP4 Download |
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1 | Lecture 1: Introduction | Download |

2 | Lecture 2: DNA packing and structure | Download |

3 | Lecture 3: Shape and function | Download |

4 | Lecture 4: Numbers and sizes | Download |

5 | Lecture 5: Spatial scales and System variation | Download |

6 | Lecture 6: Timescales in Biology | Download |

7 | Lecture 7: Random walks and Passive diffusion | Download |

8 | Lecture 8: Random walks to model Biology | Download |

9 | Lecture 9: Derivation of FRAP equations | Download |

10 | Lecture 10: Drift-diffusion equations | Download |

11 | Lecture 11: Solutions of the drift-diffusion equations | Download |

12 | Lecture 12: The cell signaling problem | Download |

13 | Lecture 13: Cell Signalling and Capture Probability of absorbing sphere | Download |

14 | Lecture 14: Capture probability of reflecting sphere | Download |

15 | Lecture 15: Mean capture time | Download |

16 | Lecture 16: Introduction to fluids, viscosity and reynolds number | Download |

17 | Lecture 17: Introduction to the navier stokes equation | Download |

18 | Lecture 18: Understanding reynolds number | Download |

19 | Lecture 19: Life at low reynolds number | Download |

20 | Lecture 20: Various phenomena at low reynolds number | Download |

21 | Lecture 21: Bacterial flagellar motion | Download |

22 | Lecture 22: Rotating flagellum | Download |

23 | Lecture 23: Energy and equilibrium | Download |

24 | Lecture 24: Binding problems | Download |

25 | Lecture 25: Transcription and translation | Download |

26 | Lecture 26: Internal states of macromolecules | Download |

27 | Lecture 27: Protein modification problem | Download |

28 | Lecture 28: Haemoglobin-Oxygen binding problem | Download |

29 | Lecture 29: Freely jointed polymer model | Download |

30 | Lecture 30: Entropic springs and persistence length | Download |

31 | Lecture 31: Freely rotating chain model and radius of gyration | Download |

32 | Lecture 32: The hierarchical chromatin packing model | Download |

33 | Lecture 33: FISH & DNA looping | Download |

34 | Lecture 34: Nucleosomes as barriers, Hi-C, and contact probabilities | Download |

35 | Lecture 35: Deriving the full force extension curve | Download |

36 | Lecture 36: Random walk models for proteins | Download |

37 | Lecture 37: Hydrophobic polar protein model | Download |

38 | Lecture 38: Diffusion in crowded environments | Download |

39 | Lecture 39: Depletion interactions | Download |

40 | Lecture 40: Examples & implications of depletion interactions | Download |

41 | Lecture 41: Introduction to Biological dynamics | Download |

42 | Lecture 42: Introduction to rate equations | Download |

43 | Lecture 43: Separation of timescales in enzyme kinetics | Download |

44 | Lecture 44: Structure and treadmilling of actins and microtubules | Download |

45 | Lecture 45: Average length of polymers in equilibrium | Download |

46 | Lecture 46: Growth rate of polymers | Download |

47 | Lecture 47: Dynamic treadmilling in microtubules | Download |

48 | Lecture 48: Introduction to molecular motors | Download |

49 | Lecture 49: Force generation by molecular motors | Download |

50 | Lecture 50: Models of motor motion | Download |

Sl.No | Chapter Name | English |
---|---|---|

1 | Lecture 1: Introduction | PDF unavailable |

2 | Lecture 2: DNA packing and structure | PDF unavailable |

3 | Lecture 3: Shape and function | PDF unavailable |

4 | Lecture 4: Numbers and sizes | PDF unavailable |

5 | Lecture 5: Spatial scales and System variation | PDF unavailable |

6 | Lecture 6: Timescales in Biology | PDF unavailable |

7 | Lecture 7: Random walks and Passive diffusion | PDF unavailable |

8 | Lecture 8: Random walks to model Biology | PDF unavailable |

9 | Lecture 9: Derivation of FRAP equations | PDF unavailable |

10 | Lecture 10: Drift-diffusion equations | PDF unavailable |

11 | Lecture 11: Solutions of the drift-diffusion equations | PDF unavailable |

12 | Lecture 12: The cell signaling problem | PDF unavailable |

13 | Lecture 13: Cell Signalling and Capture Probability of absorbing sphere | PDF unavailable |

14 | Lecture 14: Capture probability of reflecting sphere | PDF unavailable |

15 | Lecture 15: Mean capture time | PDF unavailable |

16 | Lecture 16: Introduction to fluids, viscosity and reynolds number | PDF unavailable |

17 | Lecture 17: Introduction to the navier stokes equation | PDF unavailable |

18 | Lecture 18: Understanding reynolds number | PDF unavailable |

19 | Lecture 19: Life at low reynolds number | PDF unavailable |

20 | Lecture 20: Various phenomena at low reynolds number | PDF unavailable |

21 | Lecture 21: Bacterial flagellar motion | PDF unavailable |

22 | Lecture 22: Rotating flagellum | PDF unavailable |

23 | Lecture 23: Energy and equilibrium | PDF unavailable |

24 | Lecture 24: Binding problems | PDF unavailable |

25 | Lecture 25: Transcription and translation | PDF unavailable |

26 | Lecture 26: Internal states of macromolecules | PDF unavailable |

27 | Lecture 27: Protein modification problem | PDF unavailable |

28 | Lecture 28: Haemoglobin-Oxygen binding problem | PDF unavailable |

29 | Lecture 29: Freely jointed polymer model | PDF unavailable |

30 | Lecture 30: Entropic springs and persistence length | PDF unavailable |

31 | Lecture 31: Freely rotating chain model and radius of gyration | PDF unavailable |

32 | Lecture 32: The hierarchical chromatin packing model | PDF unavailable |

33 | Lecture 33: FISH & DNA looping | PDF unavailable |

34 | Lecture 34: Nucleosomes as barriers, Hi-C, and contact probabilities | PDF unavailable |

35 | Lecture 35: Deriving the full force extension curve | PDF unavailable |

36 | Lecture 36: Random walk models for proteins | PDF unavailable |

37 | Lecture 37: Hydrophobic polar protein model | PDF unavailable |

38 | Lecture 38: Diffusion in crowded environments | PDF unavailable |

39 | Lecture 39: Depletion interactions | PDF unavailable |

40 | Lecture 40: Examples & implications of depletion interactions | PDF unavailable |

41 | Lecture 41: Introduction to Biological dynamics | PDF unavailable |

42 | Lecture 42: Introduction to rate equations | PDF unavailable |

43 | Lecture 43: Separation of timescales in enzyme kinetics | PDF unavailable |

44 | Lecture 44: Structure and treadmilling of actins and microtubules | PDF unavailable |

45 | Lecture 45: Average length of polymers in equilibrium | PDF unavailable |

46 | Lecture 46: Growth rate of polymers | PDF unavailable |

47 | Lecture 47: Dynamic treadmilling in microtubules | PDF unavailable |

48 | Lecture 48: Introduction to molecular motors | PDF unavailable |

49 | Lecture 49: Force generation by molecular motors | PDF unavailable |

50 | Lecture 50: Models of motor motion | PDF unavailable |

Sl.No | Language | Book link |
---|---|---|

1 | English | Not Available |

2 | Bengali | Not Available |

3 | Gujarati | Not Available |

4 | Hindi | Not Available |

5 | Kannada | Not Available |

6 | Malayalam | Not Available |

7 | Marathi | Not Available |

8 | Tamil | Not Available |

9 | Telugu | Not Available |