Lecture 1 - Need to Study Mechanobiology
Lecture 2 - Cell as a Tent, Individual Components
Lecture 3 - Cell-ECM Crosstalk
Lecture 4 - ECM Proteins: Collagen
Lecture 5 - Measuring Properties of Collagen Networks
Lecture 6 - Properties of Collagen Networks
Lecture 7 - Rheology
Lecture 8 - Rheology of Biopolymer Networks
Lecture 9 - Atomic Force Microscopy (AFM)
Lecture 10 - Design of Protein Constructs for AFM
Lecture 11 - Protein Unfolding using AFM
Lecture 12 - Protein Unfolding using AFM
Lecture 13 - Focal Adhesions: Focal Adhesion Proteins
Lecture 14 - Focal Adhesion Organization
Lecture 15 - Focal Adhesions: Role of Forces
Lecture 16 - Cytoskeleton: Actin
Lecture 17 - Force-velocity Relationships of Actin Networks
Lecture 18 - Mesenchymal Cell Migration
Lecture 19 - Actin Dynamics during Mesenchymal Migration
Lecture 20 - Actin Dynamics during Mesenchymal Migration
Lecture 21 - Adhesion Independent Migration
Lecture 22 - Adhesion Independent and Collective Cell Migration
Lecture 23 - Collective Cell Migration
Lecture 24 - Mechanobiology of Stem Cell Fate - I
Lecture 25 - Mechanobiology of Stem Cell Fate - II
Lecture 26 - Mechanobiology of Stem Cell Fate - III
Lecture 27 - Mechanobiology of Diseases: Cancer - I
Lecture 28 - Mechanobiology of Diseases: Cancer - II
Lecture 29 - Mechanobiology of Diseases: Cancer - III
Lecture 30 - Mechanobiology of Diseases: Atherosclerosis and Hypertension
Lecture 31 - Mechanobiology of Diseases: Muscular Dystrophy
Lecture 32 - Nuclear Mechanotransduction: LINC complex
Lecture 33 - Nuclear Mechanotransduction: LINC Complex in Cell Migration
Lecture 34 - Nuclear Mechanotransduction: Gene Regulation
Lecture 35 - Mechanical Forces and DNA damage
Lecture 36 - Techniques in Mechanobiology: Hydrogels
Lecture 37 - Techniques in Mechanobiology: AFM
Lecture 38 - Techniques in Mechanobiology: Traction Force Microscopy, Trypson Deadhesion and Laser Ablation
Lecture 39 - Techniques in Mechanobiology: Microfabrication
Lecture 40 - Techniques in Mechanobiology: FRET
