Delves into the principles of symmetry and conservation in cellular biology, emphasizing the importance of energy, entropy, and computational modeling.
Explores the history, mathematical models, and experimental techniques of Brownian Motion, revealing its molecular nature and significance in cell biology.
Explores forces and structures of biomolecular condensates, including direct and indirect forces, compartmentalization, and phase separation of Intrinsically Disordered Proteins.
Covers the fundamental concepts of classical thermodynamics and its applications in cell biology, emphasizing the importance of equilibrium and the laws of thermodynamics.
Explores cellular cytoskeleton components, including actin filaments and microtubules, and discusses solvent-free molecular dynamics and Monte Carlo simulations.
Explores the properties of lipid membranes, emphasizing their structure, stability, and controlled permeation, as well as the role of proteins and cholesterol.
Covers the fundamentals and applications of coarse-grained simulations, including advantages, challenges, single-scale simulations, brain modeling techniques, and lipid membrane coarse-graining.
