An important open question in biophysics is to understand how mechanical forces shape membrane-bounded cells and their organelles. A general solution to this problem is to calculate the bending energy of an arbitrarily shaped membrane surface, which can include both lipids and cytoskeletal proteins, and minimize the energy subject to all mechanical constraints. However, the calculations are difficult to perform, especially for shapes that do not possess axial symmetry. We show that the spherical harmonics parameterization (SHP) provides an analytic description of shape that can be used to quickly and reliably calculate minimum energy shapes of both symmetric and asymmetric surfaces. Using this method, we probe the entire set of shapes predi...
ABSTRACT We study the shapes of human red blood cells using continuum mechanics. In particular, we m...
Cell membranes are crucial to the life of cells and vesicles are important model systems for cell me...
AbstractWe study the shapes of human red blood cells using continuum mechanics. In particular, we mo...
An important open question in biophysics is to understand how mechanical forces shape membrane-bound...
A theoretical approach to determine nearly spherical shapes of phospholipid vesicles is developed. T...
Model calculations were performed to explore quantitative aspects of the discocyte-echinocyte shape ...
We present a computational study of bending models for the curvature elasticity of lipid bilayer mem...
AbstractThe main objective of this lecture is to discuss the role of lipid-bilayer elasticity (1) fo...
It is known that fission yeast Schizosaccharomyces pombe maintains its nuclear envelope during mitos...
Cellular membranes display an incredibly diverse range of shapes, both in the plasma membrane and at...
ABSTRACT: We have developed an algorithm to determine membrane structure, area per lipid, and bendin...
Fluid-phase phospholipid vesicles are abundant in biological cells and play an essential role in cel...
To dynamically reshape the membrane, cells rely on a variety of intracellular mechanisms, ranging fr...
We theoretically study the shapes of lipid vesicles confined to a spherical cavity, elaborating a fr...
Recent advances have enabled 3-dimensional reconstructions of biological structures in vivo, ranging...
ABSTRACT We study the shapes of human red blood cells using continuum mechanics. In particular, we m...
Cell membranes are crucial to the life of cells and vesicles are important model systems for cell me...
AbstractWe study the shapes of human red blood cells using continuum mechanics. In particular, we mo...
An important open question in biophysics is to understand how mechanical forces shape membrane-bound...
A theoretical approach to determine nearly spherical shapes of phospholipid vesicles is developed. T...
Model calculations were performed to explore quantitative aspects of the discocyte-echinocyte shape ...
We present a computational study of bending models for the curvature elasticity of lipid bilayer mem...
AbstractThe main objective of this lecture is to discuss the role of lipid-bilayer elasticity (1) fo...
It is known that fission yeast Schizosaccharomyces pombe maintains its nuclear envelope during mitos...
Cellular membranes display an incredibly diverse range of shapes, both in the plasma membrane and at...
ABSTRACT: We have developed an algorithm to determine membrane structure, area per lipid, and bendin...
Fluid-phase phospholipid vesicles are abundant in biological cells and play an essential role in cel...
To dynamically reshape the membrane, cells rely on a variety of intracellular mechanisms, ranging fr...
We theoretically study the shapes of lipid vesicles confined to a spherical cavity, elaborating a fr...
Recent advances have enabled 3-dimensional reconstructions of biological structures in vivo, ranging...
ABSTRACT We study the shapes of human red blood cells using continuum mechanics. In particular, we m...
Cell membranes are crucial to the life of cells and vesicles are important model systems for cell me...
AbstractWe study the shapes of human red blood cells using continuum mechanics. In particular, we mo...