The fibroblast response to tubes exhibiting internal nanotopography

## Abstract It has been known for many years that cells will react to the shape of their microenvironment. It is more recently becoming clear that cells can alter their morphology, adhesions, and cytoskeleton in response to their nanoenvironment. A few studies have gone further and measured cellula

## Abstract It is becoming clear that cells do not only respond to micrometric scale topography, but may also respond to topography at the nanometric scale. Nano‐fabrication methods such as electron beam lithography are, however, expensive and time consuming. Polymer demixing of poly(styrene) and p

This paper deals with the structural response of a tube to an internal gaseous detonation. An internal detonation produces a pressure load that propagates down the tube. Because the speed of the gaseous detonation can be comparable to the flexural wave group speed, excitation of flexural waves in th

This paper reports the analytical and numerical modeling of transient-dynamic response of tubes to internal detonation loading. Since gaseous detonation involves loads that propagate at high speeds, the excitations of flexural waves in the tube wall become significant. Flexural waves can result in h

## Background It has been well established that human fetuses will heal cutaneous wounds with perfect regeneration. Insulin-like growth factors are pro-fibrotic fibroblast mitogens that have important roles in both adult wound healing and during development, although their relative contribution tow