Keymer Lab: Difference between revisions
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We study the molecular biophysics and spatial evolutionary ecology of microbial (bacteria, phages and plasmids) and cellular (macrophages) assemblages in nanofabricated adaptive (<i>habitat</i>) landscapes. We combine theoretical biology with experimental biophysics to study systems biology in nano-scale on-chip ecosystems.<br> | We study the molecular biophysics and spatial evolutionary ecology of microbial (bacteria, phages and plasmids) and cellular (macrophages) assemblages in nanofabricated adaptive (<i>habitat</i>) landscapes. We combine theoretical biology with experimental biophysics to study systems biology in nano-scale on-chip ecosystems.<br> | ||
<b>PHYSICS:</b> We study the interface between "individuals" (<i>cells</i>) and their enviroment (<i>niches</i>). At the nanoscale, this distinction blurs into a soft-matter physical (adaptive) system (<i>organism</i>). We are interested in autopoiesis, self-regeneration, self-assembly, and adaptation (bio-computation) in biophysical evolutionary systems (replicator-interactor instances). <br> | <b>PHYSICS:</b> We study the interface between "individuals" (<i>cells</i>) and their "enviroment" (<i>niches</i>). At the nanoscale, this distinction blurs into a soft-matter physical (adaptive) system (<i>organism</i>). We are interested in autopoiesis, self-regeneration, self-assembly, and adaptation (bio-computation) in biophysical evolutionary systems (replicator-interactor instances). <br> | ||
<b>TECHNOLOGY:</b> We are interested in evolving life (<i>metabolism</i>) into physical materials to provide biology-based functionality to human-built devices. We see nano-bio as the natural outcome of the evolutionary trajectory of technology. It corresponds to an the adaptive radiation into the nanoscopic world within the human built-environment. | <b>TECHNOLOGY:</b> We are interested in evolving life (<i>metabolism</i>) into physical materials to provide biology-based functionality to human-built devices. We see nano-bio as the natural outcome of the evolutionary trajectory of technology. It corresponds to an the adaptive radiation into the nanoscopic world within the human built-environment. |
Revision as of 12:54, 17 June 2007
Welkom op het Keymer LaboratoriumBIOLOGY:
We study the molecular biophysics and spatial evolutionary ecology of microbial (bacteria, phages and plasmids) and cellular (macrophages) assemblages in nanofabricated adaptive (habitat) landscapes. We combine theoretical biology with experimental biophysics to study systems biology in nano-scale on-chip ecosystems. PHYSICS: We study the interface between "individuals" (cells) and their "enviroment" (niches). At the nanoscale, this distinction blurs into a soft-matter physical (adaptive) system (organism). We are interested in autopoiesis, self-regeneration, self-assembly, and adaptation (bio-computation) in biophysical evolutionary systems (replicator-interactor instances). TECHNOLOGY: We are interested in evolving life (metabolism) into physical materials to provide biology-based functionality to human-built devices. We see nano-bio as the natural outcome of the evolutionary trajectory of technology. It corresponds to an the adaptive radiation into the nanoscopic world within the human built-environment. |