Brownian dynamics simulations demonstrate that multi-scale chromatin fiber geometry and network organization control the positioning, size, morphology, and multiplicity of liquid-liquid phase separated condensates via protein-fiber interactions.
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2 Pith papers cite this work. Polarity classification is still indexing.
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2026 2verdicts
UNVERDICTED 2representative citing papers
A dynamic-graph model derived from first principles describes multicellular self-organization and gene control in E. coli.
citing papers explorer
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A Brownian dynamics study of liquid-liquid phase separation in multi-scale chromatin networks
Brownian dynamics simulations demonstrate that multi-scale chromatin fiber geometry and network organization control the positioning, size, morphology, and multiplicity of liquid-liquid phase separated condensates via protein-fiber interactions.
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Control of genes by self-organizing multicellular interaction networks
A dynamic-graph model derived from first principles describes multicellular self-organization and gene control in E. coli.