Search results for " Lipid systems"

showing 2 items of 2 documents

Chemical self-organization in self-assembling biomimetic systems

2009

Abstract Far-from-equillibrium oscillating chemical reactions are among the simplest systems showing complex behaviors and emergent properties. This class of reactions is often employed to mimic and understand the mechanisms of a great variety of biological processes. In this context, pattern formation due to the coupling between reaction and transport phenomena represent an active and promising research area. In this paper, we present results coming from experiments where we tried to blend the structural properties of self-assembled matrixes (sodium dodecyl sulphate micelles and phospholipid bilayers) together with the evolutive peculiarities of the Belousov–Zhabotinsky reaction. A series …

Materials science{CHEMICAL} {OSCILLATORS}Pattern formation{SELF-ORGANIZATION}Context (language use)Chemical reaction{CONVECTION}surface tension{CHEMICAL} {OSCILLATORS}; {CONVECTION}; {DIFFUSION}; Lipid systems; {MICELLES}; Self-assembly; {SELF-ORGANIZATION}; surface tensionSelf-organization Self-assembly Belousov–Zhabotinsky reaction Chemical oscillators Turing structures Biomimetic systems Lipid systems Micelles Surface tension Diffusion Convection{MICELLES}Settore CHIM/02 - Chimica FisicaSelf-organizationMICELLESEcological ModelingLipid systemsCHEMICAL OSCILLATORS; CONVECTION; DIFFUSION; Lipid systems; MICELLES; Self-assembly; SELF-ORGANIZATION; surface tensionSelf-assemblySELF-ORGANIZATIONCHEMICAL OSCILLATORS{DIFFUSION}DIFFUSIONCoupling (physics)Belousov–Zhabotinsky reactionChemical physicsCONVECTIONSelf-assemblyTransport phenomena

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Dynamics of Pattern Formation in Biomimetic Systems

2008

This paper is an attempt to conceptualize pattern formation in self-organizing systems and, in particular, to understand how structures, oscillations or waves arise in a steady and homogenous environment, a phenomenon called symmetry breaking. The route followed to develop these ideas was to couple chemical oscillations produced by Belousov-Zhabotinsky reaction with confined reaction environments, the latter being an essential requirement for any process of Life. Special focus was placed on systems showing organic or lipidic compartments, which represent more reliable biomimetic matrices.

Statistics and Probability{CHEMICAL} {OSCILLATORS}Belousov-Zhabotinsky reactionLipid BilayersPattern formationNanotechnology{CHEMICAL} {OSCILLATORS}; Lipid systems; Reverse microemulsionsModels BiologicalTuring structuresGeneral Biochemistry Genetics and Molecular BiologyDiffusionBiomimeticsChemical oscillatorsAnimalsSymmetry breakingPhysicsGeneral Immunology and MicrobiologyChemistry PhysicalSystems BiologyApplied MathematicsLipid systemsBiomimetic systemsGeneral MedicineBelousov-Zhabotinsky reaction; Chemical oscillators; Turing structures; Biomimetic systems; Lipid systems; Reverse microemulsionsReverse microemulsionsBelousov–Zhabotinsky reactionModeling and SimulationEmulsionsGeneral Agricultural and Biological SciencesBiological system

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