Curvature Memory in Electrically Stimulated Lipid Membranes

Maxim O. Lavrentovich; Jan Michael Y. Carrillo; Charles Patrick Collier; John Katsaras; Dima Bolmatov

doi:10.1021/acs.langmuir.4c03799

Curvature Memory in Electrically Stimulated Lipid Membranes

Maxim O. Lavrentovich
, Jan Michael Y. Carrillo
, Charles Patrick Collier
, John Katsaras
, Dima Bolmatov

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

We demonstrate, using non-equilibrium molecular dynamics simulations, that lipid membrane capacitance varies with surface charge accumulation linked to membrane shape and curvature changes. Specifically, we show that lipid membranes exhibit a hysteretic response when exposed to oscillatory electric fields. The electromechanical coupling in these membranes leads to hysteretic buckling, in which the membrane can spontaneously buckle in one of two distinct directions along the electric field, even for the same ionic charge accumulation at the water-membrane interface. In this regard, these binary buckled membrane states suggest potential applications in neuromorphic computing. Their bistable nature, characterized by two distinct and stable configurations, could serve as a foundation for implementing memory storage systems and logic operations. Furthermore, we introduce a circuit model that captures these dynamic effects, offering insights into emergent memory effects in electrically stimulated lipid membranes. Finally, this work presents lipid bilayers as dynamic, adaptable elements and suggests a new platform for exploring energy storage, information processing, and memory encoding at the lipid membrane level.

Original language	English
Pages (from-to)	3157-3165
Number of pages	9
Journal	Langmuir
Volume	41
Issue number	5
DOIs	https://doi.org/10.1021/acs.langmuir.4c03799
State	Published - Feb 11 2025

Funding

M.O.L. and D.B. are supported through the National Science Foundation, Division of Molecular and Cellular Biosciences, under Grant 2219289. Portions of the computational aspect of this research were supported by the Center for Nanophase Materials Sciences (CNMS), which is a U.S. Department of Energy Office of Science User Facility at Oak Ridge National Laboratory. The authors thank Amelie Gail Carrillo for her exceptional contribution to creating the cover artwork. This research used resources of the Oak Ridge Leadership Computing Facility (OLCF) at the Oak Ridge National Laboratory, which is, in addition to J.K., C.P.C., and J.-M.Y.C., supported by the Office of Science of the U.S. Department of Energy under Contract DE-AC05-00OR22725.

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title = "Curvature Memory in Electrically Stimulated Lipid Membranes",

abstract = "We demonstrate, using non-equilibrium molecular dynamics simulations, that lipid membrane capacitance varies with surface charge accumulation linked to membrane shape and curvature changes. Specifically, we show that lipid membranes exhibit a hysteretic response when exposed to oscillatory electric fields. The electromechanical coupling in these membranes leads to hysteretic buckling, in which the membrane can spontaneously buckle in one of two distinct directions along the electric field, even for the same ionic charge accumulation at the water-membrane interface. In this regard, these binary buckled membrane states suggest potential applications in neuromorphic computing. Their bistable nature, characterized by two distinct and stable configurations, could serve as a foundation for implementing memory storage systems and logic operations. Furthermore, we introduce a circuit model that captures these dynamic effects, offering insights into emergent memory effects in electrically stimulated lipid membranes. Finally, this work presents lipid bilayers as dynamic, adaptable elements and suggests a new platform for exploring energy storage, information processing, and memory encoding at the lipid membrane level.",

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AU - Lavrentovich, Maxim O.

AU - Carrillo, Jan Michael Y.

AU - Collier, Charles Patrick

AU - Katsaras, John

AU - Bolmatov, Dima

PY - 2025/2/11

Y1 - 2025/2/11

N2 - We demonstrate, using non-equilibrium molecular dynamics simulations, that lipid membrane capacitance varies with surface charge accumulation linked to membrane shape and curvature changes. Specifically, we show that lipid membranes exhibit a hysteretic response when exposed to oscillatory electric fields. The electromechanical coupling in these membranes leads to hysteretic buckling, in which the membrane can spontaneously buckle in one of two distinct directions along the electric field, even for the same ionic charge accumulation at the water-membrane interface. In this regard, these binary buckled membrane states suggest potential applications in neuromorphic computing. Their bistable nature, characterized by two distinct and stable configurations, could serve as a foundation for implementing memory storage systems and logic operations. Furthermore, we introduce a circuit model that captures these dynamic effects, offering insights into emergent memory effects in electrically stimulated lipid membranes. Finally, this work presents lipid bilayers as dynamic, adaptable elements and suggests a new platform for exploring energy storage, information processing, and memory encoding at the lipid membrane level.

AB - We demonstrate, using non-equilibrium molecular dynamics simulations, that lipid membrane capacitance varies with surface charge accumulation linked to membrane shape and curvature changes. Specifically, we show that lipid membranes exhibit a hysteretic response when exposed to oscillatory electric fields. The electromechanical coupling in these membranes leads to hysteretic buckling, in which the membrane can spontaneously buckle in one of two distinct directions along the electric field, even for the same ionic charge accumulation at the water-membrane interface. In this regard, these binary buckled membrane states suggest potential applications in neuromorphic computing. Their bistable nature, characterized by two distinct and stable configurations, could serve as a foundation for implementing memory storage systems and logic operations. Furthermore, we introduce a circuit model that captures these dynamic effects, offering insights into emergent memory effects in electrically stimulated lipid membranes. Finally, this work presents lipid bilayers as dynamic, adaptable elements and suggests a new platform for exploring energy storage, information processing, and memory encoding at the lipid membrane level.

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Curvature Memory in Electrically Stimulated Lipid Membranes

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