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Main Authors: Paquin-Lefebvre, Frédéric, Basnayake, Kanishka, Holcman, David
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2212.09179
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author Paquin-Lefebvre, Frédéric
Basnayake, Kanishka
Holcman, David
author_facet Paquin-Lefebvre, Frédéric
Basnayake, Kanishka
Holcman, David
contents Cellular networks are often composed of thin tubules connecting much larger node compartments. These structures serve for active or diffusion transport of proteins. Examples are glial networks in the brain, the endoplasmic reticulum in cells or dendritic spines located on dendrites. In this latter case, a large ball forming the head is connected by a narrow passage. In all cases, how the transport of molecules, ions or proteins is regulated determines the time scale of chemical reactions or signal transduction. In the present study, based on modeling diffusion in three dimensions, we compute the mean time for a Brownian particle to reach a narrow target inside such a composite network made of tubules connected to spherical nodes. We derive asymptotic formulas by solving a mixed Neumann-Dirichlet boundary value problem with small Dirichlet part. We first consider the case of a network domain organized in a 2-D lattice structure that consists of spherical ball compartments connected via narrow cylindrical passages. When there is a single target we derive a matrix equation for each Mean First Passage Time (MFPT) averaged over each spherical compartment. We then consider a composite domain consisting of a spherical head-like domain connected to a large cylinder via a narrow cylindrical neck. For Brownian particles starting within the narrow neck, we derive formulas for the MFPT to reach a target on the spherical head. When diffusing particles can be absorbed upon hitting additional absorbing boundaries of the large cylinder, we compute the probability and conditional MFPT to reach a target. We compare these formulas with numerical solutions of the mixed boundary value problem and with Brownian simulations. To conclude, the present analysis reveals that the mean arrival time, driven by diffusion in heterogeneous networks, is controlled by the target and narrow passage sizes.
format Preprint
id arxiv_https___arxiv_org_abs_2212_09179
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Narrow escape in composite domains forming heterogeneous networks
Paquin-Lefebvre, Frédéric
Basnayake, Kanishka
Holcman, David
Soft Condensed Matter
Analysis of PDEs
Quantitative Methods
35J05, 35J08, 35J25
Cellular networks are often composed of thin tubules connecting much larger node compartments. These structures serve for active or diffusion transport of proteins. Examples are glial networks in the brain, the endoplasmic reticulum in cells or dendritic spines located on dendrites. In this latter case, a large ball forming the head is connected by a narrow passage. In all cases, how the transport of molecules, ions or proteins is regulated determines the time scale of chemical reactions or signal transduction. In the present study, based on modeling diffusion in three dimensions, we compute the mean time for a Brownian particle to reach a narrow target inside such a composite network made of tubules connected to spherical nodes. We derive asymptotic formulas by solving a mixed Neumann-Dirichlet boundary value problem with small Dirichlet part. We first consider the case of a network domain organized in a 2-D lattice structure that consists of spherical ball compartments connected via narrow cylindrical passages. When there is a single target we derive a matrix equation for each Mean First Passage Time (MFPT) averaged over each spherical compartment. We then consider a composite domain consisting of a spherical head-like domain connected to a large cylinder via a narrow cylindrical neck. For Brownian particles starting within the narrow neck, we derive formulas for the MFPT to reach a target on the spherical head. When diffusing particles can be absorbed upon hitting additional absorbing boundaries of the large cylinder, we compute the probability and conditional MFPT to reach a target. We compare these formulas with numerical solutions of the mixed boundary value problem and with Brownian simulations. To conclude, the present analysis reveals that the mean arrival time, driven by diffusion in heterogeneous networks, is controlled by the target and narrow passage sizes.
title Narrow escape in composite domains forming heterogeneous networks
topic Soft Condensed Matter
Analysis of PDEs
Quantitative Methods
35J05, 35J08, 35J25
url https://arxiv.org/abs/2212.09179