Biomimetic models of the actin cytoskeleton

Camilla Mohrdieck; Florent Dalmas; Eduard Arzt; Rainer Tharmann; Mireille M.A.E. Claessens; Andreas R. Bausch; Alexander Roth; Erich Sackmann; Christian H.J. Schmitz; Jennifer Curtis; Wouter Roos; Simon Schulz; Kai Uhrig; Joachim P. Spatz

doi:10.1002/smll.200600565

Biomimetic models of the actin cytoskeleton

Camilla Mohrdieck
, Florent Dalmas
, Eduard Arzt
, Rainer Tharmann
, Mireille M.A.E. Claessens
, Andreas R. Bausch
, Alexander Roth
, Erich Sackmann
, Christian H.J. Schmitz
, Jennifer Curtis
, Wouter Roos
, Simon Schulz
, Kai Uhrig
, Joachim P. Spatz

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

20 Scopus citations

Abstract

The cytoskeleton is a complex polymer network that plays an essential role in the functionality of eukaryotic cells. It endows cells with mechanical stability, adaptability, and motility. To identify and understand the mechanisms underlying this large variety of capabilities and to possibly transfer them to engineered networks makes it necessary to have in vitro and in silico model systems of the cytoskeleton. These models must be realistic representatives of the cellular network and at the same time be controllable and reproducible. Here, an approach to design complementary experimental and numerical model systems of the actin cytoskeleton is presented and some of their properties discussed.

Original language	English
Pages (from-to)	1015-1022
Number of pages	8
Journal	Small
Volume	3
Issue number	6
DOIs	https://doi.org/10.1002/smll.200600565
State	Published - Jun 2007

Keywords

Cells
Mechanical properties
Microfluidics
Self-assembly
Simulations

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10.1002/smll.200600565

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title = "Biomimetic models of the actin cytoskeleton",

abstract = "The cytoskeleton is a complex polymer network that plays an essential role in the functionality of eukaryotic cells. It endows cells with mechanical stability, adaptability, and motility. To identify and understand the mechanisms underlying this large variety of capabilities and to possibly transfer them to engineered networks makes it necessary to have in vitro and in silico model systems of the cytoskeleton. These models must be realistic representatives of the cellular network and at the same time be controllable and reproducible. Here, an approach to design complementary experimental and numerical model systems of the actin cytoskeleton is presented and some of their properties discussed.",

keywords = "Cells, Mechanical properties, Microfluidics, Self-assembly, Simulations",

author = "Camilla Mohrdieck and Florent Dalmas and Eduard Arzt and Rainer Tharmann and Claessens, \{Mireille M.A.E.\} and Bausch, \{Andreas R.\} and Alexander Roth and Erich Sackmann and Schmitz, \{Christian H.J.\} and Jennifer Curtis and Wouter Roos and Simon Schulz and Kai Uhrig and Spatz, \{Joachim P.\}",

year = "2007",

month = jun,

doi = "10.1002/smll.200600565",

language = "English",

volume = "3",

pages = "1015--1022",

journal = "Small",

issn = "1613-6810",

publisher = "John Wiley and Sons Inc.",

number = "6",

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TY - JOUR

T1 - Biomimetic models of the actin cytoskeleton

AU - Mohrdieck, Camilla

AU - Dalmas, Florent

AU - Arzt, Eduard

AU - Tharmann, Rainer

AU - Claessens, Mireille M.A.E.

AU - Bausch, Andreas R.

AU - Roth, Alexander

AU - Sackmann, Erich

AU - Schmitz, Christian H.J.

AU - Curtis, Jennifer

AU - Roos, Wouter

AU - Schulz, Simon

AU - Uhrig, Kai

AU - Spatz, Joachim P.

PY - 2007/6

Y1 - 2007/6

N2 - The cytoskeleton is a complex polymer network that plays an essential role in the functionality of eukaryotic cells. It endows cells with mechanical stability, adaptability, and motility. To identify and understand the mechanisms underlying this large variety of capabilities and to possibly transfer them to engineered networks makes it necessary to have in vitro and in silico model systems of the cytoskeleton. These models must be realistic representatives of the cellular network and at the same time be controllable and reproducible. Here, an approach to design complementary experimental and numerical model systems of the actin cytoskeleton is presented and some of their properties discussed.

AB - The cytoskeleton is a complex polymer network that plays an essential role in the functionality of eukaryotic cells. It endows cells with mechanical stability, adaptability, and motility. To identify and understand the mechanisms underlying this large variety of capabilities and to possibly transfer them to engineered networks makes it necessary to have in vitro and in silico model systems of the cytoskeleton. These models must be realistic representatives of the cellular network and at the same time be controllable and reproducible. Here, an approach to design complementary experimental and numerical model systems of the actin cytoskeleton is presented and some of their properties discussed.

KW - Cells

KW - Mechanical properties

KW - Microfluidics

KW - Self-assembly

KW - Simulations

UR - https://www.scopus.com/pages/publications/34250327484

U2 - 10.1002/smll.200600565

DO - 10.1002/smll.200600565

M3 - Article

C2 - 17487896

AN - SCOPUS:34250327484

SN - 1613-6810

VL - 3

SP - 1015

EP - 1022

JO - Small

JF - Small

IS - 6

ER -

Biomimetic models of the actin cytoskeleton

Abstract

Keywords

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