skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: Quantification of stromal vascular cell mechanics with a linear cell monolayer rheometer

Abstract

Over the past few decades researchers have developed a variety of methods for measuring the mechanical properties of whole cells, including traction force microscopy, atomic force microscopy (AFM), and single-cell tensile testing. Though each of these techniques provides insight into cell mechanics, most also involve some nonideal conditions for acquiring live cell data, such as probing only one portion of a cell at a time, or placing the cell in a nonrepresentative geometry during testing. In the present work, we describe the development of a linear cell monolayer rheometer (LCMR) and its application to measure the mechanics of a live, confluent monolayer of stromal vascular cells. In the LCMR, a monolayer of cells is contacted on both top and bottom by two collagen-coated plates and allowed to adhere. The top plate then shears the monolayer by stepping forward to induce a predetermined step strain, while a force transducer attached to the top plate collects stress information. The stress and strain data are then used to determine the maximum relaxation modulus recorded after step-strain, G{sub r}{sup 0}, referred to as the zero-time relaxation modulus of the cell monolayer. The present study validates the ability of the LCMR to quantify cell mechanicsmore » by measuring the change in G{sub r}{sup 0} of a confluent cell monolayer upon the selective inhibition of three major cytoskeletal components (actin microfilaments, vimentin intermediate filaments, and microtubules). The LCMR results indicate that both actin- and vimentin-deficient cells had ∼50% lower G{sub r}{sup 0} values than wild-type, whereas tubulin deficiency resulted in ∼100% higher G{sub r}{sup 0} values. These findings constitute the first use of a cell monolayer rheometer to quantitatively distinguish the roles of different cytoskeletal elements in maintaining cell stiffness and structure. Significantly, they are consistent with results obtained using single-cell mechanical testing methods, suggesting that the rheology-based LCMR technique may be a useful tool for rapid analysis of cell mechanics by shearing an entire cell monolayer.« less

Authors:
 [1]; ; ;  [2]
  1. Department of Chemical Engineering, Stanford University, Stanford, California 94305 (United States)
  2. Division of Endocrinology, Gerontology and Metabolism, Stanford University, Stanford, California 94305 and Veterans Affairs Palo Alto Health Care System, Palo Alto, California 94304 (United States)
Publication Date:
OSTI Identifier:
22413355
Resource Type:
Journal Article
Journal Name:
Journal of Rheology
Additional Journal Information:
Journal Volume: 59; Journal Issue: 1; Other Information: (c) 2015 The Society of Rheology; Country of input: International Atomic Energy Agency (IAEA); Journal ID: ISSN 0148-6055
Country of Publication:
United States
Language:
English
Subject:
75 CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY; 60 APPLIED LIFE SCIENCES; ACTIN; ATOMIC FORCE MICROSCOPY; COLLAGEN; FILAMENTS; FLEXIBILITY; MICROTUBULES; PLATES; PROBES; RELAXATION; RHEOLOGY; SHEAR PROPERTIES; STRAINS; STRESSES; TRANSDUCERS

Citation Formats

Elkins, Claire M., E-mail: cma9@stanford.edu, Fuller, Gerald G., Shen, Wen-Jun, Khor, Victor K., and Kraemer, Fredric B. Quantification of stromal vascular cell mechanics with a linear cell monolayer rheometer. United States: N. p., 2015. Web. doi:10.1122/1.4902437.
Elkins, Claire M., E-mail: cma9@stanford.edu, Fuller, Gerald G., Shen, Wen-Jun, Khor, Victor K., & Kraemer, Fredric B. Quantification of stromal vascular cell mechanics with a linear cell monolayer rheometer. United States. https://doi.org/10.1122/1.4902437
Elkins, Claire M., E-mail: cma9@stanford.edu, Fuller, Gerald G., Shen, Wen-Jun, Khor, Victor K., and Kraemer, Fredric B. 2015. "Quantification of stromal vascular cell mechanics with a linear cell monolayer rheometer". United States. https://doi.org/10.1122/1.4902437.
@article{osti_22413355,
title = {Quantification of stromal vascular cell mechanics with a linear cell monolayer rheometer},
author = {Elkins, Claire M., E-mail: cma9@stanford.edu and Fuller, Gerald G. and Shen, Wen-Jun and Khor, Victor K. and Kraemer, Fredric B.},
abstractNote = {Over the past few decades researchers have developed a variety of methods for measuring the mechanical properties of whole cells, including traction force microscopy, atomic force microscopy (AFM), and single-cell tensile testing. Though each of these techniques provides insight into cell mechanics, most also involve some nonideal conditions for acquiring live cell data, such as probing only one portion of a cell at a time, or placing the cell in a nonrepresentative geometry during testing. In the present work, we describe the development of a linear cell monolayer rheometer (LCMR) and its application to measure the mechanics of a live, confluent monolayer of stromal vascular cells. In the LCMR, a monolayer of cells is contacted on both top and bottom by two collagen-coated plates and allowed to adhere. The top plate then shears the monolayer by stepping forward to induce a predetermined step strain, while a force transducer attached to the top plate collects stress information. The stress and strain data are then used to determine the maximum relaxation modulus recorded after step-strain, G{sub r}{sup 0}, referred to as the zero-time relaxation modulus of the cell monolayer. The present study validates the ability of the LCMR to quantify cell mechanics by measuring the change in G{sub r}{sup 0} of a confluent cell monolayer upon the selective inhibition of three major cytoskeletal components (actin microfilaments, vimentin intermediate filaments, and microtubules). The LCMR results indicate that both actin- and vimentin-deficient cells had ∼50% lower G{sub r}{sup 0} values than wild-type, whereas tubulin deficiency resulted in ∼100% higher G{sub r}{sup 0} values. These findings constitute the first use of a cell monolayer rheometer to quantitatively distinguish the roles of different cytoskeletal elements in maintaining cell stiffness and structure. Significantly, they are consistent with results obtained using single-cell mechanical testing methods, suggesting that the rheology-based LCMR technique may be a useful tool for rapid analysis of cell mechanics by shearing an entire cell monolayer.},
doi = {10.1122/1.4902437},
url = {https://www.osti.gov/biblio/22413355}, journal = {Journal of Rheology},
issn = {0148-6055},
number = 1,
volume = 59,
place = {United States},
year = {Thu Jan 15 00:00:00 EST 2015},
month = {Thu Jan 15 00:00:00 EST 2015}
}