An Inverse Method for Predicting Tissue-level Mechanics from Cellular Mechanical Input

Overview

Journal J Biomech

Specialty Physiology

Date 2009 Jan 13

PMID 19135204

Citations 7

Authors

Wangdo Kim

Derek C Tretheway

Sean S Kohles

Affiliations

Soon will be listed here.

Abstract

Extracellular matrix (ECM) provides a dynamic three-dimensional structure which translates mechanical stimuli to cells. This local mechanical stimulation may direct biological function including tissue development. Theories describing the role of mechanical regulators hypothesize the cellular response to variations in the external mechanical forces on the ECM. The exact ECM mechanical stimulation required to generate a specific pattern of localized cellular displacement is still unknown. The cell to tissue inverse problem offers an alternative approach to clarify this relationship. Developed for structural dynamics, the inverse dynamics problem translates measurements of local state variables (at the cell level) into an unknown or desired forcing function (at the tissue or ECM level). This paper describes the use of eigenvalues (resonant frequencies), eigenvectors (mode shapes), and dynamic programming to reduce the mathematical order of a simplified cell-tissue system and estimate the ECM mechanical stimulation required for a specified cellular mechanical environment. Finite element and inverse numerical analyses were performed on a simple two-dimensional model to ascertain the effects of weighting parameters and a reduction of analytical modes leading toward a solution. Simulation results indicate that the reduced number of mechanical modes (from 30 to 14 to 7) can adequately reproduce an unknown force time history on an ECM boundary. A representative comparison between cell to tissue (inverse) and tissue to cell (boundary value) modeling illustrates the multiscale applicability of the inverse model.

Citing Articles

Validation of a Biomechanical Injury and Disease Assessment Platform Applying an Inertial-Based Biosensor and Axis Vector Computation.

Kim W, Vela E, Kohles S, Huayamave V, Gonzalez O Electronics (Basel). 2023; 12(17).

PMID: 37974898 PMC: 10653259. DOI: 10.3390/electronics12173694.

Tracking Knee Joint Functional Axes through Tikhonov Filtering and Plűcker Coordinates.

Kim W, Kim Y, Veloso A, Kohles S J Nov Physiother. 2013; Suppl 4(1).

PMID: 23720709 PMC: 3664552. DOI: 10.4172/2165-7025.S4-001.

Cytoskeletal strains in modeled optohydrodynamically stressed healthy and diseased biological cells.

Kohles S, Liang Y, Saha A J Biophys. 2013; 2012:830741.

PMID: 23304139 PMC: 3523158. DOI: 10.1155/2012/830741.

Volumetric stress-strain analysis of optohydrodynamically suspended biological cells.

Kohles S, Liang Y, Saha A J Biomech Eng. 2010; 133(1):011004.

PMID: 21186894 PMC: 3022349. DOI: 10.1115/1.4002939.

A Distinct Catabolic to Anabolic Threshold Due to Single-Cell Static Nanomechanical Stimulation in a Cartilage Biokinetics Model.

Saha A, Kohles S J Nanotechnol Eng Med. 2010; 1(3).

PMID: 21152243 PMC: 2998284. DOI: 10.1115/1.4001934.

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