We describe a modeling methodology intended as a preliminary step in the identification of appropriate constitutive frameworks for the time-dependent response of biological tissues. The modeling approach comprises a customizable rheological network of viscous and elastic elements governed by user-defined 1D constitutive relationships. The model parameters are identified by iterative nonlinear optimization, minimizing the error between experimental and model-predicted structural (load-displacement) tissue response under a specific mode of deformation. We demonstrate the use of this methodology by determining the minimal rheological arrangement, constitutive relationships, and model parameters for the structural response of various soft tissues, including ex vivo perfused porcine liver in indentation, ex vivo porcine brain cortical tissue in indentation, and ex vivo human cervical tissue in unconfined compression. Our results indicate that the identified rheological configurations provide good agreement with experimental data, including multiple constant strain rate load/unload tests and stress relaxation tests. Our experience suggests that the described modeling framework is an efficient tool for exploring a wide array of constitutive relationships and rheological arrangements, which can subsequently serve as a basis for 3D constitutive model development and finite-element implementations. The proposed approach can also be employed as a self-contained tool to obtain simplified 1D phenomenological models of the structural response of biological tissue to single-axis manipulations for applications in haptic technologies.
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April 2011
Research Papers
Identifying a Minimal Rheological Configuration: A Tool for Effective and Efficient Constitutive Modeling of Soft Tissues
Petr Jordan,
Petr Jordan
Harvard School of Engineering and Applied Sciences
, Cambridge, MA 02138; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
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Amy E. Kerdok,
Amy E. Kerdok
Harvard School of Engineering and Applied Sciences
, Cambridge, MA 02138; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
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Robert D. Howe,
Robert D. Howe
Harvard School of Engineering and Applied Sciences
, Cambridge, MA 02138; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
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Simona Socrate
Simona Socrate
Department of Mechanical Engineering,
Massachusetts Institute of Technology
, Cambridge, MA 02139; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
Search for other works by this author on:
Petr Jordan
Harvard School of Engineering and Applied Sciences
, Cambridge, MA 02138; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
Amy E. Kerdok
Harvard School of Engineering and Applied Sciences
, Cambridge, MA 02138; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
Robert D. Howe
Harvard School of Engineering and Applied Sciences
, Cambridge, MA 02138; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139
Simona Socrate
Department of Mechanical Engineering,
Massachusetts Institute of Technology
, Cambridge, MA 02139; Harvard-MIT Division of Health Sciences and Technology
, Cambridge, MA 02139J Biomech Eng. Apr 2011, 133(4): 041006 (11 pages)
Published Online: March 15, 2011
Article history
Received:
January 17, 2010
Revised:
January 31, 2011
Posted:
February 9, 2011
Published:
March 15, 2011
Online:
March 15, 2011
Citation
Jordan, P., Kerdok, A. E., Howe, R. D., and Socrate, S. (March 15, 2011). "Identifying a Minimal Rheological Configuration: A Tool for Effective and Efficient Constitutive Modeling of Soft Tissues." ASME. J Biomech Eng. April 2011; 133(4): 041006. https://doi.org/10.1115/1.4003620
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