Tissue adaptation as a dynamical process far from equilibrium

H Weinans; P J Prendergast

doi:10.1016/8756-3282(96)00143-3

Tissue adaptation as a dynamical process far from equilibrium

H Weinans
, P J Prendergast

Research output: Contribution to journal › Review article › peer-review

Abstract

It is well established that tissue growth, maintenance, and degeneration are biochemically regulated processes influenced by mechanical function. Biomechanical models have been developed to predict adaptive processes; for example, computer simulation of bone remodeling around orthopaedic implants can accurately predict the effect of certain implant design variables. However, the same success remains to be achieved with other adaptive processes such as joint morphogenesis or osteoporosis. We propose that, to become capable of stimulating such adaptive processes, biomechanical models should capture the inherently irreversible nature of tissue adaptation and therefore should not rely on the assumption of a "homeostatic" equilibrium. In this article, it is proposed that tissue adaptation is an unstable process of moving between tissue states that are far from the equilibrium state--and that to simulate it, independent sensors and positive feedback stimuli should be employed.

Original language	English
Pages (from-to)	143-9
Number of pages	7
Journal	Bone
Volume	19
Issue number	2
DOIs	https://doi.org/10.1016/8756-3282(96)00143-3
Publication status	Published - Aug 1996
Externally published	Yes

Keywords

Adaptation, Physiological
Animals
Biomechanical Phenomena
Bone and Bones/embryology
Computer Simulation
Feedback
Homeostasis/physiology
Humans
Models, Biological

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title = "Tissue adaptation as a dynamical process far from equilibrium",

abstract = "It is well established that tissue growth, maintenance, and degeneration are biochemically regulated processes influenced by mechanical function. Biomechanical models have been developed to predict adaptive processes; for example, computer simulation of bone remodeling around orthopaedic implants can accurately predict the effect of certain implant design variables. However, the same success remains to be achieved with other adaptive processes such as joint morphogenesis or osteoporosis. We propose that, to become capable of stimulating such adaptive processes, biomechanical models should capture the inherently irreversible nature of tissue adaptation and therefore should not rely on the assumption of a {"}homeostatic{"} equilibrium. In this article, it is proposed that tissue adaptation is an unstable process of moving between tissue states that are far from the equilibrium state--and that to simulate it, independent sensors and positive feedback stimuli should be employed.",

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year = "1996",

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doi = "10.1016/8756-3282(96)00143-3",

language = "English",

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pages = "143--9",

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publisher = "Elsevier",

number = "2",

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TY - JOUR

T1 - Tissue adaptation as a dynamical process far from equilibrium

AU - Weinans, H

AU - Prendergast, P J

PY - 1996/8

Y1 - 1996/8

N2 - It is well established that tissue growth, maintenance, and degeneration are biochemically regulated processes influenced by mechanical function. Biomechanical models have been developed to predict adaptive processes; for example, computer simulation of bone remodeling around orthopaedic implants can accurately predict the effect of certain implant design variables. However, the same success remains to be achieved with other adaptive processes such as joint morphogenesis or osteoporosis. We propose that, to become capable of stimulating such adaptive processes, biomechanical models should capture the inherently irreversible nature of tissue adaptation and therefore should not rely on the assumption of a "homeostatic" equilibrium. In this article, it is proposed that tissue adaptation is an unstable process of moving between tissue states that are far from the equilibrium state--and that to simulate it, independent sensors and positive feedback stimuli should be employed.

AB - It is well established that tissue growth, maintenance, and degeneration are biochemically regulated processes influenced by mechanical function. Biomechanical models have been developed to predict adaptive processes; for example, computer simulation of bone remodeling around orthopaedic implants can accurately predict the effect of certain implant design variables. However, the same success remains to be achieved with other adaptive processes such as joint morphogenesis or osteoporosis. We propose that, to become capable of stimulating such adaptive processes, biomechanical models should capture the inherently irreversible nature of tissue adaptation and therefore should not rely on the assumption of a "homeostatic" equilibrium. In this article, it is proposed that tissue adaptation is an unstable process of moving between tissue states that are far from the equilibrium state--and that to simulate it, independent sensors and positive feedback stimuli should be employed.

KW - Adaptation, Physiological

KW - Animals

KW - Biomechanical Phenomena

KW - Bone and Bones/embryology

KW - Computer Simulation

KW - Feedback

KW - Homeostasis/physiology

KW - Humans

KW - Models, Biological

U2 - 10.1016/8756-3282(96)00143-3

DO - 10.1016/8756-3282(96)00143-3

M3 - Review article

C2 - 8853858

SN - 8756-3282

VL - 19

SP - 143

EP - 149

JO - Bone

JF - Bone

IS - 2

ER -

Tissue adaptation as a dynamical process far from equilibrium

Abstract

Keywords

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