<i>In silico</i> bone mechanobiology: modeling a multifaceted biological system

Giorgi, Mario; Verbruggen, Stefaan W.; Lacroix, Damien

doi:10.1002/wsbm.1356

Cited by 39 publications

(38 citation statements)

References 147 publications

(193 reference statements)

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“…The results are then assembled into a larger system of equations, allowing modelling and analysis of the entire complex problem. Thus, finite element modelling has developed into a powerful engineering tool to assess the mechanical behaviour of physical structures, mechanical systems and, more recently, biological processes [32]. …”

Section: Methodsmentioning

confidence: 99%

Function and failure of the fetal membrane: Modelling the mechanics of the chorion and amnion

et al. 2017

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The fetal membrane surrounds the fetus during pregnancy and is a thin tissue composed of two layers, the chorion and the amnion. While rupture of this membrane normally occurs at term, preterm rupture can result in increased risk of fetal mortality and morbidity, as well as danger of infection in the mother. Although structural changes have been observed in the membrane in such cases, the mechanical behaviour of the human fetal membrane in vivo remains poorly understood and is challenging to investigate experimentally. Therefore, the objective of this study was to develop simplified finite element models to investigate the mechanical behaviour and rupture of the fetal membrane, particularly its constituent layers, under various physiological conditions. It was found that modelling the chorion and amnion as a single layer predicts remarkably different behaviour compared with a more anatomically-accurate bilayer, significantly underestimating stress in the amnion and under-predicting the risk of membrane rupture. Additionally, reductions in chorion-amnion interface lubrication and chorion thickness (reported in cases of preterm rupture) both resulted in increased membrane stress. Interestingly, the inclusion of a weak zone in the fetal membrane that has been observed to develop overlying the cervix would likely cause it to fail at term, during labour. Finally, these findings support the theory that the amnion is the dominant structural component of the fetal membrane and is required to maintain its integrity. The results provide a novel insight into the mechanical effect of structural changes in the chorion and amnion, in cases of both normal and preterm rupture.

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Section: Methodsmentioning

confidence: 99%

Function and failure of the fetal membrane: Modelling the mechanics of the chorion and amnion

et al. 2017

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“…Identifying these molecular signals will allow them to be targetted in novel ways to initiate, maintain, and accelerate the repair process. Unraveling the interplay between mechanics and biology in this setting is a problem for the emerging field of systems biology (Bizzarri et al, 2013; Giorgi et al, 2016). The levels and types of complexity are massive, and their understanding will require a big data approach.…”

Section: Future Perspectivesmentioning

confidence: 99%

A Concert between Biology and Biomechanics: The Influence of the Mechanical Environment on Bone Healing

2017

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In order to achieve consistent and predictable fracture healing, a broad spectrum of growth factors are required to interact with one another in a highly organized response. Critically important, the mechanical environment around the fracture site will significantly influence the way bone heals, or if it heals at all. The role of the various biological factors, the timing, and spatial relationship of their introduction, and how the mechanical environment orchestrates this activity, are all crucial aspects to consider. This review will synthesize decades of work and the acquired knowledge that has been used to develop new treatments and technologies for the regeneration and healing of bone. Moreover, it will discuss the current state of the art in experimental and clinical studies concerning the application of these mechano-biological principles to enhance bone healing, by controlling the mechanical environment under which bone regeneration takes place. This includes everything from the basic principles of fracture healing, to the influence of mechanical forces on bone regeneration, and how this knowledge has influenced current clinical practice. Finally, it will examine the efforts now being made for the integration of this research together with the findings of complementary studies in biology, tissue engineering, and regenerative medicine. By bringing together these diverse disciplines in a cohesive manner, the potential exists to enhance fracture healing and ultimately improve clinical outcomes.

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“…The revealed regularities can be considered as in tissue engineering when setting properties of the newly developed structures (Gu et al, 2016;Li et al, 2016), and for monitoring postimplantation period where it could obtain a non-invasive way information about the most likely mechanobiology properties of the implanted object in the dynamics of its remodeling (Giorgi et al, 2016).…”

Section: Transformation Models For the Case With Tec Presencementioning

confidence: 99%

Comparative Modeling the Thermal Transfer in Tissues with Volume Pathological Focuses and Tissue Engineering Constructs: a Pilot Study

2016

European Journal of Molecular Biotechnology

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The goal of this study was to conduct the computing experiments on the use of the spatial temperature distribution and heat flow in biological tissues obtained on the basis of microwave radiometry, and to develop the predictive algorithm of their specific properties and conditions. In the first stage, the data about the surface and deep temperature in different parts of the mammary glands of healthy women were used to build the model of heat flow in this body, proved that there is a lateral heat transfer from one part to another. Accounting for this phenomenon in the analysis of the spatial distribution of temperature in the breast with verified malignant tumours with installed localization made it possible to prove a several decision rules with a potentially high diagnostic efficiency. Based on the assumption about spatial variation of the dielectric constant and electrical conductivity in biological tissue at the installation site and subsequent remodeling of tissueengineered constructs to develop in similar patterns, and to be capable of the same impact on brightness temperature of the tissues under the antenna of a microwave radiometer, we conducted simulation in the second phase of the study. The crucial equations, being able to differentiate different states of adaptation (remodeling) of tissue-engineered constructs were offered, that can be used in tissue engineering as creating data structures, also for monitoring postimplantation period.

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In silico bone mechanobiology: modeling a multifaceted biological system

Cited by 39 publications

References 147 publications

Function and failure of the fetal membrane: Modelling the mechanics of the chorion and amnion

Function and failure of the fetal membrane: Modelling the mechanics of the chorion and amnion

A Concert between Biology and Biomechanics: The Influence of the Mechanical Environment on Bone Healing

Comparative Modeling the Thermal Transfer in Tissues with Volume Pathological Focuses and Tissue Engineering Constructs: a Pilot Study

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