Nonlinear elastic-viscoplastic constitutive equations for aging facial tissues

Mazza, Edoardo; Papes, O.; Rubin, M. B.; Bodner, S. R.; Binur, N. S.

doi:10.1007/s10237-005-0074-y

Cited by 30 publications

(17 citation statements)

References 28 publications

(47 reference statements)

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“…Especially when discretizing the individual skin layers, it might become essential to model skin using membrane or shell elements to increase computational efficiency, to ensure well-conditioning of the overall system matrix, and to avoid the typical locking effects associated with thin geometries subjected to bending [59]. Fourth, the calibration of the material parameters for both the elastic model and the growth model remains a question to be addressed in the future [44]. Here, for conceptual comparison, we have only used generic material parameter values.…”

Section: Example Of Skin Expansion and Growthmentioning

confidence: 99%

Growing skin: A computational model for skin expansion in reconstructive surgery

Tepole

Ploch

Wong

et al. 2011

Journal of the Mechanics and Physics of Solids

113

106

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The goal of this manuscript is to establish a novel computational model for stretch-induced skin growth during tissue expansion. Tissue expansion is a common surgical procedure to grow extra skin for reconstructing birth defects, burn injuries, or cancerous breasts. To model skin growth within the framework of nonlinear continuum mechanics, we adopt the multiplicative decomposition of the deformation gradient into an elastic and a growth part. Within this concept, we characterize growth as an irreversible, stretch-driven, transversely isotropic process parameterized in terms of a single scalar-valued growth multiplier, the in-plane area growth. To discretize its evolution in time, we apply an unconditionally stable, implicit Euler backward scheme. To discretize it in space, we utilize the finite element method. For maximum algorithmic efficiency and optimal convergence, we suggest an inner Newton iteration to locally update the growth multiplier at each integration point. This iteration is embedded within an outer Newton iteration to globally update the deformation at each finite element node. To demonstrate the characteristic features of skin growth, we simulate the process of gradual tissue expander inflation. To visualize growth-induced residual stresses, we simulate a subsequent tissue expander deflation. In particular, we compare the spatio-temporal evolution of area growth, elastic strains, and residual stresses for four commonly available tissue expander geometries. We believe that predictive computational modeling can open new avenues in reconstructive surgery to rationalize and standardize clinical process parameters such as expander geometry, expander size, expander placement, and inflation timing.

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Section: Example Of Skin Expansion and Growthmentioning

confidence: 99%

Growing skin: A computational model for skin expansion in reconstructive surgery

Tepole

Ploch

Wong

et al. 2011

Journal of the Mechanics and Physics of Solids

113

106

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show abstract

“…We have recently shown that it is straightforward combine our growth model with in-plane anisotropy, introduced through pronounced stiffness along Langer’s lines [9, 30]. It might also be interesting to elaborate out-of-plane anisotropy and model the different skin layers individually [39]. We have demonstrated how to model the growth process itself as anisotropic as well [16].…”

Section: Discussionmentioning

confidence: 99%

Growing skin: tissue expansion in pediatric forehead reconstruction

Zöllner

Tepole

Gosain

et al. 2011

Biomech Model Mechanobiol

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Tissue expansion is a common surgical procedure to grow extra skin through controlled mechanical over-stretch. It creates skin that matches the color, texture, and thickness of the surrounding tissue, while minimizing scars and risk of rejection. Despite intense research in tissue expansion and skin growth, there is a clear knowledge gap between heuristic observation and mechanistic understanding of the key phenomena that drive the growth process. Here, we show that a continuum mechanics approach, embedded in a custom-designed finite element model, informed by medical imaging, provides valuable insight into the biomechanics of skin growth. In particular, we model skin growth using the concept of an incompatible growth configuration. We characterize its evolution in time using a second-order growth tensor parameterized in terms of a scalar-valued internal variable, the in-plane area growth. When stretched beyond the physiological level, new skin is created, and the in-plane area growth increases. For the first time, we simulate tissue expansion on a patient-specific geometric model, and predict stress, strain, and area gain at three expanded locations in a pediatric skull: in the scalp, in the forehead, and in the cheek. Our results may help the surgeon to prevent tissue over-stretch and make informed decisions about expander geometry, size, placement, and inflation. We anticipate our study to open new avenues in reconstructive surgery, and enhance treatment for patients with birth defects, burn injuries, or breast tumor removal.

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“…The soft tissue model proposed by Rubin and Bodner [2002] provides a versatile framework [Helfenstein et al, 2010] to represent the mechanical behavior of collagenous tissues [Mazza et al, 2005;Barbarino et al, 2011;Weickenmeier and Jabareen, 2014;Flynn and Rubin, 2014;Safadi and Rubin, 2014] offering the possibility to include dissipative, inelastic characteristics. In application to FM tissues, Jabareen et al [2009] used an elastic isotropic formulation of the Rubin-Bodner (RB) model to represent the uniaxial response of the amnion.…”

Section: Introductionmentioning

confidence: 99%

A model for the compressible, viscoelastic behavior of human amnion addressing tissue variability through a single parameter

Mauri

Ehret

Focatiis

et al. 2015

Biomech Model Mechanobiol

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A viscoelastic, compressible model is proposed to rationalize the recently reported response of human amnion in multiaxial relaxation and creep experiments. The theory includes two viscoelastic contributions responsible for the short-and long-term timedependent response of the material. These two contributions can be related to physical processes: water flow through the tissue and dissipative characteristics of the collagen fibers, respectively. An accurate agreement of the model with the mean tension and kinematic response of amnion in uniaxial relaxation tests was achieved. By variation of a single linear factor that accounts for the variability among tissue samples, the model provides very sound predictions not only of the uniaxial relaxation but also of the uniaxial creep and strip-biaxial relaxation behavior of individual samples. This suggests that a wide range of viscoelastic behaviors due to patient-specific variations in tissue composition * AM and AEE share first authorship of this article.

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Nonlinear elastic-viscoplastic constitutive equations for aging facial tissues

Cited by 30 publications

References 28 publications

Growing skin: A computational model for skin expansion in reconstructive surgery

Growing skin: A computational model for skin expansion in reconstructive surgery

Growing skin: tissue expansion in pediatric forehead reconstruction

A model for the compressible, viscoelastic behavior of human amnion addressing tissue variability through a single parameter

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