A Realistic 3d Computational Model of the Closure of Skin Wound With Interrupted Sutures

Chanda, Arnab; Unnikrishnan, Vinu

doi:10.1142/s0219519417500257

Cited by 34 publications

(31 citation statements)

References 22 publications

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“…In the current work, the main focus is to study the effect of a novel custom insole design with ulcer isolations on the diabetic foot with ulcers, and hence a simple foot model has been used which includes the geometrical and material effects of all the bones and the skin tissue covering in a diabetic foot condition [208,[215][216][217]. The material model assumed is based on literature values of the modulus of elasticity and Poisson's ratio of the bones, cartilages, ligaments and muscles in a diabetic foot condition [218,219] (Table 5.6). To validate the chosen material model for diabetic foot condition, standing posture was simulated with the foot FE model, and the resulting stresses were estimated.…”

Section: Finite Element Modelingmentioning

confidence: 99%

Biofidelic soft composites–experimental and computational modeling

Chanda¹

2018

Preprint

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Biofidelic soft composites or tissues form the building blocks of the human body. Understanding the complex mechanics of these soft composites is the key to understanding the genesis and progression of disease. Biomechanically, soft composites exhibit anisotropic mechanical behavior and comprise of multiple fiber layers within a soft matrix. To date, there is a lack of understanding of the anisotropic mechanical behavior of soft composites, primarily due to unavailability of a robust characterization framework. In this dissertation, novel multiscale computational and experimental investigation models are developed to simulate and characterize anisotropic soft composite mechanical behavior. Soft composite surrogates were first developed to simulate various tissues in the human body namely the skin, brain, artery and vaginal tissues. Novel anisotropic soft composite models were also fabricated taking into consideration the tissue anisotropy and multifunctional properties. Hyperelastic anisotropic constitutive relationships were formulated to precisely characterize the mechanical behavior of soft composite considering varying fiber and matrix contributions, fiber-matrix interactions, fiber orientations and multiple fiber layers. Coupled with high fidelity experimental and computational models, microscopy, and Digital Image Correlation (DIC) studies, the damage and repair of soft composite surrogates are also discussed in this dissertation, with relevance to soft tissue wounds and suture. Computational modeling to understand the interaction between multiple soft composite systems and its effect on soft composite damage are also highlighted in this work. Some specific soft composite interaction systems modeled were the female pelvic system under abdominal loads, whole body impact due to blast, and ulceration in diabetic foot. This dissertation lays the foundation for micro and macro scale anisotropic soft composite modeling and characterization using high fidelity experimental and numerical techniques which will be indispensable for studying tissue mechanics and other soft composite applications in engineering and medicine.

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Section: Finite Element Modelingmentioning

confidence: 99%

Biofidelic soft composites–experimental and computational modeling

Chanda¹

2018

Preprint

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“…Soft tissues, polymers and rubbers exhibit a non-linear stress versus strain response which can be characterized using hyperelastic constitutive material models such as Fung, Mooney-Rivlin, Yeoh, Veronda-Westmann, and Humphrey [10,12,13,[16][17][18][19][20][21][22][23]. Hyperelastic curve fit models are based on the definition of the strain-energy function (denoted as Ψ), which depends on the type of material [24,25].…”

Section: Non-linear Materials Modelingmentioning

confidence: 99%

Biofidelic Conductive Synthetic Skin Composites

Chanda¹

2018

Preprint

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Skin is the first point of contact of the human body with the outer environment, and influences the biomechanics of different organ systems in normal and diseased states. Wearable electronics such as fitness tracking equipment, motion sensing devices, and advanced wearables in prosthetics and orthotics are often used to quantify the interaction of the body with the environment during different physical activities, and improve health. These wearable equipment can be bulky and a source of discomfort to the human skin with prolonged wear. To date, very few flexible polymers have been developed which can conduct electricity and be used in wearable devices. In the current work, a novel conductive synthetic skin composite system was developed, which would be indispensable for integration into wearable technologies, and also allow the biomechanical testing of the human skin for different engineering and medical applications. The mechanical behavior of this polymer can be tuned to mimic the human skin from different locations of the body with varying stiffnesses, with a phenomenal degree of accuracy. The composite system is composed of short carbon fibers dispersed in a multi part silicone based matrix material. The volume fraction of the fibers were varied to control the mechanical and electrical properties of the composite. Uniaxial tensile tests were conducted to generate stress versus strain responses of the synthetic skin composites at different fiber volume fractions, and electrical measurements were recorded at different strains. Microscopy was used to understand composite fiber orientations in unstretched and stretched states, and its effects on the electrical conductivity of the material. Additionally, non-linear material characterization models were developed to characterize the composite variants. To the best of our knowledge, such an accurate synthetic skin composite system with tailorable electrical properties has not been developed; making this state of the art in bio mimicking and functionalization of the human skin.

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“…Besides blast impact mitigation, other requirements of such materials include light weight, tailorability, and flexibility [27]. Based on the recent developments on human tissue simulants [29][30][31][32], a novel skin simulant material was developed and recreated within a FE model. Kevlar 129 fibers (typically used in combat helmets) were embedded into the novel skin simulant (as the matrix material) numerically to simulate a two-layer composite covering.…”

Section: Introductionmentioning

confidence: 99%

Human Skin-Like Composite Materials for Blast Induced Injury Mitigation

Chanda

Graeter

2018

J. Compos. Sci.

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Armors and military grade personal protection equipment (PPE) materials to date are bulky and are not designed to effectively mitigate blast impacts. In the current work, a human skin-like castable simulant material was developed and its blast mitigation characteristics (in terms of induced stress reduction at the bone and muscles) were characterized in the presence of composite reinforcements. The reinforcement employed was Kevlar 129 (commonly used in advanced combat helmets), which was embedded within the novel skin simulant material as the matrix and used to cover a representative extremity based human skin, muscle and bone section finite element (FE) model. The composite variations tested were continuous and short-fiber types, lay-ups (0/0, 90/0, and 45/45 orientations) and different fiber volume fractions. From the analyses, the 0/0 continuous fiber lay-up with a fiber volume fraction close to 0.1 (or 10%) was found to reduce the blast-induced dynamic stresses at the bone and muscle sections by 78% and 70% respectively. These findings indicate that this novel skin simulant material with Kevlar 129 reinforcement, with further experimental testing, may present future opportunities in blast resistant armor padding designing.

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A Realistic 3d Computational Model of the Closure of Skin Wound With Interrupted Sutures

Cited by 34 publications

References 22 publications

Biofidelic soft composites–experimental and computational modeling

Biofidelic soft composites–experimental and computational modeling

Biofidelic Conductive Synthetic Skin Composites

Human Skin-Like Composite Materials for Blast Induced Injury Mitigation

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