Age-dependent biomechanical properties of the skin

Pawlaczyk, Mariola; Lelonkiewicz, Monika; Wieczorowski, Michał

doi:10.5114/pdia.2013.38359

Cited by 242 publications

(178 citation statements)

References 40 publications

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“…Although, the modulus and UTS of the fabricated structure on the pattern didn't changed significantly in comparison with the random structure. The Young's modulus of both scaffolds were about 0.43 MPa which is in the range of skin modulus . The elongation at break of both scaffolds was high enough for skin substitution while using the pattern as a collector increased it more up to 145%.…”

Section: Discussionmentioning

confidence: 88%

Nanofibrous scaffolds with biomimetic structure

Khalili

Khorasani

Razavi

et al. 2017

J Biomedical Materials Res

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This research studies the effect of using a grid-like pattern as a collector on increasing the pore size of the electrospun gelatin/cellulose acetate/elastin scaffolds. The morphological study showed an enlargement in pore size and a decline in fiber diameter in comparison with the scaffold fabricated using conventional flat sheet collectors. The use of the pattern increased the swelling ratio and degradation rate of the scaffold. Investigating the tensile properties of scaffolds revealed that the patterned collector increased the elongation at break up to 145%. In vitro experiments revealed the patterned scaffold as a good substrate for attachment and proliferation of fibroblast cells. Overall, our results indicated that the patterned scaffold of gelatin/cellulose acetate/elastin could provide a better microenvironment for fibroblast cells compared to the conventional scaffolds. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 370-376, 2018.

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Section: Discussionmentioning

confidence: 88%

Nanofibrous scaffolds with biomimetic structure

Khalili

Khorasani

Razavi

et al. 2017

J Biomedical Materials Res

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“…Large discrepancies in the results may dictate the corroboration for the variation occurring in the skin during the process of ageing, and delineates the differences in the skin properties, depending on its anatomic location 54. Similarly, a recent analysis of mechanical property of artificial IVDwas performed by Kannan et al In this study, the significance of distinguishing loads was depicted.…”

mentioning

confidence: 67%

Review: unraveling the less explored flocking technology for tissue engineering scaffolds

Vellayappan

Jaganathan

Supriyanto³

2015

RSC Adv.

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Clinical translation of the scaffold-based tissue engineering (TE) therapy still faces multitude challenges despite intense investigations and advancement over the years. In order to circumvent clinical barriers, it is important to analyze the current technical challenges in constructing a clinically efficacious scaffold and subsequent issues relating to tissue repair. The major limitations of current scaffolds are lack of sufficient vascularisation, mechanical strength and issues related to the osseointegration of the scaffold in case of bone tissue engineering. Hence, this review accentuates the main challenges hampering widespread clinical translation of scaffold-based TE, with a focus on novel scaffolds fabricated using flocking technology. Flock technology is a well known method used in textile industry. Flocking application for scaffold fabrication is less explored yet they offer promising solutions for creating anisotropic scaffolds with high compressive strength despite of high porosity. Critical insights on the current researches of the fabricated flock scaffold and future directions for advancing flocking to next-generation TE scaffolds into the clinical realm are discussed. This review will serve as a one stop arrangement for understanding the vital pre-requisite properties of scaffolds, principle as well as factors governing flocking of scaffolds and the improved properties of flock scaffolds. Further, this will promulgate flocking technology as a plausible candidate to spearhead TE scaffold fabrication.

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“…Organism ageing leads to chemical bonds modification in proteins and water [11]. Skin becomes more slim, stiff and it is no longer so tense [23]. The existing research agrees that the lipid structures help in preventing water loss and penetration in substances readily soluble.…”

Section: Pathological Processes Of the Skin And The Distribution Of Wmentioning

confidence: 90%

Structure and Mechanical Properties of Soft Tissues during Selected Pathological Processes

Kmiecik¹,

Skotny²,

Detyna³

2017

Gen Med (Los Angeles)

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Pathological process often modifies the structure of the soft tissue and can lead changes of mechanical properties. The regularity of this relationship has already been used in the elastography and currently it is applied in medical diagnostic. Tissue stiffness can be identified by a quick measurement but more accurate details can be obtained only by biopsy. Studies, presented in a scientific literature, focus only on pathological stiffness or consider only changes in biochemical structure. These researches revealed two very important components of those modifications -elastin and collagen. Soft tissues are multicomponent, inhomogeneous and anisotropic structures. Their functionality depends on complicated processes on molecular level. Probably the individual components of the tissue can effect on each other. They may promote creation of processes, which can participate in modifications of elasticity. For this reason, it is very important to relate changes on the structural level with mechanical properties. This information can be very helpful in diagnosis and treatment of soft tissue disease.

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Age-dependent biomechanical properties of the skin

Cited by 242 publications

References 40 publications

Nanofibrous scaffolds with biomimetic structure

Nanofibrous scaffolds with biomimetic structure

Review: unraveling the less explored flocking technology for tissue engineering scaffolds

Structure and Mechanical Properties of Soft Tissues during Selected Pathological Processes

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