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Shape or size matters?

Standard

Shape or size matters? / Lin, Alvin C.; Pirrung, Felix; Niestrawska, Justyna A.; Ondruschka, Benjamin; Pinter, Gerald; Henyš, Petr; Hammer, Niels.

In: FRONT BIOENG BIOTECH, Vol. 12, 1368383, 2024, p. 1368383.

Research output: SCORING: Contribution to journalSCORING: Review articleResearch

Harvard

Lin, AC, Pirrung, F, Niestrawska, JA, Ondruschka, B, Pinter, G, Henyš, P & Hammer, N 2024, 'Shape or size matters?', FRONT BIOENG BIOTECH, vol. 12, 1368383, pp. 1368383. https://doi.org/10.3389/fbioe.2024.1368383

APA

Lin, A. C., Pirrung, F., Niestrawska, J. A., Ondruschka, B., Pinter, G., Henyš, P., & Hammer, N. (2024). Shape or size matters? FRONT BIOENG BIOTECH, 12, 1368383. [1368383]. https://doi.org/10.3389/fbioe.2024.1368383

Vancouver

Lin AC, Pirrung F, Niestrawska JA, Ondruschka B, Pinter G, Henyš P et al. Shape or size matters? FRONT BIOENG BIOTECH. 2024;12:1368383. 1368383. https://doi.org/10.3389/fbioe.2024.1368383

Bibtex

@article{3e215b676e2e4f79810aab91b823d643,
title = "Shape or size matters?",
abstract = "Material properties of soft-tissue samples are often derived through uniaxial tensile testing. For engineering materials, testing parameters (e.g., sample geometries and clamping conditions) are described by international standards; for biological tissues, such standards do not exist. To investigate what testing parameters have been reported for tensile testing of human soft-tissue samples, a systematic review of the literature was performed using PRISMA guidelines. Soft tissues are described as anisotropic and/or hyperelastic. Thus, we explored how the retrieved parameters compared against standards for engineering materials of similar characteristics. All research articles published in English, with an Abstract, and before 1 January 2023 were retrieved from databases of PubMed, Web of Science, and BASE. After screening of articles based on search terms and exclusion criteria, a total 1,096 articles were assessed for eligibility, from which 361 studies were retrieved and included in this review. We found that a non-tapered shape is most common (209 of 361), followed by a tapered sample shape (92 of 361). However, clamping conditions varied and were underreported (156 of 361). As a preliminary attempt to explore how the retrieved parameters might influence the stress distribution under tensile loading, a pilot study was performed using finite element analysis (FEA) and constitutive modeling for a clamped sample of little or no fiber dispersion. The preliminary FE simulation results might suggest the hypothesis that different sample geometries could have a profound influence on the stress-distribution under tensile loading. However, no conclusions can be drawn from these simulations, and future studies should involve exploring different sample geometries under different computational models and sample parameters (such as fiber dispersion and clamping effects). Taken together, reporting and choice of testing parameters remain as challenges, and as such, recommendations towards standard reporting of uniaxial tensile testing parameters for human soft tissues are proposed.",
author = "Lin, {Alvin C.} and Felix Pirrung and Niestrawska, {Justyna A.} and Benjamin Ondruschka and Gerald Pinter and Petr Heny{\v s} and Niels Hammer",
year = "2024",
doi = "10.3389/fbioe.2024.1368383",
language = "English",
volume = "12",
pages = "1368383",
journal = "FRONT BIOENG BIOTECH",
issn = "2296-4185",
publisher = "Frontiers Media S. A.",

}

RIS

TY - JOUR

T1 - Shape or size matters?

AU - Lin, Alvin C.

AU - Pirrung, Felix

AU - Niestrawska, Justyna A.

AU - Ondruschka, Benjamin

AU - Pinter, Gerald

AU - Henyš, Petr

AU - Hammer, Niels

PY - 2024

Y1 - 2024

N2 - Material properties of soft-tissue samples are often derived through uniaxial tensile testing. For engineering materials, testing parameters (e.g., sample geometries and clamping conditions) are described by international standards; for biological tissues, such standards do not exist. To investigate what testing parameters have been reported for tensile testing of human soft-tissue samples, a systematic review of the literature was performed using PRISMA guidelines. Soft tissues are described as anisotropic and/or hyperelastic. Thus, we explored how the retrieved parameters compared against standards for engineering materials of similar characteristics. All research articles published in English, with an Abstract, and before 1 January 2023 were retrieved from databases of PubMed, Web of Science, and BASE. After screening of articles based on search terms and exclusion criteria, a total 1,096 articles were assessed for eligibility, from which 361 studies were retrieved and included in this review. We found that a non-tapered shape is most common (209 of 361), followed by a tapered sample shape (92 of 361). However, clamping conditions varied and were underreported (156 of 361). As a preliminary attempt to explore how the retrieved parameters might influence the stress distribution under tensile loading, a pilot study was performed using finite element analysis (FEA) and constitutive modeling for a clamped sample of little or no fiber dispersion. The preliminary FE simulation results might suggest the hypothesis that different sample geometries could have a profound influence on the stress-distribution under tensile loading. However, no conclusions can be drawn from these simulations, and future studies should involve exploring different sample geometries under different computational models and sample parameters (such as fiber dispersion and clamping effects). Taken together, reporting and choice of testing parameters remain as challenges, and as such, recommendations towards standard reporting of uniaxial tensile testing parameters for human soft tissues are proposed.

AB - Material properties of soft-tissue samples are often derived through uniaxial tensile testing. For engineering materials, testing parameters (e.g., sample geometries and clamping conditions) are described by international standards; for biological tissues, such standards do not exist. To investigate what testing parameters have been reported for tensile testing of human soft-tissue samples, a systematic review of the literature was performed using PRISMA guidelines. Soft tissues are described as anisotropic and/or hyperelastic. Thus, we explored how the retrieved parameters compared against standards for engineering materials of similar characteristics. All research articles published in English, with an Abstract, and before 1 January 2023 were retrieved from databases of PubMed, Web of Science, and BASE. After screening of articles based on search terms and exclusion criteria, a total 1,096 articles were assessed for eligibility, from which 361 studies were retrieved and included in this review. We found that a non-tapered shape is most common (209 of 361), followed by a tapered sample shape (92 of 361). However, clamping conditions varied and were underreported (156 of 361). As a preliminary attempt to explore how the retrieved parameters might influence the stress distribution under tensile loading, a pilot study was performed using finite element analysis (FEA) and constitutive modeling for a clamped sample of little or no fiber dispersion. The preliminary FE simulation results might suggest the hypothesis that different sample geometries could have a profound influence on the stress-distribution under tensile loading. However, no conclusions can be drawn from these simulations, and future studies should involve exploring different sample geometries under different computational models and sample parameters (such as fiber dispersion and clamping effects). Taken together, reporting and choice of testing parameters remain as challenges, and as such, recommendations towards standard reporting of uniaxial tensile testing parameters for human soft tissues are proposed.

U2 - 10.3389/fbioe.2024.1368383

DO - 10.3389/fbioe.2024.1368383

M3 - SCORING: Review article

C2 - 38600944

VL - 12

SP - 1368383

JO - FRONT BIOENG BIOTECH

JF - FRONT BIOENG BIOTECH

SN - 2296-4185

M1 - 1368383

ER -