Community challenge towards consensus on characterization of biological tissue: C4Bio's first findings

Nele Famaey; Heleen Fehervary; Yoann Lafon; Ali Akyildiz; Silke Dreesen; Karine Bruyère-Garnier; Jean Marc Allain; Marta Alloisio; Alejandro Aparici-Gil; Chiara Catalano; Fanette Chassagne; Snehal Chokhandre; Kimberly Crevits; Hanneke Crielaard; Eoghan Cunnane; Connor Cunnane; Karen De Leener; Amisha Desai; Rob Driessen; Ahmet Erdemir; Mona Eskandari; Sam Evans; Christian Gasser; Marc Gebhardt; Birgit Glasmacher; Gerhard A. Holzapfel; Mikel Isasi; Louise Jennings; Sascha Kurz; Sara Leal-Marin; Pauline Lecomte; Annie Morch; John Mulvihill; Fulufhelo Nemavhola; Thanyani Pandelani; Salvatore Pasta; Estefania Peña; Baptiste Pierrat; Heidi Lynn Ploeg; Stanislav Polzer; Manuel Rausch; David Schwarz; Hazel Screen; Selda Sherifova; Gerhard Sommer; Shengzhang Wang; Darragh Walsh; Deepesh Yadav; Thierry Marchal; Liesbet Geris

doi:10.1016/j.jbiomech.2025.113021

Community challenge towards consensus on characterization of biological tissue: C⁴Bio's first findings

Nele Famaey
, Heleen Fehervary
, Yoann Lafon
, Ali Akyildiz
, Silke Dreesen
, Karine Bruyère-Garnier
, Jean Marc Allain
, Marta Alloisio
, Alejandro Aparici-Gil
, Chiara Catalano
, Fanette Chassagne
, Snehal Chokhandre
, Kimberly Crevits
, Hanneke Crielaard
, Eoghan Cunnane
, Connor Cunnane
, Karen De Leener
, Amisha Desai
, Rob Driessen
, Ahmet Erdemir

Mona Eskandari, Sam Evans, Christian Gasser, Marc Gebhardt, Birgit Glasmacher, Gerhard A. Holzapfel, Mikel Isasi, Louise Jennings, Sascha Kurz, Sara Leal-Marin, Pauline Lecomte, Annie Morch, John Mulvihill, Fulufhelo Nemavhola, Thanyani Pandelani, Salvatore Pasta, Estefania Peña, Baptiste Pierrat, Heidi Lynn Ploeg, Stanislav Polzer, Manuel Rausch, David Schwarz, Hazel Screen, Selda Sherifova, Gerhard Sommer, Shengzhang Wang, Darragh Walsh, Deepesh Yadav, Thierry Marchal, Liesbet Geris

KU Leuven
Université Claude Bernard Lyon 1
Erasmus University Medical Center
Delft University of Technology
Department of Mechanics École Polytechnique
INRIA
KTH Royal Institute of Technology
University of Zaragoza
University of Palermo
Université Jean Monnet Saint-Étienne
Cleveland Clinic Foundation
University of Limerick
Materialise NV
University of Leeds
Technical University of Eindhoven
University of California at Riverside
Cardiff University
University of Applied Sciences, Leipzig
Leibniz Universität Hannover
Graz University of Technology
Norwegian University of Science and Technology
Leartiker
University of Leipzig
Multiéchelle
M.L. Sultan Technikon
University of South Africa
Queen's University
Technical University Ostrava
University of Texas at Austin
Queen Mary University of London
Fudan University
Avicenna Alliance
Virtual Physiological Human Institute

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

This study investigates methodological variability across various expert laboratories worldwide, with regards to characterizing the mechanical properties of biological tissues. Two testing rounds were conducted on the specific use case of uniaxial tensile testing of porcine aorta. In the first round, 24 labs were invited to apply their established methods to assess inter-laboratory variability. This revealed significant methodological diversity and associated variability in the stress–stretch results, underscoring the necessity for a standardized approach. In the second round, a consensus protocol was collaboratively developed and adopted by 19 labs in an attempt to minimize variability. This involved standardized sample preparation and uniformity in testing protocol, including the use of a common cutting and thickness measurement tool. Despite protocol harmonization, significant variability persisted across labs, which could not be solely attributed to inherent biological differences in tissue samples. These results illustrate the challenges in unifying testing methods across different research settings, underlining the necessity for further refinement of testing practices. Enhancing consistency in biomechanical experiments is pivotal when comparing results across studies, as well as when using the resulting material properties for in silico simulations in medical research.

langue originale	Anglais
Numéro d'article	113021
journal	Journal of Biomechanics
Volume	194
Les DOIs	https://doi.org/10.1016/j.jbiomech.2025.113021
état	Publié - 1 janv. 2026
Modification externe	Oui

Accès au document

10.1016/j.jbiomech.2025.113021

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Contient cette citation

Famaey, N., Fehervary, H., Lafon, Y., Akyildiz, A., Dreesen, S., Bruyère-Garnier, K., Allain, J. M., Alloisio, M., Aparici-Gil, A., Catalano, C., Chassagne, F., Chokhandre, S., Crevits, K., Crielaard, H., Cunnane, E., Cunnane, C., De Leener, K., Desai, A., Driessen, R., ... Geris, L. (2026). Community challenge towards consensus on characterization of biological tissue: C⁴Bio's first findings. Journal of Biomechanics, 194, Article 113021. https://doi.org/10.1016/j.jbiomech.2025.113021

@article{11596d7af9ca4b75ae9b70db6294895e,

title = "Community challenge towards consensus on characterization of biological tissue: C4Bio's first findings",

abstract = "This study investigates methodological variability across various expert laboratories worldwide, with regards to characterizing the mechanical properties of biological tissues. Two testing rounds were conducted on the specific use case of uniaxial tensile testing of porcine aorta. In the first round, 24 labs were invited to apply their established methods to assess inter-laboratory variability. This revealed significant methodological diversity and associated variability in the stress–stretch results, underscoring the necessity for a standardized approach. In the second round, a consensus protocol was collaboratively developed and adopted by 19 labs in an attempt to minimize variability. This involved standardized sample preparation and uniformity in testing protocol, including the use of a common cutting and thickness measurement tool. Despite protocol harmonization, significant variability persisted across labs, which could not be solely attributed to inherent biological differences in tissue samples. These results illustrate the challenges in unifying testing methods across different research settings, underlining the necessity for further refinement of testing practices. Enhancing consistency in biomechanical experiments is pivotal when comparing results across studies, as well as when using the resulting material properties for in silico simulations in medical research.",

keywords = "Biomechanical characterization, Methodological variability, Standardization, Uncertainty",

author = "Nele Famaey and Heleen Fehervary and Yoann Lafon and Ali Akyildiz and Silke Dreesen and Karine Bruy{\`e}re-Garnier and Allain, \{Jean Marc\} and Marta Alloisio and Alejandro Aparici-Gil and Chiara Catalano and Fanette Chassagne and Snehal Chokhandre and Kimberly Crevits and Hanneke Crielaard and Eoghan Cunnane and Connor Cunnane and \{De Leener\}, Karen and Amisha Desai and Rob Driessen and Ahmet Erdemir and Mona Eskandari and Sam Evans and Christian Gasser and Marc Gebhardt and Birgit Glasmacher and Holzapfel, \{Gerhard A.\} and Mikel Isasi and Louise Jennings and Sascha Kurz and Sara Leal-Marin and Pauline Lecomte and Annie Morch and John Mulvihill and Fulufhelo Nemavhola and Thanyani Pandelani and Salvatore Pasta and Estefania Pe{\~n}a and Baptiste Pierrat and Ploeg, \{Heidi Lynn\} and Stanislav Polzer and Manuel Rausch and David Schwarz and Hazel Screen and Selda Sherifova and Gerhard Sommer and Shengzhang Wang and Darragh Walsh and Deepesh Yadav and Thierry Marchal and Liesbet Geris",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Ltd",

year = "2026",

month = jan,

day = "1",

doi = "10.1016/j.jbiomech.2025.113021",

language = "English",

volume = "194",

journal = "Journal of Biomechanics",

issn = "0021-9290",

}

Famaey, N, Fehervary, H, Lafon, Y, Akyildiz, A, Dreesen, S, Bruyère-Garnier, K, Allain, JM, Alloisio, M, Aparici-Gil, A, Catalano, C, Chassagne, F, Chokhandre, S, Crevits, K, Crielaard, H, Cunnane, E, Cunnane, C, De Leener, K, Desai, A, Driessen, R, Erdemir, A, Eskandari, M, Evans, S, Gasser, C, Gebhardt, M, Glasmacher, B, Holzapfel, GA, Isasi, M, Jennings, L, Kurz, S, Leal-Marin, S, Lecomte, P, Morch, A, Mulvihill, J, Nemavhola, F, Pandelani, T, Pasta, S, Peña, E, Pierrat, B, Ploeg, HL, Polzer, S, Rausch, M, Schwarz, D, Screen, H, Sherifova, S, Sommer, G, Wang, S, Walsh, D, Yadav, D, Marchal, T & Geris, L 2026, 'Community challenge towards consensus on characterization of biological tissue: C⁴Bio's first findings', Journal of Biomechanics, VOL. 194, 113021. https://doi.org/10.1016/j.jbiomech.2025.113021

TY - JOUR

T1 - Community challenge towards consensus on characterization of biological tissue

T2 - C4Bio's first findings

AU - Famaey, Nele

AU - Fehervary, Heleen

AU - Lafon, Yoann

AU - Akyildiz, Ali

AU - Dreesen, Silke

AU - Bruyère-Garnier, Karine

AU - Allain, Jean Marc

AU - Alloisio, Marta

AU - Aparici-Gil, Alejandro

AU - Catalano, Chiara

AU - Chassagne, Fanette

AU - Chokhandre, Snehal

AU - Crevits, Kimberly

AU - Crielaard, Hanneke

AU - Cunnane, Eoghan

AU - Cunnane, Connor

AU - De Leener, Karen

AU - Desai, Amisha

AU - Driessen, Rob

AU - Erdemir, Ahmet

AU - Eskandari, Mona

AU - Evans, Sam

AU - Gasser, Christian

AU - Gebhardt, Marc

AU - Glasmacher, Birgit

AU - Holzapfel, Gerhard A.

AU - Isasi, Mikel

AU - Jennings, Louise

AU - Kurz, Sascha

AU - Leal-Marin, Sara

AU - Lecomte, Pauline

AU - Morch, Annie

AU - Mulvihill, John

AU - Nemavhola, Fulufhelo

AU - Pandelani, Thanyani

AU - Pasta, Salvatore

AU - Peña, Estefania

AU - Pierrat, Baptiste

AU - Ploeg, Heidi Lynn

AU - Polzer, Stanislav

AU - Rausch, Manuel

AU - Schwarz, David

AU - Screen, Hazel

AU - Sherifova, Selda

AU - Sommer, Gerhard

AU - Wang, Shengzhang

AU - Walsh, Darragh

AU - Yadav, Deepesh

AU - Marchal, Thierry

AU - Geris, Liesbet

PY - 2026/1/1

Y1 - 2026/1/1

N2 - This study investigates methodological variability across various expert laboratories worldwide, with regards to characterizing the mechanical properties of biological tissues. Two testing rounds were conducted on the specific use case of uniaxial tensile testing of porcine aorta. In the first round, 24 labs were invited to apply their established methods to assess inter-laboratory variability. This revealed significant methodological diversity and associated variability in the stress–stretch results, underscoring the necessity for a standardized approach. In the second round, a consensus protocol was collaboratively developed and adopted by 19 labs in an attempt to minimize variability. This involved standardized sample preparation and uniformity in testing protocol, including the use of a common cutting and thickness measurement tool. Despite protocol harmonization, significant variability persisted across labs, which could not be solely attributed to inherent biological differences in tissue samples. These results illustrate the challenges in unifying testing methods across different research settings, underlining the necessity for further refinement of testing practices. Enhancing consistency in biomechanical experiments is pivotal when comparing results across studies, as well as when using the resulting material properties for in silico simulations in medical research.

AB - This study investigates methodological variability across various expert laboratories worldwide, with regards to characterizing the mechanical properties of biological tissues. Two testing rounds were conducted on the specific use case of uniaxial tensile testing of porcine aorta. In the first round, 24 labs were invited to apply their established methods to assess inter-laboratory variability. This revealed significant methodological diversity and associated variability in the stress–stretch results, underscoring the necessity for a standardized approach. In the second round, a consensus protocol was collaboratively developed and adopted by 19 labs in an attempt to minimize variability. This involved standardized sample preparation and uniformity in testing protocol, including the use of a common cutting and thickness measurement tool. Despite protocol harmonization, significant variability persisted across labs, which could not be solely attributed to inherent biological differences in tissue samples. These results illustrate the challenges in unifying testing methods across different research settings, underlining the necessity for further refinement of testing practices. Enhancing consistency in biomechanical experiments is pivotal when comparing results across studies, as well as when using the resulting material properties for in silico simulations in medical research.

KW - Biomechanical characterization

KW - Methodological variability

KW - Standardization

KW - Uncertainty

UR - https://www.scopus.com/pages/publications/105020922788

U2 - 10.1016/j.jbiomech.2025.113021

DO - 10.1016/j.jbiomech.2025.113021

M3 - Article

C2 - 41138606

AN - SCOPUS:105020922788

SN - 0021-9290

VL - 194

JO - Journal of Biomechanics

JF - Journal of Biomechanics

M1 - 113021