Rational design and modeling of auxetic fiber scaffolds for soft tissue engineering via melt electrowriting
Lecina-Tejero, Óscar (Universidad de Zaragoza) ; Iamsamang, Jirawat ; Alamán-Díez, Pilar (Universidad de Zaragoza) ; García-Gareta, Elena (Universidad de Zaragoza) ; Cuartero, Jesús (Universidad de Zaragoza) ; Pérez, María Ángeles (Universidad de Zaragoza) ; Castilho, Miguel ; Borau, Carlos (Universidad de Zaragoza)
Resumen: Background: The development of regenerative biomaterial scaffolds with mechanical properties tailored to native soft tissues remains a challenge in tissue engineering. Mechanical metamaterials with auxetic architectures have taken enormous flight over the past years, as they offer improved control over mechanical function and performance through spatially defined material architecture. However, despite their potential, auxetic scaffold designs are often developed empirically, and the relationship between scaffold microarchitecture, mechanical function, and manufacturability remains poorly defined, limiting their applicability in tissue engineering. In this study, we present a computational framework for the rational design of auxetic fiber scaffolds manufactured using Melt Electro-writing (MEW) for soft tissue engineering. To address the challenge of tailoring scaffold mechanical properties to native tissue, we integrated finite element method (FEM) modeling with experimental validation to predict the mechanical behavior of the scaffolds.
Method: The micro-fibrous scaffolds with customizable auxetic re-entrant structures were designed using Python scripts for generating G-code used in fabrication and for model definition in FEM modeling, respectively. Four distinct auxetic structures – HCELL, SREG, SINV, and STRI – were selected for this study to cover the wide range of mechanical properties of soft tissue, and their geometry parameters were adjusted to reduce the pore size while considering printing resolution. FEM modeling was employed to predict the mechanical behavior of the scaffolds. To validate the predictions, the scaffolds were manufactured via MEW and characterized mechanically under biaxial tensile loading.
Results and conclusion: MEW manufacturing enabled the production of auxetic fiber scaffolds with sub-millimeter pore resolution, while rational design allowed to correct fabrication discrepancies and improve printed design fidelity. Experimental biaxial characterization of the scaffolds revealed design-dependent, biphasic, non-linear mechanical response, and the developed FEM model was capable of not only accurately simulating the observed mechanical response but also accounting for variations introduced by MEW during fabrication. Additionally, auxetic scaffolds supported fibroblast viability over 7 days, confirming biocompatibility as a first step toward soft tissue engineering. The good alignment between numerical predictions and experimental results highlights the value of FEM modeling as a powerful computational tool for guiding the design and optimization of auxetic scaffolds with tailored mechanical performance for specific soft tissue requirements. The presented methodology offers a significant advancement in the development of functional biomaterials for biomedical applications.
Idioma: Inglés
DOI: 10.1016/j.rineng.2025.107001
Año: 2025
Publicado en: Results in Engineering 28 (2025), 107001 [11 pp.]
ISSN: 2590-1230
Financiación: info:eu-repo/grantAgreement/ES/MICINN/PID2023-146072OB-I00
Financiación: info:eu-repo/grantAgreement/ES/MICINN/RYC2021-033490-I
Tipo y forma: Article (Published version)
Área (Departamento): Área Ingen.e Infraestr.Transp. (Dpto. Ingeniería Mecánica)
Área (Departamento): Área Mec.Med.Cont. y Teor.Est. (Dpto. Ingeniería Mecánica)
Área (Departamento): Área Cienc.Mater. Ingen.Metal. (Dpto. Ciencia Tecnol.Mater.Fl.)
You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use. You may not use the material for commercial purposes. If you remix, transform, or build upon the material, you may not distribute the modified material.
Exportado de SIDERAL (2025-10-17-14:18:12)
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Method: The micro-fibrous scaffolds with customizable auxetic re-entrant structures were designed using Python scripts for generating G-code used in fabrication and for model definition in FEM modeling, respectively. Four distinct auxetic structures – HCELL, SREG, SINV, and STRI – were selected for this study to cover the wide range of mechanical properties of soft tissue, and their geometry parameters were adjusted to reduce the pore size while considering printing resolution. FEM modeling was employed to predict the mechanical behavior of the scaffolds. To validate the predictions, the scaffolds were manufactured via MEW and characterized mechanically under biaxial tensile loading.
Results and conclusion: MEW manufacturing enabled the production of auxetic fiber scaffolds with sub-millimeter pore resolution, while rational design allowed to correct fabrication discrepancies and improve printed design fidelity. Experimental biaxial characterization of the scaffolds revealed design-dependent, biphasic, non-linear mechanical response, and the developed FEM model was capable of not only accurately simulating the observed mechanical response but also accounting for variations introduced by MEW during fabrication. Additionally, auxetic scaffolds supported fibroblast viability over 7 days, confirming biocompatibility as a first step toward soft tissue engineering. The good alignment between numerical predictions and experimental results highlights the value of FEM modeling as a powerful computational tool for guiding the design and optimization of auxetic scaffolds with tailored mechanical performance for specific soft tissue requirements. The presented methodology offers a significant advancement in the development of functional biomaterials for biomedical applications.
Idioma: Inglés
DOI: 10.1016/j.rineng.2025.107001
Año: 2025
Publicado en: Results in Engineering 28 (2025), 107001 [11 pp.]
ISSN: 2590-1230
Financiación: info:eu-repo/grantAgreement/ES/MICINN/PID2023-146072OB-I00
Financiación: info:eu-repo/grantAgreement/ES/MICINN/RYC2021-033490-I
Tipo y forma: Article (Published version)
Área (Departamento): Área Ingen.e Infraestr.Transp. (Dpto. Ingeniería Mecánica)
Área (Departamento): Área Mec.Med.Cont. y Teor.Est. (Dpto. Ingeniería Mecánica)
Área (Departamento): Área Cienc.Mater. Ingen.Metal. (Dpto. Ciencia Tecnol.Mater.Fl.)
You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use. You may not use the material for commercial purposes. If you remix, transform, or build upon the material, you may not distribute the modified material. Exportado de SIDERAL (2025-10-17-14:18:12)
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Este artículo se encuentra en las siguientes colecciones:
Articles > Artículos por área > Ciencia de los Materiales e Ingeniería Metalúrgica
Articles > Artículos por área > Ingeniería e Infraestructura de los Transportes
Articles > Artículos por área > Mec. de Medios Contínuos y Teor. de Estructuras
Record created 2025-09-19, last modified 2025-10-17