# From Fiber Architecture to Functional Attachment: A Clinically Relevant, Mechanically Tunable Cardiac Patch

**Authors:** Johannes Braig, Ross Kent, Ainitze Gereka Goienetxe, Nicolás Laita, Ming Wu, Miguel Ángel Martínez, Margarida Serra, Koen Janssens, Uzuri Urtaza, Eduardo Larequi, Ilazki Anaut‐Lusar, Hilde Gillijns, Michiel Algoet, Britt van Kerkhof, Maite van der Knaap, Gerardo Cedillo‐Servin, Miguel Castilho, Alain van Mil, Joost P. G. Sluijter, Jos Malda, Piet Claus, Peter H. M. Bovendeerd, Estefanía Peña, Manuel Doblare, Wouter Oosterlinck, Stefan Janssens, Ane M. Zaldua, Olalla Iglesias‐García, Felipe Prósper, Manuel M. Mazo Vega, Jürgen Groll, Tomasz Jüngst

PMC · DOI: 10.1002/adma.202515863 · 2026-02-19

## TL;DR

A customizable cardiac patch design is developed to support heart function by mimicking natural tissue mechanics and promoting integration with the heart.

## Contribution

A multi-zonal cardiac patch design is introduced, enabling precise customization of fiber architecture and mechanical properties for clinical applications.

## Key findings

- Digital image correlation shows a 2.6-fold strain difference between scaffold zones under physiological deformation.
- The patch achieves complete epicardial attachment and vascular ingrowth in a porcine model within 7 days.
- Dynamic cultivation with cardiomyocytes significantly improves cell alignment compared to controls.

## Abstract

Contractile engineered cardiac patches hold great potential for treating myocardial infarction, serving as biological ventricular assist devices (BioVADs). However, optimal design and attachment of cardiac patches remain insufficiently explored, although both are essential for the mechanical support of damaged hearts. This study presents a platform for personalized macroscale patches with a multi‐zonal microarchitecture combining a regenerative zone for cell alignment, a stiff force transmission zone for load transfer, and an elastic attachment zone enabling integration. Based on computational modeling, the design is implemented using a custom G‐code generator for melt electrowriting (MEW). Digital image correlation reveals up to a 2.6‐fold strain difference between scaffold zones under physiological deformation, confirming zonal interplay. Biaxial testing with preconditioning shows scaffold mechanics replicating native myocardium properties up to 10% strain. For epicardial suture attachment, a reinforced outline enables shape‐morphing and increases suture retention 2.16‐fold. Dynamic BioVAD cultivation with fibrin‐embedded cardiomyocytes significantly (p = 0.01) improves cell alignment versus controls. Finally, in a porcine myocardial infarction model, the BioVAD achieves complete epicardial attachment and vascular ingrowth within 7 days, compared to partial attachment in controls. This study highlights MEW as a versatile platform for tailoring cardiac scaffold mechanics to support tissue integration and cardiac function.

A personalizable platform featuring a multi‐zonal cardiac patch design at clinical scale enables precise customization of fiber architecture at micro‐ and macroscale via melt electrowriting. Distinct scaffold zones support cell alignment with mechanical force transfer and epicardial attachment. In a porcine myocardial infarction model, the patch integrates within 7 days with capillary ingrowth, demonstrating strong potential to restore heart function.

## Linked entities

- **Diseases:** myocardial infarction (MONDO:0005068)

## Full-text entities

- **Diseases:** myocardial infarction (MESH:D009203)

## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC13003913/full.md

---
Source: https://tomesphere.com/paper/PMC13003913