A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering

Caterina Cristallini; Daniela Rossin; Roberto Vanni; Niccoletta Barbani; Chiara Bulgheresi; Massimiliano Labardi; Sadia Perveen; Silvia Burchielli; Domiziana Terlizzi; Claudia Kusmic; Silvia Del Ry; Manuela Cabiati; Cheherazade Trouki; Dawid Rossino; Francesca Sergi; Anthea Villano; Giovanni D. Aquaro; Giorgia Scarpellino; Federico A. Ruffinatti; Sara Amorim; Ricardo A. Pires; Rui L. Reis; Raffaella Rastaldo; Claudia Giachino

doi:10.1016/j.bioactmat.2025.04.008

A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering

Caterina Cristallini^*, Daniela Rossin^*, Roberto Vanni^*, Niccoletta Barbani^*, Chiara Bulgheresi^*, Massimiliano Labardi^*, Sadia Perveen^*, Silvia Burchielli^*, Domiziana Terlizzi^*, Claudia Kusmic^*, Silvia Del Ry^*, Manuela Cabiati^*, Cheherazade Trouki^*, Dawid Rossino^*, Francesca Sergi^*, Anthea Villano^*, Giovanni D. Aquaro^*, Giorgia Scarpellino^*, Federico A. Ruffinatti^*, Sara Amorim^*Ricardo A. Pires^*, Rui L. Reis^*, Raffaella Rastaldo^*, Claudia Giachino^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We produced a microstructured, electroconductive and nano-functionalized drug eluting cardiac patch (MENDEP) designed to attract endogenous precursor cells, favor their differentiation and counteract adverse ventricular remodeling in situ. MENDEP showed mechanical anisotropy and biaxial strength comparable to porcine myocardium, reduced impedance, controlled biodegradability, molecular recognition ability and controlled drug release activity. In vitro, cytocompatibility and cardioinductivity were demonstrated. Migration tests showed the chemoattractive capacity of the patches and conductivity assays showed unaltered cell-cell interactions and cell beating synchronicity. MENDEP was then epicardially implanted in a rat model of ischemia/reperfusion (I/R). Histological, immunofluorescence and biomarker analysis indicated that implantation did not cause damage to the healthy myocardium. After I/R, MENDEP recruited precursor cells into the damaged myocardium and triggered their differentiation towards the vascular lineage. Under the patch, the myocardial tissue appeared well preserved and cardiac gap junctions were correctly distributed at the level of the intercalated discs. The fibrotic area measured in the I/R group was partially reduced in the patch group. Overall, these results demonstrate that MENDEP was fully retained on the epicardial surface of the left ventricle over 4-week implantation period, underwent progressive vascularization, did not perturb the healthy myocardium and showed great potential in repairing the infarcted area.

Original language	English
Pages (from-to)	246-272
Number of pages	27
Journal	Bioactive Materials
Volume	50
DOIs	https://doi.org/10.1016/j.bioactmat.2025.04.008
Publication status	Published - Aug 2025
Externally published	Yes

Keywords

Acellular Electroconductive Cardiac Patch
Cardioprotection
Drug delivery
Molecular imprinting
Myocardial infarction
Cardiac regeneration

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Cristallini, C., Rossin, D., Vanni, R., Barbani, N., Bulgheresi, C., Labardi, M., Perveen, S., Burchielli, S., Terlizzi, D., Kusmic, C., Del Ry, S., Cabiati, M., Trouki, C., Rossino, D., Sergi, F., Villano, A., Aquaro, G. D., Scarpellino, G., Ruffinatti, F. A., ... Giachino, C. (2025). A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering. Bioactive Materials, 50, 246-272. https://doi.org/10.1016/j.bioactmat.2025.04.008

@article{5b052ff2393d425ebb942498e03f94ca,

title = "A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering",

abstract = "We produced a microstructured, electroconductive and nano-functionalized drug eluting cardiac patch (MENDEP) designed to attract endogenous precursor cells, favor their differentiation and counteract adverse ventricular remodeling in situ. MENDEP showed mechanical anisotropy and biaxial strength comparable to porcine myocardium, reduced impedance, controlled biodegradability, molecular recognition ability and controlled drug release activity. In vitro, cytocompatibility and cardioinductivity were demonstrated. Migration tests showed the chemoattractive capacity of the patches and conductivity assays showed unaltered cell-cell interactions and cell beating synchronicity. MENDEP was then epicardially implanted in a rat model of ischemia/reperfusion (I/R). Histological, immunofluorescence and biomarker analysis indicated that implantation did not cause damage to the healthy myocardium. After I/R, MENDEP recruited precursor cells into the damaged myocardium and triggered their differentiation towards the vascular lineage. Under the patch, the myocardial tissue appeared well preserved and cardiac gap junctions were correctly distributed at the level of the intercalated discs. The fibrotic area measured in the I/R group was partially reduced in the patch group. Overall, these results demonstrate that MENDEP was fully retained on the epicardial surface of the left ventricle over 4-week implantation period, underwent progressive vascularization, did not perturb the healthy myocardium and showed great potential in repairing the infarcted area.",

keywords = "Acellular Electroconductive Cardiac Patch, Cardioprotection, Drug delivery, Molecular imprinting, Myocardial infarction, Cardiac regeneration",

author = "Caterina Cristallini and Daniela Rossin and Roberto Vanni and Niccoletta Barbani and Chiara Bulgheresi and Massimiliano Labardi and Sadia Perveen and Silvia Burchielli and Domiziana Terlizzi and Claudia Kusmic and {Del Ry}, Silvia and Manuela Cabiati and Cheherazade Trouki and Dawid Rossino and Francesca Sergi and Anthea Villano and Aquaro, {Giovanni D.} and Giorgia Scarpellino and Ruffinatti, {Federico A.} and Sara Amorim and Pires, {Ricardo A.} and Reis, {Rui L.} and Raffaella Rastaldo and Claudia Giachino",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors",

year = "2025",

month = aug,

doi = "10.1016/j.bioactmat.2025.04.008",

language = "English",

volume = "50",

pages = "246--272",

journal = "Bioactive Materials",

issn = "2452-199X",

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Cristallini, C, Rossin, D, Vanni, R, Barbani, N, Bulgheresi, C, Labardi, M, Perveen, S, Burchielli, S, Terlizzi, D, Kusmic, C, Del Ry, S, Cabiati, M, Trouki, C, Rossino, D, Sergi, F, Villano, A, Aquaro, GD, Scarpellino, G, Ruffinatti, FA, Amorim, S, Pires, RA, Reis, RL, Rastaldo, R & Giachino, C 2025, 'A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering', Bioactive Materials, vol. 50, pp. 246-272. https://doi.org/10.1016/j.bioactmat.2025.04.008

TY - JOUR

T1 - A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering

AU - Cristallini, Caterina

AU - Rossin, Daniela

AU - Vanni, Roberto

AU - Barbani, Niccoletta

AU - Bulgheresi, Chiara

AU - Labardi, Massimiliano

AU - Perveen, Sadia

AU - Burchielli, Silvia

AU - Terlizzi, Domiziana

AU - Kusmic, Claudia

AU - Del Ry, Silvia

AU - Cabiati, Manuela

AU - Trouki, Cheherazade

AU - Rossino, Dawid

AU - Sergi, Francesca

AU - Villano, Anthea

AU - Aquaro, Giovanni D.

AU - Scarpellino, Giorgia

AU - Ruffinatti, Federico A.

AU - Amorim, Sara

AU - Pires, Ricardo A.

AU - Reis, Rui L.

AU - Rastaldo, Raffaella

AU - Giachino, Claudia

PY - 2025/8

Y1 - 2025/8

N2 - We produced a microstructured, electroconductive and nano-functionalized drug eluting cardiac patch (MENDEP) designed to attract endogenous precursor cells, favor their differentiation and counteract adverse ventricular remodeling in situ. MENDEP showed mechanical anisotropy and biaxial strength comparable to porcine myocardium, reduced impedance, controlled biodegradability, molecular recognition ability and controlled drug release activity. In vitro, cytocompatibility and cardioinductivity were demonstrated. Migration tests showed the chemoattractive capacity of the patches and conductivity assays showed unaltered cell-cell interactions and cell beating synchronicity. MENDEP was then epicardially implanted in a rat model of ischemia/reperfusion (I/R). Histological, immunofluorescence and biomarker analysis indicated that implantation did not cause damage to the healthy myocardium. After I/R, MENDEP recruited precursor cells into the damaged myocardium and triggered their differentiation towards the vascular lineage. Under the patch, the myocardial tissue appeared well preserved and cardiac gap junctions were correctly distributed at the level of the intercalated discs. The fibrotic area measured in the I/R group was partially reduced in the patch group. Overall, these results demonstrate that MENDEP was fully retained on the epicardial surface of the left ventricle over 4-week implantation period, underwent progressive vascularization, did not perturb the healthy myocardium and showed great potential in repairing the infarcted area.

AB - We produced a microstructured, electroconductive and nano-functionalized drug eluting cardiac patch (MENDEP) designed to attract endogenous precursor cells, favor their differentiation and counteract adverse ventricular remodeling in situ. MENDEP showed mechanical anisotropy and biaxial strength comparable to porcine myocardium, reduced impedance, controlled biodegradability, molecular recognition ability and controlled drug release activity. In vitro, cytocompatibility and cardioinductivity were demonstrated. Migration tests showed the chemoattractive capacity of the patches and conductivity assays showed unaltered cell-cell interactions and cell beating synchronicity. MENDEP was then epicardially implanted in a rat model of ischemia/reperfusion (I/R). Histological, immunofluorescence and biomarker analysis indicated that implantation did not cause damage to the healthy myocardium. After I/R, MENDEP recruited precursor cells into the damaged myocardium and triggered their differentiation towards the vascular lineage. Under the patch, the myocardial tissue appeared well preserved and cardiac gap junctions were correctly distributed at the level of the intercalated discs. The fibrotic area measured in the I/R group was partially reduced in the patch group. Overall, these results demonstrate that MENDEP was fully retained on the epicardial surface of the left ventricle over 4-week implantation period, underwent progressive vascularization, did not perturb the healthy myocardium and showed great potential in repairing the infarcted area.

KW - Acellular Electroconductive Cardiac Patch

KW - Cardioprotection

KW - Drug delivery

KW - Molecular imprinting

KW - Myocardial infarction

KW - Cardiac regeneration

UR - http://www.scopus.com/inward/record.url?scp=105002461662&partnerID=8YFLogxK

U2 - 10.1016/j.bioactmat.2025.04.008

DO - 10.1016/j.bioactmat.2025.04.008

M3 - Article

C2 - 40270551

AN - SCOPUS:105002461662

SN - 2452-199X

VL - 50

SP - 246

EP - 272

JO - Bioactive Materials

JF - Bioactive Materials

ER -

A biodegradable, microstructured, electroconductive and nano-integrated drug eluting patch (MENDEP) for myocardial tissue engineering

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Keywords

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