Gold nanoparticle-decellularized matrix hybrids for cardiac tissue engineering

Michal Shevach; Sharon Fleischer; Assaf Shapira; Tal Dvir

doi:10.1021/nl502673m

Gold nanoparticle-decellularized matrix hybrids for cardiac tissue engineering

Michal Shevach, Sharon Fleischer, Assaf Shapira, Tal Dvir

Tel Aviv University

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

Abstract

Decellularized matrices are valuable scaffolds for engineering functional cardiac patches for treating myocardial infarction. However, the lack of quick and efficient electrical coupling between adjacent cells may jeopardize the success of the treatment. To address this issue, we have deposited gold nanoparticles on fibrous decellularized omental matrices and investigated their morphology, conductivity, and degradation. We have shown that cardiac cells engineered within the hybrid scaffolds exhibited elongated and aligned morphology, massive striation, and organized connexin 43 electrical coupling proteins. Finally, we have shown that the hybrid patches demonstrated superior function as compared to pristine patches, including a stronger contraction force, lower excitation threshold, and faster calcium transients.

Original language	American English
Pages (from-to)	5792-5796
Number of pages	5
Journal	Nano Letters
Volume	14
Issue number	10
DOIs	https://doi.org/10.1021/nl502673m
State	Published - 8 Oct 2014

Keywords

Cardiac tissue engineering
decellularized matrix
gold nanoparticles
omentum
scaffold

All Science Journal Classification (ASJC) codes

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/nl502673m

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title = "Gold nanoparticle-decellularized matrix hybrids for cardiac tissue engineering",

abstract = "Decellularized matrices are valuable scaffolds for engineering functional cardiac patches for treating myocardial infarction. However, the lack of quick and efficient electrical coupling between adjacent cells may jeopardize the success of the treatment. To address this issue, we have deposited gold nanoparticles on fibrous decellularized omental matrices and investigated their morphology, conductivity, and degradation. We have shown that cardiac cells engineered within the hybrid scaffolds exhibited elongated and aligned morphology, massive striation, and organized connexin 43 electrical coupling proteins. Finally, we have shown that the hybrid patches demonstrated superior function as compared to pristine patches, including a stronger contraction force, lower excitation threshold, and faster calcium transients.",

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author = "Michal Shevach and Sharon Fleischer and Assaf Shapira and Tal Dvir",

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AU - Fleischer, Sharon

AU - Shapira, Assaf

AU - Dvir, Tal

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Y1 - 2014/10/8

N2 - Decellularized matrices are valuable scaffolds for engineering functional cardiac patches for treating myocardial infarction. However, the lack of quick and efficient electrical coupling between adjacent cells may jeopardize the success of the treatment. To address this issue, we have deposited gold nanoparticles on fibrous decellularized omental matrices and investigated their morphology, conductivity, and degradation. We have shown that cardiac cells engineered within the hybrid scaffolds exhibited elongated and aligned morphology, massive striation, and organized connexin 43 electrical coupling proteins. Finally, we have shown that the hybrid patches demonstrated superior function as compared to pristine patches, including a stronger contraction force, lower excitation threshold, and faster calcium transients.

AB - Decellularized matrices are valuable scaffolds for engineering functional cardiac patches for treating myocardial infarction. However, the lack of quick and efficient electrical coupling between adjacent cells may jeopardize the success of the treatment. To address this issue, we have deposited gold nanoparticles on fibrous decellularized omental matrices and investigated their morphology, conductivity, and degradation. We have shown that cardiac cells engineered within the hybrid scaffolds exhibited elongated and aligned morphology, massive striation, and organized connexin 43 electrical coupling proteins. Finally, we have shown that the hybrid patches demonstrated superior function as compared to pristine patches, including a stronger contraction force, lower excitation threshold, and faster calcium transients.

KW - Cardiac tissue engineering

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KW - gold nanoparticles

KW - omentum

KW - scaffold

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JO - Nano Letters

JF - Nano Letters

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Gold nanoparticle-decellularized matrix hybrids for cardiac tissue engineering

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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