One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation
Abstract Three dimensional (3D) printing of heart patches usually provides the ability to precisely control cell location in 3D space. Here, one‐step 3D printing of cardiac patches with built‐in soft and stretchable electronics is reported. The tissue is simultaneously printed using three distinct b...
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Online Access: | https://doi.org/10.1002/advs.202004205 |
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doaj-aaa9254c7ce349a2a5edf18adcb9b2322021-05-05T07:56:42ZengWileyAdvanced Science2198-38442021-05-0189n/an/a10.1002/advs.202004205One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance RegulationMasha Asulin0Idan Michael1Assaf Shapira2Tal Dvir3The Shmunis School of Biomedicine and Cancer Research Faculty of Life Sciences Tel Aviv University Tel Aviv 6997801 IsraelThe Shmunis School of Biomedicine and Cancer Research Faculty of Life Sciences Tel Aviv University Tel Aviv 6997801 IsraelThe Shmunis School of Biomedicine and Cancer Research Faculty of Life Sciences Tel Aviv University Tel Aviv 6997801 IsraelThe Shmunis School of Biomedicine and Cancer Research Faculty of Life Sciences Tel Aviv University Tel Aviv 6997801 IsraelAbstract Three dimensional (3D) printing of heart patches usually provides the ability to precisely control cell location in 3D space. Here, one‐step 3D printing of cardiac patches with built‐in soft and stretchable electronics is reported. The tissue is simultaneously printed using three distinct bioinks for the cells, for the conducting parts of the electronics and for the dielectric components. It is shown that the hybrid system can withstand continuous physical deformations as those taking place in the contracting myocardium. The electronic patch is flexible, stretchable, and soft, and the electrodes within the printed patch are able to monitor the function of the engineered tissue by providing extracellular potentials. Furthermore, the system allowed controlling tissue function by providing electrical stimulation for pacing. It is envisioned that such transplantable patches may regain heart contractility and allow the physician to monitor the implant function as well as to efficiently intervene from afar when needed.https://doi.org/10.1002/advs.2020042053D printingbioinkscardiac tissue engineeringECM hydrogelselectronics |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Masha Asulin Idan Michael Assaf Shapira Tal Dvir |
spellingShingle |
Masha Asulin Idan Michael Assaf Shapira Tal Dvir One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation Advanced Science 3D printing bioinks cardiac tissue engineering ECM hydrogels electronics |
author_facet |
Masha Asulin Idan Michael Assaf Shapira Tal Dvir |
author_sort |
Masha Asulin |
title |
One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation |
title_short |
One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation |
title_full |
One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation |
title_fullStr |
One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation |
title_full_unstemmed |
One‐Step 3D Printing of Heart Patches with Built‐In Electronics for Performance Regulation |
title_sort |
one‐step 3d printing of heart patches with built‐in electronics for performance regulation |
publisher |
Wiley |
series |
Advanced Science |
issn |
2198-3844 |
publishDate |
2021-05-01 |
description |
Abstract Three dimensional (3D) printing of heart patches usually provides the ability to precisely control cell location in 3D space. Here, one‐step 3D printing of cardiac patches with built‐in soft and stretchable electronics is reported. The tissue is simultaneously printed using three distinct bioinks for the cells, for the conducting parts of the electronics and for the dielectric components. It is shown that the hybrid system can withstand continuous physical deformations as those taking place in the contracting myocardium. The electronic patch is flexible, stretchable, and soft, and the electrodes within the printed patch are able to monitor the function of the engineered tissue by providing extracellular potentials. Furthermore, the system allowed controlling tissue function by providing electrical stimulation for pacing. It is envisioned that such transplantable patches may regain heart contractility and allow the physician to monitor the implant function as well as to efficiently intervene from afar when needed. |
topic |
3D printing bioinks cardiac tissue engineering ECM hydrogels electronics |
url |
https://doi.org/10.1002/advs.202004205 |
work_keys_str_mv |
AT mashaasulin onestep3dprintingofheartpatcheswithbuiltinelectronicsforperformanceregulation AT idanmichael onestep3dprintingofheartpatcheswithbuiltinelectronicsforperformanceregulation AT assafshapira onestep3dprintingofheartpatcheswithbuiltinelectronicsforperformanceregulation AT taldvir onestep3dprintingofheartpatcheswithbuiltinelectronicsforperformanceregulation |
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