Bioprinted optoelectronically active cardiac tissues

Faheem Ershad; Zhoulyu Rao; Sushila Maharajan; Fernanda C.Paccola Mesquita; Junkyu Ha; Lei Gonzalez; Tahir Haideri; Ernesto Curty Da Costa; Angel Moctezuma-Ramirez; Yuqi Wang; Seonmin Jang; Yuntao Lu; Shubham Patel; Xiaoyang Wang; Yifan Tao; Joshua Weygant; Carlos Ezio Garciamendez-Mijares; Luis Carlos Orrantia Clark; Muhammad Zubair; Xiaojun Lance Lian; Abdelmotagaly Elgalad; Jian Yang; Camila Hochman-Mendez; Yu Shrike Zhang; Cunjiang Yu

doi:10.1126/sciadv.adt7210

Bioprinted optoelectronically active cardiac tissues

Faheem Ershad, Zhoulyu Rao, Sushila Maharajan, Fernanda C.Paccola Mesquita, Junkyu Ha, Lei Gonzalez, Tahir Haideri, Ernesto Curty Da Costa, Angel Moctezuma-Ramirez, Yuqi Wang, Seonmin Jang, Yuntao Lu, Shubham Patel, Xiaoyang Wang, Yifan Tao, Joshua Weygant, Carlos Ezio Garciamendez-Mijares, Luis Carlos Orrantia Clark, Muhammad Zubair, Xiaojun Lance LianAbdelmotagaly Elgalad, Jian Yang, Camila Hochman-Mendez, Yu Shrike Zhang, Cunjiang Yu

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

Abstract

Electrical stimulation of existing three-dimensional bioprinted tissues to alter tissue activities is typically associated with wired delivery, invasive electrode placement, and potential cell damage, minimizing its efficacy in cardiac modulation. Here, we report an optoelectronically active scaffold based on printed gelatin methacryloyl embedded with micro-solar cells, seeded with cardiomyocytes to form light-stimulable tissues. This enables untethered, noninvasive, and damage-free optoelectronic stimulation-induced modulation of cardiac beating behaviors without needing wires or genetic modifications to the tissue solely with light. Pulsed light stimulation of human cardiomyocytes showed that the optoelectronically active scaffold could increase their beating rates (>40%), maintain high cell viability under light stimulation (>96%), and negligibly affect the electrocardiogram morphology. The seeded scaffolds, termed optoelectronically active tissues, were able to successfully accelerate heart beating in vivo in rats. Our work demonstrates a viable wireless, printable, and optically controllable tissue, suggesting a transformative step in future therapy of electrically active tissues/organs.

Original language	English (US)
Article number	eadt7210
Journal	Science Advances
Volume	11
Issue number	4
DOIs	https://doi.org/10.1126/sciadv.adt7210
State	Published - Jan 24 2025

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Ershad, F., Rao, Z., Maharajan, S., Mesquita, F. C. P., Ha, J., Gonzalez, L., Haideri, T., Da Costa, E. C., Moctezuma-Ramirez, A., Wang, Y., Jang, S., Lu, Y., Patel, S., Wang, X., Tao, Y., Weygant, J., Garciamendez-Mijares, C. E., Carlos Orrantia Clark, L., Zubair, M., ... Yu, C. (2025). Bioprinted optoelectronically active cardiac tissues. Science Advances, 11(4), Article eadt7210. https://doi.org/10.1126/sciadv.adt7210

Ershad, F, Rao, Z, Maharajan, S, Mesquita, FCP, Ha, J, Gonzalez, L, Haideri, T, Da Costa, EC, Moctezuma-Ramirez, A, Wang, Y, Jang, S, Lu, Y, Patel, S, Wang, X, Tao, Y, Weygant, J, Garciamendez-Mijares, CE, Carlos Orrantia Clark, L, Zubair, M, Lian, XL, Elgalad, A, Yang, J, Hochman-Mendez, C, Zhang, YS & Yu, C 2025, 'Bioprinted optoelectronically active cardiac tissues', Science Advances, vol. 11, no. 4, eadt7210. https://doi.org/10.1126/sciadv.adt7210

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title = "Bioprinted optoelectronically active cardiac tissues",

abstract = "Electrical stimulation of existing three-dimensional bioprinted tissues to alter tissue activities is typically associated with wired delivery, invasive electrode placement, and potential cell damage, minimizing its efficacy in cardiac modulation. Here, we report an optoelectronically active scaffold based on printed gelatin methacryloyl embedded with micro-solar cells, seeded with cardiomyocytes to form light-stimulable tissues. This enables untethered, noninvasive, and damage-free optoelectronic stimulation-induced modulation of cardiac beating behaviors without needing wires or genetic modifications to the tissue solely with light. Pulsed light stimulation of human cardiomyocytes showed that the optoelectronically active scaffold could increase their beating rates (>40%), maintain high cell viability under light stimulation (>96%), and negligibly affect the electrocardiogram morphology. The seeded scaffolds, termed optoelectronically active tissues, were able to successfully accelerate heart beating in vivo in rats. Our work demonstrates a viable wireless, printable, and optically controllable tissue, suggesting a transformative step in future therapy of electrically active tissues/organs.",

author = "Faheem Ershad and Zhoulyu Rao and Sushila Maharajan and Mesquita, {Fernanda C.Paccola} and Junkyu Ha and Lei Gonzalez and Tahir Haideri and {Da Costa}, {Ernesto Curty} and Angel Moctezuma-Ramirez and Yuqi Wang and Seonmin Jang and Yuntao Lu and Shubham Patel and Xiaoyang Wang and Yifan Tao and Joshua Weygant and Garciamendez-Mijares, {Carlos Ezio} and {Carlos Orrantia Clark}, Luis and Muhammad Zubair and Lian, {Xiaojun Lance} and Abdelmotagaly Elgalad and Jian Yang and Camila Hochman-Mendez and Zhang, {Yu Shrike} and Cunjiang Yu",

note = "We thank the Texas Heart Institute Cardiovascular Research Laboratories for contribution to the porcine tissue sharing resource and G. Costas for the animal care and welfare. C.Y. and Y.S.Z. would like to acknowledge the funding support by the National Institutes of Health (R21EB026175 and R21EB030257). C.Y. would also like to acknowledge the funding support by the National Science Foundation (CBET-2227063). Y.S.Z. would also like to acknowledge the support from the National Institutes of Health (R21HL168656, R00CA201603, R01EB028143, R01HL166522, R56EB034702, and R01CA282451), the National Science Foundation (CBET-EBMS-1936105 and CISE-II S-2225698), the American Heart Association (19TPA34850188), the Chan Zuckerberg Initiative (2022-316712), and the Brigham Research Institute.",

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month = jan,

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doi = "10.1126/sciadv.adt7210",

language = "English (US)",

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T1 - Bioprinted optoelectronically active cardiac tissues

AU - Ershad, Faheem

AU - Rao, Zhoulyu

AU - Maharajan, Sushila

AU - Mesquita, Fernanda C.Paccola

AU - Ha, Junkyu

AU - Gonzalez, Lei

AU - Haideri, Tahir

AU - Da Costa, Ernesto Curty

AU - Moctezuma-Ramirez, Angel

AU - Wang, Yuqi

AU - Jang, Seonmin

AU - Lu, Yuntao

AU - Patel, Shubham

AU - Wang, Xiaoyang

AU - Tao, Yifan

AU - Weygant, Joshua

AU - Garciamendez-Mijares, Carlos Ezio

AU - Carlos Orrantia Clark, Luis

AU - Zubair, Muhammad

AU - Lian, Xiaojun Lance

AU - Elgalad, Abdelmotagaly

AU - Yang, Jian

AU - Hochman-Mendez, Camila

AU - Zhang, Yu Shrike

AU - Yu, Cunjiang

N1 - We thank the Texas Heart Institute Cardiovascular Research Laboratories for contribution to the porcine tissue sharing resource and G. Costas for the animal care and welfare. C.Y. and Y.S.Z. would like to acknowledge the funding support by the National Institutes of Health (R21EB026175 and R21EB030257). C.Y. would also like to acknowledge the funding support by the National Science Foundation (CBET-2227063). Y.S.Z. would also like to acknowledge the support from the National Institutes of Health (R21HL168656, R00CA201603, R01EB028143, R01HL166522, R56EB034702, and R01CA282451), the National Science Foundation (CBET-EBMS-1936105 and CISE-II S-2225698), the American Heart Association (19TPA34850188), the Chan Zuckerberg Initiative (2022-316712), and the Brigham Research Institute.

PY - 2025/1/24

Y1 - 2025/1/24

N2 - Electrical stimulation of existing three-dimensional bioprinted tissues to alter tissue activities is typically associated with wired delivery, invasive electrode placement, and potential cell damage, minimizing its efficacy in cardiac modulation. Here, we report an optoelectronically active scaffold based on printed gelatin methacryloyl embedded with micro-solar cells, seeded with cardiomyocytes to form light-stimulable tissues. This enables untethered, noninvasive, and damage-free optoelectronic stimulation-induced modulation of cardiac beating behaviors without needing wires or genetic modifications to the tissue solely with light. Pulsed light stimulation of human cardiomyocytes showed that the optoelectronically active scaffold could increase their beating rates (>40%), maintain high cell viability under light stimulation (>96%), and negligibly affect the electrocardiogram morphology. The seeded scaffolds, termed optoelectronically active tissues, were able to successfully accelerate heart beating in vivo in rats. Our work demonstrates a viable wireless, printable, and optically controllable tissue, suggesting a transformative step in future therapy of electrically active tissues/organs.

AB - Electrical stimulation of existing three-dimensional bioprinted tissues to alter tissue activities is typically associated with wired delivery, invasive electrode placement, and potential cell damage, minimizing its efficacy in cardiac modulation. Here, we report an optoelectronically active scaffold based on printed gelatin methacryloyl embedded with micro-solar cells, seeded with cardiomyocytes to form light-stimulable tissues. This enables untethered, noninvasive, and damage-free optoelectronic stimulation-induced modulation of cardiac beating behaviors without needing wires or genetic modifications to the tissue solely with light. Pulsed light stimulation of human cardiomyocytes showed that the optoelectronically active scaffold could increase their beating rates (>40%), maintain high cell viability under light stimulation (>96%), and negligibly affect the electrocardiogram morphology. The seeded scaffolds, termed optoelectronically active tissues, were able to successfully accelerate heart beating in vivo in rats. Our work demonstrates a viable wireless, printable, and optically controllable tissue, suggesting a transformative step in future therapy of electrically active tissues/organs.

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JO - Science Advances

JF - Science Advances

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ER -

Bioprinted optoelectronically active cardiac tissues

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