Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research

Philipp Gutruf; Vaishnavi Krishnamurthi; Abraham Vázquez-Guardado; Zhaoqian Xie; Anthony Banks; Chun Ju Su; Yeshou Xu; Chad R. Haney; Emily A. Waters; Irawati Kandela; Siddharth R. Krishnan; Tyler Ray; John P. Leshock; Yonggang Huang; Debashis Chanda; John A. Rogers

doi:10.1038/s41928-018-0175-0

Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research

Philipp Gutruf, Vaishnavi Krishnamurthi, Abraham Vázquez-Guardado, Zhaoqian Xie, Anthony Banks, Chun Ju Su, Yeshou Xu, Chad R. Haney, Emily A. Waters, Irawati Kandela, Siddharth R. Krishnan, Tyler Ray, John P. Leshock, Yonggang Huang, Debashis Chanda, John A. Rogers

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127 Scopus citations

Abstract

Recently developed ultrasmall, fully implantable devices for optogenetic neuromodulation eliminate the physical tethers associated with conventional set-ups and avoid the bulky head-stages and batteries found in alternative wireless technologies. The resulting systems allow behavioural studies without motion constraints and enable experiments in a range of environments and contexts, such as social interactions. However, these devices are purely passive in their electronic design, thereby precluding any form of active control or programmability; independent operation of multiple devices, or of multiple active components in a single device, is, in particular, impossible. Here we report optoelectronic systems that, through developments in integrated circuit and antenna design, provide low-power operation, and position- and angle-independent wireless power harvesting, with full user-programmability over individual devices and collections of them. Furthermore, these integrated platforms have sizes and weights that are not significantly larger than those of previous, passive systems. Our results qualitatively expand options in output stabilization, intensity control and multimodal operation, with broad potential applications in neuroscience research and, in particular, the precise dissection of neural circuit function during unconstrained behavioural studies.

Original language	English (US)
Pages (from-to)	652-660
Number of pages	9
Journal	Nature Electronics
Volume	1
Issue number	12
DOIs	https://doi.org/10.1038/s41928-018-0175-0
State	Published - Dec 1 2018

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Instrumentation
Electrical and Electronic Engineering

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Gutruf, P., Krishnamurthi, V., Vázquez-Guardado, A., Xie, Z., Banks, A., Su, C. J., Xu, Y., Haney, C. R., Waters, E. A., Kandela, I., Krishnan, S. R., Ray, T., Leshock, J. P., Huang, Y., Chanda, D., & Rogers, J. A. (2018). Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research. Nature Electronics, 1(12), 652-660. https://doi.org/10.1038/s41928-018-0175-0

Gutruf, P, Krishnamurthi, V, Vázquez-Guardado, A, Xie, Z, Banks, A, Su, CJ, Xu, Y, Haney, CR, Waters, EA, Kandela, I, Krishnan, SR, Ray, T, Leshock, JP, Huang, Y, Chanda, D & Rogers, JA 2018, 'Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research', Nature Electronics, vol. 1, no. 12, pp. 652-660. https://doi.org/10.1038/s41928-018-0175-0

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title = "Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research",

abstract = "Recently developed ultrasmall, fully implantable devices for optogenetic neuromodulation eliminate the physical tethers associated with conventional set-ups and avoid the bulky head-stages and batteries found in alternative wireless technologies. The resulting systems allow behavioural studies without motion constraints and enable experiments in a range of environments and contexts, such as social interactions. However, these devices are purely passive in their electronic design, thereby precluding any form of active control or programmability; independent operation of multiple devices, or of multiple active components in a single device, is, in particular, impossible. Here we report optoelectronic systems that, through developments in integrated circuit and antenna design, provide low-power operation, and position- and angle-independent wireless power harvesting, with full user-programmability over individual devices and collections of them. Furthermore, these integrated platforms have sizes and weights that are not significantly larger than those of previous, passive systems. Our results qualitatively expand options in output stabilization, intensity control and multimodal operation, with broad potential applications in neuroscience research and, in particular, the precise dissection of neural circuit function during unconstrained behavioural studies.",

author = "Philipp Gutruf and Vaishnavi Krishnamurthi and Abraham V{\'a}zquez-Guardado and Zhaoqian Xie and Anthony Banks and Su, {Chun Ju} and Yeshou Xu and Haney, {Chad R.} and Waters, {Emily A.} and Irawati Kandela and Krishnan, {Siddharth R.} and Tyler Ray and Leshock, {John P.} and Yonggang Huang and Debashis Chanda and Rogers, {John A.}",

note = "Funding Information: We acknowledge support from the Center for Bio-Integrated Electronics at Northwestern University. C.R.H. is supported by Cancer Center Support Grant P30 CA060553 from the National Cancer Institute awarded to the Robert H. Lurie Comprehensive Cancer Center. Z.X. acknowledges support from the National Natural Science Foundation of China (grant number 11402134). Y.H. acknowledges support from the National Science Foundation (grant numbers 1400169, 1534120 and 1635443). Publisher Copyright: {\textcopyright} 2018, The Author(s), under exclusive licence to Springer Nature Limited.",

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AU - Krishnamurthi, Vaishnavi

AU - Vázquez-Guardado, Abraham

AU - Xie, Zhaoqian

AU - Banks, Anthony

AU - Su, Chun Ju

AU - Xu, Yeshou

AU - Haney, Chad R.

AU - Waters, Emily A.

AU - Kandela, Irawati

AU - Krishnan, Siddharth R.

AU - Ray, Tyler

AU - Leshock, John P.

AU - Huang, Yonggang

AU - Chanda, Debashis

AU - Rogers, John A.

N1 - Funding Information: We acknowledge support from the Center for Bio-Integrated Electronics at Northwestern University. C.R.H. is supported by Cancer Center Support Grant P30 CA060553 from the National Cancer Institute awarded to the Robert H. Lurie Comprehensive Cancer Center. Z.X. acknowledges support from the National Natural Science Foundation of China (grant number 11402134). Y.H. acknowledges support from the National Science Foundation (grant numbers 1400169, 1534120 and 1635443). Publisher Copyright: © 2018, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2018/12/1

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N2 - Recently developed ultrasmall, fully implantable devices for optogenetic neuromodulation eliminate the physical tethers associated with conventional set-ups and avoid the bulky head-stages and batteries found in alternative wireless technologies. The resulting systems allow behavioural studies without motion constraints and enable experiments in a range of environments and contexts, such as social interactions. However, these devices are purely passive in their electronic design, thereby precluding any form of active control or programmability; independent operation of multiple devices, or of multiple active components in a single device, is, in particular, impossible. Here we report optoelectronic systems that, through developments in integrated circuit and antenna design, provide low-power operation, and position- and angle-independent wireless power harvesting, with full user-programmability over individual devices and collections of them. Furthermore, these integrated platforms have sizes and weights that are not significantly larger than those of previous, passive systems. Our results qualitatively expand options in output stabilization, intensity control and multimodal operation, with broad potential applications in neuroscience research and, in particular, the precise dissection of neural circuit function during unconstrained behavioural studies.

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Fully implantable optoelectronic systems for battery-free, multimodal operation in neuroscience research

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