Literature DB >> 28132830

Flexible Near-Field Wireless Optoelectronics as Subdermal Implants for Broad Applications in Optogenetics.

Gunchul Shin1, Adrian M Gomez2, Ream Al-Hasani2, Yu Ra Jeong3, Jeonghyun Kim1, Zhaoqian Xie4, Anthony Banks1, Seung Min Lee1, Sang Youn Han5, Chul Jong Yoo6, Jong-Lam Lee6, Seung Hee Lee6, Jonas Kurniawan1, Jacob Tureb1, Zhongzhu Guo1, Jangyeol Yoon1, Sung-Il Park7, Sang Yun Bang8, Yoonho Nam1, Marie C Walicki2, Vijay K Samineni9, Aaron D Mickle9, Kunhyuk Lee1, Seung Yun Heo1, Jordan G McCall9, Taisong Pan10, Liang Wang11, Xue Feng12, Tae-Il Kim13, Jong Kyu Kim6, Yuhang Li14, Yonggang Huang15, Robert W Gereau16, Jeong Sook Ha17, Michael R Bruchas18, John A Rogers19.   

Abstract

In vivo optogenetics provides unique, powerful capabilities in the dissection of neural circuits implicated in neuropsychiatric disorders. Conventional hardware for such studies, however, physically tethers the experimental animal to an external light source, limiting the range of possible experiments. Emerging wireless options offer important capabilities that avoid some of these limitations, but the current size, bulk, weight, and wireless area of coverage is often disadvantageous. Here, we present a simple but powerful setup based on wireless, near-field power transfer and miniaturized, thin, flexible optoelectronic implants, for complete optical control in a variety of behavioral paradigms. The devices combine subdermal magnetic coil antennas connected to microscale, injectable light-emitting diodes (LEDs), with the ability to operate at wavelengths ranging from UV to blue, green-yellow, and red. An external loop antenna allows robust, straightforward application in a multitude of behavioral apparatuses. The result is a readily mass-producible, user-friendly technology with broad potential for optogenetics applications.
Copyright © 2017 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  ChR2; Chrimson; LED; NAc; VTA; dopamine; near-field communication; optogenetics; reward; wireless

Mesh:

Substances:

Year:  2017        PMID: 28132830      PMCID: PMC5377903          DOI: 10.1016/j.neuron.2016.12.031

Source DB:  PubMed          Journal:  Neuron        ISSN: 0896-6273            Impact factor:   17.173


  35 in total

1.  Millisecond-timescale, genetically targeted optical control of neural activity.

Authors:  Edward S Boyden; Feng Zhang; Ernst Bamberg; Georg Nagel; Karl Deisseroth
Journal:  Nat Neurosci       Date:  2005-08-14       Impact factor: 24.884

2.  Retinal receptors in rodents maximally sensitive to ultraviolet light.

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Review 3.  Neural stimulation and recording electrodes.

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Journal:  Annu Rev Biomed Eng       Date:  2008       Impact factor: 9.590

4.  A Miniature, Fiber-Coupled, Wireless, Deep-Brain Optogenetic Stimulator.

Authors:  Steven T Lee; Pete A Williams; Catherine E Braine; Da-Ting Lin; Simon W M John; Pedro P Irazoqui
Journal:  IEEE Trans Neural Syst Rehabil Eng       Date:  2015-01-15       Impact factor: 3.802

Review 5.  The development and application of optogenetics.

Authors:  Lief Fenno; Ofer Yizhar; Karl Deisseroth
Journal:  Annu Rev Neurosci       Date:  2011       Impact factor: 12.449

6.  A silicon-based, three-dimensional neural interface: manufacturing processes for an intracortical electrode array.

Authors:  P K Campbell; K E Jones; R J Huber; K W Horch; R A Normann
Journal:  IEEE Trans Biomed Eng       Date:  1991-08       Impact factor: 4.538

7.  Optogenetics.

Authors:  Karl Deisseroth
Journal:  Nat Methods       Date:  2010-12-20       Impact factor: 28.547

Review 8.  Targeting neurons and photons for optogenetics.

Authors:  Adam M Packer; Botond Roska; Michael Häusser
Journal:  Nat Neurosci       Date:  2013-06-25       Impact factor: 24.884

9.  Optogenetic control of targeted peripheral axons in freely moving animals.

Authors:  Chris Towne; Kate L Montgomery; Shrivats M Iyer; Karl Deisseroth; Scott L Delp
Journal:  PLoS One       Date:  2013-08-21       Impact factor: 3.240

10.  Virally mediated optogenetic excitation and inhibition of pain in freely moving nontransgenic mice.

Authors:  Shrivats Mohan Iyer; Kate L Montgomery; Chris Towne; Soo Yeun Lee; Charu Ramakrishnan; Karl Deisseroth; Scott L Delp
Journal:  Nat Biotechnol       Date:  2014-02-16       Impact factor: 54.908
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  80 in total

1.  Wireless, battery-free, flexible, miniaturized dosimeters monitor exposure to solar radiation and to light for phototherapy.

Authors:  Seung Yun Heo; Jeonghyun Kim; Philipp Gutruf; Anthony Banks; Pinghung Wei; Rafal Pielak; Guive Balooch; Yunzhou Shi; Hitoshi Araki; Derrick Rollo; Carey Gaede; Manish Patel; Jean Won Kwak; Amnahir E Peña-Alcántara; Kyu-Tae Lee; Yeojeong Yun; June K Robinson; Shuai Xu; John A Rogers
Journal:  Sci Transl Med       Date:  2018-12-05       Impact factor: 17.956

2.  Remote control of movement disorders using a photoactive adenosine A2A receptor antagonist.

Authors:  Jaume Taura; Ernest G Nolen; Gisela Cabré; Jordi Hernando; Lucia Squarcialupi; Marc López-Cano; Kenneth A Jacobson; Víctor Fernández-Dueñas; Francisco Ciruela
Journal:  J Control Release       Date:  2018-05-31       Impact factor: 9.776

3.  Multifunctional materials for implantable and wearable photonic healthcare devices.

Authors:  Geon-Hui Lee; Hanul Moon; Hyemin Kim; Gae Hwang Lee; Woosung Kwon; Seunghyup Yoo; David Myung; Seok Hyun Yun; Zhenan Bao; Sei Kwang Hahn
Journal:  Nat Rev Mater       Date:  2020-01-07       Impact factor: 66.308

4.  Cellular, circuit and transcriptional framework for modulation of itch in the central amygdala.

Authors:  Vijay K Samineni; Jose G Grajales-Reyes; Gary E Grajales-Reyes; Eric Tycksen; Bryan A Copits; Christian Pedersen; Edem S Ankudey; Julian N Sackey; Sienna B Sewell; Michael R Bruchas; Robert W Gereau
Journal:  Elife       Date:  2021-05-25       Impact factor: 8.140

5.  Rapidly-customizable, scalable 3D-printed wireless optogenetic probes for versatile applications in neuroscience.

Authors:  Juhyun Lee; Kyle E Parker; Chinatsu Kawakami; Jenny R Kim; Raza Qazi; Junwoo Yea; Shun Zhang; Choong Yeon Kim; John Bilbily; Jianliang Xiao; Kyung-In Jang; Jordan G McCall; Jae-Woong Jeong
Journal:  Adv Funct Mater       Date:  2020-09-18       Impact factor: 18.808

Review 6.  A bright future? Optogenetics in the periphery for pain research and therapy.

Authors:  Aaron D Mickle; Robert W Gereau
Journal:  Pain       Date:  2018-09       Impact factor: 6.961

7.  Soft-Hard Composites for Bioelectric Interfaces.

Authors:  Yiliang Lin; Yin Fang; Jiping Yue; Bozhi Tian
Journal:  Trends Chem       Date:  2020-04-23

Review 8.  The Opioid Crisis and the Future of Addiction and Pain Therapeutics.

Authors:  Nathan P Coussens; G Sitta Sittampalam; Samantha G Jonson; Matthew D Hall; Heather E Gorby; Amir P Tamiz; Owen B McManus; Christian C Felder; Kurt Rasmussen
Journal:  J Pharmacol Exp Ther       Date:  2019-09-03       Impact factor: 4.030

9.  Miniaturized, Battery-Free Optofluidic Systems with Potential for Wireless Pharmacology and Optogenetics.

Authors:  Kyung Nim Noh; Sung Il Park; Raza Qazi; Zhanan Zou; Aaron D Mickle; Jose G Grajales-Reyes; Kyung-In Jang; Robert W Gereau; Jianliang Xiao; John A Rogers; Jae-Woong Jeong
Journal:  Small       Date:  2017-12-07       Impact factor: 13.281

10.  Contemporary strategies for dissecting the neuronal basis of neurodevelopmental disorders.

Authors:  Dong-Oh Seo; Laura E Motard; Michael R Bruchas
Journal:  Neurobiol Learn Mem       Date:  2018-03-14       Impact factor: 2.877
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