Publication detail

Laser-Driven Wireless Deep Brain Stimulation using Temporal Interference and Organic Electrolytic Photocapacitors

MISSEY, F. DONAHUE, M. WEBER, P. NGOM, I. ACERBO, E. BOTZANOWSKI, B. MIGLIACCIO, L. JIRSA, V. GLOWACKI, E. WILLIAMSON, A.

Original Title

Laser-Driven Wireless Deep Brain Stimulation using Temporal Interference and Organic Electrolytic Photocapacitors

Type

journal article in Web of Science

Language

English

Original Abstract

Deep brain stimulation (DBS) is a technique commonly used both in clinical and fundamental neurosciences. Classically, brain stimulation requires an implanted and wired electrode system to deliver stimulation directly to the target area. Although techniques such as temporal interference (TI) can provide stimulation at depth without involving any implanted electrodes, these methods still rely on a wired apparatus which limits free movement. Herein organic photocapacitors as untethered light-driven electrodes which convert deep-red light into electric current are reported. Pairs of these ultrathin devices can be driven using lasers at two different frequencies to deliver stimulation at depth via temporally interfering fields. This concept of laser TI stimulation using numerical modeling, tests with phantom brain samples, and finally in vivo tests is validated. Wireless organic photocapacitors are placed on the cortex and elicit stimulation in the hippocampus, while not delivering off-target stimulation in the cortex. This laser-driven wireless TI evokes a neuronal response at depth that is comparable to control experiments induced with deep brain stimulation protocols using implanted electrodes. This work shows that a combination of these two techniques-temporal interference and organic electrolytic photocapacitors-provides a reliable way to target brain structures requiring neither deeply implanted electrodes nor tethered stimulator devices. The laser TI protocol demonstrated here addresses two of the most important drawbacks in the field of DBS and thus holds potential to solve many issues in freely moving animal experiments or for clinical chronic therapy application.

Keywords

deep brain stimulation; optoelectronics; organic bioelectronics; organic electrolytic photocapacitors; temporal interference

Authors

MISSEY, F.; DONAHUE, M.; WEBER, P.; NGOM, I.; ACERBO, E.; BOTZANOWSKI, B.; MIGLIACCIO, L.; JIRSA, V.; GLOWACKI, E.; WILLIAMSON, A.

Released

1. 6. 2022

Publisher

WILEY-V C H VERLAG GMBH

Location

WEINHEIM

ISBN

1616-301X

Periodical

ADVANCED FUNCTIONAL MATERIALS

Year of study

32

Number

33

State

Federal Republic of Germany

Pages from

2200691-1

Pages to

2200691-8

Pages count

8

URL

https://onlinelibrary.wiley.com/doi/10.1002/adfm.202200691