Journal article
Artifact-free, colocalized opto-electrophysiology enabled by a flexible, multimodal interface integrating transparent MXene microelectrodes and microLEDs
Biosensors & bioelectronics, v 304, 118620
13 Mar 2026
PMID: 41849889
Featured in Collection : Drexel's Newest Publications
Abstract
Neurotechnologies capable of both modulating and recording neural activity are critical for investigating neural function and disease. Optoelectronic probes incorporating micro-light-emitting diodes (μLEDs) and transparent microelectrodes enable colocalized optogenetic stimulation and electrophysiological recordings with high spatiotemporal resolution but often suffer from stimulation artifacts. In this work, we present a thin, flexible, and conformal neural interface integrating blue μLEDs (460 nm) with transparent Ti3C2Tx MXene micro-electrocorticography (μECoG) electrodes for simultaneous, crosstalk-free optical stimulation and electrical recordings. Transparent Ti3C2Tx μECoG electrodes show an optical transmittance of 54.9 ± 0.9% at 460 nm and an impedance modulus of 291.9 ± 99.9 kΩ at 1 kHz. The μLEDs provide up to 86.1 ± 14.7 mW mm−2 with minimal tissue heating and negligible optical distortion through transparent Ti3C2Tx channels. We systematically investigate the mechanisms of the stimulation artifacts and present a methodological framework that is generalizable across multimodal neural interface materials and geometries. With this framework, we demonstrate that the Ti3C2Tx electrodes are minimally susceptible to photoelectric artifacts and that the remaining electromagnetic interference artifacts are minimized using transient μLED drive pulse shaping, ultimately achieving artifact-free, colocalized functionality. The novel multimodal interface is validated in an acute mouse model, establishing it as a powerful platform that enables bidirectional, crosstalk-free interrogation of neural circuits with high spatiotemporal precision.
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Details
- Title
- Artifact-free, colocalized opto-electrophysiology enabled by a flexible, multimodal interface integrating transparent MXene microelectrodes and microLEDs
- Creators
- Royce Dong - Philadelphia VA Medical CenterYuzhang Chen - Translational Therapeutics (United States)Raghav Garg - University of PennsylvaniaSpencer R. Averbeck - University of PennsylvaniaChris Wun - Philadelphia VA Medical CenterPlacid Unegbu - Philadelphia VA Medical CenterSneha Shankar - University of PennsylvaniaShereen Ahmad - Philadelphia VA Medical CenterJimin Jung - Philadelphia VA Medical CenterMd Abu Zahed - Philadelphia VA Medical CenterDanzhen Zhang - Drexel University, A.J. Drexel Nanomaterials InstituteYury Gogotsi - Drexel University, Materials Science and EngineeringHajime Takano - Children's Hospital of PhiladelphiaBrian Litt - Department of Bioengineering, University of Pennsylvania, Philadelphia, PA, USAFlavia Vitale - University of Pennsylvania
- Publication Details
- Biosensors & bioelectronics, v 304, 118620
- Publisher
- Elsevier B.V
- Number of pages
- 16
- Grant note
- National Science Foundation: NNCI-2025608 National Institutes of Health: 5R01NS123054-03, R01NS121219, 5T32NS091006-10, 1F30EY037143-01 Advanced Research and Invention Agency: SCNI-PR01-P014
The work was supported by the National Science Foundation [CAREER 2339748, F.V.] , National Institutes of Health [5R01NS123054-03, F.V.; R01NS121219, F.V. and Y.G.; 5T32NS091006-10, R.D.; 1F30EY037143-01, R.D.] , and the Advanced Research and Invention Agency (ARIA) [SCNI-PR01-P014, F.V.] . Microfabrication was conducted in the Singh Center for Nanotech-nology, which was supported by the National Science Foundation [NNCI-2025608] .
- Resource Type
- Journal article
- Language
- English
- Academic Unit
- Materials Science and Engineering; A.J. Drexel Nanomaterials Institute
- Web of Science ID
- WOS:001719940800001
- Other Identifier
- 991022170454704721