Jung Min Lee scite author profile

The retina, which processes visual information and sends it to the brain, is an excellent model for studying neural circuitry. It has been probed extensively ex vivo, but has been refractory to chronic in vivo electrophysiology. We report a non-surgical method to achieve chronically stable in vivo recordings from single retinal ganglion cells (RGCs) in awake mice. We develop a non-coaxial intravitreal injection scheme in which injected mesh electronics unrolls inside the eye and conformally coats the highly curved retina without compromising normal eye functions. The method allows 16-channel recordings from multiple types of RGCs with stable responses to visual stimuli for at least two weeks, and reveals circadian rhythms in RGC responses over multiple day/night cycles

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Scalable Three-Dimensional Recording Electrodes for Probing Biological Tissues

Lee

Lin

Hong

et al. 2022

Nano Lett.

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Electrophysiological recording technologies can provide critical insight into the function of the nervous system and other biological tissues. Standard silicon-based probes have limitations, including single-sided recording sites and intrinsic instabilities due to the probe stiffness. Here, we demonstrate high-performance neural recording using double-sided threedimensional (3D) electrodes integrated in an ultraflexible bioinspired open mesh structure, allowing electrodes to sample fully the 3D interconnected tissue of the brain. In vivo electrophysiological recording using 3D electrodes shows statistically significant increases in the number of neurons per electrode, average spike amplitudes, and signal to noise ratios in comparison to standard two-dimensional electrodes, while achieving stable detection of single-neuron activity over months. The capability of these 3D electrodes is further shown for chronic recording from retinal ganglion cells in mice. This approach opens new opportunities for a comprehensive 3D interrogation, stimulation, and understanding of the complex circuitry of the brain and other electrogenic tissues in live animals over extended time periods.

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All-Tissue-like Multifunctional Optoelectronic Mesh for Deep-Brain Modulation and Mapping

Lee

Lin²,

Kim

et al. 2021

Nano Lett.

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The development of a multifunctional device that achieves optogenetic neuromodulation and extracellular neural mapping is crucial for understanding neural circuits and treating brain disorders. Although various devices have been explored for this purpose, it is challenging to develop biocompatible optogenetic devices that can seamlessly interface with the brain. Herein, we present a tissue-like optoelectronic mesh with a compact interface that enables not only high spatial and temporal resolutions of optical stimulation but also the sampling of optically evoked neural activities. An in vitro experiment in hydrogel showed efficient light propagation through a freestanding SU-8 waveguide that was integrated with flexible mesh electronics. Additionally, an in vivo implantation of the tissue-like optoelectronic mesh in the brain of a live transgenic mouse enabled the sampling of optically evoked neural signals. Therefore, this multifunctional device can aid the chronic modulation of neural circuits and behavior studies for developing biological and therapeutic applications.

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Jung Min Lee

A method for single-neuron chronic recording from the retina in awake mice

Scalable Three-Dimensional Recording Electrodes for Probing Biological Tissues

All-Tissue-like Multifunctional Optoelectronic Mesh for Deep-Brain Modulation and Mapping

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