Ege Iseri scite author profile

Electrophysiology is a decades-old technique widely used for monitoring activity of individual neurons and local field potentials. Optogenetics has revolutionized neuroscience studies by offering selective and fast control of targeted neurons and neuron populations. The combination of these two techniques is crucial for causal investigation of neural circuits and understanding their functional connectivity. However, electrical artifacts generated by light stimulation interfere with neural recordings and hinder the development of compact closed-loop systems for precise control of neural activity. Here, we demonstrate that transparent graphene micro-electrodes fabricated on a clear polyethylene terephthalate film eliminate the light-induced artifact problem and allow development of a compact battery-powered closed-loop optogenetics system. We extensively investigate light-induced artifacts for graphene electrodes in comparison to metal control electrodes. We then design optical stimulation module using micro-LED chips coupled to optical fibers to deliver light to intended depth for optogenetic stimulation. For artifact-free integration of graphene micro-electrode recordings with optogenetic stimulation, we design and develop a compact closed-loop system and validate it for different frequencies of interest for neural recordings. This compact closed-loop optogenetics system can be used for various applications involving optogenetic stimulation and electrophysiological recordings.

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Implantable optoelectronic probes forin vivooptogenetics

Iseri

Kuzum

2017

J. Neural Eng.

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More than a decade has passed since optics and genetics came together and lead to the emerging technologies of optogenetics. The advent of light-sensitive opsins made it possible to optically trigger the neurons into activation or inhibition by using visible light. The importance of spatiotemporally isolating a segment of a neural network and controlling nervous signaling in a precise manner has driven neuroscience researchers and engineers to invest great efforts in designing high precision in vivo implantable devices. These efforts have focused on delivery of sufficient power to deep brain regions, while monitoring neural activity with high resolution and fidelity. In this review, we report the progress made in the field of hybrid optoelectronic neural interfaces that combine optical stimulation with electrophysiological recordings. Different approaches that incorporate optical or electrical components on implantable devices are discussed in detail. Advantages of various different designs as well as practical and fundamental limitations are summarized to illuminate the future of neurotechnology development.

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Model-based comparison of current flow in rod bipolar cells of healthy and early-stage degenerated retina

Kosta

Iseri

Loizos

et al. 2021

Experimental Eye Research

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Recent Advances in Computational and Experimental Bioelectromagnetics for Neuroprosthetics

Stang

Chen

Kosta

et al. 2019

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Transparent artifact-free graphene electrodes for compact closed-loop optogenetics systems

Liu

Iseri

et al. 2017

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Ege Iseri

A Compact Closed-Loop Optogenetics System Based on Artifact-Free Transparent Graphene Electrodes

Implantable optoelectronic probes forin vivooptogenetics

Model-based comparison of current flow in rod bipolar cells of healthy and early-stage degenerated retina

Recent Advances in Computational and Experimental Bioelectromagnetics for Neuroprosthetics

Transparent artifact-free graphene electrodes for compact closed-loop optogenetics systems

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