Flexible Polymer Electrodes for Stable Prosthetic Visual Perception in Mice

Orlemann, Corinne; Boehler, Christian; Kooijmans, Roxana N.; Li, Bingshuo; Asplund, Maria; Roelfsema, Pieter R.

doi:10.1002/adhm.202304169

Adv Healthcare Materials

2024

DOI: 10.1002/adhm.202304169

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Flexible Polymer Electrodes for Stable Prosthetic Visual Perception in Mice

Corinne Orlemann,

Christian Boehler,

Roxana N. Kooijmans

et al.

Abstract: Brain interfaces that can stimulate neurons, cause minimal damage and work for a long time will be central for future neuroprosthetics. Here we report on the long‐term performance of highly flexible, thin polyimide shanks with several small (< 15 μm) electrodes during electrical microstimulation of the visual cortex. The electrodes exhibited a remarkable stability when we applied several billions of electrical pulses in vitro. When we implanted the devices in the primary visual cortex of mice and trained th… Show more

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Inkjet-printed transparent electrodes for electrical brain stimulation

Matta,

Reato,

Lombardini

et al. 2024

Preprint

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Electrical stimulation is a powerful tool for investigating and modulating brain activity, as well as for treating neurological disorders. However, understanding the precise effects of electrical stimulation on neural activity has been hindered by limitations in recording neuronal responses near the stimulating electrode, such as stimulation artifacts in electrophysiology or obstruction of the field of view in imaging. In this study, we introduce a novel stimulation device fabricated from conductive polymers that is transparent and therefore compatible with optical imaging techniques. The device is manufactured using a combination of microfabrication and inkjet printing techniques and is flexible, allowing better adherence to the brain’s natural curvature. We characterized the electrical and optical properties of the electrode and evaluated its performance in the brain of an anesthetized mouse. Furthermore, we combined experimental data with a finite-element model of the in-vivo experimental setup to estimate the maximum electric field that the highly transparent device can generate in the mouse brain. Our findings indicate that the device can generate an electric field as high as 300 V/m, demonstrating its potential for studying and manipulating neural activity using a range of electrical stimulation techniques relevant to human applications. Overall, this work presents a promising approach for developing versatile new tools to apply and study electrical brain stimulation.

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Inkjet-printed transparent electrodes for electrical brain stimulation

Matta,

Reato,

Lombardini

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

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Flexible Polymer Electrodes for Stable Prosthetic Visual Perception in Mice

Cited by 1 publication

References 59 publications

Inkjet-printed transparent electrodes for electrical brain stimulation

Inkjet-printed transparent electrodes for electrical brain stimulation

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