A versatile and modular tetrode-based device for single-unit recordings in rodent ex vivo and in vivo acute preparations

Machado, Francisca; Sousa, Nuno; Monteiro, Patrícia; Jacinto, Luis

doi:10.1016/j.jneumeth.2020.108755

Cited by 2 publications

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Wireless Devices for Optical Brain Stimulation: A Review of Current Developments for Optogenetic Applications in Freely Moving Mice

Silva,

Jacinto

2024

Cel. Mol. Bioeng.

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Purpose Optogenetics is an invaluable tool to study brain circuits, but typical systems rely on tethered approaches to deliver light to the brain that hinder natural behavior. With the increasing prevalence of complex behavioral phenotyping in neuroscience experiments, wireless devices for optical stimulation offer great promise to overcome these limitations. Methods In this work we critically review recent systems engineering and device design approaches to deliver light to the brain with wireless operation for optogenetic experiments. Results We describe strategies used for wireless control and communication, wireless power transfer, and light delivery to the brain with a focus on device integration for in vivo operation in freely behaving mice. Conclusion Recent advances in optoelectronic systems, material science, and microtechnology have enabled the design and realization of miniaturized wirelessly-controlled optical stimulators for true untethered experiments in rodent models.

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Wireless Devices for Optical Brain Stimulation: A Review of Current Developments for Optogenetic Applications in Freely Moving Mice

Silva,

Jacinto

2024

Cel. Mol. Bioeng.

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Small form factor implantable neural probe with efficient flip chip μLED for in vivo optogenetics

Abrantes,

Pereira,

Silva

et al. 2024

Preprint

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Optogenetics is a widely used tool to dissect neural circuits with optical stimulation, but it requires that light is delivered to photosensitive neurons inside the brain. Implantable neural probes with microscale LEDs (μLEDs) are an emerging approach to delivering light to the brain with superior light output control. However, approaches to integrate μLEDs in neural probes depend on complex fabrication processes. Here, we developed an implantable small form factor neural probe that integrates highly efficient commercial flip chip μLEDs using only standard lithography processes in silicon and a custom automated LED mounting approach with custom 3D-printed tools on a pick-and-place machine. The probe has a cross-sectional area under 0.013 mm2but can output up to 2.3 mW of optical power with an irradiance of 175 mW/mm2. Due to the high plug efficiency of the LED and wide large interconnect lines, the neural probe has improved heat dissipation properties and can perform stimulation protocols up to 50 Hz and 90% duty cycles without surpassing hotspot temperature elevations above 1 ºC. The neural probes were validated in vivo, with brain activity in the motor cortex of transgenic optogenetic mice being reliably modulated by pulsed light emitted from the probe.

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A versatile and modular tetrode-based device for single-unit recordings in rodent ex vivo and in vivo acute preparations

Cited by 2 publications

References 24 publications

Wireless Devices for Optical Brain Stimulation: A Review of Current Developments for Optogenetic Applications in Freely Moving Mice

Wireless Devices for Optical Brain Stimulation: A Review of Current Developments for Optogenetic Applications in Freely Moving Mice

Small form factor implantable neural probe with efficient flip chip μLED for in vivo optogenetics

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