Multiplexed neural recording along a single optical fiber via optical reflectometry

Rodriques, Samuel G.; Marblestone, Adam; Scholvin, Jörg; Dapello, Joel; Sarkar, Deblina; Mankin, Max; Gao, Ruixuan; Wood, Lowell; Boyden, Edward S.

doi:10.1117/1.jbo.21.5.057003

Cited by 3 publications

(3 citation statements)

References 71 publications

(134 reference statements)

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“…Using optics to observe changes in cell refractive index and birefringence during electrical excitation [34] has failed to materialise as mainstream techniques. Theoretical studies have explored the feasibility of optical fibre refractometry [35] and surface plasmon resonance has been reported for neural recording in chamber [36] and fibre tip [37] configurations, but several issues remain unaddressed, including refractometry sensor characterisation, poor signal resolution, and a means of calibrating the outputted signal to biopotentials. Here, we present a practical implementation and experimental validation of a sensing fluorophore-free optrode with properties suitable for electrophysiology and brain-machine interface applications based on photonic techniques.…”

Section: Discussionmentioning

confidence: 99%

Liquid crystal electro-optical transducers for electrophysiology sensing applications

Abed¹,

Wei²,

Almasri³

et al. 2022

J. Neural Eng.

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Objective. Biomedical instrumentation and clinical systems for electrophysiology rely on electrodes and wires for sensing and transmission of bioelectric signals. However, this electronic approach constrains bandwidth, signal conditioning circuit designs, and the number of channels in invasive or miniature devices. This paper demonstrates an alternative approach using light to sense and transmit the electrophysiological signals. Approach. We develop a sensing, passive, fluorophore-free optrode based on the birefringence property of liquid crystals (LCs) operating at the microscale. Main results. We show that these optrodes can have the appropriate linearity (µ ± s.d.: 99.4 ± 0.5%, n = 11 devices), relative responsivity (µ ± s.d.: 57 ± 12%V−1, n = 5 devices), and bandwidth (µ ± s.d.: 11.1 ± 0.7 kHz, n = 7 devices) for transducing electrophysiology signals into the optical domain. We report capture of rabbit cardiac sinoatrial electrograms and stimulus-evoked compound action potentials from the rabbit sciatic nerve. We also demonstrate miniaturisation potential by fabricating multi-optrode arrays, by developing a process that automatically matches each transducer element area with that of its corresponding biological interface. Significance. Our method of employing LCs to convert bioelectric signals into the optical domain will pave the way for the deployment of high-bandwidth optical telecommunications techniques in ultra-miniature clinical diagnostic and research laboratory neural and cardiac interfaces.

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Section: Discussionmentioning

confidence: 99%

Liquid crystal electro-optical transducers for electrophysiology sensing applications

Abed¹,

Wei²,

Almasri³

et al. 2022

J. Neural Eng.

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“…Recently, preliminary designs have been proposed to allow fiber-based electro-optic neural activity sensing [115]. The design is similar to that of free carrier effect based electrooptic modulators.…”

Section: Electro-optics For Ultraminiature Brain Sensorsmentioning

confidence: 99%

“…Improved designs using resonant enhancement of the electro-optic effects via optical cavities, or improved capacitor materials, could allow the still-hypothetical system to operate at lower light powers, reducing heat dissipation from the fiber. With such improvements, as well as improvements in the reflectometry or multiplexing scheme, e.g., wavelength multiplexing, it may be possible to engineer ultra-long (e.g., centimeters), ultramultiplexed, low-power neural activity sensors for deployment into the brain tissue or via the cerebral vasculature [115]. Achieving this will require creative designs from nanophotonics experts via a cross-disciplinary collaboration with neurophysiologists, materials scientists and experts on optical detection methods.…”

Section: Electro-optics For Ultraminiature Brain Sensorsmentioning

confidence: 99%

Developing Next-Generation Brain Sensing Technologies—A Review

et al. 2019

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Advances in sensing technology raise the possibility of creating neural interfaces that can more effectively restore or repair neural function and reveal fundamental properties of neural information processing. To realize the potential of these bioelectronic devices, it is necessary to understand the capabilities of emerging technologies and identify the best strategies to translate these technologies into products and therapies that will improve the lives of patients with neurological and other disorders. Here, we discuss emerging technologies for sensing brain activity, anticipated challenges for translation, and perspectives for how to best transition these technologies from academic research labs to useful products for neuroscience researchers and human patients.

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From Green Electronics to Gray Matter and Cyborg Cells

Sarkar

2023

IEEE Nanotechnology Mag.

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Multiplexed neural recording along a single optical fiber via optical reflectometry

Cited by 3 publications

References 71 publications

Liquid crystal electro-optical transducers for electrophysiology sensing applications

Liquid crystal electro-optical transducers for electrophysiology sensing applications

Developing Next-Generation Brain Sensing Technologies—A Review

From Green Electronics to Gray Matter and Cyborg Cells

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