Organ-specific, multimodal, wireless optoelectronics for high-throughput phenotyping of peripheral neural pathways

The vagus nerve supports diverse autonomic functions and behaviors important for health and survival. To understand how specific components of the vagus contribute to behaviors and long-term physiological effects, it is critical to modulate their activity with anatomical specificity in awake, freely...

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Bibliographic Details
Published in:Nature communications 2021-01, Vol.12 (1), p.157-157, Article 157
Main Authors: Kim, Woo Seok, Hong, Sungcheol, Gamero, Milenka, Jeevakumar, Vivekanand, Smithhart, Clay M., Price, Theodore J., Palmiter, Richard D., Campos, Carlos, Park, Sung Il
Format: Article
Language:English
Subjects:
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Animals
Appetite
Appetite - physiology
Autonomic nervous system
Behavior Observation Techniques - instrumentation
Calcitonin Gene-Related Peptide - genetics
Chemoreceptor Cells - physiology
Coils
Durability
Equipment Design
Female
Fibers
High-Throughput Screening Assays - instrumentation
Humanities and Social Sciences
Light sources
Male
Mice, Transgenic
Models, Animal
multidisciplinary
Multiplexing
Neural networks
Neural Pathways - physiology
Optoelectronic devices
Optogenetics - instrumentation
Organs
Phenotyping
Physiological effects
Physiology
Remote Sensing Technology - instrumentation
Science
Science (multidisciplinary)
Sensory neurons
Stomach - cytology
Stomach - innervation
Stomach - physiology
Telemetry
Vagus nerve
Vagus Nerve - cytology
Vagus Nerve - physiology
Wireless Technology - instrumentation
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Description
Summary:The vagus nerve supports diverse autonomic functions and behaviors important for health and survival. To understand how specific components of the vagus contribute to behaviors and long-term physiological effects, it is critical to modulate their activity with anatomical specificity in awake, freely behaving conditions using reliable methods. Here, we introduce an organ-specific scalable, multimodal, wireless optoelectronic device for precise and chronic optogenetic manipulations in vivo. When combined with an advanced, coil-antenna system and a multiplexing strategy for powering 8 individual homecages using a single RF transmitter, the proposed wireless telemetry enables low cost, high-throughput, and precise functional mapping of peripheral neural circuits, including long-term behavioral and physiological measurements. Deployment of these technologies reveals an unexpected role for stomach, non-stretch vagal sensory fibers in suppressing appetite and demonstrates the durability of the miniature wireless device inside harsh gastric conditions. Advances in wireless technologies have enabled internalisation of light sources, but organ specific illumination is challenging. Here, the authors present a durable, multimodal, wireless system enabling optogenetic stimulation of peripheral neurons within organs.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-020-20421-8