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- Title
T-DOpE probes reveal sensitivity of hippocampal oscillations to cannabinoids in behaving mice.
- Authors
Kim, Jongwoon; Huang, Hengji; Gilbert, Earl T.; Arndt, Kaiser C.; English, Daniel Fine; Jia, Xiaoting
- Abstract
Understanding the neural basis of behavior requires monitoring and manipulating combinations of physiological elements and their interactions in behaving animals. We developed a thermal tapering process enabling fabrication of low-cost, flexible probes combining ultrafine features: dense electrodes, optical waveguides, and microfluidic channels. Furthermore, we developed a semi-automated backend connection allowing scalable assembly. We demonstrate T-DOpE (Tapered Drug delivery, Optical stimulation, and Electrophysiology) probes achieve in single neuron-scale devices (1) high-fidelity electrophysiological recording (2) focal drug delivery and (3) optical stimulation. The device tip can be miniaturized (as small as 50 µm) to minimize tissue damage while the ~20 times larger backend allows for industrial-scale connectorization. T-DOpE probes implanted in mouse hippocampus revealed canonical neuronal activity at the level of local field potentials (LFP) and neural spiking. Taking advantage of the triple-functionality of these probes, we monitored LFP while manipulating cannabinoid receptors (CB1R; microfluidic agonist delivery) and CA1 neuronal activity (optogenetics). Focal infusion of CB1R agonist downregulated theta and sharp wave-ripple oscillations (SPW-Rs). Furthermore, we found that CB1R activation reduces sharp wave-ripples by impairing the innate SPW-R-generating ability of the CA1 circuit. Neural activity is regulated by synapse-neuromodulator interactions, necessitating optoelectro-pharmacological investigations. Here, authors implement their multi-modal probe to show focal infusion of synthetic cannabinoid disrupts CA1 oscillations.
- Subjects
OSCILLATIONS; CANNABINOIDS; OPTICAL waveguides; CANNABINOID receptors; HIPPOCAMPUS (Brain)
- Publication
Nature Communications, 2024, Vol 15, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-024-46021-4