| Literature DB >> 34824397 |
Raza Qazi1,2, Kyle E Parker3,4,5,6, Choong Yeon Kim1, Ruediger Rill7, Makenzie R Norris3,4,5,6,8, Jaeyoon Chung7, John Bilbily3,4,5,6,9, Jenny R Kim3,4,5,6, Marie C Walicki3,4,5,6, Graydon B Gereau3,4,5,6, Hyoyoung Lim7, Yanyu Xiong10, Jenna R Lee11, Melissa A Tapia12, Alexxai V Kravitz9, Matthew J Will12, Sangtae Ha13, Jordan G McCall14,15,16,17,18, Jae-Woong Jeong19.
Abstract
The use of rodents to acquire understanding of the function of neural circuits and of the physiological, genetic and developmental underpinnings of behaviour has been constrained by limitations in the scalability, automation and high-throughput operation of implanted wireless neural devices. Here we report scalable and modular hardware and software infrastructure for setting up and operating remotely programmable miniaturized wireless networks leveraging Bluetooth Low Energy for the study of the long-term behaviour of large groups of rodents. The integrated system allows for automated, scheduled and real-time experimentation via the simultaneous and independent use of multiple neural devices and equipment within and across laboratories. By measuring the locomotion, feeding, arousal and social behaviours of groups of mice or rats, we show that the system allows for bidirectional data transfer from readily available hardware, and that it can be used with programmable pharmacological or optogenetic stimulation. Scalable and modular wireless-network infrastructure should facilitate the remote operation of fully automated large-scale and long-term closed-loop experiments for the study of neural circuits and animal behaviour.Entities:
Mesh:
Year: 2021 PMID: 34824397 DOI: 10.1038/s41551-021-00814-w
Source DB: PubMed Journal: Nat Biomed Eng ISSN: 2157-846X Impact factor: 29.234