Recording the exercise of huge populations of single neurons within the mind over lengthy durations of time is essential to additional our understanding of neural circuits, to allow novel medical device-based therapies and, sooner or later, for mind–pc interfaces requiring high-resolution electrophysiological data.
However right this moment there’s a tradeoff between how a lot high-resolution data an implanted system can measure and the way lengthy it could preserve recording or stimulation performances. Inflexible, silicon implants with many sensors, can gather a number of data however cannot keep within the physique for very lengthy. Versatile, smaller gadgets are much less intrusive and may last more within the mind however solely present a fraction of the accessible neural data.
Not too long ago, an interdisciplinary group of researchers from the Harvard John A. Paulson College of Engineering and Utilized Sciences (SEAS), in collaboration with The College of Texas at Austin, MIT and Axoft, Inc., developed a gentle implantable system with dozens of sensors that may report single-neuron exercise within the mind stably for months.
The analysis was revealed in Nature Nanotechnology.
We have now developed mind–electronics interfaces with single-cell decision which might be extra biologically compliant than conventional supplies. This work has the potential to revolutionize the design of bioelectronics for neural recording and stimulation, and for mind–pc interfaces.”
Paul Le Floch, first writer of the paper and former graduate pupil within the lab of Jia Liu, Assistant Professor of Bioengineering at SEAS
Le Floch is at present the CEO of Axoft, Inc, an organization based in 2021 by Le Floch, Liu and Tianyang Ye, a former graduate pupil and postdoctoral fellow within the Park Group at Harvard. Harvard’s Workplace of Know-how Growth has protected the mental property related to this analysis and licensed the expertise to Axoft for additional improvement.
To beat the tradeoff between high-resolution knowledge price and longevity, the researchers turned to a bunch of supplies often called fluorinated elastomers. Fluorinated supplies, like Teflon, are resilient, secure in biofluids, have glorious long-term dielectic efficiency, and are suitable with normal microfabrication methods.
The researchers built-in these fluorinated dielectric elastomers with stacks of soppy microelectrodes -; 64 sensors in complete -; to develop a long-lasting probe that’s 10,000 instances softer than typical versatile probes fabricated from supplies engineering plastics, reminiscent of polyimide or parylene C.
The group demonstrated the system in vivo, recording neural data from the mind and spinal cords of mice over the course of a number of months.
“Our analysis highlights that, by fastidiously engineering varied elements, it’s possible to design novel elastomers for long-term-stable neural interfaces,” mentioned Liu, who’s the corresponding writer of the paper. “This examine might increase the vary of design potentialities for neural interfaces.”
The interdisciplinary analysis group additionally included SEAS Professors Katia Bertoldi, Boris Kozinsky and Zhigang Suo.
“Designing new neural probes and interfaces is a really interdisciplinary downside that requires experience in biology, electrical engineering, supplies science, mechanical and chemical engineering,” mentioned Le Floch.
The analysis was co-authored by Siyuan Zhao, Ren Liu, Nicola Molinari, Eder Medina, Hao Shen, Zheliang Wang, Junsoo Kim, Hao Sheng, Sebastian Partarrieu, Wenbo Wang, Chanan Sessler, Guogao Zhang, Hyunsu Park, Xian Gong, Andrew Spencer, Jongha Lee, Tianyang Ye, Xin Tang, Xiao Wang and Nanshu Lu.
The work was supported by the Nationwide Science Basis by way of the Harvard College Supplies Analysis Science and Engineering Middle Grant No. DMR-2011754.
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Journal reference:
Le Floch, P., et al. (2023). 3D spatiotemporally scalable in vivo neural probes primarily based on fluorinated elastomers. Nature Nanotechnology. doi.org/10.1038/s41565-023-01545-6.