Nature Communications (Jul 2024)

Origami-inspired soft fluidic actuation for minimally invasive large-area electrocorticography

  • Lawrence Coles,
  • Domenico Ventrella,
  • Alejandro Carnicer-Lombarte,
  • Alberto Elmi,
  • Joe G. Troughton,
  • Massimo Mariello,
  • Salim El Hadwe,
  • Ben J. Woodington,
  • Maria L. Bacci,
  • George G. Malliaras,
  • Damiano G. Barone,
  • Christopher M. Proctor

DOI
https://doi.org/10.1038/s41467-024-50597-2
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Electrocorticography is an established neural interfacing technique wherein an array of electrodes enables large-area recording from the cortical surface. Electrocorticography is commonly used for seizure mapping however the implantation of large-area electrocorticography arrays is a highly invasive procedure, requiring a craniotomy larger than the implant area to place the device. In this work, flexible thin-film electrode arrays are combined with concepts from soft robotics, to realize a large-area electrocorticography device that can change shape via integrated fluidic actuators. We show that the 32-electrode device can be packaged using origami-inspired folding into a compressed state and implanted through a small burr-hole craniotomy, then expanded on the surface of the brain for large-area cortical coverage. The implantation, expansion, and recording functionality of the device is confirmed in-vitro and in porcine in-vivo models. The integration of shape actuation into neural implants provides a clinically viable pathway to realize large-area neural interfaces via minimally invasive surgical techniques.