TY - JOUR
T1 - Adaptive conductive electrotherapeutic scaffolds for enhanced peripheral nerve regeneration and stimulation
AU - Srinivasan, Shriya S.
AU - Gfrerer, Lisa
AU - Karandikar, Paramesh
AU - Som, Avik
AU - Alshareef, Amro
AU - Liu, Sabrina
AU - Higginbotham, Haley
AU - Ishida, Keiko
AU - Hayward, Alison
AU - Kalva, Sanjeeva P.
AU - Langer, Robert
AU - Traverso, Giovanni
N1 - Publisher Copyright:
© 2023 Elsevier Inc.
PY - 2023/8/11
Y1 - 2023/8/11
N2 - Background: While peripheral nerve stimulation (PNS) has shown promise in applications ranging from peripheral nerve regeneration to therapeutic organ stimulation, clinical implementation has been impeded by various technological limitations, including surgical placement, lead migration, and atraumatic removal. Methods: We describe the design and validation of a platform technology for nerve regeneration and interfacing: adaptive, conductive, and electrotherapeutic scaffolds (ACESs). ACESs are comprised of an alginate/poly-acrylamide interpenetrating network hydrogel optimized for both open surgical and minimally invasive percutaneous approaches. Findings: In a rodent model of sciatic nerve repair, ACESs significantly improved motor and sensory recovery (p < 0.05), increased muscle mass (p < 0.05), and increased axonogenesis (p < 0.05). Triggered dissolution of ACESs enabled atraumatic, percutaneous removal of leads at forces significantly lower than controls (p < 0.05). In a porcine model, ultrasound-guided percutaneous placement of leads with an injectable ACES near the femoral and cervical vagus nerves facilitated stimulus conduction at significantly greater lengths than saline controls (p < 0.05). Conclusion: Overall, ACESs facilitated lead placement, stabilization, stimulation, and atraumatic removal, enabling therapeutic PNS as demonstrated in small- and large-animal models. Funding: This work was supported by K. Lisa Yang Center for Bionics at MIT.
AB - Background: While peripheral nerve stimulation (PNS) has shown promise in applications ranging from peripheral nerve regeneration to therapeutic organ stimulation, clinical implementation has been impeded by various technological limitations, including surgical placement, lead migration, and atraumatic removal. Methods: We describe the design and validation of a platform technology for nerve regeneration and interfacing: adaptive, conductive, and electrotherapeutic scaffolds (ACESs). ACESs are comprised of an alginate/poly-acrylamide interpenetrating network hydrogel optimized for both open surgical and minimally invasive percutaneous approaches. Findings: In a rodent model of sciatic nerve repair, ACESs significantly improved motor and sensory recovery (p < 0.05), increased muscle mass (p < 0.05), and increased axonogenesis (p < 0.05). Triggered dissolution of ACESs enabled atraumatic, percutaneous removal of leads at forces significantly lower than controls (p < 0.05). In a porcine model, ultrasound-guided percutaneous placement of leads with an injectable ACES near the femoral and cervical vagus nerves facilitated stimulus conduction at significantly greater lengths than saline controls (p < 0.05). Conclusion: Overall, ACESs facilitated lead placement, stabilization, stimulation, and atraumatic removal, enabling therapeutic PNS as demonstrated in small- and large-animal models. Funding: This work was supported by K. Lisa Yang Center for Bionics at MIT.
KW - electrical stimulation
KW - Foundational research
KW - lead migration
KW - muscular atrophy
KW - nerve regeneration
KW - nerve repair
KW - nerve stimulation
KW - peripheral nerve
KW - rehabilitation
KW - removable electrodes
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U2 - 10.1016/j.medj.2023.05.007
DO - 10.1016/j.medj.2023.05.007
M3 - Article
C2 - 37339635
AN - SCOPUS:85166983381
SN - 2666-6359
VL - 4
SP - 541-553.e5
JO - Med
JF - Med
IS - 8
ER -