BACKGROUND: Peripheral axon regeneration is improved when the nerve lesion under consideration has recently been preceded by another nerve injury. This is known as the conditioning lesion effect (CLE). While the CLE is one of the most robust and well characterized means to enhance motor axon regeneration in experimental models, it is not considered a clinically feasible strategy. A pharmacological means to re-produce the CLE is highly desirable. OBJECTIVE: To test whether chemodenervation with a clinical grade formulation of botulinum toxin A (BoTX) would be sufficient to reproduce the CLE. METHODS: We examined the effects of a 1-week preconditioning administration of BoTX on motor axon regrowth in both a mouse tibial nerve injury and human embryonic stem cell (hESC)-based model. We assessed neuronal reinnervation in vivo (mice) with retrograde tracers and histological analysis of peripheral nerve tissue after injections into the triceps surae muscle group. We assessed motor neuron neurite outgrowth in vitro (hESC) after incubation in BoTX by immunohistochemistry and morphometric analysis. RESULTS: We found that BoTX conditioning treatment significantly enhanced outgrowth of both murine motor axons in vivo and human MN neurites in vitro. CONCLUSIONS: BoTX preconditioning represents a pharmacological candidate approach to enhance motor axon regeneration in specific clinical scenarios such as nerve transfer surgery. Further studies are needed to elucidate the molecular mechanism.
BACKGROUND: Peripheral axon regeneration is improved when the nerve lesion under consideration has recently been preceded by another nerve injury. This is known as the conditioning lesion effect (CLE). While the CLE is one of the most robust and well characterized means to enhance motor axon regeneration in experimental models, it is not considered a clinically feasible strategy. A pharmacological means to re-produce the CLE is highly desirable. OBJECTIVE: To test whether chemodenervation with a clinical grade formulation of botulinum toxin A (BoTX) would be sufficient to reproduce the CLE. METHODS: We examined the effects of a 1-week preconditioning administration of BoTX on motor axon regrowth in both a mousetibial nerve injury and human embryonic stem cell (hESC)-based model. We assessed neuronal reinnervation in vivo (mice) with retrograde tracers and histological analysis of peripheral nerve tissue after injections into the triceps surae muscle group. We assessed motor neuron neurite outgrowth in vitro (hESC) after incubation in BoTX by immunohistochemistry and morphometric analysis. RESULTS: We found that BoTX conditioning treatment significantly enhanced outgrowth of both murine motor axons in vivo and humanMN neurites in vitro. CONCLUSIONS: BoTX preconditioning represents a pharmacological candidate approach to enhance motor axon regeneration in specific clinical scenarios such as nerve transfer surgery. Further studies are needed to elucidate the molecular mechanism.
Authors: Hexia Guo; Dom D'Andrea; Jie Zhao; Yue Xu; Zheng Qiao; Lindsay E Janes; Nikhil K Murthy; Rui Li; Zhaoqian Xie; Zhen Song; Rohan Meda; Jahyun Koo; Wubin Bai; Yeon Sik Choi; Sumanas W Jordan; Yonggang Huang; Colin K Franz; John A Rogers Journal: Adv Funct Mater Date: 2021-05-06 Impact factor: 19.924
Authors: Luis Solabre Valois; Vanilla Hua Shi; Paul Bishop; Bangfu Zhu; Yasuko Nakamura; Kevin A Wilkinson; Jeremy M Henley Journal: IBRO Neurosci Rep Date: 2021-05-13