Gabapentin's Effect on Human Dorsal Root Ganglia: Donor-Specific Electrophysiological and Transcriptomic Profiles

Neuropathic pain affects approximately 10% of the adult population and is commonly treated with gabapentin (GBP), a repurposed anticonvulsant drug. Despite its widespread clinical use, GBPs efficacy varies significantly among patients, highlighting the need to better understand its functional and molecular impacts on human pain-sensing neurons. In this study, we characterized the electrophysiological and transcriptomic effects of GBP on primary sensory neurons derived from the dorsal root ganglia (DRG) of ethically consented human donors. Using patch-clamp electrophysiology, we demonstrated that GBP treatment reduced neuronal excitability, with more pronounced effects in multi-firing vs. single-firing neuronal subtypes. Notably, significant donor-specific variability was observed in electrophysiological responsiveness to GBP treatment in vitro. RNA sequencing of DRG tissue from the GBP-responsive donor revealed differences in the transcriptome-wide expression of genes associated with ion transport, synaptic transmission, inflammation, and immune response relative to non-responsive donors. Cross-transcriptomic analyses further showed that GBP treatment counteracted these altered processes, rescuing aberrant gene expression at the pathway level and for several key genes. This study provides a comprehensive electrophysiological and transcriptomic profile of the effects of GBP on human DRG neurons. These findings enhance our understanding of GBPs mechanistic actions on peripheral sensory neurons and could help optimize its clinical use for neuropathic pain management.