In vivo calcium imaging shows that dorsal root ganglion stimulation predominantly activates large-sized sensory neurons in mice

Dorsal root ganglion (DRG) stimulation is an effective treatment for patients with refractory neuropathic pain. However, the exact mechanisms through which DRG stimulation exerts its analgesic effects, especially in relation to the recruitment of different fiber types present within the DRG, remains largely unknown. Here, we examined the effect of DRG stimulation (20Hz) on sensory neuron fiber recruitment and neuronal responses induced by mechanical hind paw stimulation using in vivo calcium imaging in mice. GCaMP6s was delivered to sensory neurons via an adeno-associated viral vector of serotype 9 (AAV9) injected subcutaneously at P2-5. In adult mice, a stimulation electrode was placed over the L4 DRG, and in vivo calcium imaging was performed. The proportion of responsive neurons and response magnitude was assessed during 30 seconds of DRG stimulation at different stimulation amplitudes (33%, 50%, 66%, 80%, 100% of motor threshold (MT)) for small, medium and large-sized subpopulations. In a second experiment, the effect of 30 minutes of DRG stimulation was assessed at 66% MT on neuronal responses induced by mechanical hind paw stimulation during and following DRG stimulation. We show that 20Hz DRG stimulation at clinically relevant amplitudes mainly activates large-size sensory neurons in mice, both in terms of the proportion of neurons responding as well as response magnitude. There was a small decrease in the proportion of neurons responding to mechanical stimulation during DRG stimulation, which did not recover 30 minutes after stimulation had been switched off. By contrast, DRG stimulation did not alter the response magnitude of responding neurons.