Abstract
Cervical radiculopathy represents aberrant mechanical hypersensitivity. Primary sensory neuron’s ability to sense mechanical force forms mechanotransduction. However, whether this property undergoes activity-dependent plastic changes and underlies mechanical hypersensitivity associated with cervical radiculopathic pain (CRP) is not clear. Here we show a new CRP model producing stable mechanical compression of dorsal root ganglion (DRG), which induces dramatic behavioral mechanical hypersensitivity. Amongst nociceptive DRG neurons, a mechanically sensitive neuron, isolectin B4 negative Aδ-type (IB4− Aδ) DRG neuron displays spontaneous activity with hyperexcitability after chronic compression of cervical DRGs. Focal mechanical stimulation on somata of IB4- Aδ neuron induces abnormal hypersensitivity. Upregulated HCN1 and HCN3 channels and increased Ih current on this subset of primary nociceptors underlies the spontaneous activity together with neuronal mechanical hypersensitivity, which further contributes to the behavioral mechanical hypersensitivity associated with CRP. This study sheds new light on the functional plasticity of a specific subset of nociceptive DRG neurons to mechanical stimulation and reveals a novel mechanism that could underlie the mechanical hypersensitivity associated with cervical radiculopathy.
Highlights
Cervical radiculopathy can be initiated by cervical spondylosis and intervertebral disc diseases with dorsal root ganglion (DRG) affected in patients[1]
Given the different location neurons in cervical radiculopathic pain (CRP) rats compared to controls. (a) Double immunofluorescence staining of DRG neurons with
IB4 and HCN1, HCN2, HCN3 antibody in CRP and control rats. (b,d) Quantitative summary from double immunofluorescence experiments showing that in CRP rats, HCN1 (b) and HCN3 (d) immunoreactivity in IB4− small diameter DRG neurons was increased in comparison with control rats
Summary
Cervical radiculopathy can be initiated by cervical spondylosis and intervertebral disc diseases with dorsal root ganglion (DRG) affected in patients[1]. Less dramatic but significant thermal hyperalgesia and frequent spontaneous pain behaviors were observed as well On this model, we demonstrated that amongst nociceptive DRG neurons, IB4− Aδ -fiber neurons but not IB4+ or IB4− C-fiber neurons derived from CRP rats exhibited hyperexcitability with persistent spontaneous discharges. We demonstrated that amongst nociceptive DRG neurons, IB4− Aδ -fiber neurons but not IB4+ or IB4− C-fiber neurons derived from CRP rats exhibited hyperexcitability with persistent spontaneous discharges Most importantly, this subset of DRG neurons is associated with hypersensitivity to focal mechanical stimulation in CRP rats. This study sheds new light on the functional plasticity of a specific subset of nociceptive DRG neurons to mechanical stimulation and reveals a novel mechanism that could underlie the mechanical hypersensitivity associated with cervical radiculopathy
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