Animal Studies

MAO-B inhibitors have been implicated to reverse neuropathic pain behaviors. Our previous study has demonstrated that KDS2010 (KDS), a newly developed reversible MAO-B inhibitor, could attenuate Paclitaxel (PTX)-induced tactile hypersensitivity in mice through suppressing reactive oxidant species (ROS)-decreased inhibitory GABA synaptic transmission in the spinal cord. In this study, we evaluated the analgesic effect of KDS under a new approach, in which KDS acts on dorsal horn sensory neurons to reduce excitatory transmission. Oral administration of KDS effectively enhanced mechanical thresholds in the spinal nerve ligation (SNL) induced neuropathic pain in rats. Moreover, we discovered that although treatment with KDS increased brain-derived neurotrophic factor (BDNF) levels, KDS inhibited Tropomyosin receptor kinase B (TrkB) receptor activation, suppressing increased p-NR2B-induced hyperexcitability in spinal dorsal horn sensory neurons after nerve injury. In addition, KDS showed its anti-inflammatory effects by reducing microgliosis and astrogliosis and the activation of MAPK and NF-ᴋB inflammatory pathways in these glial cells. The levels of ROS production in the spinal cords after the SNL procedure were also decreased with KDS treatment. Taken together, our results suggest that KDS may represent a promising therapeutic option for treating neuropathic pain. Perspective: Our study provides evidence suggesting the mechanisms by which KDS, a novel MAO-B inhibitor, can be effective in pain relief. KDS, by targeting multiple mechanisms involved in BDNF/TrkB/NR2B-related excitatory transmission and neuroinflammation, may represent the next future of pain medicine.

To verify the validity of the proposed pain treatment approach, which is based on concomitant blocking of the Transient Receptor Potential Ankyrin 1 (TRPA1) channel and phosphodiesterases (PDEs) 4B/7A activity, we continued our pharmacological studies on 8-alkoxypurine-2,6-diones selected based on previous in vitro screening.

Overactivated microglia in the spinal cord leads to neuropathic pain sensitivity. The FGF 10, a Fibroblast Growth Factor (FGFs) that is prevalent in neurons, has been demonstrated to suppress microglial polarization. The objective of this study was to investigate the role of FGF 10 in neuropathic pain and the underlying regulatory mechanisms. Immunofluorescence staining and western blot detection revealed that FGF 10 expression was upregulated in the ipsilateral spinal dorsal horn of Spared Nerve Injury (SNI) rat models and was mainly detected in neurons and microglia. To test the anti-microgliosis actions of FGF 10, SNI rats were intrathecally administered with different concentrations of recombinant FGF 10. Behavioral tests and immunostaining results showed that FGF 10 relieved hyperalgesia in SNI rats and inhibited microglial activity in the ipsilateral spinal dorsal horn in a dose-dependent manner. Besides, BV2 cells were cultured and treated with LPS to activate microglia to explore the underlying mechanisms of FGF 10-induced analgesic effects in vitro. As a result, FGF 10 administration suppressed the LPS-induced microglial augmentation in a dose-dependent manner, followed by increased PPAR-γ and decreased NFκB phosphorylation (p-NFκB) levels. Moreover, PPAR-γ agonist (pioglitazone) and antagonist (GW9662) were administrated into spinal cords of SNI rats, revealing that pioglitazone had similar anti-nociceptive and anti-microglial effects to FGF 10. Conversely, GW9662 reversed all beneficial effects of FGF 10 on SNI rats. In addition, phosphorylated levels of NFκB were reduced by pioglitazone or FGF 10 treatment but raised by GW9662 administration in FGF 10-treated SNI rats. Our findings show that FGF 10 has analgesic effects in rats after peripheral nerve injury and justify the role of PPAR-γ/NFκB signaling in FGF 10-regulated anti-microgliosis.

Hypersensitivity to mechanical stimuli is a cardinal symptom of neuropathic and inflammatory pain. A reduction in spinal inhibition is generally considered a causal factor in the development of mechanical hypersensitivity after injury. However, the extent to which presynaptic inhibition contributes to altered spinal inhibition is less well established. Here, we used conditional deletion of GABA in NaV1.8-positive sensory neurons (;) to manipulate selectively presynaptic GABAergic inhibition. Behavioral testing showed that the development of inflammatory punctate allodynia was mitigated in mice lacking pre-synaptic GABA. Dorsal horn cellular circuits were visualized in single slices using stimulus-tractable dual-labelling of mRNA for punctate and the cognate c-Fos protein for dynamic mechanical stimulation. This revealed a substantial reduction in the number of cells activated by punctate stimulation in mice lacking presynaptic GABA and an approximate 50% overlap of the punctate with the dynamic circuit, the relative percentage of which did not change following inflammation. The reduction in dorsal horn cells activated by punctate stimuli was equally prevalent in parvalbumin- and calretinin-positive cells and across all laminae I-V, indicating a generalized reduction in spinal input. In peripheral DRG neurons, inflammation following complete Freund's adjuvant (CFA) led to an increase in axonal excitability responses to GABA, suggesting that presynaptic GABA effects in NaV1.8 afferents switch from inhibition to excitation after CFA. In the days after inflammation, presynaptic GABA in NaV1.8 nociceptors constitutes an "open gate" pathway allowing mechanoreceptors responding to punctate mechanical stimulation access to nociceptive dorsal horn circuits.