Ryan B. Griggs scite author profile

Peroxisome proliferator-activated receptor gamma (PPARγ) is emerging as a new pharmacotherapeutic target for chronic pain. When oral (3–30 mg/kg/day in chow for 7 wk) or twice-daily intraperitoneal (1–10 mg/kg/day for 2 wk) administration began before spared nerve injury (SNI), pioglitazone, a PPARγ agonist, dose-dependently prevented multiple behavioral signs of somatosensory hypersensitivity. The highest dose of intraperitoneal pioglitazone did not produce ataxia or reductions in transient mechanical and heat nociception, indicating that inhibitory effects on hypersensitivity were not secondary to adverse drug-induced behaviors or antinociception. Inhibitory effects on hypersensitivity persisted at least one week beyond cessation of pioglitazone administration, suggestive of long-lasting effects on gene expression. Blockade of PPARγ with GW9662, an irreversible and selective PPARγ antagonist, dose-dependently reduced the inhibitory effect of pioglitazone on hypersensitivity, indicating a PPARγ-dependent action. Remarkably, a single preemptive injection of pioglitazone 15 min before SNI attenuated hypersensitivity for at least 2 weeks; this was enhanced with a second injection delivered 12 hr after SNI. Pioglitazone injections beginning after SNI also reduced hypersensitivity, albeit to a lesser degree than preemptive treatment. Intraperitoneal pioglitazone significantly reduced the nerve injury-induced up-regulation of cd11b, GFAP, and p-p38 in the dorsal horn, indicating a mechanism of action involving spinal microglia and/or astrocyte activation. Oral pioglitazone significantly reduced touch stimulus-evoked phospho-extracellular signal-related kinase (p-ERK) in lamina I-II, indicating a mechanism of action involving inhibition of central sensitization. We conclude that pioglitazone reduces spinal glial and stimulus-evoked p-ERK activation and that PPARγ activation blocks the development of and reduces established neuropathic pain.

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Pioglitazone rapidly reduces neuropathic pain through astrocyte and nongenomic PPARγ mechanisms

Griggs

Donahue

Morgenweck

et al. 2015

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Repeated administration of peroxisome proliferator-activated receptor gamma (PPARγ) agonists reduces neuropathic pain-like behavior and associated changes in glial activation in the spinal cord dorsal horn. As PPARγ is a nuclear receptor, sustained changes in gene expression are widely believed to be the mechanism of pain reduction. However, we recently reported that a single intrathecal injection of pioglitazone, a PPARγ agonist, reduced hyperalgesia within 30 minutes, a time frame that is typically less than that required for genomic mechanisms. To determine the very rapid anti-hyperalgesic actions of PPARγ activation we administered pioglitazone to rats with spared nerve injury (SNI) and evaluated hyperalgesia. Pioglitazone inhibited hyperalgesia within 5 min of injection, consistent with a non-genomic mechanism. Systemic or intrathecal administration of GW9662, a PPARγ antagonist, inhibited the anti-hyperalgesic actions of intraperitoneal or intrathecal pioglitazone, suggesting a spinal PPARγ-dependent mechanism. To further address the contribution of non-genomic mechanisms, we blocked new protein synthesis in the spinal cord with anisomycin. When co-administered intrathecally, anisomycin did not change pioglitazone anti-hyperalgesia at an early 7.5 min timepoint, further supporting a rapid non-genomic mechanism. At later timepoints anisomycin reduced pioglitazone anti-hyperalgesia, suggesting a delayed recruitment of genomic mechanisms. Pioglitazone reduction of SNI-induced increases in GFAP expression occurred more rapidly than expected, within 60 min. We are the first to show that activation of spinal PPARγ rapidly reduces neuropathic pain independent from canonical genomic activity. We conclude that acute pioglitazone inhibits neuropathic pain in part by reducing astrocyte activation, and via both genomic and non-genomic PPARγ mechanisms.

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Pioglitazone Inhibits the Development of Hyperalgesia and Sensitization of Spinal Nociresponsive Neurons in Type 2 Diabetes

Griggs

Donahue

Adkins

et al. 2016

The Journal of Pain

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Thiazolidinedione drugs (TZDs) such as pioglitazone are FDA-approved for the treatment of insulin resistance in type 2 diabetes. However, whether TZDs reduce painful diabetic neuropathy (PDN) remains unknown. Therefore we tested the hypothesis that chronic administration of pioglitazone would reduce PDN in Zucker Diabetic Fatty (ZDFfa/fa) rats. Compared to Zucker Lean (ZLfa/+) controls, ZDF developed: (1) elevated blood glucose, HbA1c, methylglyoxal and insulin; (2) mechanical and thermal hyperalgesia at the hindpaw; (3) increased avoidance of noxious mechanical probes in a mechanical conflict avoidance behavioral assay, the first report of a measure of affective-motivational pain-like behavior in ZDF; and (4) exaggerated lumbar dorsal horn immunohistochemical expression of pressure-evoked phosphorylated extracellular signal-regulated kinase (pERK). Seven weeks of pioglitazone (30 mg · kg−1 · d−1 in food) reduced blood glucose, HbA1c, hyperalgesia, and pERK expression in ZDF. This is the first report to reveal hyperalgesia and spinal sensitization in the same ZDF animals, both evoked by a noxious mechanical stimulus that reflects pressure pain frequently associated with clinical PDN. As pioglitazone provides the combined benefit of reducing hyperglycemia, hyperalgesia, and central sensitization, we suggest that TZDs represent an attractive pharmacotherapy in patients with type 2 diabetes-associated pain.

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Methylglyoxal and a spinal TRPA1-AC1-Epac cascade facilitate pain in the db/db mouse model of type 2 diabetes

Griggs

Santos

Laird

et al. 2019

Neurobiology of Disease

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Ryan B. Griggs

PPARγ activation blocks development and reduces established neuropathic pain in rats

Pioglitazone rapidly reduces neuropathic pain through astrocyte and nongenomic PPARγ mechanisms

Pioglitazone Inhibits the Development of Hyperalgesia and Sensitization of Spinal Nociresponsive Neurons in Type 2 Diabetes

Methylglyoxal and a spinal TRPA1-AC1-Epac cascade facilitate pain in the db/db mouse model of type 2 diabetes

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