Central and peripheral sites of action for CB2 receptor mediated analgesic activity in chronic inflammatory and neuropathic pain models in rats.

BACKGROUND AND PURPOSE: Cannabinoid CB2 receptor activation by selective agonists has been shown to produce analgesic effects in preclinical models of inflammatory and neuropathic pain. However, mechanisms underlying CB2-mediated analgesic effects remain largely unknown. The present study was conducted to elucidate the CB2 receptor expression in 'pain relevant' tissues and the potential sites of action of CB2 agonism in rats. EXPERIMENTAL APPROACH: Expression of cannabinoid receptor mRNA was evaluated by quantitative RT-PCR in dorsal root ganglia (DRGs), spinal cords, paws and several brain regions of sham, chronic inflammatory pain (CFA) and neuropathic pain (spinal nerve ligation, SNL) rats. The sites of CB2 mediated antinociception were evaluated in vivo following intra-DRG, intrathecal (i.t.) or intraplantar (i.paw) administration of potent CB2-selective agonists A-836339 and AM1241. KEY RESULTS: CB2 receptor gene expression was significantly up-regulated in DRGs (SNL and CFA), spinal cords (SNL) or paws (CFA) ipsilateral to injury under inflammatory and neuropathic pain conditions. Systemic A-836339 and AM1241 produced dose-dependent efficacy in both inflammatory and neuropathic pain models. Local administration of CB2 agonists also produced significant analgesic effects in SNL (intra-DRG and i.t.) and CFA (intra-DRG) pain models. In contrast to A-836339, i.paw administration of AM-1241 dose-relatedly reversed the CFA-induced thermal hyperalgesia, suggesting that different mechanisms may be contributing to its in vivo properties. CONCLUSIONS AND IMPLICATIONS: These results demonstrate that both DRG and spinal cord are important sites contributing to CB2 receptor-mediated analgesia and that the changes in CB2 receptor expression play a crucial role for the sites of action in regulating pain perception.

Diaryldiamines with dual inhibition of the histamine H(3) receptor and the norepinephrine transporter and the efficacy of 4-(3-(methylamino)-1-phenylpropyl)-6-(2-(pyrrolidin-1-yl)ethoxy)naphthalen-1-ol in pain.

A series of compounds was designed as dual inhibitors of the H(3) receptor and the norepinephrine transporter. Compound 5 (rNET K(i) = 14 nM; rH(3)R K(i) = 37 nM) was found to be efficacious in a rat model of osteoarthritic pain.

Antinociceptive effects of histamine H3 receptor antagonist in the preclinical models of pain in rats and the involvement of central noradrenergic systems.

The histamine H(3) receptor is predominantly expressed in the central nervous system and plays a role in diverse physiological mechanisms. In the present study, the effects of GSK189254, a potent and selective H(3) antagonist, were characterized in preclinical pain models in rats. Systemic GSK189254 produced dose-dependent efficacy (ED(50)=0.77 mg/kg i.p.) in a rat model of monoiodoacetate (MIA) induced osteoarthritic (OA) pain as evaluated by hindlimb grip force. The role of H(3) receptors in regulating pain perception was further demonstrated using other structurally distinct H(3) antagonists. GSK189254 also displayed efficacy in a rat surrogate model indicative of central sensitization, namely phase 2 response of formalin-induced flinching, and attenuated tactile allodynia in the spinal nerve ligation model of neuropathic pain (ED(50)=1.5mg/kg i.p.). In addition, GSK189254 reversed persistent (CFA) (ED(50)=2.1mg/kg i.p,), whereas was ineffective in acute (carrageenan) inflammatory pain. When administered intrathecally (i.t.) to the lumbar spinal cord, GSK189254 produced robust effects in relieving the OA pain (ED(50)=0.0027 mg/kg i.t.). The systemic GSK189254 effect was completely reversed by the alpha-adrenergic receptor antagonist phentolamine (i.p. and i.t.) but not by the opioid receptor antagonist naloxone (i.p.). Furthermore, the i.t. GSK189254 effect was abolished when co-administered with phentolamine (i.t.). These results suggest that the spinal cord is an important site of action for H(3) antagonism and the effect can be associated with activation of the noradrenergic system. Our data also provide support that selective H(3) antagonists may represent a class of agents for the treatment of pain disorders.

Characterization of Fasudil in preclinical models of pain.

UNLABELLED: Activation of Rho kinase (ROCK) has been shown to play a role in neuronal regeneration and development of posttraumatic neuropathic pain. The ROCK inhibitor Fasudil, used clinically for the treatment of vasospasm, was used to investigate the analgesic profile of a ROCK inhibitor. Fasudil was evaluated in different preclinical models of neuropathic, osteoarthritic (OA), and inflammatory pain as well as capsaicin-induced acute pain and secondary mechanical hypersensitivity. In addition, Fasudil was tested in in vivo electrophysiology to determine the mechanism by which Fasudil produces analgesia. Fasudil at the highest dose tested (30 mg/kg) significantly attenuated mechanical allodynia in spinal-nerve ligation (SNL; 77%), chronic constriction injury (CCI; 53%), capsaicin-induced secondary mechanical hypersensitivity (63%), sodium iodoacetate-induced OA pain (88%), and capsaicin-induced acute flinching behaviors (56%). However, Fasudil (at 30 mg/kg) failed to attenuate or had only modest effects on inflammatory thermal hyperalgesia following carrageenan injection and mechanical allodynia following Complete Freund's Adjuvant (CFA) injection. Fasudil produced ED(50) of 10.8 mg/kg in the SNL, and 5.7 mg/kg in the OA pain models. The ED(50) and 95% CI could not be obtained in the other models. Furthermore, administration of Fasudil (10 mg/kg, iv) significantly reduced both spontaneous and evoked firing of wide dynamic range (WDR) neurons in SNL, but not sham rats. Finally, Fasudil significantly decreased exploratory behaviors at 30 mg/kg. These results suggest that the acute administration of a ROCK inhibitor produces efficacy in both neuropathic and nociceptive pain states at doses devoid of locomotor side effects, with specific effects on WDR neurons. PERSPECTIVE: In this article, the potential analgesic effects of Fasudil in a range of preclinical pain models were assessed. Fasudil was shown to have efficacy in neuropathic and nociceptive pain models. These findings may help identify new therapeutic treatments for pain in the clinic.

H4 receptor antagonism exhibits anti-nociceptive effects in inflammatory and neuropathic pain models in rats.

The histamine H(4) receptor (H(4)R) is expressed primarily on cells involved in inflammation and immune responses. To determine the potential role of H(4)R in pain transmission, the effects of JNJ7777120, a potent and selective H(4) antagonist, were characterized in preclinical pain models. Administration of JNJ7777120 fully blocked neutrophil influx observed in a mouse zymosan-induced peritonitis model (ED(50)=17 mg/kg s.c., 95% CI=8.5-26) in a mast cell-dependent manner. JNJ7777120 potently reversed thermal hyperalgesia observed following intraplantar carrageenan injection of acute inflammatory pain (ED(50)=22 mg/kg i.p., 95% CI=10-35) in rats and significantly decreased the myeloperoxide activity in the carrageenan-injected paw. In contrast, no effects were produced by either H(1)R antagonist diphenhydramine, H(2)R antagonists ranitidine, or H(3)R antagonist ABT-239. JNJ7777120 also exhibited robust anti-nociceptive activity in persistent inflammatory (CFA) pain with an ED(50) of 29 mg/kg i.p. (95% CI=19-40) and effectively reversed monoiodoacetate (MIA)-induced osteoarthritic joint pain. This compound also produced dose-dependent anti-allodynic effects in the spinal nerve ligation (ED(50)=60 mg/kg) and sciatic nerve constriction injury (ED(50)=88 mg/kg) models of chronic neuropathic pain, as well as in a skin-incision model of acute post-operative pain (ED(50)=68 mg/kg). In addition, the analgesic effects of JNJ7777120 were maintained following repeated administration and were evident at the doses that did not cause neurologic deficits in rotarod test. Our results demonstrate that selective blockade of H(4) receptors in vivo produces significant anti-nociception in animal models of inflammatory and neuropathic pain.

Comparison of mechanical allodynia and the affective component of inflammatory pain in rats.

Most animal models of pain cannot separate the sensory and affective components of pain. One model that has been used to assess affective pain is the place escape avoidance paradigm (PEAP). The aim of the current study is two-fold. First, validate PEAP with Complete Freund's Adjuvant (CFA)-induced inflammation for the assessment of the affective component of pain using the reference analgesics celecoxib, diclofenac and duloxetine; fluoxetine and scopolamine were tested as negative controls. Secondly, determine if there is a difference in efficacy in PEAP in comparison to the effects of the same compounds on von Frey-evoked mechanical allodynia in CFA animals. All compounds were tested in mechanical allodynia, place escape/avoidance, and for potentially confounding side effects in locomotor activity. Results show that celecoxib, diclofenac, and duloxetine significantly increased the time spent on the side associated with stimulation of the injured paw, whereas fluoxetine and scopolamine had no effect. Higher doses of celecoxib, diclofenac, duloxetine, and fluoxetine were required to attenuate von Frey-evoked mechanical allodynia. In the side effect assays, only fluoxetine decreased locomotor activity at doses used in PEAP. These results show that in inflammatory pain induced by CFA injection, PEAP is more sensitive to the effects of pain relieving compounds than mechanical allodynia. Fluoxetine showed efficacy in the mechanical allodynia test, but not PEAP, whereas duloxetine showed efficacy in mechanical allodynia and PEAP. These studies show that methods other than reflex based measures of pain such as affective pain models could be more predictive of efficacy/potency in the clinic.

Characterization of a cannabinoid CB2 receptor-selective agonist, A-836339 [2,2,3,3-tetramethyl-cyclopropanecarboxylic acid [3-(2-methoxy-ethyl)-4,5-dimethyl-3H-thiazol-(2Z)-ylidene]-amide], using in vitro pharmacological assays, in vivo pain models, and pharmacological magnetic resonance imaging.

Studies demonstrating the antihyperalgesic and antiallodynic effects of cannabinoid CB(2) receptor activation have been largely derived from the use of receptor-selective ligands. Here, we report the identification of A-836339 [2,2,3,3-tetramethyl-cyclopropanecarboxylic acid [3-(2-methoxy-ethyl)-4,5-dimethyl-3H-thiazol-(2Z)-ylidene]-amide], a potent and selective CB(2) agonist as characterized in in vitro pharmacological assays and in in vivo models of pain and central nervous system (CNS) behavior models. In radioligand binding assays, A-836339 displays high affinities at CB(2) receptors and selectivity over CB(1) receptors in both human and rat. Likewise, A-836339 exhibits high potencies at CB(2) and selectivity over CB(1) receptors in recombinant fluorescence imaging plate reader and cyclase functional assays. In addition A-836339 exhibits a profile devoid of significant affinity at other G-protein-coupled receptors and ion channels. A-836339 was characterized extensively in various animal pain models. In the complete Freund's adjuvant model of inflammatory pain, A-836339 exhibits a potent CB(2) receptor-mediated antihyperalgesic effect that is independent of CB(1) or mu-opioid receptors. A-836339 has also demonstrated efficacies in the chronic constrain injury (CCI) model of neuropathic pain, skin incision, and capsaicin-induced secondary mechanical hyperalgesia models. Furthermore, no tolerance was developed in the CCI model after subchronic treatment with A-836339 for 5 days. In assessing CNS effects, A-836339 exhibited a CB(1) receptor-mediated decrease of spontaneous locomotor activities at a higher dose, a finding consistent with the CNS activation pattern observed by pharmacological magnetic resonance imaging. These data demonstrate that A-836339 is a useful tool for use of studying CB(2) receptor pharmacology and for investigation of the role of CB(2) receptor modulation for treatment of pain in preclinical animal models.