Gabapentin-induced pharmacodynamic effects in the spinal nerve ligation model of neuropathic pain.

BACKGROUND: The function of brain networks can be changed in a maladaptive manner in response to chronic neuropathic pain. Analgesics can reduce pain by acting on such networks via direct or indirect (peripheral or spinal) mechanisms. This investigation aimed to map gabapentin's pharmacodynamics (PD) in the rodent brain following induction of neuropathic pain in order to further understand its PD profile. METHODS: Pharmacological magnetic resonance imaging (phMRI) and a novel functional connectivity analysis procedure were performed following vehicle or gabapentin treatment in the rat spinal nerve ligation (SNL) model of neuropathic pain as well as sham animals. RESULTS: phMRI performed in SNL animals revealed robust gabapentin-induced responses throughout the hippocampal formation, yet significant (p < 0.05, corrected for multiple comparisons) responses were also measured in other limbic structures and the sensorimotor system. In comparison, sham animals displayed weaker and less widespread phMRI signal changes subsequent to gabapentin treatment. Next, communities of networks possessing strong functional connectivity were elucidated in vehicle-treated SNL and sham animals. We observed that SNL and sham animals possessed distinct functional connectivity signatures. When measuring how gabapentin altered the behaviour of the discovered networks, a decrease in functional connectivity driven by gabapentin was not only observed, but the magnitude of this PD effect was greater in SNL animals. CONCLUSIONS: Using phMRI and functional connectivity analysis approaches, the PD effects of gabapentin in a preclinical neuropathic pain state were characterized. Furthermore, the current results offer insights on which brain systems gabapentin directly or indirectly acts upon.

In vitro pharmacological characterization of AM1241: a protean agonist at the cannabinoid CB2 receptor?

BACKGROUND AND PURPOSE: The CB2 receptor has been proposed as a novel target for the treatment of pain, and CB2 receptor agonists defined in in vitro assays have demonstrated analgesic activity in animal models. Based on its in vivo analgesic efficacy, AM1241 has been classified as a CB2-selective agonist. However, in vitro characterization of AM1241 in functional assays has not been reported. EXPERIMENTAL APPROACH: In this study, AM1241 was characterized across multiple in vitro assays employing heterologous recombinant receptor expression systems to assess its binding potencies at the human CB2 and CB1 receptors and its functional efficacies at the human CB2 receptor. KEY RESULTS: AM1241 exhibited distinct functional properties depending on the assay conditions employed, a unique profile in contrast to those of the agonist CP 55,940 and the inverse agonist SR144528. AM1241 displayed neutral antagonist activities in FLIPR and cyclase assays. However, when cyclase assays were performed using lower forskolin concentrations for stimulation, AM1241 exhibited partial agonist efficacy. In addition, it behaved as a partial agonist in ERK (or MAP) kinase assays. CONCLUSIONS AND IMPLICATIONS: The unusual phenomenon of inconsistent functional efficacies suggests that AM1241 is a protean agonist at the CB2 receptor. We postulate that functional efficacies displayed by protean agonists in various assay systems may depend on the levels of receptor constitutive activities exhibited in the assay systems, and therefore, efficacies observed in in vitro assays may not predict in vivo activities.