The mixed-action delta/mu opioid agonist MMP-2200 does not produce conditioned place preference but does maintain drug self-administration in rats, and induces in vitro markers of tolerance and dependence.

Previous work in our laboratories provides preclinical evidence that mixed-action delta/mu receptor glycopeptides have equivalent efficacy for treating pain with reduced side effect profiles compared to widely used mu agonist analgesics such as morphine. This study evaluated the rewarding and reinforcing effects of a lead candidate, mixed-action delta/mu agonist MMP-2200, using a conditioned place preference assay as well as a drug self-administration procedure in rats. In place conditioning studies, rats underwent a 2-week conditioning protocol and were then tested for chamber preference. Rats receiving MMP-2200, at previously determined analgesic doses, could not distinguish between the drug and saline-paired chamber, whereas rats receiving the opioid agonist morphine showed a strong preference for the morphine-paired chamber. In self-administration studies, rats were trained to respond for the high efficacy mu opioid receptor agonist fentanyl on an FR5 schedule of reinforcement. Following complete dose-response determinations for fentanyl, a range of doses of MMP-2200 as well as morphine were tested. Relative to the mu agonist morphine, MMP-2200 maintained a significantly lower number of drug infusions. To begin investigating potential molecular mechanisms for the reduced side effect profile of MMP-2200, we also examined ßarrestin2 (ßarr2) recruitment and chronic MMP-2200 induced cAMP tolerance and super-activation at the human delta and mu receptors in vitro. MMP-2200 efficaciously recruited ßarr2 to both receptors, and induced cAMP tolerance and super-activation equivalent to or greater than morphine at both receptors. The in vivo findings suggest that MMP-2200 may be less reinforcing than morphine but may have some abuse potential. The reduced side effect profile cannot be explained by reduced ßarr2 recruitment or reduced cAMP tolerance and superactivation at the monomeric receptors in vitro.

Monosodium iodoacetate-induced osteoarthritis produces pain-depressed wheel running in rats: implications for preclinical behavioral assessment of chronic pain.

Pain stimulates some behaviors (e.g., withdrawal responses) and depresses other behaviors (e.g., feeding and locomotion). We are developing methods for testing candidate analgesics using measurements of pain-depressed behaviors. Such assays may model important aspects of clinical pain and complement traditional procedures that measure pain-stimulated behaviors. The present study characterized the effects of a chronic pain manipulation (monosodium iodoacetate (MIA)-induced osteoarthritis) on wheel running in rats. Rats had 24 h voluntary access to running wheels. Duration of running wheel acquisition was manipulated such that rats had either 21 or 7 days of running wheel access prior to MIA administration. Wheel running was monitored for an additional 21 days following MIA administration. MIA produced concentration- and acquisition length-dependent decreases in wheel running. Parallel experiments demonstrated that MIA produced concentration-dependent tactile allodynia and shifts in hind limb weight bearing. MIA was differentially potent across assays with a potency rank: weight-bearing≥von Frey>running wheel. MIA produced greater depression of wheel running in rats with relatively high baseline running rates compared to rats with relatively low baseline running rates. The differential potency of MIA across assays and apparent rate-dependent effects in running wheels may impact our traditional interpretations of preclinical nociceptive and antinociceptive testing.