Jacinta L. Johnson, Larisa Bobrovskaya, Mark R. Hutchinson, Desmond B. Williams, Kirk W. Johnson, Paul Rolan, Jonathan Tuke, Michaela E. Johnson, Johnson, JL, Rolan, PE, Johnson, ME, Bobrovskaya, L, Williams, DB, Johnson, K, Tuke, J, and Hutchinson, M
Chronic morphine therapy has been associated with paradoxically increased pain. Codeine is a widely used opioid, which is metabolized to morphine to elicit analgesia. Prolonged morphine exposure exacerbates pain by activating the innate immune tolllike receptor-4 (TLR4) in the central nervous system. In silico docking simulations indicate codeine also docks to MD2, an accessory protein for TLR4, suggesting potential to induce TLR4-dependent pain facilitation. We hypothesized codeine would cause TLR4- dependent hyperalgesia/allodynia that is disparate from its opioid receptor-dependent analgesic rank potency. Hyperalgesia and allodynia were assessed using hotplate and von Frey tests at days 0, 3 and 5 in mice receiving intraperitoneal equimolar codeine (21 mg kg− 1), morphine (20 mg kg− 1) or saline, twice daily. This experiment was repeated in animals with prior partial nerve injury and in TLR4 null mutant mice. Interventions with interleukin-1 receptor antagonist (IL-1RA) and glial-attenuating drug ibudilast were assessed. Analyses of glial activation markers (glial fibrillary acid protein and CD11b) in neuronal tissue were conducted at the completion of behavioural testing. Despite providing less acute analgesia (P = 0.006), codeine induced similar hotplate hyperalgesia to equimolar morphine vs saline (−9.5 s, P