Artemin-GFRα3 interactions partially contribute to acute inflammatory hypersensitivity.

The expression of artemin (ARTN), a glial cell line-derived neurotrophic factor (GDNF) family ligand, increases in pre-clinical models of nociception and recent evidence suggests this growth factor may play a causative role in inflammatory pain mechanisms. The aim of this study was to demonstrate functional inhibition of ARTN with monoclonal antibodies and to determine whether ARTN neutralisation could reverse inflammatory pain in mice. We show that monoclonal antibodies with high affinity to ARTN, completely inhibit ARTN-induced Ret and ERK activation in a human neuroblastoma cell line, and block capsaicin-induced CGRP secretion from primary rat DRG cultures. In addition, administration of anti-ARTN antibodies to mice provides a transient, partial reversal (41%) of FCA-induced mechanical hypersensitivity. Anti-ARTN antibodies had no effect on hypersensitivity in response to partial nerve ligation in mice. These data suggest that ARTN-GFRα3 interactions partially mediate early stage nociceptive signalling following an inflammatory insult.

Regional differences in bioavailability of an opioid tetrapeptide in vivo in rats after administration to the respiratory tract.

TArPP (Tyr-D-Arg-Phe-Phe-NH(2)), 1-10 micromol/kg, was administered to anesthetized rats by nasal microinfusion, intratracheal microinfusion, intratracheal nebulization, aerosol inhalation, and i.v. bolus and infusion. Plasma concentrations of TArPP and its deamidated metabolite were determined by LC-MS-MS. Regional differences in bioavailability (F), first-pass metabolism, and absorption rate were found for TArPP after delivery to the respiratory tract. Absorption was rapid after both pulmonary and nasal administration (t(max) approximately 10-20 min). After nasal microinfusion, F was 52 +/- 9%. For all the pulmonary groups, F was higher (72-114%). First-pass metabolism of TArPP was lower in the lung than in the nasal cavity. It is evident that the pulmonary route is attractive for successful systemic delivery of small, hydrophilic and enzymatic susceptible peptides.