F Porreca

Studies in vivo with ICI 174864 and [D-Pen2, D-Pen5]enkephalin.

We studied the in vivo pharmacology of a selective agonist (DPDPE) and a selective antagonist (ICI 174864) at delta opioid receptors. ICI 174864 (10 micrograms icv) caused postural abnormalities, barrel rotation and hypothermia in rats. DPDPE induced behavioural arousal (at 75 micrograms icv) and barrel rotation (at 125 micrograms) in rats. ICI 174864 (10 micrograms icv) attenuated acetic acid induced writhing in mice. This action was antagonized by naloxone (10 but not 2 mg/kg s.c.). A lower, non-agonist dose of ICI 174864 (5 micrograms) antagonized DPDPE (3 micrograms icv) in this test without affecting DAGO (0.0006 micrograms icv), a selective agonist at mu receptors. In the mouse tail flick test, ICI 174864 (10-50 micrograms icv) did not significantly antagonize the agonist actions of DPDPE (40 micrograms icv) or DAGO (0.3 micrograms icv). At 10-50 micrograms icv, ICI 174864 had no marked effect on gastrointestinal transit in mice. ICI 174864 (25 micrograms icv or 20 mg/kg s.c.) did not interact with mu opioid receptors in mice rendered physically dependent on morphine.

Studies in vitro with ICI 174, 864, [D-Pen2, D-Pen5]-enkephalin (DPDPE) and [D-Ala2, NMePhe4, Gly-ol]-enkephalin (DAGO)

The interactions of a proposed, selective delta receptor antagonist (ICI 174,864) and selective agonists at mu and delta receptors, [D-Ala2, NMePhe4, Gly-ol]-enkephalin (DAGO) and [D-Pen2, D-Pen5]-enkephalin (DPDPE), respectively, have been studied using the electrically-stimulated mouse isolated vas deferens (MVD) and the guinea-pig isolated ileum (GPI). Incubation of increasing concentrations of ICI 174,864 (10,30,100 and 300 nM) produced a dose-related and parallel rightward displacement of the DPDPE dose-response curve in the MVD. In contrast, ICI 174,864 (300-3000 nM) failed to affect the DAGO dose-response curve in the same tissue. Analysis of the DPDPE-ICI 174,864 interaction in the MVD using the pA2 method revealed a Schild plot slope of -0.68 suggesting the involvement of more than one population of receptors. ICI 174,864 (300 nM) failed to antagonize DPDPE in the GPI at doses up to 30 microM. These results suggest that (a) ICI 174,864 acts as a selective delta antagonist in the MVD; (b) DPDPE interacts with mu receptors in the MVD but only at very high concentrations, and (c) delta receptors appear not to be of functional importance in the GPI.

III. Centrally-mediated bombesin effects on gastrointestinal motility

Administration of bombesin into the lateral cerebral ventricle (i.c.v.) of rats results in a dose-related delay in gastric emptying and small intestinal transit. Recordings of intestinal intraluminal pressure in this species show that the i.c.v. peptide produces a dose-related increase in the frequency of duodenal contractions, and a complex inhibitory/excitatory jejunal effect at low and high doses, respectively. Intrathecal (i.th.) or i.c., but not intraperitoneal (i.p.), bombesin produces a dose-related slowing of gastrointestinal and colonic transit in mice. I.c.v. bombesin is 13.5 and 3406 times more potent in inhibition of gastrointestinal transit than when given by the i.th. or i.p. routes, respectively. Similarly, the i.c.v. peptide is 1.54 and over 11000 times more potent in slowing mouse colonic transit than when given by the i.th. or i.p. routes, respectively. The substance P analogue, D-Arg1, D-Pro2, D-Trp7,9, Leu11-Substance P (DAPTL-SP)(a reported bombesin antagonist in vitro) was not effective in blocking the gastrointestinal transit effects of the peptide in vivo. Transection of the spinal cord at the level of the second thoracic vertebra (T2) eliminates the gastrointestinal and colonic effects of i.th., but not i.c.v. bombesin. Thus, bombesin can affect motor function of the gut via activity within the brain or spinal cord of rats and mice; the activity of the peptide when given at the supraspinal level depends on an intact vagus nerve and adrenal-pituitary axis, while the activity of the peptide given at the spinal level appears to depend on the integrity of ascending spinal-supraspinal pathways.

The efficacy of δ-opioid receptor-selective drugs

Delta-opioid receptor-selective drugs may provide an alternative to mu-opioid-selective drugs currently used for the relief of pain. To develop improved delta-opioid receptor-selective drugs, better measures of drug activity are necessary. In this review we suggest that efficacy calculations provide a superior measure of drug activity as compared to dissociation constants and drug potencies in functional assays. Efficacy, as discussed in this review, is defined as a quantitative measurement of the ability of a drug to stimulate second messenger systems or measurable functional responses in cells or tissues under standard conditions. Efficacy values will allow medicinal chemists to understand the contributions of both the coupling efficiency and dissociation constant to drug potencies in the development of new delta-opioid receptor-selective drugs.