Extensive biliary excretion of the model opioid peptide [D-PEN2,5] enkephalin in rats

Transporters at CNS barrier sites: obstacles or opportunities for drug delivery?

The blood-brain barrier (BBB) and blood-cerebrospinal fluid (BCSF) barriers are critical determinants of CNS homeostasis. Additionally, the BBB and BCSF barriers are formidable obstacles to effective CNS drug delivery. These brain barrier sites express putative influx and efflux transporters that precisely control permeation of circulating solutes including drugs. The study of transporters has enabled a shift away from "brute force" approaches to delivering drugs by physically circumventing brain barriers towards chemical approaches that can target specific compounds of the BBB and/or BCSF barrier. However, our understanding of transporters at the BBB and BCSF barriers has primarily focused on understanding efflux transporters that efficiently prevent drugs from attaining therapeutic concentrations in the CNS. Recently, through the characterization of multiple endogenously expressed uptake transporters, this paradigm has shifted to the study of brain transporter targets that can facilitate drug delivery (i.e., influx transporters). Additionally, signaling pathways and trafficking mechanisms have been identified for several endogenous BBB/BCSF transporters, thereby offering even more opportunities to understand how transporters can be exploited for optimization of CNS drug delivery. This review presents an overview of the BBB and BCSF barrier as well as the many families of transporters functionally expressed at these barrier sites. Furthermore, we present an overview of various strategies that have been designed and utilized to deliver therapeutic agents to the brain with a particular emphasis on those approaches that directly target endogenous BBB/BCSF barrier transporters.

P-glycoprotein trafficking as a therapeutic target to optimize CNS drug delivery

The primary function of the blood-brain barrier (BBB)/neurovascular unit is to protect the central nervous system (CNS) from potentially harmful xenobiotic substances and maintain CNS homeostasis. Restricted access to the CNS is maintained via a combination of tight junction proteins as well as a variety of efflux and influx transporters that limits the transcellular and paracellular movement of solutes. Of the transporters identified at the BBB, P-glycoprotein (P-gp) has emerged as the transporter that is the greatest obstacle to effective CNS drug delivery. In this chapter, we provide data to support intracellular protein trafficking of P-gp within cerebral capillary microvessels as a potential target for improved drug delivery. We show that pain-induced changes in P-gp trafficking are associated with changes in P-gp's association with caveolin-1, a key scaffolding/trafficking protein that colocalizes with P-gp at the luminal membrane of brain microvessels. Changes in colocalization with the phosphorylated and nonphosphorylated forms of caveolin-1, by pain, are accompanied by dynamic changes in the distribution, relocalization, and activation of P-gp "pools" between microvascular endothelial cell subcellular compartments. Since redox-sensitive processes may be involved in signaling disassembly of higher-order structures of P-gp, we feel that manipulating redox signaling, via specific protein targeting at the BBB, may protect disulfide bond integrity of P-gp reservoirs and control trafficking to the membrane surface, providing improved CNS drug delivery. The advantage of therapeutic drug "relocalization" of a protein is that the physiological impact can be modified, temporarily or long term, despite pathology-induced changes in gene transcription.

P-glycoprotein modulates morphine uptake into the CNS: a role for the non-steroidal anti-inflammatory drug diclofenac

Our laboratory has previously demonstrated that peripheral inflammatory pain (PIP), induced by subcutaneous plantar injection of λ-carrageenan, results in increased expression and activity of the ATP-dependent efflux transporter P-glycoprotein (P-gp) that is endogenously expressed at the blood-brain barrier (BBB). The result of increased P-gp functional expression was a significant reduction in CNS uptake of morphine and, subsequently, reduced morphine analgesic efficacy. A major concern in the treatment of acute pain/inflammation is the potential for drug-drug interactions resulting from P-gp induction by therapeutic agents co-administered with opioids. Such effects on P-gp activity can profoundly modulate CNS distribution of opioid analgesics and alter analgesic efficacy. In this study, we examined the ability of diclofenac, a non-steroidal anti-inflammatory drug (NSAID) that is commonly administered in conjunction with the opioids during pain therapy, to alter BBB transport of morphine via P-gp and whether such changes in P-gp morphine transport could alter morphine analgesic efficacy. Administration of diclofenac reduced paw edema and thermal hyperalgesia in rats subjected to PIP, which is consistent with the known mechanism of action of this NSAID. Western blot analysis demonstrated an increase in P-gp expression in rat brain microvessels not only following PIP induction but also after diclofenac treatment alone. Additionally, in situ brain perfusion studies showed that both PIP and diclofenac treatment alone increased P-gp efflux activity resulting in decreased morphine brain uptake. Critically, morphine analgesia was significantly reduced in animals pretreated with diclofenac (3 h), as compared to animals administered diclofenac and morphine concurrently. These novel findings suggest that administration of diclofenac and P-gp substrate opioids during pain pharmacotherapy may result in a clinically significant drug-drug interaction.

Enhanced brain delivery of the opioid peptide DAMGO in glutathione pegylated liposomes: a microdialysis study

Glutathione PEGylated (GSH-PEG) liposomes were evaluated for their ability to enhance and prolong blood-to-brain drug delivery of the opioid peptide DAMGO (H-Tyr-d-Ala-Gly-MePhe-Gly-ol). An intravenous loading dose of DAMGO followed by a 2 h constant rate infusion was administered to rats, and after a washout period of 1 h, GSH-PEG liposomal DAMGO was administered using a similar dosing regimen. DAMGO and GSH-PEG liposomal DAMGO were also administered as a 10 min infusion to compare the disposition of the two formulations. Microdialysis made it possible to determine free DAMGO in brain and plasma, while the GSH-PEG liposomal encapsulated DAMGO was measured with regular plasma sampling. The antinociceptive effect of DAMGO was determined with the tail-flick method. All samples were analyzed using liquid chromatography-tandem mass spectrometry. The short infusion of DAMGO resulted in a fast decline of the peptide concentration in plasma with a half-life of 9.2 ± 2.1 min. Encapsulation in GSH-PEG liposomes prolonged the half-life to 6.9 ± 2.3 h. Free DAMGO entered the brain to a limited extent with a steady state ratio between unbound drug concentrations in brain interstitial fluid and in blood (Kp,uu) of 0.09 ± 0.04. GSH-PEG liposomes significantly increased the brain exposure of DAMGO to a Kp,uu of 0.21 ± 0.17 (p < 0.05). By monitoring the released, active substance in both blood and brain interstitial fluid over time, we were able to demonstrate that GSH-PEG liposomes offer a promising platform for enhancing and prolonging the delivery of drugs to the brain.

Endogenous opioids modulate the growth of the biliary tree in the course of cholestasis

BACKGROUND & AIMS

There is poor knowledge on the factors that modulate the growth of cholangiocytes, the epithelial cell target of cholangiopathies, which are diseases leading to progressive loss of bile ducts and liver failure. Endogenous opioids are known to modulate cell growth. In the course of cholestasis, the opioidergic system is hyperactive, and in cholangiocytes a higher expression of opioid peptide messenger RNA has been described. This study aimed to verify if such events affect the cholangiocyte proliferative response to cholestasis.

METHODS

The presence of the delta opioid receptor (OR), muOR, and kappaOR was evaluated. The effects on cholangiocyte proliferation of the in vitro and in vivo exposure to their selective agonists, together with the intracellular signals, were then studied. The effects of the OR antagonist naloxone on cell growth were also tested both in vivo and in vitro.

RESULTS

Cholangiocytes express all 3 receptors studied. deltaOR activation strongly diminished the proliferative and functional response of cholangiocytes to cholestasis, whereas muOR resulted in a slight increase in cell growth. The deltaOR signal is mediated by the IP3/CamKIIalpha/PKCalpha pathway, which inhibits the cAMP/PKA/ERK1/2/AKT cascade. In contrast, muOR activation stimulates the cAMP/PKA/ERK1/2/AKT cascade but does not affect the IP3/CamKIIalpha/PKCalpha pathway. The blockage of endogenous opioid peptides by naloxone further enhanced cholangiocyte growth both in vivo and in vitro.

CONCLUSIONS

The increase in opioid peptide synthesis in the course of cholestasis aims to limit the excessive growth of the biliary tree in the course of cholestasis by the interaction with the deltaOR expressed by cholangiocytes.

Integration of hepatic drug transporters and phase II metabolizing enzymes: Mechanisms of hepatic excretion of sulfate, glucuronide, and glutathione metabolites

The liver is the primary site of drug metabolism in the body. Typically, metabolic conversion of a drug results in inactivation, detoxification, and enhanced likelihood for excretion in urine or feces. Sulfation, glucuronidation, and glutathione conjugation represent the three most prevalent classes of phase II metabolism, which may occur directly on the parent compounds that contain appropriate structural motifs, or, as is usually the case, on functional groups added or exposed by phase I oxidation. These three conjugation reactions increase the molecular weight and water solubility of the compound, in addition to adding a negative charge to the molecule. As a result of these changes in the physicochemical properties, phase II conjugates tend to have very poor membrane permeability, and necessitate carrier-mediated transport for biliary or hepatic basolateral excretion into sinusoidal blood for eventual excretion into urine. This review summarizes sulfation, glucuronidation, and glutathione conjugation reactions, as well as recent progress in elucidating the hepatic transport mechanisms responsible for the excretion of these conjugates from the liver. The discussion focuses on alterations of metabolism and transport by chemical modulators, and disease states, as well as pharmacodynamic and toxicological implications of hepatic metabolism and/or transport modulation for certain active phase II conjugates. A brief discussion of issues that must be considered in the design and interpretation of phase II metabolite transport studies follows.

Predicting oral drug absorption and hepatobiliary clearance: Human intestinal and hepatic in vitro cell models

Membrane transport proteins control the uptake and efflux of many drugs in tissues including the intestine, liver and kidneys and thus play important roles in drug absorption, distribution and excretion. With the development of high throughput screening in an industrial environment, the importance of having appropriate in vitro systems to study drug transporter function, regulation, and interactions are invaluable. Cell lines are efficient tools in screening individual transport processes. In this review, we focus on the processes involved in the absorption and hepatobiliary clearance of drugs and the potential of cell lines to model such process, paying particular attention to the use of Caco-2 and HepG2 cells.

Development of neuropeptide drugs that cross the blood-brain barrier

In recent years, there have been several important advancements in the development of neuropeptide therapeutics. Nevertheless, the targeting of peptide drugs to the CNS remains a formidable obstacle. Delivery of peptide drugs is limited by their poor bioavailability to the brain due to low metabolic stability, high clearance by the liver, and the presence of the blood brain barrier (BBB). Multiple strategies have been devised in an attempt to improve peptide drug delivery to the brain, with variable results. In this review, we discuss several of the strategies that have been used to improve both bioavailability and BBB transport, with an emphasis on antibody based vector delivery, useful for large peptides/small proteins, and glycosylation, useful for small peptides. Further development of these delivery methods may finally enable peptide drugs to be useful for the treatment of neurological disease states.

MULTIPLE TRANSPORT SYSTEMS MEDIATE THE HEPATIC UPTAKE AND BILIARY EXCRETION OF THE METABOLICALLY STABLE OPIOID PEPTIDE [d-PENICILLAMINE2,5]ENKEPHALIN

Rapid and extensive biliary excretion of [D-penicillamine2,5]enkephalin (DPDPE) in rats as the unchanged peptide suggests that multiple transport proteins may be involved in the hepatobiliary disposition of this zwitterionic peptide. Although DPDPE is a P-glycoprotein substrate, the role of other transport proteins in the hepatic clearance of DPDPE has not been established. Furthermore, the ability of various experimental approaches to quantitate the contribution of a specific hepatic uptake or excretion process when multiple transport systems are involved has not been addressed. 3H-DPDPE uptake in suspended Wistar rat hepatocytes was primarily (>95%) due to temperature-dependent transport mechanisms; similar results were obtained in suspended hepatocytes from Mrp2-deficient (TR-) rats. Pharmacokinetic modeling revealed that saturable and linear processes were involved in 3H-DPDPE uptake in hepatocytes. The use of transport modulators suggested that hepatic uptake of 3H-DPDPE was mediated by Oatp1a1, Oatp1a4, and likely Oatp1b2. Accumulation of 3H-DPDPE in sandwich-cultured (SC) hepatocytes was rapid; uptake of 3H-DPDPE in SC rat hepatocytes from control and TR- rats was similar. However, the biliary excretion index and biliary clearance decreased by 83 and 85%, respectively, in TR- SC rat hepatocytes, indicating that DPDPE is an Mrp2 substrate. Rate constants for uptake and excretion of 3H-DPDPE in SC rat hepatocytes were determined by pharmacokinetic modeling; data were consistent with basolateral excretion of 3H-DPDPE from the hepatocyte. These results demonstrate the complexities of hepatobiliary disposition when multiple transport mechanisms are involved for a given substrate and emphasize the necessity of multi-experimental approaches for the comprehensive resolution of these processes.

Hepatobiliary Disposition of the Metabolically Stable Opioid Peptide [d-Pen2, d-Pen5]-Enkephalin (DPDPE): Pharmacokinetic Consequences of the Interplay between Multiple Transport Systems

[D-Pen2,D-Pen5]-Enkephalin (DPDPE) is excreted extensively into the bile. Although DPDPE is transported by P-glycoprotein (P-gp), multidrug resistance-associated protein 2 (Mrp2) has been identified as an important mechanism for DPDPE transport across the canalicular membrane of the hepatocyte. The present studies determined the relative impact of Mrp2 and P-gp on the hepatobiliary disposition of [3H]DPDPE in isolated perfused rat livers (IPLs). Perfusate clearance of [3H]DPDPE was not different between livers from control and Mrp2-deficient (TR-) rats. Biliary excretion of [3H]DPDPE in IPLs from Wistar control rats was rapid and extensive. However, when [3H]DPDPE was administered to livers from TR- rats, the rate and extent of excretion decreased significantly. Surprisingly, in the presence of the P-gp inhibitor GF120918 [N-(4-[2-(1,2,3,4-tetrahydro-6,7-dimethoxy-2-isoquinolinyl)ethyl]-phenyl)-9,10-dihydro-5-methoxy-9-oxo-4-acridine carboxamide], biliary excretion of [3H]DPDPE was not inhibited in control livers. In contrast, administration of GF120918 to TR- livers further reduced the maximal excretion rate and decreased net biliary excretion of [3H]DPDPE by 87%. GF120918 administration caused an unexpected increase in perfusate clearance in both control and TR- rat livers. At distribution equilibrium, [3H]DPDPE liver/perfusate partitioning was higher in GF120918-treated livers. Results of pharmacokinetic modeling were consistent with the hypothesis that GF120918 inhibited a [3H]DPDPE basolateral excretion mechanism. Mrp2 is the primary mechanism for [3H]DPDPE biliary excretion, and P-gp facilitates excretion of [3H]DPDPE only in the absence of functional Mrp2. [3H]DPDPE is a substrate for a basolateral efflux mechanism that is sensitive to inhibition by GF120918. These data emphasize the importance of using appropriate model systems and comprehensive pharmacokinetic modeling in elucidating the complex interplay between multiple transport systems.

Contribution of organic anion transporting polypeptide OATP-C to hepatic elimination of the opioid pentapeptide analogue [D-Ala2, D-Leu5]-enkephalin

The objective of this study was to examine the transport activity of the human organic anion transporter OATP-C (SLC21A6) for oligopeptides that are eliminated rapidly from the systemic circulation. We focused on an opioid peptide analogue, [D-Ala(2), D-Leu(5)]-enkephalin (DADLE), a linear pentapeptide modified to be stable. [(3)H]DADLE was taken up by rat isolated hepatocytes in a saturable manner and highly accumulated in the liver after intravenous administration to rats. The uptake of [(3)H]DADLE by the isolated hepatocytes was inhibited by several organic anions and pentapeptides, but not by tetra- or tripeptides. When OATP-C was expressed in Xenopus laevis oocytes, a significant increase in uptake of [(3)H]DADLE was observed. Moreover, the inhibitory effects of various compounds, including some peptides, on [(3)H]estrone-3-sulfate uptake by OATP-C were similar to those observed in [(3)H]DADLE uptake by rat isolated hepatocytes. In conclusion, it was demonstrated that OATP-C contributes to the rapid hepatic excretion of peptides and peptide-mimetic drugs.

Rapid quantification of the delta-opioid receptor selective enkephalin DPDPE in canine cerebrospinal fluid by liquid chromatography--mass spectrometry

An atmospheric pressure ionization liquid chromatographic-mass spectrometric assay was developed and validated for the determination of D-penicillamine(2,5) enkephalin (DPDPE) in cerebrospinal fluid (CSF) from dog. DPDPE and internal standard (D-Ala(2),D-Leu(5) enkephalin=DADLE) were isolated from CSF by reversed-phase C(18) solid-phase extraction with ZipTip micro-cartridges. Aliquots of extracted eluate were injected onto an Agilent Zorbax SB C(18) column (30 x 2.2 mm; 3.5 microm) at a flow-rate of 0.4 ml/min. The isocratic mobile phase of methanol-10 mM ammonium formate (pH 3) (75:25, v/v) was then diverted to waste for 45 s after injection, after which time flow was directed to the single quadrupole mass spectrometer. DPDPE was detected by positive mode selected ion monitoring. Standard curves were linear (r(2)> or =0.991) over the concentration range 1-1000 ng/ml. The efficiency of extraction recovery was greater than 97%, and the intra-assay and inter-assay precisions were within 9% relative standard deviation. DPDPE and the internal standard were stable in the injection solvent at 4 degrees C for at least 48 h. The assay was applied to the pharmacokinetic study of intrathecal DPDPE administration in the dog animal model.

Pharmacokinetic and pharmacodynamic implications of P-glycoprotein modulation

P-glycoprotein (P-gp) is a cell membrane-associated protein that transports a variety of drug substrates. Although P-gp has been studied extensively as a mediator of multidrug resistance in cancer, only recently has the role of P-gp expressed in normal tissues as a determinant of drug pharmacokinetics and pharmacodynamics been examined. P-glycoprotein is present in organ systems that influence drug absorption (intestine), distribution to site of action (central nervous system and leukocytes), and elimination (liver and kidney), as well as several other tissues. Many marketed drugs inhibit P-gp function, and several compounds are under development as P-gp inhibitors. Similarly, numerous drugs can induce P-gp expression. While P-gp induction does not have a therapeutic role, P-gp inhibition is an attractive therapeutic approach to reverse multidrug resistance. Clinicians should recognize that P-gp induction or inhibition may have a substantial effect on the pharmacokinetics and pharmacodynamics of concomitantly administered drugs that are substrates for this transporter.

Uptake and efflux of the peptidic delta-opioid receptor agonist

P-glycoprotein (P-gp) and organic anion transporting polypeptides (Oatp) are expressed at the blood-brain barrier (BBB). There is little functional evidence for Oatp-mediated transport at the BBB. The peptidic delta opioid-receptor agonist [D-penicillamine(2,5)]-enkephalin (DPDPE) is a substrate of mdr1a P-gp and Oatp2. The present study evaluated the influence of these transporters on brain uptake of DPDPE by in situ perfusion in mice. Brain uptake was increased approximately 12-fold in mice lacking P-gp in the BBB, but the P-gp inhibitor dexverapamil did not increase uptake in P-gp-competent mice. In P-gp-deficient mice, DPDPE uptake was saturable (K(m) approximately 24 mM), and was inhibited by dexverapamil and the Oatp2 substrates digoxin, estradiol-17beta-glucuronide and fexofenadine. These results confirm P-gp-mediated efflux of DPDPE, and suggest functional uptake transport of DPDPE by Oatp, at the murine BBB.

In vitro metabolism of opioid tetrapeptide agonists in various tissues and subcellular fractions from rats

The metabolism of three mu-selective opioid tetrapeptide agonists, Tyr-D-Arg-Phe-Nva-NH(2) (TArPN), Tyr-D-Arg-Phe-Phe-NH(2) (TArPP), and Tyr-D-Ala-Phe-Phe-NH(2) (TAPP), was investigated in different rat tissues. High metabolic activity (<20% peptide remaining after 30 min) was found against the three peptides in the kidney homogenate and against TArPN in spleen homogenate. Low metabolic activity (>80% peptide remaining after 30 min) was found for all peptides in brain homogenate and plasma, and for TArPN and TArPP in blood. The other tissue homogenates, prepared from the small and large intestine, liver and lung, all exhibited intermediate metabolic activity (20-80% peptide remaining after 30 min) against the peptides. In all tissues investigated, the tetrapeptides were metabolized at the C-terminal amide by deamidation.A further in depth metabolic investigation was performed in subcellular fractions isolated from three tissues (small intestine, liver and kidney). In the liver, the deamidation was predominantly localized to the mitochondrial/lysosomal fraction, while hydrolysis at the N-terminal Tyr residue was the major metabolic pathway in the microsomal/brush-border membrane fraction from the kidney and small intestine.

Morphine antinociception is enhanced in mdr1a gene-deficient mice

PURPOSE

Previous studies have suggested that P-glycoprotein (P-gp) modulates opioid antinociception for selected mu-and delta-agonists. This study was undertaken to assess morphine antinociception in mice lacking the mdr1a gene for expression of P-gp in the CNS.

METHODS

Morphine (n = 4-5/group) was administered as a single s.c. dose to mdr1a(-/-) mice (3-5 mg/kg) or wild-type FVB controls (8-10 mg/kg). Tail-flick response to radiant heat, expressed as percent of maximum response (%MPR), was used to determine the antinociceptive effect of morphine. Concentrations in serum, brain tissue, and spinal cord samples obtained immediately after the tail-flick test were determined by HPLC with fluorescence detection. Parallel experiments with R(+)-verapamil, a chemical inhibitor of P-gp, also were performed to further investigate the effect of P-gp on morphine-associated antinociception.

RESULTS

Morphine-associated antinociception was increased significantly in the mdr1a(-/-) mice. The ED50 for morphine was > 2-fold lower in mdr1a(-/-) (3.8+/-0.2 mg/kg) compared to FVB (8.8+/-0.2 mg/kg) mice. However, the EC50 derived from the brain tissue was similar between the two mouse strains (295 ng/g vs. 371 ng/g). Pretreatment with R(+)-verapamil produced changes similar to those observed in gene-deficient mice. P-gp does not appear to affect morphine distribution between spinal cord and blood, as the spinal cord:serum morphine concentration ratio was similar between gene-deficient and wild-type mice (0.47+/-0.03 vs. 0.56+/-0.04, p>0.05).

CONCLUSIONS

The results of this study are consistent with the hypothesis that P-gp attenuates the antinociceptive action of morphine by limiting the brain:blood partitioning of the opioid.

Immunohistochemical distribution and functional characterization of an organic anion transporting polypeptide 2 (oatp2)

The rabbit polyclonal antibody against rat organic anion transporting polypeptide 2 (oatp2) was raised and immunoaffinity-purified. Western blot analysis for oatp2 detected two bands ( 74 and 76 kDa) in rat brain and a single band (76 kDa) in the liver. By immunohistochemical analysis, the oatp2 immunoreactivity was specifically high at the basolateral membrane of rat hepatocytes. Functionally, the oatp2-expressing oocytes were found to transport dehydroepiandrosterone sulfate, delta1 opioid receptor agonist [D-Pen2,D-Pen5]enkephalin, Leuenkephalin, and biotin significantly, as well as the substrates previously reported. These data reveal the exact distribution of the rat oatp2 at the protein level in the liver, and that oatp2 appears to be involved in the multispecificity of the uptaking substrates in the liver and brain.

Enkephalin analogs containing 4,4-difluoro-2-aminobutyric acid: synthesis and fluorine effect on the biological activity

Analogs of Met-enkephalin and [D-Pen2, D-Pen5]enkephalin (DPDPE) containing the partially fluorinated amino acid 4,4-difluoro-2-aminobutyric acid (DFAB) in the 2- or 3-position of the peptide sequence were synthesized and their opioid activities and receptor selectivities were determined in vitro. The linear fluorinated [D-DFAB2, Met5-NH2]enkephalin showed mu and delta agonist potencies comparable to those of natural [Leu5]enkephalin. The partially fluorinated DPDPE analogs behaved differently as compared with their non-fluorinated correlates. While L-amino acid substitution in position 3 of DPDPE usually resulted in higher delta agonist potency than D-amino acid substitution. [D-DFAB3]DPDPE turned out to be a more potent delta agonist than [L-DFAB3]DPDPE. Furthermore, [D-DFAB3]DPDPE showed over 100-fold higher delta agonist potency than [D-Abu3]DPDPE (Abu = 2-aminobutyric acid), indicating that the fluorine substituents interact favorably with a delta opioid receptor subsite.

Pharmacokinetic evaluation of ipamorelin and other peptidyl growth hormone secretagogues with emphasis on nasal absorption

1. The pharmacokinetics of three new peptidyl growth hormone secretagogues, ipamorelin (NNC 26-0161), NNC 26-0194 and NNC 26-0235, were compared with two well-known hexapeptides, GHRP-2 and GHRP-6, in the male rat following different routes of administration. 2. Following i.v. bolus injection, plasma concentrations of the peptides declined biexponentially. Ipamorelin differed markedly from the other peptides investigated, demonstrating a systemic plasma clearance 5-fold lower than that of GHRP-6. Ipamorelin was mainly excreted in the urine, whereas GHRP-6 was predominantly excreted in the bile. NNC 26-0194 and NNC 26-0235 also showed high biliary excretions. Ipamorelin and the two NNC peptides were moderately resistant towards metabolism as 60-80% of the administered dose could be recovered from bile and urine as intact peptide. 3. After intranasal application, the bioavailability of ipamorelin was estimated at approximately 20%. Higher bioavailabilities of approximately 50% were determined for NNC 26-0235, NNC 26-0194 and GHRP-2, whereas the nasal absorption of GHRP-6 was somewhat lower. Thus, the peptides could be easily transported across the nasal epithelium suggesting that the nasal route seems promising for systemic delivery of this family of peptidyl growth hormone secretagogues.

Endogenous opiates: 1997

This paper is the twentieth installment of our annual review of research concerning the opiate system. It summarizes papers published during 1997 that studied the behavioral effects of the opiate peptides and antagonists, excluding the purely analgesic effects, although stress-induced analgesia is included. The specific topics covered this year include stress; tolerance and dependence; eating and drinking; alcohol; gastrointestinal, renal, and hepatic function; mental illness and mood; learning, memory, and reward; cardiovascular responses; respiration and thermoregulation; seizures and other neurologic disorders; electrical-related activity; general activity and locomotion; sex, pregnancy, and development; immunologic responses; and other behaviors.