In a Rat Model of Opioid Maintenance, the G Protein-Biased Mu Opioid Receptor Agonist TRV130 Decreases Relapse to Oxycodone Seeking and Taking and Prevents Oxycodone-Induced Brain Hypoxia.

BACKGROUND: Maintenance treatment with opioid agonists (buprenorphine, methadone) is effective for opioid addiction but does not eliminate opioid use in all patients. We modeled maintenance treatment in rats that self-administered the prescription opioid oxycodone. The maintenance medication was either buprenorphine or the G protein-biased mu opioid receptor agonist TRV130. We then tested prevention of oxycodone seeking and taking during abstinence using a modified context-induced reinstatement procedure, a rat relapse model. METHODS: We trained rats to self-administer oxycodone (6 hours/day, 14 days) in context A; infusions were paired with discrete tone-light cues. We then implanted osmotic pumps containing buprenorphine or TRV130 (0, 3, 6, or 9 mg/kg/day) and performed 3 consecutive tests: lever pressing reinforced by oxycodone-associated discrete cues in nondrug context B (extinction responding), context-induced reinstatement of oxycodone seeking in context A, and reacquisition of oxycodone self-administration in context A. We also tested whether TRV130 maintenance would protect against acute oxycodone-induced decreases in nucleus accumbens oxygen levels. RESULTS: In male rats, buprenorphine and TRV130 decreased extinction responding and reacquisition of oxycodone self-administration but had a weaker (nonsignificant) effect on context-induced reinstatement. In female rats, buprenorphine decreased responding in all 3 tests, while TRV130 decreased only extinction responding. In both sexes, TRV130 prevented acute brain hypoxia induced by moderate doses of oxycodone. CONCLUSIONS: TRV130 decreased oxycodone seeking and taking during abstinence in a partly sex-specific manner and prevented acute oxycodone-induced brain hypoxia. We propose that G protein-biased mu opioid receptor agonists, currently in development as analgesics, should be considered as relapse prevention maintenance treatment for opioid addiction.

The Role of Peripheral Opioid Receptors in Triggering Heroin-induced Brain Hypoxia.

While it is known that opioid receptors (ORs) are densely expressed in both the brain and periphery, it is widely accepted that hypoxic effects of opioids result solely from their direct action in the CNS. To examine the role of peripheral ORs in triggering brain hypoxia, we used oxygen sensors in freely moving rats to examine how naloxone-HCl and naloxone-methiodide, the latter which is commonly believed to be peripherally restricted, affect brain oxygen responses induced by intravenous heroin at low, human-relevant doses. Similar to naloxone-HCl, naloxone-methiodide at a relatively low dose (2 mg/kg) fully blocked heroin-induced decreases in brain oxygen levels. As measured by mass spectrometry, naloxone-methiodide was found to be ~40-fold less permeable than naloxone-HCl across the blood-brain barrier, thus acting as a selective blocker of peripheral ORs. Despite this selectivity, a low but detectable amount of naloxone was found in brain tissue after naloxone-methiodide administration, potentially influencing our results. Therefore, we examined the effects of naloxone-methiodide at a very low dose (0.2 mg/kg; at which naloxone was undetectable in brain tissue) and found that this drug still powerfully attenuates heroin-induced brain oxygen responses. These data demonstrate the role of peripheral ORs in triggering heroin-induced respiratory depression and subsequent brain hypoxia.

Sex differences in anxiety-like behaviors in rats.

The use of animal models for behavioral and pharmaceutical testing is employed in many different fields of research but often relies solely on male animals. When females are included, the existing literature frequently offers inconsistent results regarding the effects of sex and/or estrous cycle on anxiety-like behaviors. Our current study sought to establish baseline or normative behaviors in three commonly employed tests of anxiety-like behavior, and determine any sex or cycle differences. Anxiety-like behaviors in male and naturally-cycling female Sprague-Dawley rats were assessed using elevated plus maze, open field, and a social interaction/avoidance paradigm. Female rats were examined once daily to determine their stage of estrous. Results from the elevated plus maze but not the open field showed that female rats spent significantly more time in open areas than did male rats; however, there was no effect of estrous cycle stage. The social avoidance test revealed that female rats spent significantly more time in the interaction zone with an empty wire mesh cage (novel object), but there was no sex difference in time spent with an age- and sex- matched target rat. Females often exhibited greater locomotion as compared to males in social and non-social tests, but this was not related to primary anxiety measures in these tests. Overall, our findings indicate that outcomes differ in tests of anxiety-like behaviors, highlighting sex differences in the expression of anxiety-like behaviors that depend on the test employed. Importantly, the lack of estrous cycle effects suggest that for these anxiety-based tests, female Sprague-Dawley rats could be collapsed across the cycle phases to facilitate the inclusion of females in future behavioral experiments.

Interactions of benzodiazepines with heroin: Respiratory depression, temperature effects, and behavior.

Benzodiazepines are important therapeutic drugs, but they are often abused and co-abused with opioids. Clinical evidence suggests that benzodiazepines can inhibit respiration, and when combined with the respiratory-depressive effects of opioids, may increase likelihood of death. In this study we used oxygen sensors coupled with high-speed amperometry and multi-site thermorecording to examine how intravenous (iv) midazolam, a potent benzodiazepine, modulates the brain hypoxic and temperature effects of iv heroin in freely-moving rats. Oxygen levels and brain temperature were assessed with high temporal resolution in the nucleus accumbens (NAc), an important structure in the motivational-reinforcement circuit. When administered alone, midazolam (2 mg/kg) modestly decreased NAc temperature but had no evident effects on oxygen levels in this structure. In contrast, heroin (0.4 mg/kg) induced a strong decrease in NAc oxygen that was followed by a weaker, rebound-like oxygen increase. Midazolam pretreatment did not affect heroin-induced brain hypoxia but potentiated the initial hypothermia induced by heroin. However, co-administration of these drugs potentiated the heroin-induced oxygen decrease and enhanced heroin-induced brain hypothermia. Co-administration of heroin and midazolam also resulted in enhanced locomotor inhibition and loss of motor control. This effect caused some rats to collapse, resulting in nose and mouth occlusion, which caused a secondary hypoxic phase. These results could have important implications for human drug users, as the combined use of benzodiazepines with potent opioids not only results in sustained brain hypoxia but creates conditions of loss of motor control which could result in asphyxia and death. This article is part of the Special Issue entitled 'New Vistas in Opioid Pharmacology'.

Intravenous Cocaine Increases Oxygen Entry into Brain Tissue: Critical Role of Peripheral Drug Actions.

Although it is well established that the direct action of cocaine on centrally located neural substrates is essential in mediating its reinforcing properties, cocaine induces very rapid immediate neural effects that imply cocaine's action on peripheral neural substrates. We employed oxygen sensors coupled with high-speed amperometery to examine the effects of standard cocaine HCl that easily enters the blood-brain barrier and its blood-brain barrier-impermeable methiodide analogue on oxygen levels in the nucleus accumbens in awake, freely moving rats. Both drugs induced strong increases in nucleus accumbens oxygen levels, which displayed similarly short, second-scale latencies and a general similarity with oxygen increases induced by an auditory stimulus. This study provides additional support for the view that the immediate neural effects of intravenous cocaine are triggered via its direct action on peripherally located neural substrates and fast neural transmission to the central nervous system via somatosensory pathways.

Opposing mechanisms underlying differential changes in brain oxygen and temperature induced by intravenous morphine.

Morphine remains widely used in clinical settings due to its potent analgesic properties. However, one of the gravest risks of all opioids is their ability to induce respiratory depression and subsequent brain hypoxia that can lead to coma and death. Due to these life-threatening effects, our goal was to examine the effects of intravenous morphine at a wide range of doses (0.1-6.4 mg/kg) on changes in brain oxygen levels in freely moving rats. We used oxygen sensors coupled with high-speed amperometry and conducted measurements in the nucleus accumbens (NAc) and subcutaneous (SC) space, the latter serving as a proxy for blood oxygen levels that depend on respiratory activity. We also examined the effects of morphine on NAc, muscle, and skin temperature. Morphine induced dose-dependent decreases in SC oxygen levels, suggesting respiratory depression, but differential effects on NAc oxygen: increases at low and moderate doses (0.1-1.6 mg/kg) and decreases at the highest dose tested (6.4 mg/kg). Morphine also increased brain temperature at low and moderate doses but induced a biphasic, down-up change at high doses. The oxygen increases appear to result from a neurovascular coupling mechanism via local vasodilation and enhanced oxygen entry into brain tissue to compensate for blood oxygen drops caused by modest respiratory depression. At high morphine doses, this adaptive mechanism is unable to compensate for the enhanced respiratory depression, resulting in brain hypoxia. Hence, morphine appears to be safe when used as an analgesic at clinically relevant doses but poses great risks at high doses, likely to be abused by drug users. NEW & NOTEWORTHY With the use of oxygen sensors coupled with amperometry, we show that morphine induces differential effects on brain oxygen levels, slightly increasing them at low doses and strongly decreasing them at high doses. In contrast, morphine dose dependently decreases oxygen levels in the SC space. Therefore, morphine engages opposing mechanisms affecting brain oxygen levels, enhancing them through neurovascular coupling at low, clinically relevant doses and decreasing them due to dramatic respiratory depression at high doses, likely to be abused.

Changes in brain oxygen and glucose induced by oxycodone: Relationships with brain temperature and peripheral vascular tone.

Oxycodone is a semi-synthetic opioid drug that is used to alleviate acute and chronic pain. However, oxycodone is often abused and, when taken at high doses, can induce powerful CNS depression that manifests in respiratory abnormalities, hypotension, coma, and death. Here, we employed several techniques to examine the effects of intravenous oxycodone at a wide range of doses on various metabolism-related parameters in awake, freely-moving rats. High-speed amperometry was used to assess how oxycodone affects oxygen and glucose levels in the nucleus accumbens (NAc). These measurements were supplemented by recordings of locomotor activity and temperature in the NAc, temporal muscle, and skin. At low doses, which are known to maintain self-administration behavior (0.15-0.3 mg/kg), oxycodone transiently decreased locomotor activity, induced modest brain and body hyperthermia, and monotonically increased NAc oxygen and glucose levels. While locomotor inhibition became stronger with higher oxycodone doses (0.6-1.2 mg/kg), NAc oxygen and glucose transiently decreased and subsequently increased. High-dose oxycodone induced similar biphasic down-up changes in brain and body temperature, with the initial decreases followed by increases. While cerebral vasodilation induced by neural activation appears to be the underlying mechanism for the correlative increases in brain oxygen and glucose levels, respiratory depression and the subsequent drop in blood oxygen likely mediate the brain hypoxia induced by large-dose oxycodone injections. The initial inhibitory effects induced by large-dose oxycodone injections could be attributed to rapid and profound CNS depression-the most dangerous health complication linked to opioid overdose in humans.