Melatonin and morphine: potential beneficial effects of co-use

Morphine is a potent analgesic agent used to control acute or chronic pain. Chronic administration of morphine results in analgesic tolerance, hyperalgesia, and other side effects including dependence, addiction, respiratory depression, and constipation, which limit its clinical usage. Therefore, identifying the new analgesics with fewer side effects which could increase the effect of morphine and reduce its side effects is crucial. Melatonin, a multifunctional molecule produced in the body, is known to play an important role in pain regulation. The strong anti-inflammatory effect of melatonin is suggested to be involved in the attenuation of the pain associated with inflammation. Melatonin also increases the anti-nociceptive actions of opioids, such as morphine, and reverses their tolerance through regulating several cellular signaling pathways. In this review, published articles evaluating the effect of the co-consumption of melatonin and morphine in different conditions were investigated. Our results show that melatonin has pain-killing properties when administered alone or in combination with other anti-nociceptive drugs. Melatonin decreases morphine consumption in different pathologies. Furthermore, attenuation of morphine intake can be accompanied by reduction of morphine-associated side-effects, including physical dependence, morphine tolerance, and morphine-related hyperalgesia. Therefore, it is reasonable to believe that the combination of melatonin with morphine could reduce morphine-induced tolerance and hyperalgesia, which may result from anti-inflammatory and antioxidant properties of melatonin. Overall, we underscore that, to further ameliorate patients' life quality and control their pain in various pathological conditions, melatonin deserves to be used with morphine by anesthesiologists in clinical practice.

Non-invasively assessing disturbance and stress in laboratory rats by scoring chromodacryorrhoea

In rats, like many rodents, Harderian glands next to the orbits secrete porphyrins, lipids and other compounds. High levels of secretion lead to chromodacryorrhoea (red or "bloody" tears), often taken as a sign of stress or disease. Here, we developed a scoring system for recording chromodacryorrhoea in a quantitative way, and investigated whether the low-level, transient Harderian secretions of normal, healthy rats correlate with low to moderate levels of stress or disturbance. Rather than exposing our subjects (24 Lister Hoodeds, housed in 11 single-sex cages) experimentally to stressors, we made opportunistic use of three likely sources of low-level stress within the unit: 1) building maintenance work, taking several hours and involving several potential stressors; 2) visits by unfamiliar humans, and the other mild sources of disturbance normal in an animal unit; and 3) social status within the cage. The mean daily chromodacryorrhoea score increased most with the severe disturbance of building maintenance work (F1,9 = 602.67, p < < 0.0001), and also increased--though to a lesser extent--with the mild disturbance of visitors and similar (F1,9 = 8.77, p = 0.008), while being the subordinate member of a cage-group had a smaller effect still (F1,6 = 7.86, p = 0.03). Individual rats scored consistently across treatment conditions, and there was also significant inter-observer reliability between independent scorers. We therefore suggest that scoring chromodacryorrhoea could be a simple, practical and non-invasive way of sensitively assessing the impact on rats of housing, husbandry, or procedures.

Autonomic areas of rat brain exhibit increased Fos-like immunoreactivity during opiate withdrawal in rats

We sought to identify the brain areas that might contribute to the increased autonomic activity seen during morphine withdrawal by mapping neuronal expression of c-fos protein (Fos) and Fos-related antigens. Rats were implanted with morphine pellets or placebo pellets over a 5 day regimen and injected on day 6 with either saline or naltrexone (100 mg/kg). After a standard PAP immunocytochemical protocol, Fos-like immunoreactivity (Fos-LIR) was observed in medullary nuclei including the NTS (nucleus of the solitary tract), caudal (CVL) and rostral ventrolateral medulla (RVL). Although some Fos-LIR was seen in these areas in control rats (either morphine-implanted, saline injected, or placebo-implanted, saline or naltrexone injected), a significantly higher number of Fos-LIR-positive cells in NTS, CVL and RVL were seen after morphine withdrawal. Large numbers of Fos-like immunoreactive cells were also seen in the A5 area, the parabrachial nuclei of the pons and the locus coeruleus. Increased Fos-LIR was also detected in the paraventricular nucleus of the hypothalamus and the amygdala of morphine withdrawn rats. The Fos-LIR was co-localized with tyrosine hydroxylase immunoreactivity in many of the cells in caudal and rostral ventrolateral medulla, A5 and locus coeruleus. These data support the conclusion that autonomic areas in brain and noradrenergic/adrenergic cells in these areas are activated during morphine withdrawal and may contribute to the autonomic symptoms of opiate withdrawal.

Central haemodynamics during morphine abstinence in anaesthetized rats

Central haemodynamics were studied in one group of morphine-dependent rats, and in a non-dependent control group, before and after administration of repeated bolus doses of naloxone. Dependence was induced by s.c. morphine pellet implantations. Mean arterial pressure (MAP), heart rate (HR), cardiac output (CO) and mean transit time (MTT) were measured in the conscious state, after induction of chloralose anaesthesia and after the administration of naloxone (0.005, 0.05, 0.5 and 5 mg kg-1 i.v.). Total peripheral resistance (TPR), stroke volume (SV) and central blood volume (CBV) were subsequently calculated. The haemodynamic variables did not differ significantly in the conscious state, except for a lower SV, when compared with the non-dependent control group. However, in response to anaesthesia the dependent rats exhibited a greater fall in MAP, mainly due to a TPR decrease. Naloxone elicited a marked increase in MAP in the morphine-dependent group, which was mainly caused by an increase in TPR. Naloxone induced no significant change compared with the control group in CO and CBV, while SV increased concomitantly with a lowered HR after naloxone in the morphine-dependent group. These results suggest that the withdrawal hypertension during morphine abstinence was mainly explained by an increase in TPR, reflecting an augmented tone of the resistance vessels. The minor changes in CBV indicate that the tone of the venous capacitance vessels was largely unaffected by naloxone-induced morphine abstinence.