Central nervous system with opioids

Heroin s primary toxic principle is its profound ability to depress the central nervous system (CNS). Opioid analgesics bind with stereospecific receptors at many sites within the CNS. Heroin, similar to other opioids, exerts its pharmacologic effect by acting at mu, kappa, and delta receptors in the brain. Although the precise sites and mechanisms of action have not been fully determined, alterations in the release of various neurotransmitters from afferent nerves sensitive to painful stimuli may be partially responsible for the analgesic effect. Activities associated with the stimulation of opiate receptors are analgesia, euphoria, respiratory depression, miosis, and reduced gastrointestinal motility. 

Opioid-like analgesic activity was observed after intraperitoneal injection of this alkaloid in hot-plate and tail-flick models [137]. Also, intraperitoneal injection of 10 mg kg reduces 5-HT and DA levels (followed up by an increase of 5-HIAA, DOPAC, and HVA levels), showing relevant effect in the central nervous system [139]. Opioid-like denomination suggests morphine-similar effect, being blocked with naloxone-like antagonists. 

In addition to the weU-defined opioid systems in the central nervous system, the three opioid peptides and their precursor mRNA have also been identified in peripheral tissues. ( -Endorphin is most abundant in the pituitary, where it exists in corticotroph cells with ACTH in the anterior lobe and in melanotroph cells with MSH in the intermediate lobe (59). Enkephalin and pre-pro-enkephalin mRNA have been identified in the adrenal medulla (60) and this has been the source of material for many studies of pro-enkephalin synthesis and regulation. Pre-pro-enkephalin mRNA has also been identified in the anterior and posterior lobes of the pituitary (61). mRNA for all three opioid precursors has been identified in the reproductive system (62—64). POMC... 

Severe pain should be treated with an opioid such as morphine, hydromorphone, methadone, or fentanyl. Moderate pain can be treated effectively in most cases with a weak opioid such as codeine or hydrocodone, usually in combination with acetaminophen. Meperidine should be avoided owing to its relatively short analgesic effect and its toxic metabolite, normeperidine. Normeperidine may accumulate with repeated dosing and can lead to central nervous system side effects including seizures. 

The three prototype mixed p agonist/S antagonists described in this chapter have excellent potential as analgesics with low propensity to produce tolerance and dependence. The pseudotetrapeptide DIPP-NH2[ ] has already been shown to produce a potent analgesic effect, less tolerance than morphine, and no physical dependence upon chronic administration. In preliminary experiments, the tetrapeptides DIPP-NH2 and DIPP-NH2[T] were shown to cross the BBB to some extent, but further structural modifications need to be performed in order to improve the BBB penetration of these compounds. The Tyr-Tic dipeptide derivatives can also be expected to penetrate into the central nervous system because they are relatively small, lipophilic molecules. In this context, it is of interest to point out that the structurally related dipeptide H-Dmt-D-Ala-NH-(CH2)3-Ph (SC-39566), a plain p-opioid agonist, produced antinociception in the rat by subcutaneous and oral administration [72], As indicated by the results of the NMR and molecular mechanics studies, the conformation of the cyclic p-casomorphin analogue H-Tyr-c[-D-Orn-2-Nal-D-Pro-Gly-] is stabilized by intramolecular hydrogen bonds. There-... 

Codeine phosphate is still used for diarrhea predominantly based on hypermotility but the longer-acting loperamide is more convenient and has less central nervous system effects. Codeine has an exceptionally low affinity for opioid receptors and its effects are due to the fact that it is converted for approximately 10% to morphine. The active metabolite of morphine, morphine-6-glucuronide, may also accumulate during repeated administration of codeine to patients with impaired renal function. 

The gastrointestinal tract is the only system outside the central nervous system (CNS) with significant concentrations of opioid receptors. This reflects their common embryonic origins. Opioids increase intestinal tone and decrease propulsive peristalsis, resulting in delayed gastric emptying and constipation or ileus. Opioids increase common bile duct pressure and decrease bile production and flow, primarily because of spasm of the sphincter of Oddi. The tone of the bile duct itself is also increased. 

Central nervous system depression is the usual effect of morphine, and sedation and drowsiness are frequently observed with therapeutic doses. When given in the absence of pain morphine may sometimes produce dysphora—an unpleasant sensation of fear and anxiety. The most important stimulatory effects of morphine in man are emesis and miosis. Miosis, due to stimulation of the Edinger-Westphal nucleus of the third nerve, occurs with all opioids. The combination of pinpoint pupils, coma, and respiratory depression are classical signs of morphine overdosage. Stimulation of the solitary nuclei may also be responsible for depression of the cough reflex (antitussive effect). Pharmacokinetics and metabolism... 

Opioid alkaloids (eg, morphine) produce analgesia through actions at receptors in the central nervous system (CNS) that contain peptides with opioid-like pharmacologic properties. The general term currently used for these endogenous substances is endogenous opioid peptides. 

Alvimopan, methylnaltrexone bromide Potent antagonists with poor entry into the central nervous system can be used to treat severe opioid-induced constipation without precipitating an abstinence syndrome ... 

The investigations of Stein (1991) and Stein et al. (1999) have shown that pain-relevant opioid receptors are not only situated in the central nervous system but also in peripheral organs and tissues. Investigations in pain models with peripherally-acting opioids indicate that k-... 

The opium alkaloids codeine and morphine served as models for the synthesis of naloxone, an important analog used to treat and diagnose opiate addicts, and also led to the discovery of endogenous opioids (enkephalins and endorphins) (see Chapter 47). Similarly, A9-tetrahydro-cannabinol (THC), the component of Cannabis sativa responsible for the central nervous system (CNS) effect, has also been found to reduce nausea associated with cancer chemotherapy (see Chapter 18). 

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