Friday, 8 April 2011

Opioid Analgesics

Introduction:

Morphine, the prototypical opioid agonist, has long been known to relieve severe pain with remarkable efficacy. The opium poppy is the source of crude opium from which Sertürner in 1803 isolated morphine, the pure alkaloid, naming it after Morpheus, the Greek god of dreams. It remains the standard against which all drugs that have strong analgesic action are compared. These drugs are collectively known as opioid analgesics and include not only the natural and semisynthetic alkaloid derivatives from opium but also synthetic surrogates, other opioid-like drugs whose actions are blocked by the nonselective antagonist naloxone, plus several endogenous peptides that interact with the different subtypes of opioid receptors.

Basic Pharmacology of the Opioid Analgesics:

Source

Opium, the source of morphine, is obtained from the poppy, Papaver somniferum and P album. After incision, the poppy seed pod exudes a white substance that turns into a brown gum that is crude opium. Opium contains many alkaloids, the principle one being morphine, which is present in a concentration of about 10%. Codeine is synthesized commercially from morphine.

Classification & Chemistry

Opioid drugs include full agonists, partial agonists, and antagonists. Morphine is a full agonist at the (mu)-opioid receptor, the major analgesic opioid receptor. In contrast, codeine functions as a partial (or "weak") -receptor agonist. Other opioid receptor subtypes include (delta) and (kappa) receptors. Simple substitution of an allyl group on the nitrogen of the full agonist morphine plus addition of a single hydroxyl group results in naloxone, a strong -receptor antagonist. Some opioids, eg, nalbuphine, are capable of producing an agonist (or partial agonist) effect at one opioid receptor subtype and an antagonist effect at another. The activating properties of opioid analgesics can be manipulated by pharmaceutical chemistry; in addition, certain opioid analgesics are modified in the liver, resulting in compounds with greater analgesic action. Chemically, the opioids derived from opium are phenanthrene derivatives and include four or more fused rings, while most of the synthetic opioids are simpler molecules.

Opioid Receptor Subtypes, Their Functions, and Their Endogenous Peptide Affinities.

Receptor Subtype
Functions
Endogenous Opioid Peptide Affinity
(mu)
Supraspinal and spinal analgesia; sedation; inhibition of respiration; slowed gastrointestinal transit; modulation of hormone and neurotransmitter release
Endorphins > enkephalins > dynorphins
(delta)
Supraspinal and spinal analgesia; modulation of hormone and neurotransmitter release
Enkephalins > endorphins and dynorphins
(kappa)
Supraspinal and spinal analgesia; psychotomimetic effects; slowed gastrointestinal transit
Dynorphins > > endorphins and enkephalins

Endogenous Opioid Peptides

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.

Three families of endogenous opioid peptides have been described in detail: the endorphins, the pentapeptide enkephalins methionine-enkephalin (met-enkephalin) and leucine-enkephalin (leu-enkephalin), and the dynorphins. The three families of opioid receptors have overlapping affinities for these endogenous peptides.

The endogenous opioid peptides are derived from three precursor proteins: prepro-opiomelanocortin (POMC), preproenkephalin (proenkephalin A), and preprodynorphin (proenkephalin B). POMC contains the met-enkephalin sequence, -endorphin, and several nonopioid peptides, including adrenocorticotropic hormone (ACTH), beta-lipotropin, and melanocyte-stimulating hormone. 
Preproenkephalin contains six copies of met-enkephalin and one copy of leu-enkephalin. Leu- and met-enkephalin have slightly higher affinity for the (delta) than for the mu-opioid receptor. Preprodynorphin yields several active opioid peptides that contain the leu-enkephalin sequence. These are dynorphin A, dynorphin B, and and neoendorphins. The endogenous peptides endomorphin-1 and endomorphin-2 also possess many of the properties of opioid peptides, notably analgesia and high-affinity binding to the receptor. Endomorphin-1 and -2 selectively activate central and peripheral -opioid receptors but much about them remains unknown, including the identity of their preproendomorphin gene. Both the endogenous opioid precursor molecules and the endomorphins are present at CNS sites that have been implicated in pain modulation. Evidence suggests that they can be released during stressful conditions such as pain or the anticipation of pain and diminish the sensation of noxious stimuli. Whether acupuncture releases endogenous opioid peptides is under investigation.

In contrast to the analgesic role of leu- and met-enkephalin, an analgesic action of dynorphin A—through its binding to (kappa) opioid receptors—remains controversial. Dynorphin A is also found in the dorsal horn of the spinal cord, where it may play a critical role in the sensitization  of nociceptive neurotransmission. Increased levels of dynorphin can be found in the dorsal horn after tissue injury and inflammation. This elevated dynorphin level is proposed to increase pain and induce a state of long-lasting hyperalgesia. The pronociceptive action of dynorphin in the spinal cord appears to be independent of the opioid receptor system but dependent on the activation of the bradykinin receptor. Moreover, dynorphin A can bind and activate the N -methyl-D-aspartate (NMDA) receptor complex, a site of action that is the focus of intense therapeutic development.

Recently, a novel receptor-ligand system homologous to the opioid peptides has been found. The principle receptor for this system is the G protein-coupled orphanin opioid-receptor-likesubtype 1 (ORL1). Its endogenous ligand has been termed nociceptin by one group of investigators and orphanin FQ by another group. This ligand-receptor system is currently known as the N/OFQ system. Nociceptin is structurally similar to dynorphin except for the absence of an N-terminal tyrosine; it acts only at the ORL1 receptor, now known as NOP. The N/OFQ system is widely expressed in the CNS and periphery, reflecting its equally diverse biology and pharmacology. As a result of experiments using highly selective NOP receptor ligands, the N/OFQ system has been implicated in both pro- and anti-nociceptive activity as well as in the modulation of drug reward, learning, mood, anxiety, and cough processes, and of parkinsonism.

0 comments:

Post a Comment

 
Design by Wordpress Theme | Bloggerized by Free Blogger Templates | Free Samples