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(Redirected from Opioid agonist) Psychoactive chemical

Opioid
Drug class
Chemical structure of morphine, the prototypical opioid.
Class identifiers
UsePain relief
ATC codeN02A
Mode of actionOpioid receptor
External links
MeSHD000701
Legal status
In Wikidata

Opioids are a class of drugs that derive from, or mimic, natural substances found in the opium poppy plant. Opioids work in the brain to produce a variety of effects, including pain relief. As a class of substances, they act on opioid receptors to produce morphine-like effects.

The terms 'opioid' and 'opiate' are sometimes used interchangeably, but there are key differences based on the manufacturing processes of these medications.

Medically they are primarily used for pain relief, including anesthesia. Other medical uses include suppression of diarrhea, replacement therapy for opioid use disorder, reversing opioid overdose, and suppressing cough. Extremely potent opioids such as carfentanil are approved only for veterinary use. Opioids are also frequently used recreationally for their euphoric effects or to prevent withdrawal. Opioids can cause death and have been used for executions in the United States.

Side effects of opioids may include itchiness, sedation, nausea, respiratory depression, constipation, and euphoria. Long-term use can cause tolerance, meaning that increased doses are required to achieve the same effect, and physical dependence, meaning that abruptly discontinuing the drug leads to unpleasant withdrawal symptoms. The euphoria attracts recreational use, and frequent, escalating recreational use of opioids typically results in addiction. An overdose or concurrent use with other depressant drugs like benzodiazepines commonly results in death from respiratory depression.

Opioids act by binding to opioid receptors, which are found principally in the central and peripheral nervous system and the gastrointestinal tract. These receptors mediate both the psychoactive and the somatic effects of opioids. Opioid drugs include partial agonists, like the anti-diarrhea drug loperamide and antagonists like naloxegol for opioid-induced constipation, which do not cross the blood–brain barrier, but can displace other opioids from binding to those receptors in the myenteric plexus.

Because opioids are addictive and may result in fatal overdose, most are controlled substances. In 2013, between 28 and 38 million people used opioids illicitly (0.6% to 0.8% of the global population between the ages of 15 and 65). In 2011, an estimated 4 million people in the United States used opioids recreationally or were dependent on them. As of 2015, increased rates of recreational use and addiction are attributed to over-prescription of opioid medications and inexpensive illicit heroin. Conversely, fears about overprescribing, exaggerated side effects, and addiction from opioids are similarly blamed for under-treatment of pain.

Educational video on opioid dependence.

Terminology

Opiates v. opioids with chemical structures indicated. Many classical opiates are also referred to as opioids in modern nomenclature.
Opiates and opioids with chemical structures indicated. Many classical opiates are also referred to as opioids in modern nomenclature.

Opioids include opiates, an older term that refers to such drugs derived from opium, including morphine itself. Other opioids are semi-synthetic and synthetic drugs such as hydrocodone, oxycodone, and fentanyl; antagonist drugs such as naloxone; and endogenous peptides such as endorphins. The terms opiate and narcotic are sometimes encountered as synonyms for opioid. Opiate is properly limited to the natural alkaloids found in the resin of the opium poppy although some include semi-synthetic derivatives. Narcotic, derived from words meaning 'numbness' or 'sleep', as an American legal term, refers to cocaine and opioids, and their source materials; it is also loosely applied to any illegal or controlled psychoactive drug. In some jurisdictions all controlled drugs are legally classified as narcotics. The term can have pejorative connotations and its use is generally discouraged where that is the case.

Medical uses

Pain

The weak opioid codeine, in low doses and combined with one or more other drugs, is commonly available in prescription medicines and without a prescription to treat mild pain. Other opioids are usually reserved for the relief of moderate to severe pain.

Acute pain

Opioids are effective for the treatment of acute pain (such as pain following surgery). For immediate relief of moderate to severe acute pain, opioids are frequently the treatment of choice due to their rapid onset, efficacy and reduced risk of dependence. However, a new report showed a clear risk of prolonged opioid use when opioid analgesics are initiated for an acute pain management following surgery or trauma. They have also been found to be important in palliative care to help with the severe, chronic, disabling pain that may occur in some terminal conditions such as cancer, and degenerative conditions such as rheumatoid arthritis. In many cases opioids are a successful long-term care strategy for those with chronic cancer pain.

Just over half of all states in the US have enacted laws that restrict the prescribing or dispensing of opioids for acute pain.

Chronic non-cancer pain

Guidelines have suggested that the risk of opioids is likely greater than their benefits when used for most non-cancer chronic conditions including headaches, back pain, and fibromyalgia. Thus they should be used cautiously in chronic non-cancer pain. If used the benefits and harms should be reassessed at least every three months.

In treating chronic pain, opioids are an option to be tried after other less risky pain relievers have been considered, including paracetamol or NSAIDs like ibuprofen or naproxen. Some types of chronic pain, including the pain caused by fibromyalgia or migraine, are preferentially treated with drugs other than opioids. The efficacy of using opioids to lessen chronic neuropathic pain is uncertain.

Opioids are contraindicated as a first-line treatment for headache because they impair alertness, bring risk of dependence, and increase the risk that episodic headaches will become chronic. Opioids can also cause heightened sensitivity to headache pain. When other treatments fail or are unavailable, opioids may be appropriate for treating headache if the patient can be monitored to prevent the development of chronic headache.

Opioids are being used more frequently in the management of non-malignant chronic pain. This practice has now led to a new and growing problem with addiction and misuse of opioids. Because of various negative effects the use of opioids for long-term management of chronic pain is not indicated unless other less risky pain relievers have been found ineffective. Chronic pain which occurs only periodically, such as that from nerve pain, migraines, and fibromyalgia, frequently is better treated with medications other than opioids. Paracetamol and nonsteroidal anti-inflammatory drugs including ibuprofen and naproxen are considered safer alternatives. They are frequently used combined with opioids, such as paracetamol combined with oxycodone (Percocet) and ibuprofen combined with hydrocodone (Vicoprofen), which boosts the pain relief but is also intended to deter recreational use.

Other

Cough

Codeine was once viewed as the "gold standard" in cough suppressants, but this position is now questioned. Some recent placebo-controlled trials have found that it may be no better than a placebo for some causes including acute cough in children. As a consequence, it is not recommended for children. Additionally, there is no evidence that hydrocodone is useful in children. Similarly, a 2012 Dutch guideline regarding the treatment of acute cough does not recommend its use. (The opioid analogue dextromethorphan, long claimed to be as effective a cough suppressant as codeine, has similarly demonstrated little benefit in several recent studies.)

Low dose morphine may help chronic cough but its use is limited by side effects.

Diarrhea

In cases of diarrhea-predominate irritable bowel syndrome, opioids may be used to suppress diarrhea. Loperamide is a peripherally selective opioid available without a prescription used to suppress diarrhea.

The ability to suppress diarrhea also produces constipation when opioids are used beyond several weeks. Naloxegol, a peripherally-selective opioid antagonist is now available to treat opioid induced constipation.

Shortness of breath

Opioids may help with shortness of breath particularly in advanced diseases such as cancer and COPD among others. However, findings from two recent systematic reviews of the literature found that opioids were not necessarily more effective in treating shortness of breath in patients who have advanced cancer.

Restless legs syndrome

Though not typically a first line of treatment, opioids, such as oxycodone and methadone, are sometimes used in the treatment of severe and refractory restless legs syndrome.

Hyperalgesia

Main article: Opioid-induced hyperalgesia

Opioid-induced hyperalgesia (OIH) has been evident in patients after chronic opioid exposure.

Adverse effects

See also: Opioid overdose Adverse effects of opioids

Common and short term

Other

Each year 69,000 people worldwide die of opioid overdose, and 15 million people have an opioid addiction.

In older adults, opioid use is associated with increased adverse effects such as "sedation, nausea, vomiting, constipation, urinary retention, and falls". As a result, older adults taking opioids are at greater risk for injury. Opioids do not cause any specific organ toxicity, unlike many other drugs, such as aspirin and paracetamol. They are not associated with upper gastrointestinal bleeding and kidney toxicity.

Prescription of opioids for acute low back pain and management of osteoarthritis seem to have long-term adverse effects

According to the USCDC, methadone was involved in 31% of opioid related deaths in the US between 1999–2010 and 40% as the sole drug involved, far higher than other opioids. Studies of long term opioids have found that many stop them, and that minor side effects were common. Addiction occurred in about 0.3%. In the United States in 2016 opioid overdose resulted in the death of 1.7 in 10,000 people.

Reinforcement disorders

Main article: Opioid use disorder

Tolerance

Tolerance is a process characterized by neuroadaptations that result in reduced drug effects. While receptor upregulation may often play an important role other mechanisms are also known. Tolerance is more pronounced for some effects than for others; tolerance occurs slowly to the effects on mood, itching, urinary retention, and respiratory depression, but occurs more quickly to the analgesia and other physical side effects. However, tolerance does not develop to constipation or miosis (the constriction of the pupil of the eye to less than or equal to two millimeters). This idea has been challenged, however, with some authors arguing that tolerance does develop to miosis.

Tolerance to opioids is attenuated by a number of substances, including:

Tolerance is a physiologic process where the body adjusts to a medication that is frequently present, usually requiring higher doses of the same medication over time to achieve the same effect. It is a common occurrence in individuals taking high doses of opioids for extended periods, but does not predict any relationship to misuse or addiction.

Physical dependence

Physical dependence is the physiological adaptation of the body to the presence of a substance, in this case opioid medication. It is defined by the development of withdrawal symptoms when the substance is discontinued, when the dose is reduced abruptly or, specifically in the case of opioids, when an antagonist (e.g., naloxone) or an agonist-antagonist (e.g., pentazocine) is administered. Physical dependence is a normal and expected aspect of certain medications and does not necessarily imply that the patient is addicted.

The withdrawal symptoms for opiates may include severe dysphoria, craving for another opiate dose, irritability, sweating, nausea, rhinorrea, tremor, vomiting and myalgia. Slowly reducing the intake of opioids over days and weeks can reduce or eliminate the withdrawal symptoms. The speed and severity of withdrawal depends on the half-life of the opioid; heroin and morphine withdrawal occur more quickly than methadone withdrawal. The acute withdrawal phase is often followed by a protracted phase of depression and insomnia that can last for months. The symptoms of opioid withdrawal can be treated with other medications, such as clonidine. Physical dependence does not predict drug misuse or true addiction, and is closely related to the same mechanism as tolerance. While there is anecdotal claims of benefit with ibogaine, data to support its use in substance dependence is poor.

Critical patients who received regular doses of opioids experience iatrogenic withdrawal as a frequent syndrome.

Addiction

Drug addiction is a complex set of behaviors typically associated with misuse of certain drugs, developing over time and with higher drug dosages. Addiction includes psychological compulsion, to the extent that the affected person persists in actions leading to dangerous or unhealthy outcomes. Opioid addiction includes insufflation or injection, rather than taking opioids orally as prescribed for medical reasons.

In European nations such as Austria, Bulgaria, and Slovakia, slow-release oral morphine formulations are used in opiate substitution therapy (OST) for patients who do not well tolerate the side effects of buprenorphine or methadone. Buprenorphine can also be used together with naloxone for a longer treatment of addiction. In other European countries including the UK, this is also legally used for OST although on a varying scale of acceptance.

Slow-release formulations of medications are intended to curb misuse and lower addiction rates while trying to still provide legitimate pain relief and ease of use to pain patients. Questions remain, however, about the efficacy and safety of these types of preparations. Further tamper resistant medications are currently under consideration with trials for market approval by the FDA.

The amount of evidence available only permits making a weak conclusion, but it suggests that a physician properly managing opioid use in patients with no history of substance use disorder can give long-term pain relief with little risk of developing addiction, or other serious side effects.

Problems with opioids include the following:

  1. Some people find that opioids do not relieve all of their pain.
  2. Some people find that opioids side effects cause problems which outweigh the therapy's benefit.
  3. Some people build tolerance to opioids over time. This requires them to increase their drug dosage to maintain the benefit, and that in turn also increases the unwanted side effects.
  4. Long-term opioid use can cause opioid-induced hyperalgesia, which is a condition in which the patient has increased sensitivity to pain.

All of the opioids can cause side effects. Common adverse reactions in patients taking opioids for pain relief include nausea and vomiting, drowsiness, itching, dry mouth, dizziness, and constipation.

Nausea and vomiting

Tolerance to nausea occurs within 7–10 days, during which antiemetics (e.g. low dose haloperidol once at night) are very effective. Due to severe side effects such as tardive dyskinesia, haloperidol is now rarely used. A related drug, prochlorperazine is more often used, although it has similar risks. Stronger antiemetics such as ondansetron or tropisetron are sometimes used when nausea is severe or continuous and disturbing, despite their greater cost. A less expensive alternative is dopamine antagonists such as domperidone and metoclopramide. Domperidone does not cross the blood–brain barrier and produce adverse central antidopaminergic effects, but blocks opioid emetic action in the chemoreceptor trigger zone. This drug is not available in the U.S.

Some antihistamines with anticholinergic properties (e.g. orphenadrine, diphenhydramine) may also be effective. The first-generation antihistamine hydroxyzine is very commonly used, with the added advantages of not causing movement disorders, and also possessing analgesic-sparing properties. Δ-tetrahydrocannabinol relieves nausea and vomiting; it also produces analgesia that may allow lower doses of opioids with reduced nausea and vomiting.

Vomiting is due to gastric stasis (large volume vomiting, brief nausea relieved by vomiting, oesophageal reflux, epigastric fullness, early satiation), besides direct action on the chemoreceptor trigger zone of the area postrema, the vomiting centre of the brain. Vomiting can thus be prevented by prokinetic agents (e.g. domperidone or metoclopramide). If vomiting has already started, these drugs need to be administered by a non-oral route (e.g. subcutaneous for metoclopramide, rectally for domperidone).

Evidence suggests that opioid-inclusive anaesthesia is associated with postoperative nausea and vomiting.

Patients with chronic pain using opioids had small improvements in pain and physically functioning and increased risk of vomiting.

Drowsiness

Tolerance to drowsiness usually develops over 5–7 days, but if troublesome, switching to an alternative opioid often helps. Certain opioids such as fentanyl, morphine and diamorphine (heroin) tend to be particularly sedating, while others such as oxycodone, tilidine and meperidine (pethidine) tend to produce comparatively less sedation, but individual patients responses can vary markedly and some degree of trial and error may be needed to find the most suitable drug for a particular patient. Otherwise, treatment with CNS stimulants is generally effective.

Itching

Itching tends not to be a severe problem when opioids are used for pain relief, but antihistamines are useful for counteracting itching when it occurs. Non-sedating antihistamines such as fexofenadine are often preferred as they avoid increasing opioid induced drowsiness. However, some sedating antihistamines such as orphenadrine can produce a synergistic pain relieving effect permitting smaller doses of opioids be used. Consequently, several opioid/antihistamine combination products have been marketed, such as Meprozine (meperidine/promethazine) and Diconal (dipipanone/cyclizine), and these may also reduce opioid induced nausea.

Constipation

Opioid-induced constipation (OIC) develops in 90 to 95% of people taking opioids long-term. Since tolerance to this problem does not generally develop, most people on long-term opioids need to take a laxative or enemas.

Treatment of OIC is successional and dependent on severity. The first mode of treatment is non-pharmacological, and includes lifestyle modifications like increasing dietary fiber, fluid intake (around 1.5 L (51 US fl oz) per day), and physical activity. If non-pharmacological measures are ineffective, laxatives, including stool softeners (e.g., polyethylene glycol), bulk-forming laxatives (e.g., fiber supplements), stimulant laxatives (e.g., bisacodyl, senna), and/or enemas, may be used. A common laxative regimen for OIC is the combination of docusate and bisacodyl. Osmotic laxatives, including lactulose, polyethylene glycol, and milk of magnesia (magnesium hydroxide), as well as mineral oil (a lubricant laxative), are also commonly used for OIC.

If laxatives are insufficiently effective (which is often the case), opioid formulations or regimens that include a peripherally-selective opioid antagonist, such as methylnaltrexone bromide, naloxegol, alvimopan, or naloxone (as in oxycodone/naloxone), may be tried. A 2018 (updated in 2022) Cochrane review found that the evidence was moderate for alvimopan, naloxone, or methylnaltrexone bromide but with increased risk of adverse events. Naloxone by mouth appears to be the most effective. A daily 0.2 mg dose of naldemedine has been shown to significantly improve symptoms in patients with OIC.

Opioid rotation is one method suggested to minimise the impact of constipation in long-term users. While all opioids cause constipation, there are some differences between drugs, with studies suggesting tramadol, tapentadol, methadone and fentanyl may cause relatively less constipation, while with codeine, morphine, oxycodone or hydromorphone constipation may be comparatively more severe.

Respiratory depression

Respiratory depression is the most serious adverse reaction associated with opioid use, but it usually is seen with the use of a single, intravenous dose in an opioid-naïve patient. In patients taking opioids regularly for pain relief, tolerance to respiratory depression occurs rapidly, so that it is not a clinical problem. Several drugs have been developed which can partially block respiratory depression, although the only respiratory stimulant currently approved for this purpose is doxapram, which has only limited efficacy in this application. Newer drugs such as BIMU-8 and CX-546 may be much more effective.

  • Respiratory stimulants: carotid chemoreceptor agonists (e.g. doxapram), 5-HT4 agonists (e.g. BIMU8), δ-opioid agonists (e.g. BW373U86) and AMPAkines (e.g. CX717) can all reduce respiratory depression caused by opioids without affecting analgesia, but most of these drugs are only moderately effective or have side effects which preclude use in humans. 5-HT1A agonists such as 8-OH-DPAT and repinotan also counteract opioid-induced respiratory depression, but at the same time reduce analgesia, which limits their usefulness for this application.
  • Opioid antagonists (e.g. naloxone, nalmefene, diprenorphine)

The initial 24 hours after opioid administration appear to be the most critical with regard to life-threatening OIRD, but may be preventable with a more cautious approach to opioid use.

Patients with cardiac, respiratory disease and/or obstructive sleep apnoea are at increased risk for OIRD.

Increased pain sensitivity

Main article: Opioid-induced hyperalgesia

Opioid-induced hyperalgesia – where individuals using opioids to relieve pain paradoxically experience more pain as a result of that medication – has been observed in some people. This phenomenon, although uncommon, is seen in some people receiving palliative care, most often when dose is increased rapidly. If encountered, rotation between several different opioid pain medications may decrease the development of increased pain. Opioid induced hyperalgesia more commonly occurs with chronic use or brief high doses but some research suggests that it may also occur with very low doses.

Side effects such as hyperalgesia and allodynia, sometimes accompanied by a worsening of neuropathic pain, may be consequences of long-term treatment with opioid analgesics, especially when increasing tolerance has resulted in loss of efficacy and consequent progressive dose escalation over time. This appears to largely be a result of actions of opioid drugs at targets other than the three classic opioid receptors, including the nociceptin receptor, sigma receptor and Toll-like receptor 4, and can be counteracted in animal models by antagonists at these targets such as J-113,397, BD-1047 or (+)-naloxone respectively. No drugs are currently approved specifically for counteracting opioid-induced hyperalgesia in humans and in severe cases the only solution may be to discontinue use of opioid analgesics and replace them with non-opioid analgesic drugs. However, since individual sensitivity to the development of this side effect is highly dose dependent and may vary depending which opioid analgesic is used, many patients can avoid this side effect simply through dose reduction of the opioid drug (usually accompanied by the addition of a supplemental non-opioid analgesic), rotating between different opioid drugs, or by switching to a milder opioid with a mixed mode of action that also counteracts neuropathic pain, particularly tramadol or tapentadol.

Other adverse effects

Low sex hormone levels

Clinical studies have consistently associated medical and recreational opioid use with hypogonadism (low sex hormone levels) in different sexes. The effect is dose-dependent. Most studies suggest that the majority (perhaps as much as 90%) of chronic opioid users develop hypogonadism. A 2015 systematic review and meta-analysis found that opioid therapy suppressed testosterone levels in men by about 165 ng/dL (5.7 nmol/L) on average, which was a reduction in testosterone level of almost 50%. Conversely, opioid therapy did not significantly affect testosterone levels in women. However, opioids can also interfere with menstruation in women by limiting the production of luteinizing hormone (LH). Opioid-induced hypogonadism likely causes the strong association of opioid use with osteoporosis and bone fracture, due to deficiency in estradiol. It also may increase pain and thereby interfere with the intended clinical effect of opioid treatment. Opioid-induced hypogonadism is likely caused by their agonism of opioid receptors in the hypothalamus and the pituitary gland. One study found that the depressed testosterone levels of heroin addicts returned to normal within one month of abstinence, suggesting that the effect is readily reversible and is not permanent. As of 2013, the effect of low-dose or acute opioid use on the endocrine system is unclear. Long-term use of opioids can affect the other hormonal systems as well.

Disruption of work

Use of opioids may be a risk factor for failing to return to work.

Persons performing any safety-sensitive task should not use opioids. Health care providers should not recommend that workers who drive or use heavy equipment including cranes or forklifts treat chronic or acute pain with opioids. Workplaces which manage workers who perform safety-sensitive operations should assign workers to less sensitive duties for so long as those workers are treated by their physician with opioids.

People who take opioids long term have increased likelihood of being unemployed. Taking opioids may further disrupt the patient's life and the adverse effects of opioids themselves can become a significant barrier to patients having an active life, gaining employment, and sustaining a career.

In addition, lack of employment may be a predictor of aberrant use of prescription opioids.

Increased accident-proneness

Opioid use may increase accident-proneness. Opioids may increase risk of traffic accidents and accidental falls.

Reduced Attention

Opioids have been shown to reduce attention, more so when used with antidepressants and/or anticonvulsants.

Rare side effects

Infrequent adverse reactions in patients taking opioids for pain relief include: dose-related respiratory depression (especially with more potent opioids), confusion, hallucinations, delirium, urticaria, hypothermia, bradycardia/tachycardia, orthostatic hypotension, dizziness, headache, urinary retention, ureteric or biliary spasm, muscle rigidity, myoclonus (with high doses), and flushing (due to histamine release, except fentanyl and remifentanil). Both therapeutic and chronic use of opioids can compromise the function of the immune system. Opioids decrease the proliferation of macrophage progenitor cells and lymphocytes, and affect cell differentiation (Roy & Loh, 1996). Opioids may also inhibit leukocyte migration. However the relevance of this in the context of pain relief is not known.

Pregnancy

This section is an excerpt from Opioids and pregnancy.

Opioid use during pregnancy can have significant implications for both the mother and the developing fetus.

Opioids are a class of drugs that include prescription painkillers (e.g., oxycodone, hydrocodone) and illicit substances like heroin. Opioid use during pregnancy is associated with an increased risk of complications, including an elevated risk of preterm birth, low birth weight, intrauterine growth restriction, and stillbirth. Opioids are substances that can cross the placenta, exposing the developing fetus to the drugs. This exposure can potentially lead to various adverse effects on fetal development, including an increased risk of birth defects. One of the most well-known consequences of maternal opioid use during pregnancy is the risk of neonatal abstinence syndrome (NAS). NAS occurs when the newborn experiences withdrawal symptoms after birth due to exposure to opioids in the womb. Maternal opioid use during pregnancy can also have long-term effects on the child's development. These effects may include cognitive and behavioral problems, as well as an increased risk of substance use disorders later in life.

Interactions

Physicians treating patients using opioids in combination with other drugs keep continual documentation that further treatment is indicated and remain aware of opportunities to adjust treatment if the patient's condition changes to merit less risky therapy.

With other depressant drugs

The concurrent use of opioids with other depressant drugs such as benzodiazepines or ethanol increases the rates of adverse events and overdose. Despite this, opioids and benzodiazepines are concurrently dispensed in many settings. As with an overdose of opioid alone, the combination of an opioid and another depressant may precipitate respiratory depression often leading to death. These risks are lessened with close monitoring by a physician, who may conduct ongoing screening for changes in patient behavior and treatment compliance.

Opioid antagonist

Main article: Opioid antagonist

Opioid effects (adverse or otherwise) can be reversed with an opioid antagonist such as naloxone or naltrexone. These competitive antagonists bind to the opioid receptors with higher affinity than agonists but do not activate the receptors. This displaces the agonist, attenuating or reversing the agonist effects. However, the elimination half-life of naloxone can be shorter than that of the opioid itself, so repeat dosing or continuous infusion may be required, or a longer acting antagonist such as nalmefene may be used. In patients taking opioids regularly it is essential that the opioid is only partially reversed to avoid a severe and distressing reaction of waking in excruciating pain. This is achieved by not giving a full dose but giving this in small doses until the respiratory rate has improved. An infusion is then started to keep the reversal at that level, while maintaining pain relief. Opioid antagonists remain the standard treatment for respiratory depression following opioid overdose, with naloxone being by far the most commonly used, although the longer acting antagonist nalmefene may be used for treating overdoses of long-acting opioids such as methadone, and diprenorphine is used for reversing the effects of extremely potent opioids used in veterinary medicine such as etorphine and carfentanil. However, since opioid antagonists also block the beneficial effects of opioid analgesics, they are generally useful only for treating overdose, with use of opioid antagonists alongside opioid analgesics to reduce side effects, requiring careful dose titration and often being poorly effective at doses low enough to allow analgesia to be maintained.

Naltrexone does not appear to increase risk of serious adverse events, which confirms the safety of oral naltrexone. Mortality or serious adverse events due to rebound toxicity in patients with naloxone were rare.

Pharmacology

See also: Opioid receptor
Opioid comparison
Drug Relative
Potency
Nonionized
Fraction
Protein
Binding
Lipid
Solubility
Morphine 1 ++ ++ ++
Pethidine (meperidine) 0.1 + +++ +++
Hydromorphone 10 + +++
Alfentanil 10–25 ++++ ++++ +++
Fentanyl 50–100 + +++ ++++
Remifentanil 250 +++ +++ ++
Sufentanil 500–1000 ++ ++++ ++++
Etorphine 1000–3000
Carfentanil 10000

Opioids bind to specific opioid receptors in the nervous system and other tissues. There are three principal classes of opioid receptors, μ, κ, δ (mu, kappa, and delta), although up to seventeen have been reported, and include the ε, ι, λ, and ζ (Epsilon, Iota, Lambda and Zeta) receptors. Conversely, σ (Sigma) receptors are no longer considered to be opioid receptors because their activation is not reversed by the opioid inverse-agonist naloxone, they do not exhibit high-affinity binding for classical opioids, and they are stereoselective for dextro-rotatory isomers while the other opioid receptors are stereo-selective for levo-rotatory isomers. In addition, there are three subtypes of μ-receptor: μ1 and μ2, and the newly discovered μ3. Another receptor of clinical importance is the opioid-receptor-like receptor 1 (ORL1), which is involved in pain responses as well as having a major role in the development of tolerance to μ-opioid agonists used as analgesics. These are all G-protein coupled receptors acting on GABAergic neurotransmission.

Locants of the morphine molecule

The pharmacodynamic response to an opioid depends upon the receptor to which it binds, its affinity for that receptor, and whether the opioid is an agonist or an antagonist. For example, the supraspinal analgesic properties of the opioid agonist morphine are mediated by activation of the μ1 receptor; respiratory depression and physical dependence by the μ2 receptor; and sedation and spinal analgesia by the κ receptor. Each group of opioid receptors elicits a distinct set of neurological responses, with the receptor subtypes (such as μ1 and μ2 for example) providing even more specific responses. Unique to each opioid is its distinct binding affinity to the various classes of opioid receptors (e.g. the μ, κ, and δ opioid receptors are activated at different magnitudes according to the specific receptor binding affinities of the opioid). For example, the opiate alkaloid morphine exhibits high-affinity binding to the μ-opioid receptor, while ketazocine exhibits high affinity to ĸ receptors. It is this combinatorial mechanism that allows for such a wide class of opioids and molecular designs to exist, each with its own unique effect profile. Their individual molecular structure is also responsible for their different duration of action, whereby metabolic breakdown (such as N-dealkylation) is responsible for opioid metabolism.

INTA: selective agonist of KOR-DOR and KOR-MOR heteromers. Does not recruit β-arrestin II. Antinociceptive devoid of aversion, tolerance, and dependence in mice.

Functional selectivity

A new strategy of drug development takes receptor signal transduction into consideration. This strategy strives to increase the activation of desirable signalling pathways while reducing the impact on undesirable pathways. This differential strategy has been given several names, including functional selectivity and biased agonism. The first opioid that was intentionally designed as a biased agonist and placed into clinical evaluation is the drug oliceridine. It displays analgesic activity and reduced adverse effects.

Opioid comparison

Main article: Equianalgesic

Extensive research has been conducted to determine equivalence ratios comparing the relative potency of opioids. Given a dose of an opioid, an equianalgesic table is used to find the equivalent dosage of another. Such tables are used in opioid rotation practices, and to describe an opioid by comparison to morphine, the reference opioid. Equianalgesic tables typically list drug half-lives, and sometimes equianalgesic doses of the same drug by means of administration, such as morphine: oral and intravenous.

Binding profiles

Binding profiles of opioids at opioid receptors (Ki, nM)
Compound MORTooltip mu-Opioid receptor DORTooltip delta-Opioid receptor KORTooltip kappa-Opioid receptor Ref
3-HO-PCP 60 2,300 140
7-Hydroxymitragynine 13.5 155 123
β-Chlornaltrexamine 0.90 115 0.083
β-Endorphin 1.0 1.0 52
β-Funaltrexamine 0.33 48 2.8
(+)-cis-3-methylfentanyl 0.24 ND ND
Alazocine 2.7 4.1 3.2
(−)-Alazocine 3.0 15 4.7
(+)-Alazocine 1,900 19,000 1,600
Alfentanil 39 21,200 ND
Binaltorphimine 1.3 5.8 0.79
BNTXTooltip 7-Benzylidenenaltrexone 18 0.66 55
Bremazocine 0.75 2.3 0.089
(−)-Bremazocine 0.62 0.78 0.075
Buprenorphine 4.18 25.8 12.9
Butorphanol 1.7 13 7.4
BW-3734 26 0.013 17
Carfentanil 0.024 3.3 43
Cebranopadol 0.7 18 2.6
Codeine 79 >1,000 >1,000
CTOP 0.18 >1,000 >1,000
Cyclazocine 0.45 6.3 5.9
Cyprodime 9.4 356 176
DADLE 16 0.74 >1,000
DAMGO 2.0 >1,000 >1,000
Deltorphin II >1,000 3.3 >1,000
Dermorphin 0.33 >1,000 >1,000
(+)-Desmetramadol (O-DSMT) 17 690 1,800
Dextropropoxyphene 34.5 380 1,220
Dezocine 3.6 290 460
Dihydroetorphine 0.45 1.82 0.57
Dihydromorphine 2.5 137 223
Diprenorphine 0.072 0.23 0.017
DPDPE >1,000 14 >1,000
DSLET 39 4.8 >1,000
Dynorphin A 32 >1,000 0.5
Ethylketazocine 3.1 101 0.40
(−)-Ethylketazocine 2.3 5.2 2.2
(+)-Ethylketazocine 2,500 >10,000 1,600
Etorphine 0.23 1.4 0.13
Fentanyl 0.39 >1,000 255
Hydrocodone 11.1 962 501
Hydromorphone 0.47 18.5 24.9
ICI-204488 >1,000 >1,000 0.71
Leu-enkephalin 3.4 4.0 >1,000
Levacetylmethadol 9.86 169 1,020
Lofentanil 0.68 5.5 5.9
Met-enkephalin 0.65 1.7 >1,000
Metazocine 3.8 44.3 13.3
Methadone 1.7 435 405
Dextromethadone 19.7 960 1,370
Levomethadone 0.945 371 1,860
Methallorphan ND ND ND ND
Dextrallorphan 1,140 2,660 34.6
Levallorphan 0.213 2.18 1,100
Methorphan ND ND ND ND
Dextromethorphan 1,280 11,500 7,000
Levomethorphan 11.2 249 225
Mitragynine 7.24 60.3 1,100
Mitragynine pseudoindoxyl 0.087 3.02 79.4
Morphanol ND ND ND ND
Dextrorphan 420 34,700 5,950
Levorphanol 0.42 3.61 4.2
Morphiceptin 56 >1,000 >1,000
Morphine 1.8 90 317
Morphine, (−)- 1.24 145 23.4
Morphine, (+)- >10,000 >100,000 >300,000
MR-2266 1.0 3.0 0.16
Nalbuphine 11 >1,000 3.9
Nalmefene 0.24 16 0.083
Nalorphine 0.97 148 1.1
Naloxonazine 0.054 8.6 11
Naloxone 1.1 16 12
(−)-Naloxone 0.93 17 2.3
(+)-Naloxone >1,000 >1,000 >1,000
Naltrexone 1.0 149 3.9
Naltriben 12 0.013 13
Naltrindole 64 0.02 66
Norbinaltorphimine 2.2 65 0.027
Normorphine 4.0 310 149
Ohmefentanyl 0.0079 10 32
Oxycodone 8.69 901 1,350
Oxymorphindole 111 0.7 228
Oxymorphone 0.78 50 137
Pentazocine 5.7 31 7.2
Pethidine (meperidine) 385 4,350 5,140
Phenazocine 0.20 5.0 2.0
PLO17 30 >1,000 >1,000
Quadazocine 0.99 2.6 0.5
Salvinorin A >10,000 >10,000 16
Samidorphan 0.052 2.6 0.23
SIOMTooltip 7-Spiroindinooxymorphone 33 1.7 >1,000
Spiradoline 21 >1,000 0.036
Sufentanil 0.15 50 75
Tianeptine 383 >10,000 >10,000
Tifluadom 32 189 2.1
Tramadol 2,120 57,700 42,700
(+)-Tramadol 1,330 62,400 54,000
(−)-Tramadol 24,800 213,000 53,500
U-47700 11.1 1,220 287
U-50488 >1,000 >1,000 0.12
U-69593 >1,000 >1,000 0.59
U-77891 2 105 2,300
Xorphanol 0.25 1.0 0.4
Values are Ki (nM), unless otherwise noted. The smaller the value, the more strongly the drug binds to the site. Assays were done mostly with cloned or cultured rodent receptors.

Usage

Global estimates of drug users in 2016
(in millions of users)
Substance Best
estimate
Low
estimate
High
estimate
Amphetamine-
type stimulants
34.16 13.42 55.24
Cannabis 192.15 165.76 234.06
Cocaine 18.20 13.87 22.85
Ecstasy 20.57 8.99 32.34
Opiates 19.38 13.80 26.15
Opioids 34.26 27.01 44.54

Opioid prescriptions in the US increased from 76 million in 1991 to 207 million in 2013.

In the 1990s, opioid prescribing increased significantly. Once used almost exclusively for the treatment of acute pain or pain due to cancer, opioids are now prescribed liberally for people experiencing chronic pain. This has been accompanied by rising rates of accidental addiction and accidental overdoses leading to death. According to the International Narcotics Control Board, the United States and Canada lead the per capita consumption of prescription opioids. The number of opioid prescriptions per capita in the United States and Canada is double the consumption in the European Union, Australia, and New Zealand. Certain populations have been affected by the opioid addiction crisis more than others, including First World communities and low-income populations. Public health specialists say that this may result from the unavailability or high cost of alternative methods for addressing chronic pain. Opioids have been described as a cost-effective treatment for chronic pain, but the impact of the opioid epidemic and deaths caused by opioid overdoses should be considered in assessing their cost-effectiveness. Data from 2017 suggest that in the U.S. about 3.4 percent of the U.S. population are prescribed opioids for daily pain management. Calls for opioid deprescribing have led to broad scale opioid tapering practices with little scientific evidence to support the safety or benefit for patients with chronic pain.

History

Naturally occurring opioids

A sample of raw opium

Opioids are among the world's oldest known drugs. The earliest known evidence of Papaver somniferum in a human archaeological site dates to the Neolithic period around 5,700–5,500 BCE. Its seeds have been found at Cueva de los Murciélagos in the Iberian Peninsula and La Marmotta in the Italian Peninsula.

Use of the opium poppy for medical, recreational, and religious purposes can be traced to the fourth century BC, when ideograms on Sumerians clay tablets mention the use of "Hul Gil", a "plant of joy". Opium was known to the Egyptians, and is mentioned in the Ebers Papyrus as an ingredient in a mixture for the soothing of children, and for the treatment of breast abscesses.

Opium was also known to the Greeks. It was valued by Hippocrates (c. 460 – c. 370 BC) and his students for its sleep-inducing properties, and used for the treatment of pain. The Latin saying "Sedare dolorem opus divinum est", trans. "Alleviating pain is the work of the divine", has been variously ascribed to Hippocrates and to Galen of Pergamum. The medical use of opium is later discussed by Pedanius Dioscorides (c. 40 – 90 AD), a Greek physician serving in the Roman army, in his five-volume work, De Materia Medica.

During the Islamic Golden Age, the use of opium was discussed in detail by Avicenna (c. 980 – June 1037 AD) in The Canon of Medicine. The book's five volumes include information on opium's preparation, an array of physical effects, its use to treat a variety of illness, contraindications for its use, its potential danger as a poison and its potential for addiction. Avicenna discouraged opium's use except as a last resort, preferring to address the causes of pain rather than trying to minimize it with analgesics. Many of Avicenna's observations have been supported by modern medical research.

Exactly when the world became aware of opium in India and China is uncertain, but opium was mentioned in the Chinese medical work K'ai-pao-pen-tsdo (973 AD) By 1590 AD, opium poppies were a staple spring crop in the Subahs of Agra region.

The physician Paracelsus (c. 1493–1541) is often credited with reintroducing opium into medical use in Western Europe, during the German Renaissance. He extolled opium's benefits for medical use. He also claimed to have an "arcanum", a pill which he called laudanum, that was superior to all others, particularly when death was to be cheated. ("Ich hab' ein Arcanum – heiss' ich Laudanum, ist über das Alles, wo es zum Tode reichen will.") Later writers have asserted that Paracelsus' recipe for laudanum contained opium, but its composition remains unknown.

Laudanum

The term laudanum was used generically for a useful medicine until the 17th century. After Thomas Sydenham introduced the first liquid tincture of opium, "laudanum" came to mean a mixture of both opium and alcohol. Sydenham's 1669 recipe for laudanum mixed opium with wine, saffron, clove and cinnamon. Sydenham's laudanum was used widely in both Europe and the Americas until the 20th century. Other popular medicines, based on opium, included Paregoric, a much milder liquid preparation for children; Black-drop, a stronger preparation; and Dover's powder.

The opium trade

Opium became a major colonial commodity, moving legally and illegally through trade networks involving India, the Portuguese, the Dutch, the British and China, among others. The British East India Company saw the opium trade as an investment opportunity in 1683 AD. In 1773 the Governor of Bengal established a monopoly on the production of Bengal opium, on behalf of the East India Company. The cultivation and manufacture of Indian opium was further centralized and controlled through a series of acts, between 1797 and 1949. The British balanced an economic deficit from the importation of Chinese tea by selling Indian opium which was smuggled into China in defiance of Chinese government bans. This led to the First (1839–1842) and Second Opium Wars (1856–1860) between China and Britain.

Morphine

In the 19th century, two major scientific advances were made that had far-reaching effects. Around 1804, German pharmacist Friedrich Sertürner isolated morphine from opium. He described its crystallization, structure, and pharmacological properties in a well-received paper in 1817. Morphine was the first alkaloid to be isolated from any medicinal plant, the beginning of modern scientific drug discovery.

The second advance, nearly fifty years later, was the refinement of the hypodermic needle by Alexander Wood and others. Development of a glass syringe with a subcutaneous needle made it possible to easily administer controlled measurable doses of a primary active compound.

Morphine was initially hailed as a wonder drug for its ability to ease pain. It could help people sleep, and had other useful side effects, including control of coughing and diarrhea. It was widely prescribed by doctors, and dispensed without restriction by pharmacists. During the American Civil War, opium and laudanum were used extensively to treat soldiers. It was also prescribed frequently for women, for menstrual pain and diseases of a "nervous character". At first it was assumed (wrongly) that this new method of application would not be addictive.

Codeine

Codeine was discovered in 1832 by Pierre Jean Robiquet. Robiquet was reviewing a method for morphine extraction, described by Scottish chemist William Gregory (1803–1858). Processing the residue left from Gregory's procedure, Robiquet isolated a crystalline substance from the other active components of opium. He wrote of his discovery: "Here is a new substance found in opium ... We know that morphine, which so far has been thought to be the only active principle of opium, does not account for all the effects and for a long time the physiologists are claiming that there is a gap that has to be filled." His discovery of the alkaloid led to the development of a generation of antitussive and antidiarrheal medicines based on codeine.

Semi-synthetic and synthetic opioids

Synthetic opioids were invented, and biological mechanisms for their actions discovered, in the 20th century. Scientists have searched for non-addictive forms of opioids, but have created stronger ones instead. In England Charles Romley Alder Wright developed hundreds of opiate compounds in his search for a nonaddictive opium derivative. In 1874 he became the first person to synthesize diamorphine (heroin), using a process called acetylation which involved boiling morphine with acetic anhydride for several hours.

Heroin received little attention until it was independently synthesized by Felix Hoffmann (1868–1946), working for Heinrich Dreser (1860–1924) at Bayer Laboratories. Dreser brought the new drug to market as an analgesic and a cough treatment for tuberculosis, bronchitis, and asthma in 1898. Bayer ceased production in 1913, after heroin's addictive potential was recognized.

Several semi-synthetic opioids were developed in Germany in the 1910s. The first, oxymorphone, was synthesized from thebaine, an opioid alkaloid in opium poppies, in 1914. Next, Martin Freund and Edmund Speyer developed oxycodone, also from thebaine, at the University of Frankfurt in 1916. In 1920, hydrocodone was prepared by Carl Mannich and Helene Löwenheim, deriving it from codeine. In 1924, hydromorphone was synthesized by adding hydrogen to morphine. Etorphine was synthesized in 1960, from the oripavine in opium poppy straw. Buprenorphine was discovered in 1972.

The first fully synthetic opioid was meperidine (Demerol), found serendipitously by German chemist Otto Eisleb (or Eislib) at IG Farben in 1932. Meperidine was the first opioid to have a structure unrelated to morphine, but with opioid-like properties. Its analgesic effects were discovered by Otto Schaumann in 1939. Gustav Ehrhart and Max Bockmühl, also at IG Farben, built on the work of Eisleb and Schaumann. They developed "Hoechst 10820" (later methadone) around 1937. In 1959 the Belgian physician Paul Janssen developed fentanyl, a synthetic opioid with 30 to 50 times the potency of heroin. Nearly 150 synthetic opioids are now known.

Criminalization and medical use

Non-clinical use of opium was criminalized in the United States by the Harrison Narcotics Tax Act of 1914, and by many other laws. The use of opioids was stigmatized, and it was seen as a dangerous substance, to be prescribed only as a last resort for dying patients. The Controlled Substances Act of 1970 eventually relaxed the harshness of the Harrison Act.

In the United Kingdom the 1926 report of the Departmental Committee on Morphine and Heroin Addiction under the Chairmanship of the President of the Royal College of Physicians reasserted medical control and established the "British system" of control—which lasted until the 1960s.

In the 1980s the World Health Organization published guidelines for prescribing drugs, including opioids, for different levels of pain. In the U.S., Kathleen Foley and Russell Portenoy became leading advocates for the liberal use of opioids as painkillers for cases of "intractable non-malignant pain". With little or no scientific evidence to support their claims, industry scientists and advocates suggested that people with chronic pain would be resistant to addiction.

The release of OxyContin in 1996 was accompanied by an aggressive marketing campaign promoting the use of opioids for pain relief. Increasing prescription of opioids fueled a growing black market for heroin. Between 2000 and 2014 there was an "alarming increase in heroin use across the country and an epidemic of drug overdose deaths".

As a result, health care organizations and public health groups, such as Physicians for Responsible Opioid Prescribing, have called for decreases in the prescription of opioids. In 2016, the Centers for Disease Control and Prevention (CDC) issued a new set of guidelines for the prescription of opioids "for chronic pain outside of active cancer treatment, palliative care, and end-of-life care" and the increase of opioid tapering.

"Remove the Risk"

In April 2019 the U.S. Food and Drug Administration announced the launch of a new education campaign to help Americans understand the important role they play in removing and properly disposing of unused prescription opioids from their homes. This new initiative is part of the FDA's continued efforts to address the nationwide opioid crisis (see below) and aims to help decrease unnecessary exposure to opioids and prevent new addiction. The "Remove the Risk" campaign is targeting women ages 35–64, who are most likely to oversee household health care decisions and often serve as the gatekeepers to opioids and other prescription medications in the home.

Society and culture

Main article: Opioid epidemic

Definition

The term "opioid" originated in the 1950s. It combines "opium" + "-oid" meaning "opiate-like" ("opiates" being morphine and similar drugs derived from opium). The first scientific publication to use it, in 1963, included a footnote stating, "In this paper, the term, 'opioid', is used in the sense originally proposed by George H. Acheson (personal communication) to refer to any chemical compound with morphine-like activities". By the late 1960s, research found that opiate effects are mediated by activation of specific molecular receptors in the nervous system, which were termed "opioid receptors". The definition of "opioid" was later refined to refer to substances that have morphine-like activities that are mediated by the activation of opioid receptors. One modern pharmacology textbook states: "the term opioid applies to all agonists and antagonists with morphine-like activity, and also the naturally occurring and synthetic opioid peptides". Another pharmacology reference eliminates the morphine-like requirement: "Opioid, a more modern term, is used to designate all substances, both natural and synthetic, that bind to opioid receptors (including antagonists)". Some sources define the term opioid to exclude opiates, and others use opiate comprehensively instead of opioid, but opioid used inclusively is considered modern, preferred and is in wide use.

Efforts to reduce recreational use in the US

In 2011, the Obama administration released a white paper describing the administration's plan to deal with the opioid crisis. The administration's concerns about addiction and accidental overdosing have been echoed by numerous other medical and government advisory groups around the world.

As of 2015, prescription drug monitoring programs exist in every state, except for Missouri. These programs allow pharmacists and prescribers to access patients' prescription histories in order to identify suspicious use. However, a survey of US physicians published in 2015 found that only 53% of doctors used these programs, while 22% were not aware that the programs were available to them. The Centers for Disease Control and Prevention was tasked with establishing and publishing a new guideline, and was heavily lobbied. In 2016, the United States Centers for Disease Control and Prevention published its Guideline for Prescribing Opioids for Chronic Pain, recommending that opioids only be used when benefits for pain and function are expected to outweigh risks, and then used at the lowest effective dosage, with avoidance of concurrent opioid and benzodiazepine use whenever possible. Research suggests that the prescription of high doses of opioids related to chronic opioid therapy (COT) can at times be prevented through state legislative guidelines and efforts by health plans that devote resources and establish shared expectations for reducing higher doses.

On 10 August 2017, Donald Trump declared the opioid crisis a (non-FEMA) national public health emergency.

Global shortages

Morphine and other poppy-based medicines have been identified by the World Health Organization as essential in the treatment of severe pain. As of 2002, seven countries (USA, UK, Italy, Australia, France, Spain and Japan) use 77% of the world's morphine supplies, leaving many emerging countries lacking in pain relief medication. The current system of supply of raw poppy materials to make poppy-based medicines is regulated by the International Narcotics Control Board under the provision of the 1961 Single Convention on Narcotic Drugs. The amount of raw poppy materials that each country can demand annually based on these provisions must correspond to an estimate of the country's needs taken from the national consumption within the preceding two years. In many countries, underprescription of morphine is rampant because of the high prices and the lack of training in the prescription of poppy-based drugs. The World Health Organization is now working with administrations from various countries to train healthworkers and to develop national regulations regarding drug prescription to facilitate a greater prescription of poppy-based medicines.

Another idea to increase morphine availability is proposed by the Senlis Council, who suggest, through their proposal for Afghan Morphine, that Afghanistan could provide cheap pain relief solutions to emerging countries as part of a second-tier system of supply that would complement the current INCB regulated system by maintaining the balance and closed system that it establishes while providing finished product morphine to those in severe pain and unable to access poppy-based drugs under the current system.

Recreational use

See also: Opioid use disorder and Recreational drug use
Prescription opioid pain reliever overdose deaths in the United States over years

Opioids can produce strong feelings of euphoria and are frequently used recreationally. Traditionally associated with illicit opioids such as heroin, prescription opioids are misused recreationally.

Drug misuse and non-medical use include the use of drugs for reasons or at doses other than prescribed. Opioid misuse can also include providing medications to persons for whom it was not prescribed. Such diversion may be treated as crimes, punishable by imprisonment in many countries. In 2014, almost 2 million Americans abused or were dependent on prescription opioids.

Classification

There are a number of broad classes of opioids:

Tramadol and tapentadol, which act as monoamine uptake inhibitors also act as mild and potent agonists (respectively) of the μ-opioid receptor. Both drugs produce analgesia even when naloxone, an opioid antagonist, is administered.

Some minor opium alkaloids and various substances with opioid action are also found elsewhere, including molecules present in kratom, Corydalis, and Salvia divinorum plants and some species of poppy aside from Papaver somniferum. There are also strains which produce copious amounts of thebaine, an important raw material for making many semi-synthetic and synthetic opioids. Of all of the more than 120 poppy species, only two produce morphine.

Amongst analgesics there are a small number of agents which act on the central nervous system but not on the opioid receptor system and therefore have none of the other (narcotic) qualities of opioids although they may produce euphoria by relieving pain—a euphoria that, because of the way it is produced, does not form the basis of habituation, physical dependence, or addiction. Foremost amongst these are nefopam, orphenadrine, and perhaps phenyltoloxamine or some other antihistamines. Tricyclic antidepressants have painkilling effect as well, but they're thought to do so by indirectly activating the endogenous opioid system. Paracetamol is predominantly a centrally acting analgesic (non-narcotic) which mediates its effect by action on descending serotoninergic (5-hydroxy triptaminergic) pathways, to increase 5-HT release (which inhibits release of pain mediators). It also decreases cyclo-oxygenase activity. It has recently been discovered that most or all of the therapeutic efficacy of paracetamol is due to a metabolite, AM404, which enhances the release of serotonin and inhibits the uptake of anandamide.

Other analgesics work peripherally (i.e., not on the brain or spinal cord). Research is starting to show that morphine and related drugs may indeed have peripheral effects as well, such as morphine gel working on burns. Recent investigations discovered opioid receptors on peripheral sensory neurons. A significant fraction (up to 60%) of opioid analgesia can be mediated by such peripheral opioid receptors, particularly in inflammatory conditions such as arthritis, traumatic or surgical pain. Inflammatory pain is also blunted by endogenous opioid peptides activating peripheral opioid receptors.

It was discovered in 1953, that humans and some animals naturally produce minute amounts of morphine, codeine, and possibly some of their simpler derivatives like heroin and dihydromorphine, in addition to endogenous opioid peptides. Some bacteria are capable of producing some semi-synthetic opioids such as hydromorphone and hydrocodone when living in a solution containing morphine or codeine respectively.

Many of the alkaloids and other derivatives of the opium poppy are not opioids or narcotics; the best example is the smooth-muscle relaxant papaverine. Noscapine is a marginal case as it does have CNS effects but not necessarily similar to morphine, and it is probably in a category all its own.

Dextromethorphan (the stereoisomer of levomethorphan, a semi-synthetic opioid agonist) and its metabolite dextrorphan have no opioid analgesic effect at all despite their structural similarity to other opioids; instead they are potent NMDA antagonists and sigma 1 and 2-receptor agonists and are used in many over-the-counter cough suppressants.

Salvinorin A is a unique selective, powerful ĸ-opioid receptor agonist. It is not properly considered an opioid nevertheless, because:

  1. chemically, it is not an alkaloid; and
  2. it has no typical opioid properties: absolutely no anxiolytic or cough-suppressant effects. It is instead a powerful hallucinogen.
Opioid peptides Skeletal molecular images
Adrenorphin Chemical structure of Adrenorphin
Amidorphin Chemical structure of Amidorphin.
Casomorphin Chemical structure of Bovine β-casomorphin.
DADLE Chemical structure of DADLE.
DAMGO Chemical structure of DAMGO.
Dermorphin Chemical structure of Dermorphin.
Endomorphin Chemical structure of Endomorphin 1.
Morphiceptin Chemical structure of Morphiceptin.
Nociceptin Chemical structure of Nociceptin.
Octreotide Chemical structure of Octreotide.
Opiorphin Chemical structure of Opiorphin.
TRIMU 5 Chemical structure of TRIMU 5.

Endogenous opioids

Opioid-peptides that are produced in the body include:

β-endorphin is expressed in Pro-opiomelanocortin (POMC) cells in the arcuate nucleus, in the brainstem and in immune cells, and acts through μ-opioid receptors. β-endorphin has many effects, including on sexual behavior and appetite. β-endorphin is also secreted into the circulation from pituitary corticotropes and melanotropes. α-neoendorphin is also expressed in POMC cells in the arcuate nucleus.

Met-enkephalin is widely distributed in the CNS and in immune cells; -enkephalin is a product of the proenkephalin gene, and acts through μ and δ-opioid receptors. leu-enkephalin, also a product of the proenkephalin gene, acts through δ-opioid receptors.

Dynorphin acts through κ-opioid receptors, and is widely distributed in the CNS, including in the spinal cord and hypothalamus, including in particular the arcuate nucleus and in both oxytocin and vasopressin neurons in the supraoptic nucleus.

Endomorphin acts through μ-opioid receptors, and is more potent than other endogenous opioids at these receptors.

Opium alkaloids and derivatives

Opium alkaloids

Phenanthrenes naturally occurring in (opium):

Preparations of mixed opium alkaloids, including papaveretum, are still occasionally used.

Esters of morphine

Ethers of morphine

Semi-synthetic alkaloid derivatives

Synthetic opioids

Anilidopiperidines

Benzimidazoles

Main article: List of benzimidazole opioids

Benzimidazoles opioids are also known as nitazenes.

Phenylpiperidines

Diphenylpropylamine derivatives

Benzomorphan derivatives

Oripavine derivatives

Morphinan derivatives

Others

Allosteric modulators

Plain allosteric modulators do not belong to the opioids, instead they are classified as opioidergics.

Opioid antagonists

  • Nalmefene
  • Naloxone
  • Naltrexone
  • Methylnaltrexone (Methylnaltrexone is only peripherally active as it does not cross the blood–brain barrier in sufficient quantities to be centrally active. As such, it can be considered the antithesis of loperamide.)
  • Naloxegol (Naloxegol is only peripherally active as it does not cross the blood–brain barrier in sufficient quantities to be centrally active. As such, it can be considered the antitheses of loperamide.)

Tables of opioids

Table of morphinan opioids

Table of morphinan opioids: click to
Chemical structure of Morphine.

Morphine

Chemical structure of 2,4-Dinitrophenylmorphine.

2,4-Dinitrophenylmorphine

Chemical structure of 6-Methylenedihydrodesoxymorphine.

6-MDDM

Chemical structure of Chlornaltrexamine.

Chlornaltrexamine

Chemical structure of Desomorphine.

Desomorphine

Chemical structure of Dihydromorphine 2D structure.

Dihydromorphine

Chemical structure of Hydromorphinol.

Hydromorphinol

Chemical structure of Methyldesorphine.

Methyldesorphine

Chemical structure of N-phenethylnormorphine.

N-Phenethylnormorphine

Chemical structure of RAM-378

RAM-378

3,6-diesters of morphine
Chemical structure of acetylpropionylmorphine.

Acetylpropionylmorphine

Chemical structure of dihydroheroin.

Dihydroheroin

Chemical structure of dibenzoylmorphine.

Dibenzoylmorphine

Chemical structure of dipropanoylmorphine.

Dipropanoylmorphine

Chemical structure of diacetylmorphine.

Heroin

Chemical structure of Nicomorphine.

Nicomorphine

Codeine-dionine family
Chemical structure of Codeine.

Codeine

Chemical structure of 6-MAC.

6-MAC

Chemical structure of Benzylmorphine.

Benzylmorphine

Chemical structure of Codeine methylbromide.

Codeine methylbromide

Chemical structure of Dihydroheterocodeine.

Dihydroheterocodeine

Chemical structure of ethylmorphine.

Ethylmorphine

Chemical structure of heterocodeine.

Heterocodeine

Chemical structure of pholcodine.

Pholcodine

Chemical structure of myrophine.

Myrophine

Chemical structure of Methyldihydromorphine.

Methyldihydromorphine

Morphinones and morphols
Chemical structure of 14-Cinnamoyloxycodeinone.

14-Cinnamoyloxycodeinone

Chemical structure of 14-ethoxymetopon.

14-Ethoxymetopon

Chemical structure of 14-methoxymetopon.

14-Methoxymetopon

Chemical structure of 14-phenylpropoxymetopon.

PPOM

Chemical structure of 7-Spiroindanyloxymorphone.

7-Spiroindanyloxymorphone

Chemical structure of Acetylmorphone.

Acetylmorphone

Chemical structure of Codeinone.

Codeinone

Chemical structure of Conorphone.

Conorphone

Chemical structure of Codoxime.

Codoxime

Chemical structure of Thebacon.

Thebacon

Chemical structure of Hydrocodone.

Hydrocodone

Chemical structure of Hydromorphone.

Hydromorphone

Chemical structure of Metopon.

Metopon

Chemical structure of Morphinone.

Morphinone

Chemical structure of N-Phenethyl-14-ethoxymetopon.

N-Phenethyl-14-Ethoxymetopon

Chemical structure of Oxycodone.

Oxycodone

Chemical structure of Oxymorphone.

Oxymorphone

Chemical structure of Pentamorphone.

Pentamorphone

Chemical structure of Semorphone.

Semorphone

Various semi-synthetics
Chemical structure of Chloromorphide.

Chloromorphide

Chemical structure of 14-Hydroxydihydrocodeine.

14-Hydroxydihydrocodeine

Chemical structure of Acetyldihydrocodeine.

Acetyldihydrocodeine

Chemical structure of Dihydrocodeine.

Dihydrocodeine

Chemical structure of Nalbuphine.

Nalbuphine

Chemical structure of Nicocodeine.

Nicocodeine

Chemical structure of Nicodicodeine.

Nicodicodeine

Chemical structure of Oxymorphazone.

Oxymorphazone

Chemical structure of 1-Iodomorphine.

1-Iodomorphine

Active opiate metabolites
Chemical structure of Morphine 6-glucuronide.

M6G

Chemical structure of 6-MAM.

6-MAM

Chemical structure of Norcodeine.

Norcodeine

Chemical structure of Normorphine.

Normorphine

Chemical structure of Morphine N-oxide.

Morphine-N-oxide

Synthetic morphinans
Chemical structure of Cyclorphan.

Cyclorphan

Chemical structure of Dextrallorphan.

DXA

Chemical structure of Levorphanol.

Levorphanol

Chemical structure of Levophenacylmorphan.

Levophenacylmorphan

Chemical structure of Levomethorphan.

Levomethorphan

Chemical structure of Norlevorphanol.

Norlevorphanol

Chemical structure of Oxilorphan.

Oxilorphan

Chemical structure of Phenomorphan.

Phenomorphan

Chemical structure of Furethylnorlevorphanol.

Furethylnorlevorphanol

Chemical structure of Xorphanol.

Xorphanol

Chemical structure of Butorphanol.

Butorphanol

Chemical structure of Cyprodime.

Cyprodime

Chemical structure of Drotebanol.

Drotebanol

Orvinols & Oripavine derivatives
Chemical structure of 6,14-Endoethenotetrahydrooripavine.

6,14-Endoethenotetrahydrooripavine

Chemical structure of 7-PET.

7-PET

Chemical structure of Acetorphine.

Acetorphine

Chemical structure of BU-48.

BU-48

Chemical structure of Buprenorphine.

Buprenorphine

Chemical structure of Cyprenorphine.

Cyprenorphine

Chemical structure of Dihydroetorphine.

Dihydroetorphine

Chemical structure of Etorphine.

Etorphine

Chemical structure of Norbuprenorphine.

Norbuprenorphine

Chemical structure of Thienorphine

Thienorphine

Opioid antagonists & inverse agonists
Chemical structure of 5'-Guanidinonaltrindole.

5'-Guanidinonaltrindole

Chemical structure of Diprenorphine.

Diprenorphine

Chemical structure of Levallorphan.

Levallorphan

Chemical structure of Methylnaltrexone.

MNTX

Chemical structure of Nalfurafine.

Nalfurafine

Chemical structure of Nalmefene.

Nalmefene

Chemical structure of Naloxazone.

Naloxazone

Chemical structure of Naloxone.

Naloxone

Chemical structure of Nalorphine.

Nalorphine

Chemical structure of Naltrexone.

Naltrexone

Chemical structure of Naltriben.

Naltriben

Chemical structure of Naltrindole.

Naltrindole

Chemical structure of 6β-Naltrexol-d4

6β-Naltrexol-d4

Chemical structure of IBNtxA

3-Iodobenzoyl Naltrexamine

Morphinan dimers
Chemical structure of Pseudomorphine

Pseudomorphine

Chemical structure of Naloxonazine

Naloxonazine

Chemical structure of Norbinaltorphimine

Norbinaltorphimine

Chemical structure of Somniferine

Somniferine

Table of non-morphinan opioids

Table of non-morphinan opioids: click to
Benzomorphans
Chemical structure of 8-Carboxamidocyclazocine.

8-CAC

Chemical structure of Allylnormetazocine.

Alazocine

Chemical structure of Bremazocine.

Bremazocine

Chemical structure of Dezocine.

Dezocine

Chemical structure of Ketazocine.

Ketazocine

Chemical structure of Metazocine.

Metazocine

Chemical structure of Pentazocine.

Pentazocine

Chemical structure of Phenazocine.

Phenazocine

Chemical structure of Cyclazocine.

Cyclazocine

4-Phenylpiperidines
Chemical structure of 4-Fluoromeperidine.

4-Fluoromeperidine

Chemical structure of WIN-7681.

Allylnorpethidine

Chemical structure of Anileridine.

Anileridine

Chemical structure of Benzethidine.

Benzethidine

Chemical structure of Carperidine.

Carperidine

Chemical structure of Difenoxin.

Difenoxin

Chemical structure of Diphenoxylate.

Diphenoxylate

Chemical structure of Etoxeridine.

Etoxeridine

Chemical structure of Furethidine.

Furethidine

Chemical structure of Hydroxypethidine.

Hydroxypethidine

Chemical structure of Morpheridine.

Morpheridine

Chemical structure of Oxpheneridine.

Oxpheneridine

Chemical structure of Pethidine.

Pethidine

Chemical structure of Pheneridine.

Pheneridine

Chemical structure of Phenoperidine.

Phenoperidine

Chemical structure of Piminodine.

Piminodine

Chemical structure of Properidine.

Properidine

Chemical structure of Sameridine.

Sameridine

Chemical structure of Allylprodine.

Allylprodine

Chemical structure of α-meprodine.

α-Meprodine

Chemical structure of Desmethylprodine.

MPPP

Chemical structure of PEPAP.

PEPAP

Chemical structure of α-prodine.

α-Prodine

Chemical structure of Prosidol.

Prosidol

Chemical structure of Trimeperidine.

Trimeperidine

Chemical structure of Acetoxyketobemidone.

Acetoxyketobemidone

Chemical structure of Droxypropine.

Droxypropine

Chemical structure of Ketobemidone.

Ketobemidone

Chemical structure of Methylketobemidone.

Methylketobemidone

Chemical structure of Propylketobemidone.

Propylketobemidone

Chemical structure of Alvimopan.

Alvimopan

Chemical structure of Loperamide.

Loperamide

Chemical structure of Picenadol.

Picenadol

Open chain opioids
Chemical structure of Dipipanone.

Dipipanone

Chemical structure of Methadone.

Methadone

Chemical structure of Normethadone.

Normethadone

Chemical structure of Phenadoxone.

Phenadoxone

Chemical structure of Dimepheptanol.

Dimepheptanol

Chemical structure of Levacetylmethadol.

Levacetylmethadol

Chemical structure of Dextromoramide.

Dextromoramide

Chemical structure of Levomoramide.

Levomoramide

Chemical structure of Racemoramide.

Racemoramide

Chemical structure of Diethylthiambutene

Diethylthiambutene

Chemical structure of Dimethylthiambutene.

Dimethylthiambutene

Chemical structure of Ethylmethylthiambutene.

Ethylmethylthiambutene

Chemical structure of Piperidylthiambutene

Piperidylthiambutene

Chemical structure of Pyrrolidinylthiambutene.

Pyrrolidinylthiambutene

Chemical structure of Thiambutene.

Thiambutene

Chemical structure of Tipepidine.

Tipepidine

Chemical structure of Dextropropoxyphene.

Dextropropoxyphene

Chemical structure of Dimenoxadol.

Dimenoxadol

Chemical structure of Dioxaphetyl butyrate.

Dioxaphetyl butyrate

Chemical structure of Levopropoxyphene.

Levopropoxyphene

Chemical structure of Norpropoxyphene.

Norpropoxyphene

Chemical structure of Diampromide.

Diampromide

Chemical structure of Phenampromide.

Phenampromide

Chemical structure of Propiram.

Propiram

Chemical structure of IC-26 structure.

Methiodone

Chemical structure of Isoaminile.

Isoaminile

Chemical structure of Lefetamine.

Lefetamine

Chemical structure of R-4066.

R-4066

Anilidopiperidines
Chemical structure of 3-allylfentanyl.

3-Allylfentanyl

Chemical structure of 3-Methylfentanyl.

3-Methylfentanyl

Chemical structure of 3-Methylthiofentanyl.

3-Methylthiofentanyl

Chemical structure of 4-Phenylfentanyl.

4-Phenylfentanyl

Chemical structure of Alfentanil.

Alfentanil

Chemical structure of α-methylacetylfentanyl.

α-Methylacetylfentanyl

Chemical structure of α-methylfentanyl.

α-Methylfentanyl

Chemical structure of α-methylthiofentanyl.

α-Methylthiofentanyl

Chemical structure of β-hydroxyfentanyl.

β-Hydroxyfentanyl

Chemical structure of β-hydroxythiofentanyl.

β-Hydroxythiofentanyl

Chemical structure of β-methylfentanyl.

β-Methylfentanyl

Chemical structure of Brifentanil.

Brifentanil

Chemical structure of Carfentanil.

Carfentanil

Chemical structure of Fentanyl.

Fentanyl

Chemical structure of Lofentanil.

Lofentanil

Chemical structure of Mirfentanil.

Mirfentanil

Chemical structure of Ocfentanil.

Ocfentanil

Chemical structure of Ohmefentanyl.

Ohmefentanyl

Chemical structure of Parafluorofentanyl.

Parafluorofentanyl

Chemical structure of Phenaridine.

Phenaridine

Chemical structure of Remifentanil.

Remifentanil

Chemical structure of Sufentanil.

Sufentanil

Chemical structure of Thiofentanyl.

Thiofentanyl

Chemical structure of Trefentanil.

Trefentanil

Various others
Chemical structure of Ethoheptazine.

Ethoheptazine

Chemical structure of Metheptazine.

Metheptazine

Chemical structure of Metethoheptazine.

Metethoheptazine

Chemical structure of Proheptazine.

Proheptazine

Chemical structure of Bezitramide.

Bezitramide

Chemical structure of Piritramide.

Piritramide

Chemical structure of Clonitazene.

Clonitazene

Chemical structure of Etonitazene.

Etonitazene

Chemical structure of 18-Methoxycoronaridine.

18-MC

Chemical structure of 7-Hydroxymitragynine.

7-Hydroxymitragynine

Chemical structure of Akuammine.

Akuammine

Chemical structure of Eseroline.

Eseroline

Chemical structure of Hodgkinsine.

Hodgkinsine

Chemical structure of Mitragynine.

Mitragynine

Chemical structure of Pericine.

Pericine

Chemical structure of BW373U86.

BW373U86

Chemical structure of DPI-221.

DPI-221

Chemical structure of DPI-287.

DPI-287

Chemical structure of DPI-3290.

DPI-3290

Chemical structure of SNC-80.

SNC-80

Chemical structure of AD-1211.

AD-1211

Chemical structure of AH-7921.

AH-7921

Chemical structure of Azaprocin.

Azaprocin

Chemical structure of Bromadol.

Bromadol

Chemical structure of BRL-52537.

BRL-52537

Chemical structure of Bromadoline.

Bromadoline

Chemical structure of C-8813.

C-8813

Chemical structure of Ciramadol.

Ciramadol

Chemical structure of Doxpicomine.

Doxpicomine

Chemical structure of Enadoline.

Enadoline

Chemical structure of Faxeladol.

Faxeladol

Chemical structure of GR-89696.

GR-89696

Chemical structure of Herkinorin.

Herkinorin

Chemical structure of ICI-199441.

ICI-199441

Chemical structure of ICI-204448.

ICI-204448

Chemical structure of J-113397.

J-113397

Chemical structure of JTC-801.

JTC-801

Chemical structure of LPK-26.

LPK-26

Chemical structure of Methopholine.

Methopholine

Chemical structure of MT-45.

MT-45

Chemical structure of N-Desmethylclozapine.

NDMC

Chemical structure of NNC 63-0532.

NNC 63-0532

Chemical structure of Nortilidine.

Nortilidine

Chemical structure of O-Desmethyltramadol.

O-Desmethyltramadol

Chemical structure of Prodilidine.

Prodilidine

Chemical structure of Profadol.

Profadol

Chemical structure of Ro64-6198.

Ro64-6198

Chemical structure of SB-612111.

SB-612111

Chemical structure of SC-17599.

SC-17599

Chemical structure of RWJ-394,674.

RWJ-394674

Chemical structure of TAN-67.

TAN-67

Chemical structure of Tapentadol.

Tapentadol

Chemical structure of Tifluadom.

Tifluadom

Chemical structure of Tramadol.

Tramadol

Chemical structure of Trimebutine.

Trimebutine

Chemical structure of U-50488.

U-50488

Chemical structure of U-69593.

U-69593

Chemical structure of Viminol.

Viminol

Chemical structure of W-18.

W-18

Chemical structure of Alvimopan.

Alvimopan

Chemical structure of JDTic.

JDTic

Chemical structure of MCOPPB.

MCOPPB

Chemical structure of Beta-amine ketone 'compound 29'

Beta-amine ketone 'compound 29'

See also

References

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