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Oxycodone, sold under brand name OxyContin among others, is an opioid medication used for treatment of moderate to severe pain.[11] It is usually taken by mouth, and is available in immediate release and controlled release formulations.[11] Onset of pain relief typically begins within 15 minutes and lasts for up to six hours with the immediate release formulation.[11] In the United Kingdom, it is available by injection.[12] Combination products are also available with paracetamol (acetaminophen) or aspirin.[11]

Oxycodone
Oxycodone.svg
Oxycodone strucutre.png
Clinical data
Pronunciationɒksɪˈkəʊdəʊn
Trade namesOxyContin, others
SynonymsEukodal, eucodal; dihydrohydroxycodeinone, 7,8-dihydro-14-hydroxycodeinone, 6-deoxy-7,8-dihydro-14-hydroxy-3-O-methyl-6-oxomorphine[3]
AHFS/Drugs.comMonograph
MedlinePlusa682132
Pregnancy
category
  • AU: C
  • US: B (No risk in non-human studies)
Dependence
liability
High[1]
Routes of
administration
By mouth, sublingual, intramuscular, intravenous, intranasal, subcutaneous, transdermal, rectal, epidural[2]
ATC code
Legal status
Legal status
Pharmacokinetic data
BioavailabilityBy mouth: 60–87%[4][6]
Protein binding45%[4]
MetabolismLiver: mainly CYP3A, and, to a much lesser extent, CYP2D6 (~5%);[4] 95% metabolized (i.e., 5% excreted unchanged)[5]
MetabolitesNoroxycodone (25%) [7][5]
Noroxymorphone (15%, free and conjugated)[7][5]
Oxymorphone (11%, conjugated)[7][5]
• Others (e.g., minor metabolites)[5]
Onset of actionIR: 10–30 minutes[6][5]
CR: 1 hour[8]
Elimination half-lifeBy mouth (IR): 2–3 hrs (same t1/2 for all ROAs)[5][6]
By mouth (CR): 4.5 hrs[9]
Duration of actionBy mouth (IR): 3–6 hrs[5]
By mouth (CR): 10–12 hrs[10]
ExcretionUrine (83%)[4]
Identifiers
CAS Number
PubChem CID
IUPHAR/BPS
DrugBank
ChemSpider
UNII
KEGG
ChEBI
ChEMBL
CompTox Dashboard (EPA)
ECHA InfoCard100.000.874 Edit this at Wikidata
Chemical and physical data
FormulaC18H21NO4
Molar mass315.364 g/mol g·mol−1
3D model (JSmol)
Melting point219 °C (426 °F)
Solubility in waterHCl: 166 mg/mL (20 °C)
  (verify)

Common side effects include constipation, nausea, sleepiness, dizziness, itching, dry mouth, and sweating.[11] Severe side effects may include addiction, respiratory depression (a decreased effort to breathe), and low blood pressure.[11] Those allergic to codeine may also be allergic to oxycodone.[11] Use of oxycodone in early pregnancy appears relatively safe.[11] Opioid withdrawal may occur if rapidly stopped.[11] Oxycodone acts by activating the μ-opioid receptor.[13] When taken by mouth, it has roughly 1.5 times the effect of the equivalent amount of morphine.[14]

Oxycodone was first made in Germany in 1916 from thebaine.[15] It is available as a generic medication.[11] In the United States the wholesale cost per dose is less than US$0.30 as of 2018.[16] In 2016, it was the 54th most prescribed medication in the United States, with more than 14 million prescriptions.[17] Oxycodone has been a common drug of abuse.[18] A number of abuse-deterrent formulations are available such as in combination with naloxone.[18][19]

Medical usesEdit

Oxycodone is used for managing moderate to severe acute or chronic pain when other treatments are not sufficient.[11] It may improve quality of life in certain types of pain.[20] It is unclear if use in chronic pain results in improved quality of life or ongoing pain relief.[11]

Oxycodone is available as controlled-release tablet, intended to be taken every 12 hours.[21] A July 1996 study independent of Purdue Pharma found the controlled-release formulation had a variable duration of action ranging from 10–12 hours.[10] A 2006 review found that controlled-release oxycodone is comparable to instant-release oxycodone, morphine, and hydromorphone in management of moderate to severe cancer pain, with fewer side effects than morphine. The author concluded that the controlled release form is a valid alternative to morphine and a first-line treatment for cancer pain.[21] In 2014, the European Association for Palliative Care recommended oxycodone by mouth as a second-line alternative to morphine by mouth for cancer pain.[22]

In the U.S., extended-release oxycodone is approved for use in children as young as 11 years old. The approved uses is for relief of cancer pain, trauma pain, or pain due to major surgery, in children already treated with opioids, who can tolerate at least 20 mg per day of oxycodone; this provides an alternative to Duragesic (fentanyl), the only other extended-release opioid analgesic approved for children.[23]

Available formsEdit

Both sides of a single 10mg OxyContin pill.

Oxycodone is available in a variety of formulations for by mouth or under the tongue:[6][24][25][26]

  • Immediate-release oxycodone (OxyFast, OxyIR, OxyNorm, Roxicodone)
  • Controlled-release oxycodone (OxyContin, Xtampza ER) – 10-12-hour duration[10]
  • Oxycodone tamper-resistant (OxyContin OTR)[27]
  • Immediate-release oxycodone with paracetamol (acetaminophen) (Percocet, Endocet, Roxicet, Tylox)
  • Immediate-release oxycodone with aspirin (Endodan, Oxycodan, Percodan, Roxiprin)
  • Immediate-release oxycodone with ibuprofen (Combunox)[28]
  • Controlled-release oxycodone with naloxone (Targin, Targiniq, Targinact)[29] – 10-12 hour duration[10]
  • Controlled-release oxycodone with naltrexone (Troxyca) – 10-12 hour duration[10][30]

In the United States, oxycodone is only approved for use by mouth, available as tablets and oral solutions. Parenteral formulations of oxycodone (brand name OxyNorm) are also available in the world however, and are widely used in Europe.[31][32][33] In Spain, the Netherlands and the United Kingdom, oxycodone is approved for intravenous (IV) and intramuscular (IM) use. When first introduced in Germany during World War I, both IV and IM administrations of oxycodone were commonly used for postoperative pain management of Central Powers soldiers.[2]

Side effectsEdit

 
Main side effects of oxycodone[34]
 
Two tablets (10 mg) of oxycodone and safety blisters

Serious side effects of oxycodone include reduced sensitivity to pain (beyond the pain the drug is taken to reduce), euphoria, anxiolysis, feelings of relaxation, and respiratory depression.[35] Common side effects of oxycodone include constipation (23%), nausea (23%), vomiting (12%), somnolence (23%), dizziness (13%), itching (13%), dry mouth (6%), and sweating (5%).[35][36] Less common side effects (experienced by less than 5% of patients) include loss of appetite, nervousness, abdominal pain, diarrhea, urine retention, dyspnea, and hiccups.[37] These side effects generally become less intense over time.[38] Oxycodone in combination with naloxone in managed-release tablets, has been formulated to both deter abuse and reduce "opioid-induced constipation".[39]

Dependence and withdrawalEdit

The risk of experiencing severe withdrawal symptoms is high if a patient has become physically dependent and discontinues oxycodone abruptly. Medically, when the drug has been taken regularly over an extended period, it is withdrawn gradually rather than abruptly. People who regularly use oxycodone recreationally or at higher than prescribed doses are at even higher risk of severe withdrawal symptoms. The symptoms of oxycodone withdrawal, as with other opioids, may include "anxiety, panic attack, nausea, insomnia, muscle pain, muscle weakness, fevers, and other flu-like symptoms".[40]

Withdrawal symptoms have also been reported in newborns whose mothers had been either injecting or orally taking oxycodone during pregnancy.[41]

Hormone levelsEdit

As with other opioids, chronic use of oxycodone (particularly with higher doses) often causes concurrent hypogonadism (low sex hormone levels).[42]

OverdoseEdit

In high doses, overdoses, or in some persons not tolerant to opioids, oxycodone can cause shallow breathing, slowed heart rate, cold/clammy skin, pauses in breathing, low blood pressure, constricted pupils, circulatory collapse, respiratory arrest, and death.[37]

In 2011, it was the leading cause of drug-related deaths in the United States.[43] However, from 2012 onwards, heroin and fentanyl have become more common causes of drug-related deaths.[43]

Oxycodone overdose has also been described to cause spinal cord infarction in high doses and ischemic damage to the brain, due to prolonged hypoxia from suppressed breathing.[44]

InteractionsEdit

Oxycodone is metabolized by the enzymes CYP3A4 and CYP2D6, and its clearance therefore can be altered by inhibitors and inducers of these enzymes.[32] (For lists of CYP3A4 and CYP2D6 inhibitors and inducers, see here and here, respectively.) Natural genetic variation in these enzymes can also influence the clearance of oxycodone, which may be related to the wide inter-individual variability in its half-life and potency.[32]

Ritonavir or lopinavir/ritonavir greatly increase plasma concentrations of oxycodone in healthy human volunteers due to inhibition of CYP3A4 and CYP2D6.[45] Rifampicin greatly reduces plasma concentrations of oxycodone due to strong induction of CYP3A4.[46] There is also a case report of fosphenytoin, a CYP3A4 inducer, dramatically reducing the analgesic effects of oxycodone in a chronic pain patient.[47] Dosage or medication adjustments may be necessary in each case.[45][46][47]

PharmacologyEdit

PharmacodynamicsEdit

Oxycodone (and metabolite) at opioid receptors
Compound Affinities (Ki) Ratio Ref
MOR DOR KOR MOR:DOR:KOR
Oxycodone 18 nM 958 nM 677 nM 1:53:38 [48]
Oxymorphone 0.78 nM 50 nM 137 nM 1:64:176 [49]

Equianalgesic doses[50][51][52]
Compound Route Dose
Codeine PO 200 mg
Hydrocodone PO 20–30 mg
Hydromorphone PO 7.5 mg
Hydromorphone IV 1.5 mg
Morphine PO 30 mg
Morphine IV 10 mg
Oxycodone PO 20 mg
Oxycodone IV 10 mg
Oxymorphone PO 10 mg
Oxymorphone IV 1 mg

Oxycodone, a synthetic opioid, is a highly selective full agonist of the μ-opioid receptor (MOR).[31][32] This is the main biological target of the endogenous opioid neuropeptide β-endorphin.[13] Oxycodone has low affinity for the δ-opioid receptor (DOR) and the κ-opioid receptor (KOR), where it is an agonist similarly.[31][32] After oxycodone binds to the MOR, a G protein-complex is released, which inhibits the release of neurotransmitters by the cell by decreasing the amount of cAMP produced, closing calcium channels, and opening potassium channels.[53] Opioids like oxycodone are thought to produce their analgesic effects via activation of the MOR in the midbrain periaqueductal gray (PAG) and rostral ventromedial medulla (RVM).[54] Conversely, they are thought to produce reward and addiction via activation of the MOR in the mesolimbic reward pathway, including in the ventral tegmental area, nucleus accumbens, and ventral pallidum.[55][56] Tolerance to the analgesic and rewarding effects of opioids is complex and occurs due to receptor-level tolerance (e.g., MOR downregulation), cellular-level tolerance (e.g., cAMP upregulation), and system-level tolerance (e.g., neural adaptation due to induction of ΔFosB expression).[57]

Taken orally, 20 mg of immediate release oxycodone is considered to be equivalent in analgesic effect to 30 mg of morphine,[58][59] while extended release oxycodone is considered to be twice as potent as oral morphine.[60]

Similarly to most other opioids, oxycodone increases prolactin secretion, but its influence on testosterone levels is unknown.[31] Unlike morphine, oxycodone lacks immunosuppressive activity (measured by natural killer cell activity and interleukin 2 production in vitro); the clinical relevance of this has not been clarified.[31]

Active metabolitesEdit

A few of the metabolites of oxycodone have also been found to be active as MOR agonists, some of which notably have much higher affinity for (as well as higher efficacy at) the MOR in comparison.[61][62][63] Oxymorphone possesses 3- to 5-fold higher affinity for the MOR than does oxycodone,[5] while noroxycodone and noroxymorphone possess one-third of and 3-fold higher affinity for the MOR, respectively,[5][63] and MOR activation is 5- to 10-fold less with noroxycodone but 2-fold higher with noroxymorphone relative to oxycodone.[64] Noroxycodone, noroxymorphone, and oxymorphone also have longer biological half-lives than oxycodone.[61][65]

Pharmacology of oxycodone and metabolites[35][64]
Compound Ki EC50 Cmax AUC
Oxycodone 16.0 nM 343 nM 23.2 ± 8.6 ng/mL 236 ± 102 ng/h/mL
Oxymorphone 0.36 nM 42.8 nM 0.82 ± 0.85 ng/mL 12.3 ± 12 ng/h/mL
Noroxycodone 57.1 nM 1930 nM 15.2 ± 4.5 ng/mL 233 ± 102 ng/h/mL
Noroxymorphone 5.69 nM 167 nM ND ND
Ki is for [3H]diprenorphine displacement. (Note that diprenorphine is a non-selective opioid receptor ligand, so this is not MOR-specific.) EC50 is for hMOR1 GTPyS binding. Cmax and AUC levels are for 20 mg CR oxycodone.

However, despite the greater in vitro activity of some of its metabolites, it has been determined that oxycodone itself is responsible for 83.0% and 94.8% of its analgesic effect following oral and intravenous administration, respectively.[62] Oxymorphone plays only a minor role, being responsible for 15.8% and 4.5% of the analgesic effect of oxycodone after oral and intravenous administration, respectively.[62] Although the CYP2D6 genotype and the route of administration result in differential rates of oxymorphone formation, the unchanged parent compound remains the major contributor to the overall analgesic effect of oxycodone.[62] In contrast to oxycodone and oxymorphone, noroxycodone and noroxymorphone, while also potent MOR agonists, poorly cross the blood–brain barrier into the central nervous system, and for this reason are only minimally analgesic in comparison.[61][64][62][63]

κ-opioid receptorEdit

In 1997, a group of Australian researchers proposed (based on a study in rats) that oxycodone acts on KORs, unlike morphine, which acts upon MORs.[66] Further research by this group indicated the drug appears to be a high-affinity κ2b-opioid receptor agonist.[67] However, this conclusion has been disputed, primarily on the basis that oxycodone produces effects that are typical of MOR agonists.[68] In 2006, research by a Japanese group suggested the effect of oxycodone is mediated by different receptors in different situations.[69] Specifically in diabetic mice, the KOR appears to be involved in the antinociceptive effects of oxycodone, while in nondiabetic mice, the μ1-opioid receptor seems to be primarily responsible for these effects.[69][70]

PharmacokineticsEdit

Instant-release absorption profileEdit

Oxycodone can be administered orally, intranasally, via intravenous, intramuscular, or subcutaneous injection, or rectally. The bioavailability of oral administration of oxycodone averages within a range of 60 to 87%, with rectal administration yielding the same results; intranasal varies between individuals with a mean of 46%.[71]

After a dose of conventional (instant-release) oral oxycodone, the onset of action is 10 to 30 minutes,[5][6] and peak plasma levels of the drug are attained within roughly 30 to 60 minutes;[5][6][61] in contrast, after a dose of OxyContin (an oral controlled-release formulation), peak plasma levels of oxycodone occur in about three hours.[37] The duration of instant-release oxycodone is 3 to 6 hours, although this can be variable depending on the individual.[5]

DistributionEdit

Oxycodone has a volume of distribution of 2.6L/kg,[72] in the blood is distributed to skeletal muscle, liver, intestinal tract, lungs, spleen, and brain.[37] Conventional oral preparations start to reduce pain within 10 to 15 minutes on an empty stomach; in contrast, OxyContin starts to reduce pain within one hour.[11]

MetabolismEdit

The metabolism of oxycodone in humans occurs in the liver mainly via the cytochrome P450 system and is extensive (about 95%) and complex, with many minor pathways and resulting metabolites.[5][73] Around 10% (range 8–14%) of a dose of oxycodone is excreted essentially unchanged (unconjugated or conjugated) in the urine.[5] The major metabolites of oxycodone are noroxycodone (70%), noroxymorphone ("relatively high concentrations"),[35] and oxymorphone (5%).[61][64] The immediate metabolism of oxycodone in humans is as follows:[5][9][74]

In humans, N-demethylation of oxycodone to noroxycodone by CYP3A4 is the major metabolic pathway, accounting for 45% ± 21% of a dose of oxycodone, while O-demethylation of oxycodone into oxymorphone by CYP2D6 and 6-ketoreduction of oxycodone into 6-oxycodols represent relatively minor metabolic pathways, accounting for 11% ± 6% and 8% ± 6% of a dose of oxycodone, respectively.[5][31]

Several of the immediate metabolites of oxycodone are subsequently conjugated with glucuronic acid and excreted in the urine.[5] 6α-Oxycodol and 6β-oxycodol are further metabolized by N-demethylation to nor-6α-oxycodol and nor-6β-oxycodol, respectively, and by N-oxidation to 6α-oxycodol-N-oxide and 6β-oxycodol-N-oxide (which can subsequently be glucuronidated as well).[5][9] Oxymorphone is also further metabolized, as follows:[5][9][74]

The first pathway of the above three accounts for 40% of the metabolism of oxymorphone, making oxymorphone-3-glucuronide the main metabolite of oxymorphone, while the latter two pathways account for less than 10% of the metabolism of oxymorphone.[74] After N-demethylation of oxymorphone, noroxymorphone is further glucuronidated to noroxymorphone-3-glucuronide.[74]

Because oxycodone is metabolized by the cytochrome P450 system in the liver, its pharmacokinetics can be influenced by genetic polymorphisms and drug interactions concerning this system, as well as by liver function.[37] Some people are fast metabolizers of oxycodone, resulting in reduced effects, while others are slow metabolizers, resulting in increased effects and toxicity.[75][76] While higher CYP2D6 activity increases the effects of oxycodone (owing to increased conversion into oxymorphone), higher CYP3A4 activity has the opposite effect and decreases the effects of oxycodone (owing to increased metabolism into noroxycodone and noroxymorphone).[77] The dose of oxycodone must be reduced in patients with reduced liver function.[78]

EliminationEdit

The clearance of oxycodone is 0.8 L/min.[79] Oxycodone and its metabolites are mainly excreted in urine.[80] Therefore, oxycodone accumulates in patients with kidney impairment.[78] Oxycodone is eliminated in the urine 10% as unchanged oxycodone, 45% ± 21% as N-demethylated metabolites (noroxycodone, noroxymorphone, noroxycodols), 11 ± 6% as O-demethylated metabolites (oxymorphone, oxymorphols), and 8% ± 6% as 6-keto-reduced metabolites (oxycodols).[80][81]

Duration of actionEdit

Oxycodone have a half life of 4.5 hours.[72] OxyContin currently is protected under patent and has no available generic. Its manufacturer Purdue Pharma claimed in their 1992 patent application that the duration of action of OxyContin, oxycodone's controlled-release preparation, is 12 hours in "90% of patients." It has never performed any clinical studies in which OxyContin was given at more frequent intervals. In a separate filing, Purdue claims that controlled-release oxycodone "provides pain relief in said patient for at least 12 hours after administration." [82] However, in 2016 an investigation by the Los Angeles Times found that "the drug weans off hours early in many people," inducing symptoms of opiate withdrawal and intense cravings for OxyContin. One doctor Lawrence Robbins told journalists that over 70% of his patients would report that OxyContin would only provide 4–7 hours of relief. Doctors in the 1990s often would switch their patients to a dosing schedule of once every eight hours when they complained that the duration of action for OxyContin was too short to be only taken twice a day.[82][83]

Purdue strongly discouraged the practice: Purdue's medical director Robert Reder wrote to one doctor in 1995 that "OxyContin has been developed for q12h dosing...I request that you not use a q8h dosing regimen." Purdue repeatedly released memos to its sales representatives ordering them to remind doctors not to deviate from a 12-hour dosing schedule. One such memo read, "There is no Q8 dosing with OxyContin... [8-hour dosing] needs to be nipped in the bud. NOW!!"[82] The journalists who covered the investigation argue that Purdue Pharma has insisted on a 12-hour duration of action for nearly all patients, despite evidence to the contrary, in order to protect the reputation of OxyContin as a 12-hour drug and the willingness of health insurance and managed care companies to cover OxyContin despite its high cost relative to generic opiates such as morphine.[82]

Purdue sales representatives were instructed to encourage doctors to write prescriptions for larger 12-hour doses instead of more frequent dosing. An August 1996 memo to Purdue sales representatives in Tennessee entitled "$$$$$$$$$$$$$ It’s Bonus Time in the Neighborhood!" reminded the representatives that their commissions would dramatically increase if they were successful in convincing doctors to prescribe larger doses. Los Angeles Times journalists argue using interviews from opioid addiction experts that such high doses of OxyContin spaced 12 hours apart create a combination of agony during opiate withdrawal (lower lows) and a schedule of reinforcement that relieves this agony, fostering addiction.[82]

ChemistryEdit

Oxycodone's chemical name is derived from codeine. The chemical structures are very similar, differing only in that

  • Oxycodone has a hydroxy group at carbon-14 (codeine has just a hydrogen in its place)
  • Oxycodone has a 7,8-dihydro feature. Codeine has a double bond between those two carbons; and
  • Oxycodone has a carbonyl group (as in ketones) in place of the hydroxyl group of codeine.

It is also similar to hydrocodone, differing only in that it has a hydroxyl group at carbon-14.[78]

Oxycodone is marketed as various salts, most commonly as the hydrochloride salt. The free base conversion ratios of different salts are: hydrochloride (0.896), bitartrate (0.667), tartrate (0.750), camphosulphonate (0.576), pectinate (0.588), phenylpriopionate (0.678), sulphate (0.887), phosphate (0.763), and terephthalate (0.792). The hydrochloride salt is the basis of most American oxycodone products whilst bitartrate, tartrate, pectinate, terephthalate and phosphate salts are also available in European products. Methyiodide and hydroiodide are mentioned in older European publications.

BiosynthesisEdit

In terms of biosynthesis, oxycodone has been found naturally in nectar extracts from the orchid family Epipactis helleborine; together along with another opioid: 3-{2-{3-{3-benzyloxypropyl}-3-indol, 7,8-didehydro- 4,5-epoxy-3,6-d-morphinan.[84]

Detection in biological fluidsEdit

Oxycodone and/or its major metabolites may be measured in blood or urine to monitor for clearance, abuse, confirm a diagnosis of poisoning, or assist in a medicolegal death investigation. Many commercial opiate screening tests cross-react appreciably with oxycodone and its metabolites, but chromatographic techniques can easily distinguish oxycodone from other opiates.[85]

HistoryEdit

Freund and Speyer of the University of Frankfurt in Germany first synthesized oxycodone from Thebaine in 1916,[15] a few years after the German pharmaceutical company Bayer had stopped the mass production of heroin due to hazardous use, harmful use, and dependence. It was hoped that a thebaine-derived drug would retain the analgesic effects of morphine and heroin with less dependence. Unfortunately, this was ultimately not found to be the case.

The first clinical use of the drug was documented in 1917, the year after it was first developed.[15][10] It was first introduced to the US market in May 1939. In early 1928, Merck introduced a combination product containing scopolamine, oxycodone, and ephedrine under the German initials for the ingredients SEE, which was later renamed Scophedal (SCOpolamine ePHEDrine and eukodAL) in 1942. It was last manufactured in 1987 but can be compounded. This combination is essentially an oxycodone analogue of the morphine-based "twilight sleep", with ephedrine added to reduce circulatory and respiratory effects.[86] The drug became known as the "Miracle Drug of the 1930s" in Continental Europe and elsewhere and it was the Wehrmacht's choice for a battlefield analgesic for a time. The drug was expressly designed to provide what the patent application and package insert referred to as "very deep analgesia and profound and intense euphoria" as well as tranquillisation and anterograde amnesia useful for surgery and battlefield wounding cases. Oxycodone was allegedly chosen over morphine, hydromorphone, and hydrocodone for this product because of oxycodone having subjective elements in its side effect profile similar to cocaine.[87]

During Operation Himmler Skophedal was also reportedly injected in massive overdose into the prisoners dressed in Polish Army uniforms in the staged incident on 1. September 1939 which opened the Second World War.[86][88]

The personal notes of Adolf Hitler's physician, Dr. Theodor Morell, indicate Hitler received repeated injections of "eukodal" (oxycodone) and Scophedal, as well as Dolantin (pethidine) codeine, and morphine less frequently; oxycodone could not be obtained after late January 1945 and it is likely that Hitler went through full-scale withdrawal.[89][90] Eukodal, Dicodid (hydrocodone), cocaine, and methamphetamine in different proportions were the basis of a combat drug tested by the Nazis late in 1944; the ninth in the series of ten formulae, called D IX (Drug no. 9) with 3 mg methamphetamine, 5 mg cocaine, and 5 mg eukodal with no Dicodid was given to mini-sub captains in a disastrous roll-out which led to the end of that combat drug programme.[91] Hermann Göring was taken into custody by the Americans with thousands of doses of oxycodone as well as the entire world supply of dihydrocodeine in two large suitcases.[92][93]

In the early 1970s, the United States government classified oxycodone as a schedule II drug.

Purdue Pharma — a privately held company based in Stamford, Connecticut, developed the prescription painkiller OxyContin. Upon its release in 1995, OxyContin was hailed as a medical breakthrough, a long-lasting narcotic that could help patients suffering from moderate to severe pain. The drug became a blockbuster, and has reportedly generated some thirty-five billion dollars in revenue for Purdue.[94]

Society and cultureEdit

NamesEdit

Expanded expression for the compound oxycodone in the academic literature include "dihydrohydroxycodeinone",[3][95][96] "Eucodal",[95][96] "Eukodal",[2][10] "14-hydroxydihydrocodeinone",[3][95] and "Nucodan".[95][96] In a UNESCO convention, the translations of "oxycodone" are oxycodon (Dutch), oxycodone (French), oxicodona (Spanish), الأوكسيكودون (Arabic), 羟考酮 (Chinese), and оксикодон (Russian).[97] The word "oxycodone" should not be confused with "oxandrolone", "oxazepam", "oxybutynin", "oxytocin", or "Roxanol".[98]

Other brand names include Longtec and Shortec.[99]

Legal statusEdit

GeneralEdit

Oxycodone is subject to international conventions on narcotic drugs. In addition, oxycodone is subject to national laws that differ by country. The 1931 Convention for Limiting the Manufacture and Regulating the Distribution of Narcotic Drugs of the League of Nations included oxycodone.[100] The 1961 Single Convention on Narcotic Drugs of the United Nations, which replaced the 1931 convention, categorized oxycodone in Schedule I.[101] Global restrictions on Schedule I drugs include "limit[ing] exclusively to medical and scientific purposes the production, manufacture, export, import, distribution of, trade in, use and possession of" these drugs; "requir[ing] medical prescriptions for the supply or dispensation of [these] drugs to individuals"; and "prevent[ing] the accumulation" of quantities of these drugs "in excess of those required for the normal conduct of business".[101]

AustraliaEdit

Oxycodone is in Schedule I (derived from the Single Convention on Narcotic Drugs) of the Commonwealth's Narcotic Drugs Act 1967.[102] In addition, it is in Schedule 8 of the Australian Standard for the Uniform Scheduling of Drugs and Poisons ("Poisons Standard"), meaning it is a "controlled drug... which should be available for use but require[s] restriction of manufacture, supply, distribution, possession and use to reduce abuse, misuse and physical or psychological dependence".[103]

CanadaEdit

Oxycodone is a controlled substance under Schedule I of the Controlled Drugs and Substances Act (CDSA).[104]

Canadian legislative changesEdit
 
Canadian oxycodone HCL/acetaminophen 5/325 mg tablet

In February 2012, Ontario passed legislation to allow the expansion of an already existing drug-tracking system for publicly funded drugs to include those that are privately insured. This database will function to identify and monitor patient's attempts to seek prescriptions from multiple doctors or retrieve from multiple pharmacies. Other provinces have proposed similar legislation, while some, such as Nova Scotia, have legislation already in effect for monitoring prescription drug use. These changes have coincided with other changes in Ontario's legislation to target the misuse of painkillers and high addiction rates to drugs such as oxycodone. As of February 29, 2012, Ontario passed legislation delisting oxycodone from the province's public drug benefit program. This was a first for any province to delist a drug based on addictive properties. The new law prohibits prescriptions for OxyNeo except to certain patients under the Exceptional Access Program including palliative care and in other extenuating circumstances. Patients already prescribed oxycodone will receive coverage for an additional year for OxyNeo, and after that, it will be disallowed unless designated under the exceptional access program.[105]

Much of the legislative activity has stemmed from Purdue Pharma's decision in 2011 to begin a modification of Oxycontin's composition to make it more difficult to crush for snorting or injecting. The new formulation, OxyNeo, is intended to be preventative in this regard and retain its effectiveness as a painkiller. Since introducing its Narcotics Safety and Awareness Act, Ontario has committed to focusing on drug addiction, particularly in the monitoring and identification of problem opioid prescriptions, as well as the education of patients, doctors, and pharmacists.[106] This Act, introduced in 2010, commits to the establishment of a unified database to fulfil this intention.[107] Both the public and medical community have received the legislation positively, though concerns about the ramifications of legal changes have been expressed. Because laws are largely provincially regulated, many speculate a national strategy is needed to prevent smuggling across provincial borders from jurisdictions with looser restrictions.[108]

In 2015, Purdue Pharma's abuse-resistant OxyNEO and six generic versions of OxyContin had been on the Canada-wide approved list for prescriptions since 2012. In June 2015, then federal Minister of Health Rona Ambrose announced that within three years all oxycodone products sold in Canada would need to be tamper-resistant. Some experts warned that the generic product manufacturers may not have the technology to achieve that goal, possibly giving Purdue Pharma a monopoly on this opiate.[109]

Canadian lawsuitsEdit

Several class action suits across Canada have been launched against the Purdue group of companies and affiliates. Claimants argue the pharmaceutical manufacturers did not meet a standard of care and were negligent in doing so. These lawsuits reference earlier judgments in the United States, which held that Purdue was liable for wrongful marketing practices and misbranding. Since 2007, the Purdue companies have paid over CAN$650 million in settling litigation or facing criminal fines.

GermanyEdit

The drug is in Appendix III of the Narcotics Act (Betäubungsmittelgesetz or BtMG).[110] The law allows only physicians, dentists, and veterinarians to prescribe oxycodone and the federal government to regulate the prescriptions (e.g., by requiring reporting).[110]

Hong KongEdit

Oxycodone is regulated under Part I of Schedule 1 of Hong Kong's Chapter 134 Dangerous Drugs Ordinance.[111]

JapanEdit

Oxycodone is a restricted drug in Japan. Its import and export is strictly restricted to specially designated organizations having prior permit to import it. In a high-profile case an American who was a top Toyota executive living in Tokyo, who claimed to be unaware of the law, was arrested for importing oxycodone into Japan.[112][113]

SingaporeEdit

Oxycodone is listed as a Class A drug in the Misuse of Drugs Act of Singapore, which means offences in relation to the drug attract the most severe level of punishment. A conviction for unauthorized manufacture of the drug attracts a minimum sentence of 10 years of imprisonment and corporal punishment of 5 strokes of the cane, and a maximum sentence of life imprisonment or 30 years of imprisonment and 15 strokes of the cane.[114] The minimum and maximum penalties for unauthorized trafficking in the drug are respectively 5 years of imprisonment and 5 strokes of the cane, and 20 years of imprisonment and 15 strokes of the cane.[115]

United KingdomEdit

Oxycodone is a Class A drug under the Misuse of Drugs Act.[116] For Class A drugs, which are "considered to be the most likely to cause harm", possession without a prescription is punishable by up to seven years in prison, an unlimited fine, or both.[117] Dealing of the drug illegally is punishable by up to life imprisonment, an unlimited fine, or both.[117] In addition, oxycodone is a Schedule 2 drug per the Misuse of Drugs Regulations 2001 which "provide certain exemptions from the provisions of the Misuse of Drugs Act 1971".[118]

United StatesEdit

Under the Controlled Substances Act, oxycodone is a Schedule II controlled substance whether by itself or part of a multi-ingredient medication.[119] The DEA lists oxycodone both for sale and for use in manufacturing other opioids as ACSCN 9143 and in 2013 approved the following annual aggregate manufacturing quotas: 131.5 metric tons for sale, down from 153.75 in 2012, and 10.25 metric tons for conversion, unchanged from the previous year.[120]

Recreational useEdit

EffectsEdit

Oxycodone, like other opioid analgesics, tends to induce feelings of euphoria, relaxation and reduced anxiety in those who are occasional users.[121] These effects make it one of the most commonly abused pharmaceutical drugs in the United States.[122]

Preventive measuresEdit

In August 2010, Purdue Pharma reformulated their long-acting oxycodone line, marketed as OxyContin, using a polymer, Intac,[123] to make the pills extremely difficult to crush or dissolve[124] in water to reduce OxyContin abuse.[125] The FDA approved relabeling the reformulated version as abuse-resistant in April 2013.[126]

Pfizer manufactures a preparation of short-acting oxycodone, marketed as Oxecta, which contains inactive ingredients, referred to as tamper-resistant Aversion Technology.[127] It does not deter oral abuse. Approved by the FDA in the US in June 2011, the new formulation makes crushing, chewing, snorting, or injecting the opioid impractical because of a change in its chemical properties.[128]

AustraliaEdit

The non-medical use of oxycodone existed from the early 1970s, but by 2015, 91% of a national sample of injecting drug users in Australia had reported using oxycodone, and 27% had injected it in the last six months.[129]

CanadaEdit

Opioid-related deaths in Ontario had increased by 242% from 1969 to 2014.[130] By 2009 in Ontario there were more deaths from oxycodone overdose than from cocaine overdose.[131] Deaths from opioid pain relievers had increased from 13.7 deaths per million residents in 1991 to 27.2 deaths per million residents in 2004.[132] The abuse of oxycodone in Canada became a problem. Areas where oxycodone is most problematic are Atlantic Canada and Ontario, where its abuse is prevalent in rural towns, and in many smaller to medium-sized cities.[133] Oxycodone is also widely available across Western Canada, but methamphetamine and heroin are more serious problems in the larger cities, while oxycodone is more common in rural towns. Oxycodone is diverted through doctor shopping, prescription forgery, pharmacy theft, and overprescribing.[133][134]

The recent formulations of oxycodone, particularly Purdue Pharma's crush-, chew-, injection- and dissolve-resistant OxyNEO[135] which replaced the banned OxyContin product in Canada in early 2012, have led to a decline in the abuse of this opiate but have increased the abuse of the more potent drug fentanyl.[136] According to a Canadian Centre on Substance Abuse study quoted in Maclean's magazine, there were at least 655 fentanyl-related deaths in Canada in a five-year period.[137]

In Alberta, the Blood Tribe police claimed that from the fall of 2014 through January 2015, oxycodone pills or a lethal fake variation referred to as Oxy 80s[138] containing fentanyl made in illegal labs by members of organized crime were responsible for ten deaths on the Blood Reserve, which is located southwest of Lethbridge, Alberta.[139] Province-wide, approximately 120 Albertans died from fentanyl-related overdoses in 2014.[138]

United KingdomEdit

Abuse and diversion of oxycodone in the UK commenced in the early- to mid-2000s.[140] The first known death due to overdose in the UK occurred in 2002.[141] However, recreational use remains relatively rare.

United StatesEdit

In the United States, more than 12 million people use opioid drugs recreationally.[142] Opioids were responsible for 49,000 of the 72,000 drug overdose deaths in the US in 2017.[143] In September 2013, the FDA released new labeling guidelines for long acting and extended release opioids requiring manufacturers to remove moderate pain as indication for use, instead stating the drug is for "pain severe enough to require daily, around-the-clock, long term opioid treatment."[144] The updated labeling will not restrict physicians from prescribing opioids for moderate, as needed use.[142]

Oxycodone is the most widely recreationally used opioid in America. The U.S. Department of Health and Human Services estimates that about 11 million people in the US consume oxycodone in a non-medical way annually.[145] In 2007, about 42,800 emergency room visits occurred due to "episodes" involving oxycodone.[146] Diverted oxycodone may be taken orally or ingested through insufflation; used intravenously, or the heated vapors inhaled. In 2008, recreational use of oxycodone and hydrocodone were involved in 14,800 deaths. Some of the cases were due to overdoses of the acetaminophen component, resulting in fatal liver damage.[147]

Reformulated OxyContin is causing some recreational users to change to heroin, which is cheaper and easier to obtain.[148]

EconomicsEdit

The International Narcotics Control Board estimated 11.5 short tons (10.4 t) of oxycodone were manufactured worldwide in 1998;[149] by 2007 this figure had grown to 75.2 short tons (68.2 t).[149] United States accounted for 82% of consumption in 2007 at 51.6 short tons (46.8 t). Canada, Germany, Australia, and France combined accounted for 13% of consumption in 2007.[149][150] In 2010, 1.3 short tons (1.2 t) of oxycodone were illegally manufactured using a fake pill imprint. This accounted for 0.8% of consumption. These illicit tablets were later seized by the U.S. Drug Enforcement Administration, according to the International Narcotics Control Board.[151] The board also reported 122.5 short tons (111.1 t) manufactured in 2010. This number had decreased from a record high of 135.9 short tons (123.3 t) in 2009.[152]

LawsuitsEdit

In October 2017, The New Yorker published a story on Mortimer Sackler and Purdue Pharma regarding their ties to the production and manipulation of the oxycodone markets.[94] The article links Raymond and Arthur Sackler's business practices with the rise of direct pharmaceutical marketing and eventually to the rise of addiction to oxycodone in the United States. The article implies that Sackler bears some responsibility for the opioid epidemic in the United States.[153] In 2019 the New York Times ran a piece confirming Sackler told company officials in 2008 to “measure our performance by Rx’s by strength, giving higher measures to higher strengths.”[154] This was verified with documents tied to a lawsuit – which was filed by the Massachusetts attorney general, Maura Healey – claiming that Purdue Pharma and members of the Sackler family knew that high doses of OxyContin over long periods would increase the risk of serious side effects, including addiction.[155] Despite Purdue Pharma's proposal for a US$12 billion settlement of the lawsuit, the attorneys general of 23 states, including Massachusetts, rejected the settlement offer in September, 2019.[156]

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Further readingEdit