Systematic (IUPAC) name
CAS number 76-41-5
ATC code N02A
PubChem 5284604
DrugBank APRD00158
ChemSpider 4447650
Chemical data
Formula C17H19NO4 
Mol. mass 301.337 g/mol
Synonyms 14-Hydroxydihydromorphinone
Pharmacokinetic data
Bioavailability 10% (oral)
Metabolism hepatic
Half life 1.3 +/- 0.7 hrs (with parenteral admin)[1]; 7.25-9.43 hr (with oral admin)[2]
Excretion 35% urine, 65% feces
Therapeutic considerations
Pregnancy cat. C(US)
Legal status Schedule I (CA) ? (UK) Schedule II (US)
Dependence Liability High
Routes intravenous, intramusucular, subcutaneous, oral, rectal
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Oxymorphone (Opana, Numorphan, Numorphone) or 14-Hydroxydihydromorphinone is a powerful semi-synthetic opioid analgesic first developed in Germany circa 1914, patented in the USA by Endo Pharmaceuticals in 1955 and introduced to the United States market in January 1959 and other countries around the same time. It differs from morphine in its effects in that it generates less euphoria, sedation, itching and other histamine effects. Depending on the individual patient, it can be either more or less nausea- and vomit-inducing than morphine.

The brand name Numorphan is derived by analogy to the Nucodan name for an oxycodone product (or vice versa) as well as Paramorphan/Paramorfan for dihydromorphine and Paracodin (dihydrocodeine). The only commercially available salt of oxymorphone in most of the world at this time is the hydrochloride, which has a free base conversion ratio of 0.891.

In some countries, hydromorphinol is distributed under the trade names Numorphan and Numorphan Oral. This is a relatively rare exception and the two drugs, whilst both being strong opioid analgesics, are notably different from one another.

Oxymorphone is administered as its hydrochloride salt via injection, or suppository; typically in dosages of 1 mg (injected) to 5 mg (suppository). Endo has been the major distributor of oxymorphone throughout the world and currently markets oxymorphone in the United States and elsewhere as Opana and Opana ER.

Opana is available as 5 mg and 10 mg tablets; Opana ER, an extended-release form of oxymorphone, is available as tablets in strengths of 5 mg, 7½ mg, 10 mg, 15 mg, 20 mg, 30 mg, and 40 mg. Some resources assert that 2, 12 and/or 15 mg IR tablets and 25, 36 and 50 mg extended release tablets will be introduced although apparently the timeline on that is not known to the public at this time. Opana Extended-Release tablets are based on the TIMERx system developed by a consortium led by Endo and Penwest.

In addition to the sustained-release version for Opana, other versions of TIMERx are available and being developed for other protocols such as increasing, decreasing, stepwise increasing, and stepwise decreasing dose delivery over time, single and multiple bursts of medication, and combinations of the above.

Specifically, the apparent extension of the duration of effect of the IR tablets (all other things being equal, oxymorphone has a duration of action of 5 to 8 hours in most patients) versus similar drugs in commonly used immediate-release forms—for example Dilaudid (hydromorphone), morphine, Vilan(nicomorphine), Paramorfan (dihydromorphine) as well as prodrugs for this group such as hydrocodone, nicocodeine, codeine, dihydrocodeine and others—is often attributed to a marginal extended-release effect from various excipients, particularly those which are hydrophilic and form a gel-like substance at the pH levels in the stomach and duodenum.

Both as the result of this and the pharmacokinetics of oxymorphone, the IR tablets have a de facto duration of action of 5 to 13 hours (the mean would seem to be around 7 hours with a moderately small standard deviation amd a left-skewed and leptokurtic frequency distribution) in patients with normal kidney and liver function. As a result, patients rotated on to extended release oxymorphone preparations from other opioids may very well need the Opana IR tablets, Numorphan ampoules or phials with hypodermic needles and/or a PCA pump, or immediate-release formulations of hydromorphone, dihydromorphine, high dose oxycodone, hydromorphinol, nicomorphine, diamorphine, or morphine for breakthrough pain incidents which are already in progress. An oxymorphone nasal spray is reportedly in development, along with a possible hydromorphone nasal spray and implantable osmotic pumps for both drugs.

The duration of action and metabolic half-life of oxymorphone mean that immediate-release tablets are more similar to analgesic preparations of methadone, levorphanol, piritramide, and existing extended-relase forms of morphine, oxycodone, ketobemidone and so on. The extended-release Opana tablets can provide detectable analgesia for anywhere from 6 to 36+ hours (the mean appears to be very close to the lower end of the continuum) largely contingent on things which can alter the Liberation, Absorption, Distribution, Metabolism & Elimination profile of the drug. One cause is unusual conditions in the upper and middle GI tract such as that created by misoprostol and Arthrotec (misoprostol plus diclofenac), Amongst other things, misoprostol is a smooth muscle agent which both a contact and systemic mucousagogue which coats the stomach and adjacent areas with increasing amounts of mucus. This can result in everything from even slower onset of action to intact tablets being passed with stool.

Oxymorphone is also produced within the human body when the liver metabolises oxycodone by means of O demethylation catalysed by the Cytochrome P-450 enzyme family, in particular the II-D-6 and III-A-2 thereof. Approximately 10 per cent of the dose is processed by the endocrine system in this respect; this can vary widely from person to person. The codeine-hydrocodone group and morphinans exhibit the same characteristics.

Alcohol consumption along the Opana extended-release tablets can be an extremely dangerous situation as it can cause "dose dumping" which creates a blast of drug release and increase of bioavailabilty of the oxymorphone in the tablets in excess of 70 per cent.


Oxymorphone is indicated for the relief of moderate to severe pain and also as a preoperative medication to alleviate apprehension, maintain anesthesia, and as an obstetric analgesic. Additionally, it can be used for the alleviation of pain in patients with dyspnea associated with acute left ventricular failure and pulmonary oedema.

Opana extended-release tablets are indicated for the management of chronic pain of all or most aetiologies and are indicated only for patients already on a regular schedule of strong opioids for a prolonged period. The immediate-release Opana tablets are recommended for management of breakthrough pain for patients on the extended-release version. Some protocols for chronic pain conditions characterised by severe breakthrough pain incidents add Numorphan ampoules as a third form of the drug for use when a breakthrough pain incident is in progress. An oxymorphone nasal spray is being developed for this purpose but the release date is unknown; some practitioners prefer fentanyl immediate-release formulations such as Actiq or Fentora for this purpose although some patients have severe side effects from fentanyl.

Oxymorphone is used in veterinary medicine in many of the same uses as for humans, with induction and maintenance of anaesthetia and sometimes tranquillisation of small and medium-sized animals being the most common use. Morphine, hydromorphone, various fentanyls, levorphanol, and butorphanol are also common in veterinary settings and tramadol is reportedly being studied as a general analgesic for cats, dogs, ferrets, rats and other animals in that size range.

Oxymorphone is mentioned,along with buprenorphine, oxycodone, dihydrocodeine, morphine and other opioids as a possible means of mitigating refractory depression.[3][4][5] Opioids were commonly used for this indication up until the introduction of the tricyclic antidepressants in the 1950s, even though they appear to work in a smaller percentage of cases and are generally more toxic than most chemical classes of opioids. Conversely, tricyclic anti-depressants and chemically-related drugs are the most commonly-used adjuvants and atypical analgesics used with opioids for pain, especially neuropathic pain.

 Physical characteristics

Oxymorphone HCl occurs as odorless white crystals or white to off-white powder. It will darken in color with prolonged exposure to light although this does not have an effect on potency. One gram of oxymorphone is soluble in 4 ml of water and it is slightly soluble in alcohol and ether. The commercially available injection has a pH of 2.7–4.5.


In common with other opioids, oxymorphone overdosage is characterized by respiratory depression, extreme somnolence progressing to stupor or coma, skeletal muscle flaccidity, cold and clammy skin, and sometimes bradycardia and hypotension. In a severe case of overdose, apnea, circulatory collapse, cardiac arrest, and death may occur.

At equianalgesic doses oxymorphone is marginally more toxic than morphine but less so than fully synthetic opioids such as methadone and pethidine. At therapeutic doses, toxicity is primarily manifested as miosis, nausea, and possibly occasional mild involuntary muscle movements especially in the distal portions of the extremities and the shoulder area in some cases. This is most common in patients taking a number of other drugs for their condition, especially muscle relaxants and some adjuvant analgesics, and also appears to happen most often during and immediately after a significant upward titration in the single-dose and per 24 hour doses.

Instances of the body suddenly jerking bolt upright from a more relaxed sitting position is a sign of high and/or rapidly increasing serum levels of opioids and all of the above movements are likely due to the anticholinergic or anticholinergic-like effects of opioids and/or other medications prescribed at the same time, as they manifest in patients on atropine-like drugs as well. The primary risk here involves dropping objects, spilling liquids, striking body parts against walls, and potentially losing footing on flat ice surfaces.

While all this can be frightening at first, more than 85 percent of patients do not experience it at any time during treatment, and oxymorphone does not appear to induce seizures in neurologically healthy patients as does the pethidine series of opioids (pethidine, anileridine, alphaprodine, piminodine and others) nor does it have toxic metabolites which accumulate in the system as do the pethdine and methadone families of synthetic opioids. There is also no real evidence that oxymorphone significantly lowers the seizure threshold as do tramadol and some of the other synthetics mentioned above.

 Brand Names

  • Numorphan (suppository and injectable solution)
  • Opana (tablet)
  • Opana ER (extended-release tablet)

Other manufacturers and Endo themselves have also, according to reports in the mass media and professional journals over the last few years, considered and/or are currently developing a Duragesic-style oxymorphone skin plasters and oxymorphone and hydromorphone nasal sprays.

 Illicit Use

Like other effective centrally-acting analgesics, some of the additional effects of oxymorphone can include euphoria, anxiolysis, promotion of sociability, and other similar effects that can cause psychological addiction to the drug. Also, like all other opiates, oxymorphone is physically addictive and can cause opiate withdrawal symptoms.

On the other hand oxymorphone can generate a serious narcotic habit rather quickly in those who take it recreationally in that it has powerful euphorigenic (contradiction to first paragraph which says it has less euphorigenic properties than morphine.)properties which some rank as the highest amongst narcotics, many placing it above morphine, heroin, hydromorphone, and dextromoramide.

The significant antidepressant and empathogenic properties of oxymorphone and other dihydromorphinone class semi-synthetic opioids is currently of interest to both the underground and the medical establishment, the latter of whom are "re-discovering" the anti-depressant effect and its relatively low ratio of toxic effects and lack of association with patient suicide attempts (see the oxycodone article for further discussion and footnotes) and Opana ER has been proposed as an alternative to methadone and other extended-release and/or long lasting drugs like MS-Contin, extended-release dihydrocodeine, buprenorphine, and 24-hour hydromorphone tablets for opioid detoxification and maintenance.

Endo withdrew the original Numorphan tablets from the market in 1972 as the result of regulatory and market pressures and other considerations as it was passionately sought, by any means necessary, by some narcotics addicts. Until its removal from the United States market at that point, oxymorphone in the form of Numorphan 10 mg instant-release tablets was one of the most sought-after and well-regarded opioids of the IV drug using community. Because of its low bioavailability, 10% when taken orally, a 10 mg tablet represents 10 times the average IV dose in a single tablet. Known popularly as "blues" or "Nu- Blues" for their light blue color, the tablets contained very few insoluble binders—making them easy to inject—and were extremely potent when used intravenously. "Blues" were also considered to be especially euphoric; comparable to or better than heroin. Numorphan tablets, and the oxymorphone they contained, are the "blues" referred to in the film Drugstore Cowboy.

Slang terms for oxymorphone include: blues, biscuits, blue heaven, new blues (although the immediate-release tablets are pink and off-white), octagons (extended release), [strength] octagons, stop signs, pink, pink heaven, biscuits (could also be Dilaudid tablets, meprobamate tablets, or formerly Quaaludes), pink heaven, pink lady, Mrs O, Orgasna IR, OM, Pink O, The O Bomb (by analogy to the slang term for hydromorphone "H Bomb") and others.

Oxymorphone is not a component of "T's and blues", 1970s slang for a combination of pentazocine ("T's") and pyribenzamine ("blues"). Nor are "blues" 10 mg Valium tablets, which are known as Blue Bombers and BBs.

Oxymorphone was available in the United States only as suppositories and ampoules for hospital use for 35 years until recently, making diversion of the ampoules and the time-consuming proceess of melting, mixing with water, then chilling the suppositories and drawing off the aqueous portion of the results and boiling down as the major means of use of oxymorphone pharmaceuticals in means inconsistent with their labelling in the USA. Rare cases of users baking their own at home by extracting oxycodone from pharmaceuticals and converting it to oxymorphone have been reported in the a number of countries. In some cases, codeine is the starting material with morphine, or more rarely thebaine, being the intermediate. In those cases, the more common end products sought are morphine salts, morphine base, heroin, dihydromorphine, desomorphine, and hydromorphone.

The low bioavailability of oxymorphone after oral administration requires Opana extended-release to contain up to 40 mg of oxymorphone per tablet—almost as much as an entire case of Numorphan ampoules; attempts to circumvent the extended-release mechanism by injecting or snorting the tablets are therefore particularly dangerous. However, chewing the tablets and/or taking with alcohol for the 70 per cent bioavailability boost from the latter appear to be the only means successful Opana ER misuse aside from insufflation -- the TIMERx system appears to be making the extended release tablets useless for preparing for injection. Indeed, it appears that the tablet was designed first and oxymorphone chosen as the active ingredient because all the others available in the USA for oral use (fentanils are rapidly destroyed almost completely in the digestive tract, leaving only injection, transdermal, transmucosal, sublingual, and buccal routes as options) with the possible exception of levorphanol or doses of hydromorphone in the 50 to 200 mg range as useful for making a TIMERx-based analgesic preparation.

Drug Name Opana/ Oxymorphone Strength(s) 5 mg 10 mg Imprint(s) J 93/10 mg Beige/off-white, J 95/5 mg Beige/off wihte Tablet Scored In Half on Back Side

Manufacturer: Endo Pharmaceuticals


Oxymorphone is commercially produced from thebaine, which is a minor constituent of the opium poppy (Papaver somniferum) but thebaine is found in greater abundance (3%) in the roots of the oriental poppy (Papaver orientale). Oxymorphone can also be synthesized from morphine or oxycodone, and is an active metabolite of the latter drug. The structure-activity relationship of oxymorphone and its derivatives has been well-examined. Esterification of the hydroxyl groups yields stronger compounds. The acetyl ester is 2.5 times more potent and the propenyl ester six times more potent than the parent compound. If the 14-hydroxyl group is formed into the cinnamyl ester, the product is 114 times more potent. The most powerful oxymorphone derivative known is the 14-cinnamyl 3-acetyl ester, which is over 200 times more potent than morphine.[6] Another derivative of oxymorphone is the narcotic antagonist naloxone (Narcan).

As reported in the July 1993 issue of Applied Environmental Bacteriology (PDF available at http://aem.asm.org/cgi/reprint/61/10/3645.pdf), the bacterium Pseudomonas putida, serotype M10 turns oxymorphone into oxymorphol by means of a one-step conversion involving morphine dehydrogenase and a naturally occurring NADH-dependent morphinone reductase which can work on unsaturated 7,8 bonds.

German patents from the middle 1930s indicate that oxymorphone as well as hydromorphone, hydrocodone, oxycodone, and acetylmorphone can be prepared—without the need for hydrogen gas—from solutions of codeine, morphine, and dionine by refluxing an acidic aqueous solution, or the precursor drug dissolved in ethanol, in the presence of Column 7 metals, namely palladium and platinum in fine powder or colloidal form or platina black. It is unclear from information available if aluminium or nickel can be used as a catalyst in these reactions as well.

A discussion of the above can be found at http://www.erowid.org/archive/rhodium/chemistry/dihydromorphinones.html (English). However, the aforementioned patents deal specifically with hydrogenation reactions producing dihydrocodinone (hydrocodone), dihydromorphinone (hydromorphone), and ethyldihydromorphinone as final products. Hence it is unclear at best and rather unlikely that these particular procedures can be applied for the synthesis of oxycodone or oxymorphone, as they are not typically synthesized in this manner.

The rare practise of making homebake oxymorphone generally uses oxycodone and pyridine amongst others, and the production of homebake hydromorphone (Dilaudid) from hydrocodone does also exist but is extremely rare. This is similar to a method especially common in New Zealand to make morphine out of codeine. The resultant morphine base is used as is, made into a salt (usually citrate, although ascorbate, acetate, hydrochloride, nitrate, phosphate, and sulphate are also possible) by dissolving the base in a solution containing the relevant acid, or treated with acetic anhydride or rarely other chemicals capable of acetylating compounds to produce what is usually a mixture of heroin, morphine, 3-monoacetylmorphine and 6-monoacetylmorphine. Depending on the method, this can also contain acetylcodeine and leftover codeine.

 See also


  1. ^ rxlist.com
  2. ^ Adams MP, Ahdieh H (2005). "Single- and multiple-dose pharmacokinetic and dose-proportionality study of oxymorphone immediate-release tablets". Drugs R D 6 (2): 91–9. doi:10.2165/00126839-200506020-00004. PMID 15777102. 
  3. ^ Stoll AL, Rueter S (December 1, 1999). "Treatment augmentation with opiates in severe and refractory major depression". Am J Psychiatry 156 (12): 2017. PMID 10588427. http://ajp.psychiatryonline.org/cgi/pmidlookup?view=long&pmid=10588427. Retrieved 2009-03-03. 
  4. ^ Schürks M, Overlack M, Bonnet U (March 2005). "Naltrexone treatment of combined alcohol and opioid dependence: deterioration of co-morbid major depression". Pharmacopsychiatry 38 (2): 100–2. doi:10.1055/s-2005-837812. PMID 15744636. 
  5. ^ Tejedor-Real P, Mico JA, Maldonado R, Roques BP, Gibert-Rahola J (September 1995). "Implication of endogenous opioid system in the learned helplessness model of depression". Pharmacol Biochem Behav 52 (1): 145–52. doi:10.1016/0091-3057(95)00067-7. PMID 7501657. 
  6. ^ J Exp Ther. Pharm. (1964) 174–182.


The content of this section is licensed under the GNU Free Documentation License (local copy). It uses material from the Wikipedia article "Oxymorphone" modified November 23, 2009 with previous authors listed in its history.