Oxycodone's hepatic metabolism is extensive and completed by 4 main reactions. CYP3A4 and 3A5 perform N-demethylation, CYP2D6 performs O-demethylation, unknown enzymes perform 6-keto-reduction, and unknown enzymes perform conjugation. Oxycodone is metabolized by CYP3A4 and CYP3A5 to noroxycodone and then by CYP2D6 to noroxymorphone. Noroxycodone and noroxymorphone are the primary circulating metabolites. Noroxycodone can also be 6-keto-reduced to alpha or beta noroxycodol. Oxycodone can be metabolized by CYP2D6 to oxymorphone and then by CYP3A4 to noroxymorphone. Oxymorphone can also be 6-keto-reduced to alpha or beta oxymorphol. Oxycodone can also be 6-keto-reduced to alpha and beta oxycodol. The active metabolites noroxycodone, oxymorphone, and noroxymorphone can all be conjugated before elimination.
The hepatic metabolism of oxycodone by cytochromes P450 (CYP) and the UDP-glucuronosyltransferases (UGT), the main metabolic enzymes of phase I and phase II, respectively, was assessed in vitro. The N-demethylation by CYP3A4/5 and the O-demethylation by CYP2D6 in human liver microsomes (HLM) followed Michaelis-Menten kinetics, with intrinsic clearances of 1.46 uL/min/mg and 0.35 uL/min/mg, respectively. Although noroxycodone and oxymorphone mainly contribute to the elimination of oxycodone, the simulated total in vivo clearance using in vitro phase I metabolism was underestimated. For the first time, metabolism of oxycodone by UGT was deeply investigated using HLM, recombinant enzymes and selective inhibitors. Oxycodone-glucuronide was mainly produced by UGT2B7 (Km=762 +/- 153 uM, Vmax=344 +/- 20 peak area/min/mg) and to a lesser extent by UGT2B4 (Km=2454 +/- 497 uM, Vmax=201 +/- 19 peak area/min/mg). Finally, the kinetics of the drug-drug interactions were assessed using two CYP and UGT cocktail approaches. Incubations of HLM with phase I and phase II drug probes showed that oxycodone mainly decreased the in vitro activities of CYP2D6, CYP3A4/5, UGT1A3, UGT1A6 and UGT2B subfamily with an important impact on UGT2B7.
Oxycodone hydrochloride is extensively metabolized by multiple metabolic pathways to noroxycodone, oxymorphone, and noroxymorphone, which are subsequently glucuronidated. CYP3A4 mediated N-demethylation to noroxycodone is the primary metabolic pathway of oxycodone with less contribution from CYP2D6 mediated O-demethylation to oxymorphone. Therefore, the formation of these and related metabolites can, in theory, be affected by other drugs. The major circulating metabolite is noroxycodone with an AUC ratio of 0.6 relative to that of oxycodone. Noroxycodone is reported to be a considerably weaker analgesic than oxycodone. Oxymorphone, although possessing analgesic activity, is present in the plasma only in low concentrations. The correlation between oxymorphone concentrations and opioid effects was much less than that seen with oxycodone plasma concentrations. The analgesic activity profile of other metabolites is not known.
Oxycodone undergoes N-demethylation to noroxycodone and O-demethylation to oxymorphone. The cytochrome P450 (P450) isoforms capable of mediating the oxidation of oxycodone to oxymorphone and noroxycodone were identified using a panel of recombinant human P450s. CYP3A4 and CYP3A5 displayed the highest activity for oxycodone N-demethylation; intrinsic clearance for CYP3A5 was slightly higher than that for CYP3A4. CYP2D6 had the highest activity for O-demethylation. Multienzyme, Michaelis-Menten kinetics were observed for both oxidative reactions in microsomes prepared from five human livers. Inhibition with ketoconazole showed that CYP3A is the high affinity enzyme for oxycodone N-demethylation; ketoconazole inhibited >90% of noroxycodone formation at low substrate concentrations. CYP3A-mediated noroxycodone formation exhibited a mean K(m) of 600 +/- 119 uM and a V(max) that ranged from 716 to 14523 pmol/mg/min. Contribution from the low affinity enzyme(s) did not exceed 8% of total intrinsic clearance for N-demethylation. Quinidine inhibition showed that CYP2D6 is the high affinity enzyme for O-demethylation with a mean K(m) of 130 +/- 33 uM and a V(max) that ranged from 89 to 356 pmol/mg/min. Activity of the low affinity enzyme(s) accounted for 10 to 26% of total intrinsic clearance for O-demethylation. On average, the total intrinsic clearance for noroxycodone formation was 8 times greater than that for oxymorphone formation across the five liver microsomal preparations (10.5 uL/min/mg versus 1.5 uL/min/mg). Experiments with human intestinal mucosal microsomes indicated lower N-demethylation activity (20-50%) compared with liver microsomes and negligible O-demethylation activity, which predict a minimal contribution of intestinal mucosa in the first-pass oxidative metabolism of oxycodone.
IDENTIFICATION AND USE: Oxycodone is a Schedule II controlled substance. It is an opioid agonist indicated for the management of pain severe enough to require an opioid analgesic and for which alternative treatments are inadequate. HUMAN STUDIES: Oxycodone is a full opioid agonist and is relatively selective for the mu-opioid receptor, although it can bind to other opioid receptors at higher doses. The principal therapeutic action of oxycodone is analgesia. Acute overdose can be manifested by respiratory depression, somnolence progressing to stupor or coma, skeletal muscle flaccidity, cold and clammy skin, constricted pupils, and, in some cases, pulmonary edema, bradycardia, hypotension, partial or complete airway obstruction, atypical snoring, and death. Marked mydriasis rather than miosis may be seen with hypoxia in overdose situations. Both tolerance and physical dependence can develop during chronic opioid therapy. Prolonged use during pregnancy can result in withdrawal in the neonate. Neonatal opioid withdrawal syndrome, unlike opioid withdrawal syndrome in adults, may be life-threatening. Accidental ingestion of even one dose especially by children, can result in respiratory depression and death due to an overdose of oxycodone. ANIMAL STUDIES: In embryo-fetal development studies in rats and rabbits, pregnant animals received oral doses of oxycodone administered during the period of organogenesis up to 16 mg/kg/day and 25 mg/kg/day, respectively. These studies revealed no evidence of teratogenicity or embryo-fetal toxicity due to oxycodone. Exposure to 0.5 mg/kg/day oxycodone in utero was associated with hyperactivity in adult rats in an open field. No significant effects of perinatal oxycodone exposure were detected on isolation-induced ultrasonic vocalizations in the early postnatal period or on learning and memory in the water maze in adult offspring. Offspring of pregnant rats administered oxycodone during gestation have been reported to exhibit neurobehavioral effects including altered stress responses, increased anxiety-like behavior. Oxycodone was genotoxic in an in vitro mouse lymphoma assay in the presence of metabolic activation. There was no evidence of genotoxic potential in an in vitro bacterial reverse mutation assay (Salmonella typhimurium and Escherichia coli) and in an assay for chromosomal aberrations (in vivo mouse bone marrow micronucleus assay).
Oxycodone acts as a weak agonist at mu, kappa, and delta opioid receptors within the central nervous system (CNS). Oxycodone primarily affects mu-type opioid receptors, which are coupled with G-protein receptors and function as modulators, both positive and negative, of synaptic transmission via G-proteins that activate effector proteins. Binding of the opiate stimulates the exchange of GTP for GDP on the G-protein complex. As the effector system is adenylate cyclase and cAMP located at the inner surface of the plasma membrane, opioids decrease intracellular cAMP by inhibiting adenylate cyclase. Subsequently, the release of nociceptive neurotransmitters such as substance P, GABA, dopamine, acetylcholine, and noradrenaline is inhibited. Opioids such as oxycodone also inhibit the release of vasopressin, somatostatin, insulin, and glucagon. Opioids close N-type voltage-operated calcium channels (kappa-receptor agonist) and open calcium-dependent inwardly rectifying potassium channels (mu and delta receptor agonist). This results in hyperpolarization and reduced neuronal excitability.
Despite wide scale use for many decades, oxycodone has not been convincingly linked to instances of clinically apparent acute liver injury. However, oxycodone and other opioid-acetaminophen combinations have become a common cause of acute liver injury, which is usually the result of excessive use of the medication for the opioid effect, which leads secondarily and unintentionally to an overdose of acetaminophen. In 2014, the FDA warned against the use of opioid combinations in which the dose of acetaminophen is greater than 325 mg per tablet or unit dose. Because of their potential for hepatotoxicity, opioid combinations in which the dose of acetaminophen is greater than 325 mg per tablet or capsule were discontinued.
Oxycodone, like other opiates, is metabolized in the liver by the P450 microsomal oxidizing enzyme system, and levels can be significantly affected by either inhibitors of CYP 3A4 (which increase levels and can lead to toxicity) or inducers of the enzyme (which decrease levels and reduce efficacy).
Likelihood score: E (unlikely cause of drug-induced liver injury).
References on the safety and potential hepatotoxicity of oxycodone are given in the overview section of the Opioids.
Drug Class: Opioids
Oxycodone has an oral bioavailability of 60% to 87% that is unaffected by food. The area under the curve is 135ng/mL\*hr, maximum plasma concentration is 11.5ng/mL, and time to maximum concentration is 5.11hr in patients given a 10mg oral immediate release dose of oxycodone.
Oxycodone and its metabolites are eliminated in the urine. Unbound noroxycodone makes up 23% of the dose recovered in urine and oxymorphone makes up <1%. Conjugated oxymorphone makes up 10% of the recovered dose. Free and conjugated oxycodone makes up 8.9% of the recovered dose, noroxymorphone makes up 14%, and reduced metabolites make up 18%.
About 60 to 87% of an oral dose reaches the systemic circulation in comparison to a parenteral dose. This high oral bioavailability (compared to other opioids) is due to lower pre-systemic and/or first-pass metabolism of oxycodone.
Combined biological and chemical catalysis in the preparation of oxycodone
摘要:
The opioid oxycodone was produced from codeine, using a combination of chemical and biological catalysis. The use of novel functionalized ionic liquids permitted this reaction to be performed in a single solvent. (C) 2003 Published by Elsevier Ltd.
DOI:
10.1016/j.tet.2003.11.063
作为试剂:
描述:
14beta-Hydroxycodeinone 、 氢气 在
钯羟可待酮 、 氨 、 水 作用下,
以
aqueous solution 、 溶剂黄146 、 水 为溶剂,
5.0~80.0 ℃
、14.13 MPa
条件下,
以At least 67 kg (92%, purity 98.5%) of Oxycodone is obtained的产率得到羟可待酮
[EN] S-NITROSOMERCAPTO COMPOUNDS AND RELATED DERIVATIVES<br/>[FR] COMPOSÉS DE S-NITROSOMERCAPTO ET DÉRIVÉS APPARENTÉS
申请人:GALLEON PHARMACEUTICALS INC
公开号:WO2009151744A1
公开(公告)日:2009-12-17
The present invention is directed to mercapto-based and S- nitrosomercapto-based SNO compounds and their derivatives, and their use in treating a lack of normal breathing control, including the treatment of apnea and hypoventilation associated with sleep, obesity, certain medicines and other medical conditions.
[EN] DIHYDROPYRROLONAPHTYRIDINONE COMPOUNDS AS INHIBITORS OF JAK<br/>[FR] COMPOSÉS DE DIHYDROPYRROLONAPHTYRIDINONE COMME INHIBITEURS DE JAK
申请人:TAKEDA PHARMACEUTICAL
公开号:WO2010144486A1
公开(公告)日:2010-12-16
Disclosed are JAK inhibitors of formula (I) where G1, R1, R2, R3, R4, R5, R6, and R7 are defined in the specification. Also disclosed are pharmaceutical compositions, kits and articles of manufacture which contain the compounds, methods and materials for making the compounds, and methods of using the compounds to treat diseases, disorders, and conditions involving the immune system and inflammation, including rheumatoid arthritis, hematological malignancies, epithelial cancers (i.e., carcinomas), and other diseases, disorders or conditions associated with JAK.
[EN] NOVEL COMPOUNDS AND PHARMACEUTICAL COMPOSITIONS THEREOF FOR THE TREATMENT OF INFLAMMATORY DISORDERS<br/>[FR] NOUVEAUX COMPOSÉS ET COMPOSITIONS PHARMACEUTIQUES LES COMPRENANT POUR LE TRAITEMENT DE TROUBLES INFLAMMATOIRES
申请人:GALAPAGOS NV
公开号:WO2017012647A1
公开(公告)日:2017-01-26
The present invention discloses compounds according to Formula (I), wherein R1, R3, R4, R5, L1, and Cy are as defined herein. The present invention also provides compounds, methods for the production of said compounds of the invention, pharmaceutical compositions comprising the same and their use in allergic or inflammatory conditions, autoimmune diseases, proliferative diseases, transplantation rejection, diseases involving impairment of cartilage turnover, congenital cartilage malformations, and/or diseases associated with hypersecretion of IL6 and/or interferons. The present invention also methods for the prevention and/or treatment of the aforementioned diseases by administering a compound of the invention.
[EN] COMPOUNDS AND THEIR USE AS BACE INHIBITORS<br/>[FR] COMPOSÉS ET LEUR UTILISATION EN TANT QU'INHIBITEURS DE BACE
申请人:ASTRAZENECA AB
公开号:WO2016055858A1
公开(公告)日:2016-04-14
The present application relates to compounds of formula (I), (la), or (lb) and their pharmaceutical compositions/preparations. This application further relates to methods of treating or preventing Αβ-related pathologies such as Down's syndrome, β- amyloid angiopathy such as but not limited to cerebral amyloid angiopathy or hereditary cerebral hemorrhage, disorders associated with cognitive impairment such as but not limited to MCI ("mild cognitive impairment"), Alzheimer's disease, memory loss, attention deficit symptoms associated with Alzheimer's disease, neurodegeneration associated with diseases such as Alzheimer's disease or dementia, including dementia of mixed vascular and degenerative origin, pre-senile dementia, senile dementia and dementia associated with Parkinson's disease.
[EN] ARYL ETHER-BASE KINASE INHIBITORS<br/>[FR] INHIBITEURS DE KINASES DE TYPE ARYLÉTHER-BASE
申请人:BRISTOL MYERS SQUIBB CO
公开号:WO2015038112A1
公开(公告)日:2015-03-19
The present disclosure is generally directed to compounds which can inhibit AAK1 (adaptor associated kinase 1), compositions comprising such compounds, and methods for inhibiting AAK1.
