All Medical Genetics Summaries content, except where otherwise noted, is licensed under a Creative Commons Attribution 4.0 International (CC BY 4.0) license which permits copying, distribution, and adaptation of the work, provided the original work is properly cited and any changes from the original work are properly indicated. Any altered, transformed, or adapted form of the work may only be distributed under the same or similar license to this one.
NCBI Bookshelf. A service of the National Library of Medicine, National Institutes of Health.
Pratt VM, Scott SA, Pirmohamed M, et al., editors. Medical Genetics Summaries [Internet]. Bethesda (MD): National Center for Biotechnology Information (US); 2012-.
Introduction
Oxycodone (brand names OxyContin, Roxicodone, Xtampza ER, and Oxaydo), is an opioid analgesic used for moderate to severe pain caused by various conditions for which alternative analgesic treatments are inadequate.(1) Oxycodone exerts its analgesic affects by binding to the mu-opioid receptors (MOR) in the central and peripheral nervous system. While it is an effective pain reliever, this agent also has a high potential for addiction, abuse, and misuse.
Oxycodone is metabolized by members of the cytochrome P450 (CYP) enzyme superfamily. The CYP3A4, CYP3A5, and CYP2D6 enzymes convert oxycodone to either less-active (CYP3A4 and CYP3A5) or more-active (CYP2D6) metabolites. Most of the analgesic effect is mediated by oxycodone itself, rather than its metabolites. Variation at the CYP3A4 and CYP3A5 loci leading to altered enzyme activity is rare. A handful of altered-function alleles are known, but there is no documented evidence to support altered oxycodone response in the presence of these variant alleles. The FDA approved drug label for oxycodone cautions that co-medication with CYP3A inhibitors or inducers may lead to altered pharmacokinetics and analgesia, but does not discuss genotype-based recommendations for prescribing (1).
Genetic variation at the CYP2D6 locus has conflicting evidence regarding altered response of individuals to oxycodone therapy. Thus, the Clinical Pharmacogenetics Implementation Consortium (CPIC) has determined that there is insufficient evidence to recommend alterations to standard clinical use based on CYP2D6 genotype (2). Similarly, the Dutch Pharmacogenetics Working Group (DPWG) of the Royal Dutch Association for the Advancement of Pharmacy (KNMP) recognizes the drug-gene interaction between CYP2D6 and oxycodone but states that the interaction does not affect analgesia achieved by the medication (3, 4). The PharmGKB online resource reports that drug labels in Switzerland (regulated by Swissmedic) state that CYP2D6 variation can alter oxycodone response (5, 6).
Interactions among drugs from polypharmacy may be further enhanced by genetic variation, but there are no professional recommendations to alter prescribing based on drug-drug-gene interactions. Regardless of genotype, oxycodone is contraindicated in individuals with significant respiratory depression, acute or severe bronchial asthma, known or suspect gastrointestinal obstruction, or known hypersensitivity to the medication (1).
Drug: Oxycodone
Oxycodone is a semi-synthetic derivative of thebaine, belonging to the drug class of opioid agonists. It is used to treat both chronic and acute pain of moderate to severe intensity when alternative treatments are inadequate. (1) Oxycodone has a similar half-life (2–4 hours) as morphine and approximately twice the bioavailability (7, 8). However, oxycodone is 4-fold less potent than morphine as a MOR agonist, with similar receptor activation efficiency (9). Oxycodone is approximately twice as analgesic as morphine, perhaps reflecting the increased bioavailability, but may be less effective for some pain conditions, such as diabetic neuropathy (10, 11).
However, oxycodone has a high abuse potential (11, 12). It is one of the most widely abused opioid analgesics, with increased abuse reported among all ethnic and economic groups since the 1960s (12, 13). Oxycodone is classified as a Schedule II substance by the US Drug Enforcement Agency (DEA) due the high potential for abuse leading to psychological or physical dependance (1, 13). The factors predisposing any individual to addiction are complex and as such the risk of opioid addiction should be assessed on a case-by-case basis. Clinicians are advised to ensure that the analgesic benefits outweigh the addiction, abuse, or misuse risks for each individual. A risk evaluation and mitigation strategy educational program may be offered as a part of continuing education for prescribing clinicians. (1) Clinicians should be advised that naloxone, an opioid antagonist medication is available to counter opioid overdose and individuals taking oxycodone should be at least aware of this medication. Current guidelines from the Substance Abuse and mental Health Services Administration (SAMHSA) recommend naloxone prescription to anyone on high doses of opioids or using long acting/extended release opioids.(14)
Oxycodone has multiple administration modalities, including intravenous, epidural, rectal, or oral. Oral formulations come in the form of liquid medications or tablets for immediate or extended release. Regardless of administration route, the pharmacokinetics are dose dependent, and most of the oxycodone metabolism occurs in the liver.
Oxycodone is metabolized by members of the CYP enzyme superfamily, with a small amount of oxycodone being excreted without undergoing metabolic processing. Most of the hepatic oxycodone metabolism (roughly 45–50% of the total dose) is performed by the CYP3A enzymes (CYP3A4 and CYP3A5) to form noroxycodone, a largely inactive metabolite. (11, 12, 15) Approximately 10–19% of an oxycodone dose is also metabolized by the CYP2D6 enzyme to form a potent opioid oxymorphone. Oxycodone and its metabolites can be further reduced or can undergo glucuronidation by UDP-glucuronosyltransferase (UGT) enzymes. (11)
Inhibition of the CYP2D6 enzyme by concomitant medications (such as paroxetine) reduces oxycodone analgesia (16) due to reduced oxymorphone formation. Similarly, CYP3A inhibition results in increased oxycodone and oxymorphone exposure and analgesia (17); (16). Where CYP3A4 or CYP3A5 inhibition or induction is a concern due to multiple co-medications, oxymorphone can be substituted.
Many opioids undergo CYP2D6 metabolism to varying degrees. Oxycodone is an active analgesic with minimal metabolism by CYP2D6, whereas codeine and tramadol are pro-drugs that require activation by CYP2D6 and thus are more directly affected by CYP2D6 enzyme activity. (18, 19) Another opioid, hydrocodone, is also metabolized by CYP2D6 into an active analgesic—hydromorphone—but like oxycodone, the parent and metabolite compounds can both provide analgesic effect, though with differing potency (2, 20, 21, 22).
Oxycodone and oxymorphone both activate MOR in the central nervous system and in peripheral tissues. At pharmacologically relevant concentrations oxycodone and oxymorphone act selectively through MOR, with oxymorphone being 8-fold more potent as a MOR activator than oxycodone. Unlike oxycodone, oxymorphone has also been shown to bind to delta and kappa opioid receptors, but the demonstrated affinities greatly exceed therapeutic plasma concentrations. Following oxycodone administration, oxymorphone has been reported to only account for a small portion of total opioid exposure, while the parent, oxycodone, accounts for roughly 90% of the total analgesic effect (23). Conversely, some experts have concluded that the small amount of oxymorphone produced following oxycodone administration may account for most of the analgesic effect (15). The relative role of the parent and oxymorphone metabolite may depend on the route of drug administration with more oxymorphone being produced following oral dosing than seen with parenteral dosing (8). In addition, oxymorphone is a higher potency MOR agonist and exhibits a longer half-life than oxycodone—it is the predominate MOR activator 6 hours after oxycodone dosing. Given the conflicting views regarding the contribution of oxymorphone to analgesia following oxycodone administration, the role of CYP2D6 activity in an individual’s response to oxycodone is also debated and is discussed further below. In contrast, the CYP3A metabolite noroxycodone, exhibits a 3-fold lower reduced binding affinity than the parent and appears to be an antagonist/very weak partial agonist. (11)
Clearance of oxycodone, either unmodified or following its metabolism by cytochrome P450 enzymes and UGT enzymes, is partially dependent upon renal function, hepatic metabolism, and seems to vary with age and gender. The plasma half-life for oxycodone is 3–5 hours in healthy adults(12), it decreases by 25% in geriatric individuals (24). Plasma protein binding of oxycodone is approximately 45% and so unlikely to be a significant variable affecting free oxycodone exposure in the elderly (25). Repetitive bolus simulations suggest that geriatric individuals have a 20% higher exposure and thus some increased risk of adverse effects from oxycodone at standard dosage (1). In neonates the clearance rate increases from birth to 6 months (11) .
Oxycodone use can cause life-threatening or fatal respiratory depression. Risk of this adverse reaction is greatest at initiation of therapy, following a dose increase, or due to initiation or cessation of co-medications that alter CYP2D6 or CYP3A enzyme activities. Accidental ingestion by children can result in respiratory depression and death following a single dose of oxycodone. Respiratory depression risk is also elevated for individuals who are elderly, cachectic or debilitated due to altered pharmacokinetics and drug clearance (1).
Medications that inhibit CYP3A or CYP2D6 enzyme activities will result in an increased exposure to oxycodone. Notably, CYP3A4 inhibitors such as macrolide antibiotics, azole-antifungals and protease inhibitors may prolong opioid adverse reactions. Furthermore, discontinuing a CYP3A inducer—rifampin, carbamazepine, or phenytoin—can also increase oxycodone exposure. The FDA approved drug label specifically notes the importance of CYP3A4- associated drug interactions in the black box warning on the drug label (1).
The FDA recommends monitoring for serotonin syndrome symptoms if concomitant use is warranted with oxycodone and selective serotonin reuptake inhibitors (SSRIs), serotonin and norepinephrine reuptake inhibitors (SNRIs), or other drugs that affect the serotonin neurotransmitter system (1, 26). Furthermore, the FDA approved label says to discontinue oxycodone if serotonin syndrome is suspected and advises against the use of oxycodone with monoamine oxidase inhibitors (MAOIs) or for 14 days following the completion of MAOI therapy (1).
The use of oxycodone during pregnancy can result in opioid withdrawal symptoms in the neonate, which can be life threatening. There are insufficient data to determine if oxycodone use during pregnancy leads to increased rates of birth defects or miscarriages. However, animal studies suggest that the neonate may experience adverse neurobehavioral effects following in utero exposure. Additionally, data suggests that oxycodone crosses the placenta and maternal plasma levels correlate with neonate exposure (1, 11). Chronic opioid use may cause reduced fertility in both males and females that is potentially irreversible (1).
Opioids are present in breastmilk, though one study estimated that an exclusively breast-fed infant would receive, at most, 8% of the maternal weight-adjusted dose (1, 26). However, infants are particularly sensitive to opioids and are at a significant risk for respiratory depression. As such, other analgesics are preferred over oxycodone in breastfeeding mothers (26).
Gene: CYP2D6
The cytochrome P450 superfamily (CYP450) is a large and diverse group of enzymes that form the major system for metabolizing lipids, hormones, toxins, and drugs in the liver. The CYP450 genes are very polymorphic and can result in decreased, absent, or increased enzyme activity. CYP2D6 is responsible for the metabolism of many commonly prescribed drugs, including antidepressants, antipsychotics, analgesics, and beta-blockers (27).
The CYP2D6 Alleles
The CYP2D6 gene is highly polymorphic, as over 100 star (*) alleles have been described and cataloged at the Pharmacogene Variation (PharmVar) Consortium, and each allele is associated with either increased, normal, decreased, or absent enzyme function (Table 1). (28)
The combination of CYP2D6 alleles that a person has is used to determine their diplotype (for example, CYP2D6 *4/*4). Based on their impact on enzyme function, each allele can be assigned an activity score from 0 to 1, which in turn is then used to assign a phenotype (for example, CYP2D6 PM). However, the activity score system is not standardized across all clinical laboratories or CYP2D6 genotyping platforms. The CPIC revised their activity scoring guidelines in October 2019 to promote harmonization. The CYP2D6 phenotype is predicted from the diplotype activity score defined by the sum of the allele score values, which usually ranges from 0 to 3.0: (29)
- An ultrarapid metabolizer (UM) has an activity score greater than 2.25
- A normal metabolizer phenotype (NM) has an activity score of 1.25–2.25
- An intermediate metabolizer (IM) has an activity score of >0–<1.25
- A poor metabolizer (PM) has an activity score of 0
Table 1.
Allele type | CYP2D6 alleles | Activity score |
---|---|---|
Normal function | *1, *2, *27, *33 | 1 |
Decreased function | *17, *41, *49 | 0.5 |
Strongly decreased function | *10 | 0.25 |
No function | *3, *4, *5, *6, *36 | 0 |
The CYP2D6*1 allele is the wild-type allele when no variants are detected and is associated with normal enzyme activity and the NM phenotype. The CYP2D6*2, *27, and *33 alleles are also considered to have near-normal activity.
Other CYP2D6 alleles include variants that produce a non-functioning enzyme (for example, *3, *4, *5, and *6) (30, 31, 32, 33) or an enzyme with decreased activity (for example, *10, *17, and *41) (34, 35, 36) (see Table 1). There are large inter-ethnic differences in the frequency of these alleles, with *3, *4, *5, *6, and *41 being more common in individuals with European ancestry, *17 more common in Africans, and *10 more common in Asians. (37)
Larger structural variants at the CYP2D6 locus have also been described, including gene duplications, deletions, tandem alleles, and gene conversions. As one might expect, deletions result in a no-function allele (for example, the *5 allele is a deletion). Duplications have been reported for alleles with normal function and decreased function, as well. In the case of allele duplications, the activity scores for the full complement of CYP2D6 alleles are summed to determine the predicted metabolizer phenotype. Additional details on structural variants are available from PharmVar (38).
The frequency of the CYP2D6 star alleles with altered function varies across global populations, resulting in different frequencies of the resulting metabolizer phenotype(s). Given CYP2D6’s role in metabolism of many drugs, the literature on allele and phenotype frequency is expansive. Most populations have a high frequency for normal-function star alleles and thus a high proportion of the population are NMs. However, reduced-function alleles like CYP2D6*10 are highly prevalent in east and southeast Asian populations, leading to a higher proportion of IM phenotype individuals in this ancestral group. Many nations in sub-Saharan Africa have higher frequencies of decreased-function alleles like CYP2D6*17 and *29, which can correlate with lower metabolizer scores in these individuals. More details regarding published allele and phenotype frequencies are available in the CYP2D6 supplemental chapter.
Pharmacologic Conversion of CYP2D6 Phenotype
Factors other than genotype can affect CYP2D6 enzyme activity and thus the metabolizer phenotype of any individual. Administration of multiple drugs, sometimes called polypharmacy or co-medications, can lead to a phenomenon called phenoconversion whereby an individual with one metabolizer genotype can have the enzymatic activity of a different metabolizer group (higher or lower, depending on the medications). The enzymatic activity of CYP2D6 can be inhibited or reduced by medications including duloxetine, paroxetine, fluoxetine, bupropion, and quinidine (21, 39, 40, 41). This can result in NMs or IMs responding to medications as if they were PMs. Thus, co-medication with multiple CYP2D6 strong or moderate inhibitors may result in reduced metabolism of drug substrates. In contrast, discontinuing a co-medication can increase the rate of CYP2D6 metabolism.
Other Genes of Note
The CYP3A4 and CYP3A5 Genes
Other cytochrome P450 enzymes are involved in the metabolism of oxycodone. The CYP3A enzymes, encoded by CYP3A4 and CYP3A5, perform most of the oxycodone metabolism. Similar to CYP26, the CYP3A enzymes are also susceptible to phenoconversion due to medications that inhibit or activate these enzymes, as described above. (1)
Variation at the CYP3A4 locus is relatively uncommon and CPIC has not assigned a functional status to most variants (28). Although around 40 variant CYP3A4 alleles have been reported, most have not been shown to alter CYP3A4 activity (42, 43). To date, only 3 loss-of-function CYP3A4 alleles have been identified (CYP3A4*6, CYP3A4*20 and CYP3A4*26) (Table 2) (44, 45).
The CYP3A4*22 allele has decreased function and explains 12% of the variation in CYP3A4 activity (46). This variant is present in 3.2–10.6% of the Dutch population and 5.2–8.3% of the population in America (47). The Allele Frequency Aggregator project reports this reduced-function allele to be present in approximately 5% of the global population, with the lowest prevalence in Asian and African populations (48). The 1000 Genomes Project phase 3 data release estimates global prevalence to be slightly lower (~1%); a minor allele frequency of 5% is reported for the European average (49).
The CYP3A4*20 allele has a premature stop codon that results in a loss-of-function of CYP3A4. It appears to be the most common CYP3A4-defective allele but is still relatively rare, with approximately 0.2% of European Americans and 0.05% African Americans who are heterozygous. However, in Spain, the CYP3A4*20 allele is present in 1.2% of the population, and up to 3.8% in specific Spanish regions (44).
Table 2.
Allele type# | CYP3A4 alleles |
---|---|
Normal function | *1 |
Decreased function | *22 |
No function | *6, *20, *26 |
For a comprehensive list of CYP3A4 alleles, please see PharmVar.
#As of the date of publication, there is no “CPIC Clinical Function” assessment provided for the CYP3A4 alleles within PharmVar. The activity status provided here is based on the literature and historic assessment. In the event of a discrepancy between the functional classifications provided herein and PharmVar’s data, the authors defer to PharmVar and CPIC.
The CYP3A5 locus has less than 10 known genetic variants. The CYP3A5*3, CYP3A5*6, and CYP3A5*7 alleles are important no-function alleles and the *1 allele is the normal-function allele (Table 3) (28). The combination of alleles present predicts either normal (homozygous *1), intermediate (at least one copy of *1 or compound heterozygous for no-function alleles), or PM phenotypes (homozygous for a single no-function allele) (50, 51). The PM phenotypes have been seen more commonly in individuals identified as “White” than African American or Black (52, 53). The CYP3A5*3 allele has been observed at a high frequency in Egyptian and Italian populations (54, 55).
Table 3.
Allele type | CYP3A5 alleles |
---|---|
Normal function | *1 |
No function | *3, *6, *7 |
For a comprehensive list of CYP3A5 alleles, please see PharmVar.
The OPRM1 Gene
The MOR is encoded by the OPRM1 gene. The MOR is a G-coupled protein receptor and is a key signal transducer for the desired analgesic effect of opioids such as tramadol and codeine. There are more than 200 known variant alleles of OPRM1, and some variants have been suggested to have a role in opioid response or predisposition to opioid use disorders (56, 57). However, CPIC’s expert review found inconsistent evidence linking any of these alleles to post-operative dose requirements for some opioids and the effect on morphine dose adjustment was deemed not to be clinically actionable (2).
The COMT Gene
The catechol-o-methyltransferase (COMT) enzyme is involved in the methylation and degradation of adrenaline, noradrenaline, and dopamine. This enzyme regulates the concentration of catecholamines and thus is a key regulator of the pain perception pathways (58). The variant rs4680 (p.Val158Met) in COMT has been suggested to result in decreased levels of methylation activity (2, 58). However, CPIC’s review found variable evidence associating this variant with analgesia response or opioid dose requirements and thus makes no recommendations based on COMT genotype (2).
Linking Gene Variation with Treatment Response
Altered CYP2D6 enzyme activity has been associated with altered levels and ratios of oxycodone, noroxycodone, and oxymorphone levels in the blood; lower CYP2D6 activity correlated with a decrease in this ratio in plasma and urine (11, 59, 60, 61, 62). However, there are conflicting reports regarding the associated impact on analgesia or adverse outcomes.
Several studies report improved analgesia, or higher rates of adverse reactions, or both in individuals with higher levels of CYP2D6 activity. One study in 33 healthy volunteers reported a modest but significant decrease in analgesic effect of oxycodone in CYP2D6 PM genotyped individuals in 3 out of 5 tests. Genotyping in this study was limited to analysis of variants for CYP2D6*3, *4, *6 and *9 with no detection of duplication nor deletion; individuals were classified as CYP2D6 PMs if they had 2 no-function alleles based on this limited genotyping. (63) A small study of 10 healthy volunteers reported a correlation between CYP2D6 activity and oxycodone analgesia, with CYP2D6 UM participants also reporting an increased incidence of negative side effects and more intense adverse reactions to oxycodone compared with other metabolizer phenotypes. This group also found inhibition of CYP2D6 by co-medication with quinidine reduced the peak analgesic effect along with the oxymorphone exposure. This study genotyped CYP2D6 variation by microarray and thus reported testing for a total of 32 alleles, including the CYP2D6*5 deletion and duplication of a subset of alleles (64, 65). A study of 121 post-operative individuals found a direct correlation between CYP2D6 predicted enzyme activity and oxymorphone/oxycodone ratio as well as higher oxycodone consumption in CYP2D6 PMs for 48 hours post-operative self-controlled analgesia, though the pain scores were similar across metabolizer groups. This study interrogated 8 defined CYP2D6 alleles, including the *5 deletion and gene duplication (66). Similarly, Deodhar and colleagues support the phenotypic assessment of CYP2D6 activity when oxycodone is prescribed for pain management, which could include pharmacogenomics testing to enable identification of CYP2D6 PMs or evaluation of polypharmacy leading to phenoconversion or both. (15) Another recent review suggests that within European populations, individuals who are CYP2D6 UMs have an increased risk of adverse events and additionally noted the potential impact of phenoconversion due to CYP2D6 inhibitors, which may reduce analgesic effect (67).
In contrast, multiple studies suggest the differences in oxymorphone/oxycodone ratios due to CYP2D6 activity do not impact pain management or other symptoms. A larger study of 270 individuals who had recently undergone surgical procedures were genotyped for CYP2D6 and intravenous oxycodone use for 24 hours post-surgery was monitored. This study found no significant differences in the frequency of oxycodone non-responders between CYP2D6 PM and other metabolizer phenotypes, nor differences in average oxycodone consumption between the groups, indicating that CYP2D6 metabolism did not affect oxycodone analgesia even though oxymorphone/oxycodone ratios were lower in the CYP2D6 PMs group. It should be noted that genotyping in this study was limited to detection of the *3, *4, *6 and *9 alleles, *5 was specifically excluded in the analysis and the *1 allele was assigned in the absence of any detected variants (68). A similar study in 450 individuals who were being treated for cancer pain observed changes in oxymorphone/oxycodone ratios but no difference in pain intensity, nausea, tiredness nor cognitive function, however the scope of CYP2D6 genotyping in this study was limited and the *2 duplication, *3, *4, *5, *6, *7 and *8 alleles were the only alleles specifically examined (59).
Because of the conflicting and limited evidence for either CYP2D6 metabolizer phenotypes, COMT function, or OPRM1 function being involved with altered oxycodone response, both CPIC and DPWG have no recommendations regarding dosing or selection when oxycodone is considered (2, 3).
As reported by PharmGKB, the Swiss drug labels for oxycodone state that CYP2D6 polymorphism can alter the efficacy of the medication or lead to undesired effects; “slow” metabolizers (PMs) may experience weaker analgesia and “ultra-fast” metabolizers (UMs) may have higher analgesia and increased risk of adverse effects (69).
A large study of urine drug test samples found an association between another member of the CYP450 family: CYP2C19. The CYP2C19 UMs had a higher oxymorphone/oxycodone ratio than PMs, like CYP2D6, suggesting that CYP2C19 may play a minor role in oxycodone metabolism. However, these observations warrant further research to determine if CYP2C19 genetic variations are associated with oxycodone response (60).
Genetic variation in the CYP3A4 locus is exceedingly rare and has not been associated with altered oxycodone analgesia. However, many reports have stated that induction of CYP3A4 and CYP3A5 by co-medications such as rifampin and carbamazepine are associated with decreased analgesia, though at least one report found no effect by co-medication (11, 70).
Drug-drug interactions have been reported to influence treatment responses, most likely due to enzyme inhibition or induction. Adverse reactions were more common in elderly individuals taking oxycodone concomitantly with CYP2D6 or CYP3A4 inhibitor medications (71). Rifampin has been reported to reduce analgesia from multiple opioid medications, including oxycodone, though the data is limited (72).
Genetic Testing
Genetic testing is available for many (~30) of the variant CYP2D6 alleles. Usually, an individual’s result is reported as a diplotype, which includes one maternal and one paternal allele, for example, CYP2D6 *1/*2. When individuals have more than 2 copies of the CYP2D6 allele, the copies are denoted by an “xN”, for example, CYP2D6*1/*2x2. Some laboratories also use the notation of DUP to indicate an increase in copy number. Depending on the testing methodology and platform used, a laboratory may or may not be able to specify the number of duplicated CYP2D6 alleles nor the allele that has been duplicated.
Studies in oncology and cardiovascular surgical intervention have estimated that 25–56% of these populations may be prescribed oxycodone or other opioids to manage pain during their treatment; multiple authors recommend pharmacogenomic testing in these individuals to optimize management of pain or other symptoms (20, 73, 74).
Genetic tests for oxycodone response, the CYP2D6 gene, the CYP3A4 gene, and the CYP3A5 gene can be found on the NIH Genetic Testing Registry (GTR). The available tests include targeted single-gene tests as well as multi-gene panels or genome-wide sequencing tests.
The test results may include an interpretation of the individual’s predicted metabolizer phenotype, which can be confirmed by checking the diplotype and calculating the CYP2D6 activity score, as described in the “CYP2D6 Alleles” section above. Variant CYP2D6 alleles to be included in clinical genotyping assays have been recommended by the Association for Molecular Pathology (75).
Variants in other genes, such as COMT and OPRM1, may also influence an individual’s response to oxycodone, though there are no established guidelines for dose alterations or drug selection based on genetic variation at any of the loci described in this summary.
Therapeutic Recommendations based on Genotype
This section contains excerpted1 information on gene-based dosing recommendations. Neither this section nor other parts of this review contain the complete recommendations from the sources.
2021 Statement from the US Food and Drug Administration (FDA):
Cytochrome P450 3A4 Interaction [drug-drug interactions]
The concomitant use of oxycodone hydrochloride tablets with all cytochrome P450 3A4 inhibitors may result in an increase in oxycodone plasma concentrations, which could increase or prolong adverse reactions and may cause potentially fatal respiratory depression. In addition, discontinuation of a concomitantly used cytochrome P450 3A4 inducer may result in an increase in oxycodone plasma concentration. Monitor patients receiving oxycodone hydrochloride tablets and any CYP3A4 inhibitor or inducer.
[…]
Drug interactions: Inhibitors of CYP3A4 and CYP2D6, Clinical Impact [drug-drug interactions]
The concomitant use of oxycodone hydrochloride and CYP3A4 inhibitors can increase the plasma concentration of oxycodone, resulting in increased or prolonged opioid effects. These effects could be more pronounced with concomitant use of oxycodone hydrochloride and CYP2D6 and CYP3A4 inhibitors, particularly when an inhibitor is added after a stable dose of oxycodone hydrochloride is achieved… After stopping a CYP3A4 inhibitor, as the effects of the inhibitor decline, the oxycodone plasma concentration will decrease, resulting in decreased opioid efficacy or a withdrawal syndrome in patients who had developed physical dependence to oxycodone.
[…]
Drug Interactions: CYP3A Inducers, Clinical Impact [drug-drug interactions]
The concomitant use of oxycodone hydrochloride and CYP3A4 inducers can decrease the plasma concentration of oxycodone, resulting in decreased efficacy or onset of a withdrawal syndrome in patients who have developed physical dependence to oxycodone. After stopping a CYP3A4 inducer, as the effects of the inducer decline, the oxycodone plasma concentration will increase, which could increase or prolong both the therapeutic effects and adverse reactions, and may cause serious respiratory depression.
[…]
Pharmacokinetics: Metabolism
A high portion of oxycodone is N-dealkylated to noroxycodone during first-pass metabolism, and is catalyzed by CYP3A4. Oxymorphone is formed by the O-demethylation of oxycodone. The metabolism of oxycodone to oxymorphone is catalyzed by CYP2D6.
Please review the complete therapeutic recommendations that are located here: (1).
2021 Statement from the Clinical Pharmacogenetics Implementation Consortium (CPIC)
There is insufficient evidence and confidence to provide a recommendation to guide clinical practice at this time for oxycodone or methadone based on CYP2D6 genotype or COMT genotype or OPRM1 genotype (Tables S5 and S6, no recommendation, CPIC level C).
Please review the complete therapeutic recommendations that are located here: (2).
2018 Summary of recommendations from the Dutch Pharmacogenetics Working Group (DPWG) of the Royal Dutch Association for the Advancement of Pharmacy (KNMP)
CYP2D6 IM: oxycodone[e]
[and] CYP2D6 PM: oxycodone[e]
NO action is required for this gene-drug interaction.
The reduced conversion of oxycodone to the more active metabolite oxymorphone does not result in reduced analgesia for patients.
CYP2D6 UM: oxycodone[e]
NO action is required for this gene-drug interaction.
The increased conversion of oxycodone to the more active metabolite oxymorphone does not result in an increase in side effects in patients.
Please review the complete therapeutic recommendations that are located here: (3, 4)
Nomenclature for Selected Alleles
Common allele name | Alternative names | HGVS reference sequence | dbSNP reference identifier for allele location | |
---|---|---|---|---|
Coding | Protein | |||
CYP2D6*2 | 2851C>T |
NM_000106 |
NP_000097 | rs16947 |
4181G>C |
NM_000106 |
NP_000097 | rs1135840 | |
CYP2D6*3 | 2550delA | NM_000106.6:c.775del | NP_000097.3:p.Arg259fs | rs35742686 |
CYP2D6*4 | 1846G>A |
NM_000106 | Variant occurs in a non-coding region (splice variant causes a frameshift) | rs3892097 |
CYP2D6*5 | Gene deletion | |||
CYP2D6*6 | 1707 del T |
NM_000106 |
NP_000097 | rs5030655 |
CYP2D6*10 | 100C>T |
NM_000106 |
NP_000097 | rs1065852 |
4181G>C |
NM_000106 |
NP_000097 | rs1135840 | |
CYP2D6*17 | 1022C>T |
NM_000106 |
NP_000097 | rs28371706 |
2851C>T |
NM_000106 |
NP_000097 | rs16947 | |
4181G>C |
NM_000106 |
NP_000097 | rs1135840 | |
CYP2D6*27 | 3854G>A | NM_000106.6:c.1228G>A | NP_000097.3:p.Glu410Lys | rs769157652 |
CYP2D6*31 | 2851C>T |
NM_000106 |
NP_000097 | rs16947 |
4043G>A |
NM_000106 |
NP_000097 | rs267608319 | |
4181G>C |
NM_000106 |
NP_000097 | rs1135840 | |
CYP2D6*36[1] | 100C>T |
NM_000106 |
NP_000097 | rs1065852 |
4129C>G | NM_000106.6:c.1405C>G | NP_000097.3:p.Pro469Ala | rs1135833 | |
4132A>G | NM_000106.6:c.1408A>G | NP_000097.3:p.Thr470Ala | rs1135835 | |
4156C>T+4157A>C | NM_000106.6:c.1432C>T + NM_000106.6:c.1433A>C | NP_000097.3:p.His47Ser | rs28371735 + rs766507177 | |
4159G>C | NM_000106.6:c.1435G>C | NP_00097.3:p.Gly479Arg | ||
4165T>G | NM_000106.6:c.1441T>G | NP_00097.3:p.Phe481Val | ||
4168G>A+4169C>G | NM_000106.6:c.1444G>A + NM_000106.6:c.1445C>G | NP_000097.3:p.Ala482Ser | rs74478221 + rs75467367 | |
4181G>C |
NM_000106 |
NP_000097 | rs1135840 | |
CYP2D6*41 | 2851C>T |
NM_000106 |
NP_000097 | rs16947 |
2989G>A |
NM_000106 | Variant occurs in a non-coding region (impacts slicing). | rs28371725 | |
4181G>C |
NM_000106 |
NP_000097 | rs1135840 | |
CYP2D6*49 | 100C>T |
NM_000106 |
NP_000097 | rs1065852 |
1612T>A | NM_00106.6:c.358T>A | NP_000097.3:p.Phe120Ile | rs1135822 | |
4181G> |
NM_000106 |
NP_000097 | rs1135840 |
- [1]
CYP2D6*36 is a gene conversion with CYP2D7; variants provided here are from the Pharmacogene Variation Consortium.
Alleles described in this table are selected based on discussion in the text above. This is not intended to be an exhaustive description of known alleles.
Common allele name | Alternative names | HGVS reference sequence | dbSNP reference identifier for allele location | |
---|---|---|---|---|
Coding | Protein | |||
CYP3A4*6 | 17661_17662insA 277Frameshift | NM_017460.5:c.830_831insA | NP_059488.2:p.Asp277Glufs | rs4646438 |
CYP3A4*20 | 1461_1462insA 488Frameshift | NM_017460.5:c.1461dup | NP_059488.2:p.Pro488Thrfs | rs67666821 |
CYP3A4*22 | 15389C>T | NM_017460.6:c.522-191C>T | Not applicable—variant occurs in a non-coding region | rs35599367 |
CYP3A4*26 | 17642C>T R268Stop | NM_017460.6:c.802C>T | NP_059488.2:p.Arg268Ter | rs138105638 |
CYP3A4*1.001 is the wild-type allele and is determined to be present with no variants are detected.
Common allele name | Alternative names | HGVS reference sequence | dbSNP reference identifier for allele location | |
---|---|---|---|---|
Coding | Protein | |||
CYP3A5*3 | 6981A>G |
NM_000777 | Not applicable—variant occurs in a non-coding region | rs776746 |
CYP3A5*6 | 14685G>A | NM_000777.5:c.624G>A | NP_000768.1:p.Lys208= (Alters mRNA splicing) | rs10264272 |
CYP3A5*7 | 27126_27127insT | NM_000777.5:c.1035dup | NP_000768.1:p.Thr346fs | rs41303343 |
CYP3A5*1 is the wild-type allele and is determined to be present with no variants are detected.
Pharmacogenetic Allele Nomenclature: International Workgroup Recommendations for Test Result Reporting (76).
Guidelines for the description and nomenclature of gene variations are available from the Human Genome Variation Society (HGVS).
Nomenclature for Cytochrome P450 enzymes is available from the Pharmacogene Variation (PharmVar) Consortium; the authors defer to that authority with regards to any discrepancies in allele definitions.
Acknowledgments
The author would like to thank Natalie Reizine, MD, Assistant Professor of Medicine, University of Illinois Cancer Center, Chicago, IL, USA; Aidan Hampson, PhD, National Institute on Drug Abuse, National Institutes of Health, Bethesda, MD, USA; and Houda Hachad, PharmD., M. Res, Vice President of Clinical Operations, AccessDx, Seattle, WA, USA for reviewing this summary.
Version History
Version 1.0 of this chapter was published on October 4, 2022.
Version 1.1 was published on August 21, 2024 for a minor revision to update the link for references 14 and 47.
References
- 1.
- OXYCODONE HYDROCHLORIDE- oxycodone hydrochloride tablet [package insert]. Lawrenceville, GA, USA: XLCare Pharmaceuticals, I.; 2021. Available from: https://dailymed
.nlm .nih.gov/dailymed/drugInfo .cfm?setid=e5c8e72d-4ac5-4ca3-9557-6a659d4d8338 - 2.
- Crews, K.R., A.A. Monte, R. Huddart, K.E. Caudle, et al., Clinical Pharmacogenetics Implementation Consortium Guideline for CYP2D6, OPRM1, and COMT Genotypes and Select Opioid Therapy. Clin Pharmacol Ther, 2021. 110(4): p. 888-896. [PMC free article: PMC8249478] [PubMed: 33387367]
- 3.
- Royal Dutch Pharmacists Association (KNMP). Dutch Pharmacogenetics Working Group (DPWG). Pharmacogenetic Guidelines [Internet]. Netherlands. CYP2D6: oxycodone [Cited June 2021]. Available from: https://www
.knmp.nl/dossiers /farmacogenetica - 4.
- Matic, M., M. Nijenhuis, B. Soree, N.J. de Boer-Veger, et al., Dutch Pharmacogenetics Working Group (DPWG) guideline for the gene-drug interaction between CYP2D6 and opioids (codeine, tramadol and oxycodone). Eur J Hum Genet, 2021. [PMC free article: PMC9553935] [PubMed: 34267337]
- 5.
- Annotation of Swissmedic Label for oxycodone and CYP2D6 [Cited 29 Sept 2021]. Available from: https://www
.pharmgkb .org/labelAnnotation/PA166184177 - 6.
- Oxycontin [Cited 29 Sept 2021]. Available from: https://amiko
.oddb.org/de/fi?gtin=54871 - 7.
- Lugo, R.A. and S.E. Kern, Clinical pharmacokinetics of morphine. J Pain Palliat Care Pharmacother, 2002. 16(4): p. 5-18. [PubMed: 14635822]
- 8.
- Poyhia, R., T. Seppala, K.T. Olkkola and E. Kalso, The pharmacokinetics and metabolism of oxycodone after intramuscular and oral administration to healthy subjects. Br J Clin Pharmacol, 1992. 33(6): p. 617-21. [PMC free article: PMC1381353] [PubMed: 1389934]
- 9.
- Lalovic, B., E. Kharasch, C. Hoffer, L. Risler, et al., Pharmacokinetics and pharmacodynamics of oral oxycodone in healthy human subjects: role of circulating active metabolites. Clin Pharmacol Ther, 2006. 79(5): p. 461-79. [PubMed: 16678548]
- 10.
- Treillet, E., S. Laurent and Y. Hadjiat, Practical management of opioid rotation and equianalgesia. J Pain Res, 2018. 11: p. 2587-2601. [PMC free article: PMC6211309] [PubMed: 30464578]
- 11.
- Huddart, R., M. Clarke, R.B. Altman and T.E. Klein, PharmGKB summary: oxycodone pathway, pharmacokinetics. Pharmacogenet Genomics, 2018. 28(10): p. 230-237. [PMC free article: PMC6602093] [PubMed: 30222708]
- 12.
- Connors, N.J., M. Mazer-Amirshahi, S. Motov and H.K. Kim, Relative addictive potential of opioid analgesic agents. Pain Manag (Lond.), 2021. 11(2): p. 201-215. [PubMed: 33300384]
- 13.
- Controlled Substances - Alphabetical Order. 2021 17 February 2021 2 March 2021; Available from: https://www
.deadiversion .usdoj.gov/schedules /orangebook/c_cs_alpha.pdf. - 14.
- SAMSHA. Naloxone. 2022 21 April 2022 22 July 2022; Available from: https://www
.samhsa.gov /medication-assisted-treatment /medications-counseling-related-conditions /naloxone. - 15.
- Deodhar, M., J. Turgeon and V. Michaud, Contribution of CYP2D6 Functional Activity to Oxycodone Efficacy in Pain Management: Genetic Polymorphisms, Phenoconversion, and Tissue-Selective Metabolism. Pharmaceutics, 2021. 13(9). [PMC free article: PMC8468517] [PubMed: 34575542]
- 16.
- Kummer, O., F. Hammann, C. Moser, O. Schaller, et al., Effect of the inhibition of CYP3A4 or CYP2D6 on the pharmacokinetics and pharmacodynamics of oxycodone. Eur J Clin Pharmacol, 2011. 67(1): p. 63-71. [PubMed: 20857093]
- 17.
- Marsousi, N., Y. Daali, S. Rudaz, L. Almond, et al., Prediction of Metabolic Interactions With Oxycodone via CYP2D6 and CYP3A Inhibition Using a Physiologically Based Pharmacokinetic Model. CPT Pharmacometrics Syst Pharmacol, 2014. 3(12): p. e152. [PMC free article: PMC4288002] [PubMed: 25518025]
- 18.
- Dean, L. and M. Kane, Codeine Therapy and CYP2D6 Genotype, in Medical Genetics Summaries, V.M. Pratt, et al., Editors. 2012: Bethesda (MD). [PubMed: 28520350]
- 19.
- Dean, L. and M. Kane, Tramadol Therapy and CYP2D6 Genotype, in Medical Genetics Summaries, V.M. Pratt, et al., Editors. 2012: Bethesda (MD). [PubMed: 28520365]
- 20.
- Reizine, N., K. Danahey, E. Schierer, P. Liu, et al., Impact of CYP2D6 Pharmacogenomic Status on Pain Control Among Opioid-Treated Oncology Patients. Oncologist, 2021. 26(11): p. e2042-e2052. [PMC free article: PMC8571740] [PubMed: 34423496]
- 21.
- Smith, D.M., K.W. Weitzel, A.R. Elsey, T. Langaee, et al., CYP2D6-guided opioid therapy improves pain control in CYP2D6 intermediate and poor metabolizers: a pragmatic clinical trial. Genet Med, 2019. 21(8): p. 1842-1850. [PMC free article: PMC6650382] [PubMed: 30670877]
- 22.
- Stauble, M.E., A.W. Moore, L.J. Langman, M.V. Boswell, et al., Hydrocodone in postoperative personalized pain management: pro-drug or drug? Clin Chim Acta, 2014. 429: p. 26-9. [PubMed: 24269714]
- 23.
- Umukoro, N.N., B.W. Aruldhas, R. Rossos, D. Pawale, et al., Pharmacogenomics of oxycodone: a narrative literature review. Pharmacogenomics, 2021. 22(5): p. 275-290. [PMC free article: PMC8050982] [PubMed: 33728947]
- 24.
- Saari, T.I., H. Ihmsen, P.J. Neuvonen, K.T. Olkkola, et al., Oxycodone clearance is markedly reduced with advancing age: a population pharmacokinetic study. Br J Anaesth, 2012. 108(3): p. 491-8. [PubMed: 22201184]
- 25.
- Leow, K.P., A.W. Wright, T. Cramond and M.T. Smith, Determination of the serum protein binding of oxycodone and morphine using ultrafiltration. Ther Drug Monit, 1993. 15(5): p. 440-7. [PubMed: 8249052]
- 26.
- Oxycodone, in Drugs and Lactation Database (LactMed). 2006: Bethesda (MD).
- 27.
- Nofziger, C., A.J. Turner, K. Sangkuhl, M. Whirl-Carrillo, et al., PharmVar GeneFocus: CYP2D6. Clin Pharmacol Ther, 2020. 107(1): p. 154-170. [PMC free article: PMC6925641] [PubMed: 31544239]
- 28.
- Gaedigk, A., M. Ingelman-Sundberg, N.A. Miller, J.S. Leeder, et al., The Pharmacogene Variation (PharmVar) Consortium: Incorporation of the Human Cytochrome P450 (CYP) Allele Nomenclature Database. Clin Pharmacol Ther, 2018. 103(3): p. 399-401. [PMC free article: PMC5836850] [PubMed: 29134625]
- 29.
- CPIC. CPIC® Guideline for Codeine and CYP2D6. 2019 October 2019 2020 June Available from: https://cpicpgx
.org/guidelines /guideline-for-codeine-and-cyp2d6/. - 30.
- Yokota, H., S. Tamura, H. Furuya, S. Kimura, et al., Evidence for a new variant CYP2D6 allele CYP2D6J in a Japanese population associated with lower in vivo rates of sparteine metabolism. Pharmacogenetics, 1993. 3(5): p. 256-63. [PubMed: 8287064]
- 31.
- PharmGKB [Internet]. Palo Alto (CA): Stanford University. Codeine and Morphine Pathway, Pharmacokinetics [Cited 2012 July 24]. Available from: http://www
.pharmgkb.org /pathway/PA146123006 - 32.
- Ingelman-Sundberg, M., Genetic polymorphisms of cytochrome P450 2D6 (CYP2D6): clinical consequences, evolutionary aspects and functional diversity. Pharmacogenomics J, 2005. 5(1): p. 6-13. [PubMed: 15492763]
- 33.
- PharmGKB [Internet]. Palo Alto (CA): Stanford University. Haplotype CYP2D6*1 [Cited 2020 June 11]. Available from: http://www
.pharmgkb.org /haplotype/PA165816576 - 34.
- PharmGKB [Internet]. Palo Alto (CA): Stanford University. Haplotype CYP2D6*4 [Cited 8 October 2015]. Available from: http://www
.pharmgkb.org /haplotype/PA165816579 - 35.
- PharmGKB [Internet]. Palo Alto (CA): Stanford University. Haplotype CYP2D6*6 [Cited 8 October 2015]. Available from: http://www
.pharmgkb.org /haplotype/PA165816581 - 36.
- PharmGKB [Internet]. Palo Alto (CA): Stanford University. Haplotype CYP2D6*10 [Cited 8 October 2015]. Available from: http://www
.pharmgkb.org /haplotype/PA165816582 - 37.
- Bradford, L.D., CYP2D6 allele frequency in European Caucasians, Asians, Africans and their descendants. Pharmacogenomics, 2002. 3(2): p. 229-43. [PubMed: 11972444]
- 38.
- Consortium, P.V. Structural Variation for CYP2D6. 2022 14 March 2022; Available from: https://www
.pharmvar.org/gene/CYP2D6 - 39.
- FDA. Drug Development and Drug Interactions: Table of Substrates, Inhibitors and Inducers. 2020; Available from: https://www
.fda.gov/drugs /drug-interactions-labeling /drug-development-and-drug-interactions-table-substrates-inhibitors-and-inducers. - 40.
- Codeine sulfate tablets for oral use [package insert]. Philadelphia, PA: Lannett Company, I.; 2019. Available from: https://dailymed
.nlm .nih.gov/dailymed/drugInfo .cfm?setid=5819bdf7-300e-45b8-8f3a-447b53656293 - 41.
- Monte, A.A., K. West, K.T. McDaniel, H.K. Flaten, et al., CYP2D6 Genotype Phenotype Discordance Due to Drug-Drug Interaction. Clin Pharmacol Ther, 2018. 104(5): p. 933-939. [PMC free article: PMC6197912] [PubMed: 29882961]
- 42.
- Pharmacogene Variation Consortium (PharmVar) [Internet]. CYP3A4 [Cited 4 Oct 2022]. Available from: https://www
.pharmvar.org/gene/CYP3A4 - 43.
- Westlind-Johnsson, A., R. Hermann, A. Huennemeyer, B. Hauns, et al., Identification and characterization of CYP3A4*20, a novel rare CYP3A4 allele without functional activity. Clin Pharmacol Ther, 2006. 79(4): p. 339-49. [PubMed: 16580902]
- 44.
- Apellaniz-Ruiz, M., L. Inglada-Perez, M.E. Naranjo, L. Sanchez, et al., High frequency and founder effect of the CYP3A4*20 loss-of-function allele in the Spanish population classifies CYP3A4 as a polymorphic enzyme. Pharmacogenomics J, 2015. 15(3): p. 288-92. [PubMed: 25348618]
- 45.
- Werk, A.N., S. Lefeldt, H. Bruckmueller, G. Hemmrich-Stanisak, et al., Identification and characterization of a defective CYP3A4 genotype in a kidney transplant patient with severely diminished tacrolimus clearance. Clin Pharmacol Ther, 2014. 95(4): p. 416-22. [PubMed: 24126681]
- 46.
- Wang, D., Y. Guo, S.A. Wrighton, G.E. Cooke, et al., Intronic polymorphism in CYP3A4 affects hepatic expression and response to statin drugs. Pharmacogenomics J, 2011. 11(4): p. 274-86. [PMC free article: PMC3248744] [PubMed: 20386561]
- 47.
- Royal Dutch Pharmacists Association (KNMP). Dutch Pharmacogenetics Working Group (DPWG). Pharmacogenetic Guidelines [Internet]. Netherlands. General background text Pharmacogenetics - CYP3A4 [Cited December 2020]. Available from: http://kennisbank
.knmp.nl - 48.
- ALFA: Allele Frequency Aggregator. [Cited 19 Jan 2021]. Available from: http://www
.ncbi.nlm.nih .gov/snp/docs/gsr/alfa/ - 49.
- Yates, A.D., P. Achuthan, W. Akanni, J. Allen, et al., Ensembl 2020. Nucleic Acids Res, 2020. 48(D1): p. D682-D688. [PMC free article: PMC7145704] [PubMed: 31691826]
- 50.
- Birdwell, K.A., B. Decker, J.M. Barbarino, J.F. Peterson, et al., Clinical Pharmacogenetics Implementation Consortium (CPIC) Guidelines for CYP3A5 Genotype and Tacrolimus Dosing. Clin Pharmacol Ther, 2015. 98(1): p. 19-24. [PMC free article: PMC4481158] [PubMed: 25801146]
- 51.
- Campagne, O., D.E. Mager, D. Brazeau, R.C. Venuto, et al., Tacrolimus Population Pharmacokinetics and Multiple CYP3A5 Genotypes in Black and White Renal Transplant Recipients. J Clin Pharmacol, 2018. 58(9): p. 1184-1195. [PMC free article: PMC6105387] [PubMed: 29775201]
- 52.
- Brazeau, D.A., K. Attwood, C.J. Meaney, G.E. Wilding, et al., Beyond Single Nucleotide Polymorphisms: CYP3A5 (*)3 (*)6 (*)7 Composite and ABCB1 Haplotype Associations to Tacrolimus Pharmacokinetics in Black and White Renal Transplant Recipients. Front Genet, 2020. 11: p. 889. [PMC free article: PMC7433713] [PubMed: 32849848]
- 53.
- Muller, W.K., C. Dandara, K. Manning, D. Mhandire, et al., CYP3A5 polymorphisms and their effects on tacrolimus exposure in an ethnically diverse South African renal transplant population. S Afr Med J, 2020. 110(2): p. 159-166. [PubMed: 32657689]
- 54.
- Mendrinou, E., M.E. Mashaly, A.M. Al Okily, M.E. Mohamed, et al., CYP3A5 Gene-Guided Tacrolimus Treatment of Living-Donor Egyptian Kidney Transplanted Patients. Front Pharmacol, 2020. 11: p. 1218. [PMC free article: PMC7431691] [PubMed: 32848803]
- 55.
- Provenzani, A., M. Notarbartolo, M. Labbozzetta, P. Poma, et al., Influence of CYP3A5 and ABCB1 gene polymorphisms and other factors on tacrolimus dosing in Caucasian liver and kidney transplant patients. Int J Mol Med, 2011. 28(6): p. 1093-102. [PubMed: 21922127]
- 56.
- Crist, R.C., B.C. Reiner and W.H. Berrettini, A review of opioid addiction genetics. Curr Opin Psychol, 2019. 27: p. 31-35. [PMC free article: PMC6368898] [PubMed: 30118972]
- 57.
- Owusu Obeng, A., I. Hamadeh and M. Smith, Review of Opioid Pharmacogenetics and Considerations for Pain Management. Pharmacotherapy, 2017. 37(9): p. 1105-1121. [PubMed: 28699646]
- 58.
- Andersen, S. and F. Skorpen, Variation in the COMT gene: implications for pain perception and pain treatment. Pharmacogenomics, 2009. 10(4): p. 669-84. [PubMed: 19374521]
- 59.
- Andreassen, T.N., I. Eftedal, P. Klepstad, A. Davies, et al., Do CYP2D6 genotypes reflect oxycodone requirements for cancer patients treated for cancer pain? A cross-sectional multicentre study. Eur J Clin Pharmacol, 2012. 68(1): p. 55-64. [PMC free article: PMC3249195] [PubMed: 21735164]
- 60.
- Zhu, G.D., P. Whitley, L. LaRue, B. Adkins, et al., Impact of genetic variation in CYP2C19, CYP2D6, and CYP3A4 on oxycodone and its metabolites in a large database of clinical urine drug tests. Pharmacogenomics J, 2022. 22(1): p. 25-32. [PubMed: 34480108]
- 61.
- Balyan, R., M. Mecoli, R. Venkatasubramanian, V. Chidambaran, et al., CYP2D6 pharmacogenetic and oxycodone pharmacokinetic association study in pediatric surgical patients. Pharmacogenomics, 2017. 18(4): p. 337-348. [PMC free article: PMC5558529] [PubMed: 28244808]
- 62.
- Jakobsson, G., R. Larsson, L. Pelle, R. Kronstrand, et al., Oxycodone findings and CYP2D6 function in postmortem cases. Forensic Sci Int Genet, 2021. 53: p. 102510. [PubMed: 33799050]
- 63.
- Zwisler, S.T., T.P. Enggaard, L. Noehr-Jensen, R.S. Pedersen, et al., The hypoalgesic effect of oxycodone in human experimental pain models in relation to the CYP2D6 oxidation polymorphism. Basic Clin Pharmacol Toxicol, 2009. 104(4): p. 335-44. [PubMed: 19281600]
- 64.
- Samer, C.F., Y. Daali, M. Wagner, G. Hopfgartner, et al., Genetic polymorphisms and drug interactions modulating CYP2D6 and CYP3A activities have a major effect on oxycodone analgesic efficacy and safety. Br J Pharmacol, 2010. 160(4): p. 919-30. [PMC free article: PMC2935998] [PubMed: 20590588]
- 65.
- Rebsamen, M.C., J. Desmeules, Y. Daali, A. Chiappe, et al., The AmpliChip CYP450 test: cytochrome P450 2D6 genotype assessment and phenotype prediction. Pharmacogenomics J, 2009. 9(1): p. 34-41. [PubMed: 18591960]
- 66.
- Stamer, U.M., L. Zhang, M. Book, L.E. Lehmann, et al., CYP2D6 genotype dependent oxycodone metabolism in postoperative patients. PLoS One, 2013. 8(3): p. e60239. [PMC free article: PMC3610662] [PubMed: 23555934]
- 67.
- Ballester, P., J. Muriel and A.M. Peiro, CYP2D6 phenotypes and opioid metabolism: the path to personalized analgesia. Expert Opin Drug Metab Toxicol, 2022. 18(4): p. 261-275. [PubMed: 35649041]
- 68.
- Zwisler, S.T., T.P. Enggaard, S. Mikkelsen, K. Brosen, et al., Impact of the CYP2D6 genotype on post-operative intravenous oxycodone analgesia. Acta Anaesthesiol Scand, 2010. 54(2): p. 232-40. [PubMed: 19719813]
- 69.
- Whirl-Carrillo, M., R. Huddart, L. Gong, K. Sangkuhl, et al., An Evidence-Based Framework for Evaluating Pharmacogenomics Knowledge for Personalized Medicine. Clin Pharmacol Ther, 2021. 110(3): p. 563-572. [PMC free article: PMC8457105] [PubMed: 34216021]
- 70.
- Nieminen, T.H., N.M. Hagelberg, T.I. Saari, M. Neuvonen, et al., St John's wort greatly reduces the concentrations of oral oxycodone. Eur J Pain, 2010. 14(8): p. 854-9. [PubMed: 20106684]
- 71.
- Kim, J.H., J.Y. Kim, N. Lee, J. Yee, et al., The impact of drug interactions on adverse effects of oral oxycodone in male geriatric patients. J Clin Pharm Ther, 2020. 45(5): p. 976-982. [PubMed: 32068910]
- 72.
- Kinney, E.M., S. Vijapurapu, J.R. Covvey and B.D. Nemecek, Clinical outcomes of concomitant rifamycin and opioid therapy: A systematic review. Pharmacotherapy, 2021. 41(5): p. 479-489. [PubMed: 33748959]
- 73.
- Patel, J.N., D. Boselli, E.J. Jandrisevits, I.S. Hamadeh, et al., Potentially actionable pharmacogenetic variants and symptom control medications in oncology. Support Care Cancer, 2021. 29(10): p. 5927-5934. [PubMed: 33758969]
- 74.
- Peterson, P.E., W.T. Nicholson, A.M. Moyer, C.J. Arendt, et al., Description of Pharmacogenomic Testing Among Patients Admitted to the Intensive Care Unit After Cardiovascular Surgery. J Intensive Care Med, 2021. 36(11): p. 1281-1285. [PubMed: 32734840]
- 75.
- Pratt, V.M., L.H. Cavallari, A.L. Del Tredici, A. Gaedigk, et al., Recommendations for Clinical CYP2D6 Genotyping Allele Selection: A Joint Consensus Recommendation of the Association for Molecular Pathology, College of American Pathologists, Dutch Pharmacogenetics Working Group of the Royal Dutch Pharmacists Association, and the European Society for Pharmacogenomics and Personalized Therapy. J Mol Diagn, 2021. 23(9): p. 1047-1064. [PMC free article: PMC8579245] [PubMed: 34118403]
- 76.
- Kalman, L.V., J. Agundez, M.L. Appell, J.L. Black, et al., Pharmacogenetic allele nomenclature: International workgroup recommendations for test result reporting. Clin Pharmacol Ther, 2016. 99(2): p. 172-85. [PMC free article: PMC4724253] [PubMed: 26479518]
Footnotes
- 1
The FDA labels specific drug formulations. We have substituted the generic names for any drug labels in this excerpt. The FDA may not have labeled all formulations containing the generic drug. Certain terms, genes and genetic variants may be corrected in accordance to nomenclature standards, where necessary. We have given the full name of abbreviations, shown in square brackets, where necessary.
- Amitriptyline Therapy and CYP2D6 and CYP2C19 Genotype
- Aripiprazole Therapy and CYP2D6 Genotype
- Atomoxetine Therapy and CYP2D6 Genotype
- CYP2D6 Overview: Allele and Phenotype Frequencies
- Carvedilol Therapy and CYP2D6 Genotype
- Clozapine Therapy and CYP Genotype
- Codeine Therapy and CYP2D6 Genotype
- Deutetrabenazine Therapy and CYP2D6 Genotype
- Eliglustat Therapy and CYP2D6 Genotype
- Imipramine Therapy and CYP2D6 and CYP2C19 Genotype
- Metoprolol Therapy and CYP2D6 Genotype
- Prasugrel Therapy and CYP Genotype
- Primaquine Therapy and G6PD and CYP2D6 Genotype
- Propafenone Therapy and CYP2D6 Genotype
- Risperidone Therapy and CYP2D6 Genotype
- Tamoxifen Therapy and CYP2D6 Genotype
- Thioridazine Therapy and CYP2D6 Genotypes
- Tramadol Therapy and CYP2D6 Genotype
- Venlafaxine Therapy and CYP2D6 Genotype
- Oxycodone Therapy and CYP2D6 Genotype - Medical Genetics SummariesOxycodone Therapy and CYP2D6 Genotype - Medical Genetics Summaries
- Trichoderma asperellum strain:V6.1 | isolate:myceliumTrichoderma asperellum strain:V6.1 | isolate:myceliumMorphological characteristics and transcriptome analysis of the salt tolerance Trichoderma sp. responding to salt-stress conditionsBioProject
- Fungal-bacterial associationsFungal-bacterial associationsCharacterization of bacterial associations with fungal cultures isolated from a semi-arid grassland in GermanyBioProject
- Human 5-HT1D-type serotonin receptor gene, complete cdsHuman 5-HT1D-type serotonin receptor gene, complete cdsgi|177771|gb|M89955.1|HUM5HT1DANucleotide
Your browsing activity is empty.
Activity recording is turned off.
See more...