Prerpints.org logo
Preprint
Review

This version is not peer-reviewed.

The Role of Clinical Pharmacogenetics and Opioid Interactions in Optimizing Treatment in Clinical Practice

  † The authors equally contributed.

Submitted:

13 November 2025

Posted:

14 November 2025

You are already at the latest version

Abstract

Introduction: Opioids are the most commonly used analgesic drugs for acute and chronic severe pain metabolized in the liver via cytochrome P450 (CYP) and UDP-glucuronosyltransferase (UGT). Methods: A narrative review of the literature was conducted by searching MEDLINE and PubMed databases up to October 2025, using the English language as the only restriction. Relevant studies were identified using the keywords “opioids,” “pharmacogenetic,” “cytochrome mutations,” and “interactions.” Results: Polymorphisms in the CYP2D6 and CYP3A4 genes can affect the pharmacokinetics, clinical effect, and safety of opioids. Furthermore, enzyme induction and inhibition using concomitant drugs or compounds (herbal or food) are variability factors in drug response that may be predictable. Conclusion: This review article provides an overview of the role of pharmacogenetics and opioid interactions as a rationale for multimodal approaches aimed at optimizing treatment in clinical practice, in particular opioids should be tailored to each clinical indication and patients should be stratified to receive the appropriate dose.

Keywords: 
opioids
;  
pharmacogenetics
;  
polymorphisms
;  
drug-drug interactions
Subject: 
Medicine and Pharmacology  -   Pharmacology and Toxicology

1. Introduction

Opioids are the most commonly used analgesic drugs for acute and chronic severe pain in cancer and non-cancer patients, especially in the elderly suffering from pain-related functional impairment [1,2]. Opioids use exploded in 1995 when the US Food and Drug Administration (FDA) approved oxycodone for the treatment of chronic pain in non-cancer patients. Since then, opioid prescribing in the United States has increased from 143 million prescriptions in 1991 to 219 million in 2011 [3]. Opioids induce their analgesic effect stimulating G protein-coupled receptors, particularly the µ subtype. Receptor binding alters membrane permeability to K+ and Ca2+ ions and inhibits cyclic AMP (cAMP), resulting in an inhibitory action in the central and peripheral nervous system that elicits analgesia [4].
Opioids have a high rate of toxicity due to the narrow therapeutic index [2]. The most frequent adverse effects (AEs) are constipation, nausea, and vomiting. Respiratory depression is the most serious AE, although it occurs at higher doses. Hypotension, vasodilation, bradycardia, and/or QTc interval prolongation are the cardiac long-term AEs, while further AEs include fatigue, anxiety and depression, osteoporosis, and endocrinology disorders [5]. Genes encoding enzymes involved in opioid metabolism, as well as cytochrome P450 (CYP) and UDP-glucuronosyltransferase (UGT), may harbor several polymorphisms that could affect the opioid metabolic phenotype. Therefore, pharmacogenetics may be fundamental to understanding how allelic variations can influence drug response [6].
Drug-drug interactions (DDIs) are potentially responsible for AEs and can also influence the efficacy of opioids by altering the generation of secondary active/inactive metabolites [2]. In particular, pharmacokinetic interactions deserve attention since opioids are eliminated or bioactivated through hepatic metabolism [6]. This review article provides an overview of pharmacogenetics and opioid interactions that may be useful in optimizing treatment in clinical practice.

2. Materials and Methods

This work is a narrative review aiming to summarize and critically discuss the current evidence on the impact of pharmacogenetics and drug–drug interactions on opioid pharmacokinetics and pharmacodynamics. For this purpose, a literature search was conducted in MEDLINE and PubMed databases up to October 2025, using the English language as the only restriction. The Medical Subject Heading (MeSH) and keywords: (“opioids”), AND (“pharmacogenetic”) AND (“cytochrome mutations”) AND (“interactions”). Additional relevant studies not captured in our initial literature search were identified by examining the reference lists of selected papers. We screened review articles, meta-analyses, and original research articles. As this is a narrative review, the study was not registered in PROSPERO, and no formal quality assessment or meta-analysis was performed, in accordance with the recommendations for non-systematic reviews.

3. Results

3. Opioid Pharmacology at a Glance
The term opioids refer to all compounds that bind to opioid receptors. Morphine and codeine are major alkaloids derived from the opium poppy, semi-synthetic drugs are synthesized from natural opioids (e.g., heroin from morphine, oxycodone from thebaine), while fully synthetic opioids include methadone, fentanyl, and propoxyphene. The action of opioids consists in stimulating the presynaptic and postsynaptic receptors of the endogenous opioid system that can be found in the central and peripheral nervous systems, as well as on the immune system cells. The opioids primarily used to manage chronic pain are morphine, oxycodone, hydromorphone, dextropropoxyphene, fentanyl, pethidine, and codeine. Methadone and buprenorphine are mainly used for addiction management [7].

3.1. Opioid Receptors

Opioid receptors are classified into three different classes: µ (as morphine), δ (as deferens, since first identified in mouse vas deferens), and κ (as ketocyclazocine) [8]. The nociceptin opioid receptor (NOP receptor) is another receptor subtype which is phylogenetically related to the others. Besides nociceptin, the NOP receptor (formerly Opioid Receptor-like receptor-1, ORL-1) can bind orphanin FQ, a neuropeptide that activates an opioid-like G protein-coupled receptor. The NOP-N/OFQ system is important in physiological processes due to its wide distribution in the brain, spinal cord, and peripheral organs [9]. Furthermore, some opioids, such as tramadol and methadone, have additional sites of action based on nonopioid receptors [4].
Opioid receptors are G protein-coupled (GPCRs) receptors [10]. They belong to the class A (rhodopsin) receptor family characterized by an extracellular N-terminal domain, seven transmembranes (7TM) helical domains connected by three extracellular and three intracellular domains, and an intracellular C-terminal tail [11]. The main endogenous analgesic ligands are endorphins, enkephalins, and dynorphins [12]. Enkephalins derive from pro-enkephalin and are selective δ ligands, endorphins from pro-opiomelanocortin and bind to the µ receptor, and dynorphins from pro-dynorphins and are highly selective for the µ receptor subtype. All opioid receptors modulate pain by inhibiting voltage-gated Ca2+ channels and/or opening K+ channels; as a result, neuronal excitability is inhibited [13]. Upon activations of opioid receptors, coordinated phosphorylation of the receptor by specific GPCR kinases occurs. After the interaction of the phosphorylated receptors with β-arrestin 1 and 2, desensitization and internalization may occur [14]. Endogenous and exogenous ligands may produce different effects, including respiratory depression, euphoria, and hormone release. µ and δ agonists are the predominant analgesics, while κ agonists are almost involved in dysphoria. Oxycodone is a selective μ-opioid receptor agonist which, at higher doses, can stimulate κ-opioid receptors [15]. It appears that the antinociceptive effects of oxycodone are mediated by κ-opioid receptors, while morphine mainly interacts with µ-opioid receptor subtypes [16]. Fentanyl is a potent opioid agonist widely used for severe pain that selectively binds µ-receptors while having a very low affinity for δ and κ receptor subtypes [17].

3.2. Metabolism

Most opioids undergo metabolism in the liver by CYP450 enzymes and, to a lesser extent, by UDP-glucuronosyltransferases (UGTs). Opioid metabolism can lead to the conversion of the parent drug to inactive metabolites (e.g., fentanyl) or to the activation of the prodrug to an active metabolite responsible for analgesic properties (e.g., codeine) (Table 1). The most important isoenzymes involved in opioid metabolism are CYP2D6 and CYP3A4 [18]. Age, genetic mutations, and pathophysiological changes, including renal and hepatic impairment, may also influence opioid metabolism [19].
Tramadol is a synthetic opioid mainly metabolized by CYP2D6 (about 80%) in O-desmethyl-tramadol (M1), the active metabolite with a high affinity for opioid receptors [20]. Other metabolites are derived from CYP3A4, including N-desmethyltramadol (M2), a precursor of another active metabolite, O,N-didesmethyl-tramadol (M5). Active metabolites prolong the half-life and duration of tramadol action [21].
Morphine and codeine are natural compounds derived from poppy seeds, codeine being a methylated derivative of morphine. Codeine is converted to morphine by CYP2D6, norcodeine (NORC) by CYP3A4, and the active metabolite, codeine-6 glucuronide (C-6-G), by UGT2B7 [22]. UGT2B7 is also responsible for transforming morphine into active (morphine-6-glucuronide, M-6-G) and inactive (morphine-3-glucuronide, M-3-G) metabolites.
Oxycodone is the most commonly used opioid analgesic for moderate and severe pain and is pharmacodynamically comparable to morphine. Its major metabolite, noroxycodone, is produced by CYP34A and has only a weak affinity for µ-opioid receptors. CYP2D6 is also involved in oxycodone metabolism [23].
Buprenorphine is extensively metabolized by CYP3A4 to norbuprenorphine, an active metabolite expressing only one-fiftieth of the analgesic potency of buprenorphine [24].
Unlike other opioids, methadone and fentanyl do not produce active metabolites. Fentanyl is mainly converted to the non-toxic and inactive metabolite, norfentanyl, by CYP3A4 [18]. The CYP3A4-derived metabolites of methadone are 2-ethylidene-1,5-dimethyl-3,3-diphenyl-pyrrolidine (EDDP) and 2-ethyl-5-methyl-3,3-diphenyl-pyrroline (EMDP) [19].
The morphine analog, hydromorphone, is glucuronidated in the liver by UGT1A3 and UGT2B7 to hydromorphone-6-glucuronide (H-3-G) and hydromorphone-3-glucuronide (H-6-G), without significant involvement of the CYP450 system [4]. Hydromorphone is converted to hydrocodone by CYP2D6 [25] and has also been recognized as a minor metabolite of morphine. Although the metabolic pathway has not yet been described, one hypothesis is that morphine may be converted by morphine dehydrogenase to the intermediate metabolite, morphinone, then transformed into hydromorphone by morphinone reductase (Table 1) [26].

3.3. Efflux Transporters

P-glycoprotein (P-gp) is a member of the super-family of adenosine triphosphate–binding cassette (ABC) transporters capable of binding many different substrates, including opioids [27]. Opioids can influence P-gp activity. P-gp inducers include morphine and oxycodone while buprenorphine and methadone are inhibitors of ABC transporters at the blood-brain barrier (BBB) level [28].
For example, P-gp pump fentanyl out of the central nervous system (CNS) across the blood-brain barrier, and changes in P-gp expression may be responsible for interindividual variability in fentanyl response [29]. Genetic polymorphisms in the mdr1 gene encoding P-gp were indeed correlated with lower transporter function, resulting in an increased risk of adverse CNS effects of fentanyl [30], such as sedation and respiratory depression [31,32]. P-gp may also be involved in the development of central opioid tolerance. By inhibiting cerebral and intestinal P-gp using an inhibitor such as quinidine, studies have shown that healthy human volunteer subjects given oral morphine experienced a clinically relevant increase in plasma concentrations [33]. Methadone is also a substrate of P-gp. In vivo studies in rats, P-gp inhibitors caused higher brain concentrations and a more pronounced analgesic effect of methadone [34]. Variants 1236T, 2677T and 3435T of the mdr1 gene lowered P-gp activity in vitro. In addition, individuals carrying the homozygous polymorphic haplotype (i.e., TT-TT-TT at loci rs1045642, rs2032582, and rs1128503) showed an approximately 5-fold probability of requiring a higher dose of methadone. In contrast, individuals heterozygous for these three SNPs were about 3-fold more likely to have a beneficial analgesic effect at a lower methadone dose [35].

4. Adverse Drug Reactions

The use of opioids is often associated with the development of AEs that can limit the effectiveness of the treatment. Constipation is one of the most common gastrointestinal AEs of opioids that varies among patients with a range of 40-95%. Indeed, it is pivotal that patients do prophylactic treatments for maintaining an acceptable bowel peristalsis. Usually, clinicians recommend to drink lot of water and to increase the intake of fibers and physical activity. If these measures are ineffective, stool softeners (such as sorbitol), senna, or laxatives are required. The morphine seems to be the most potent opioids for inducing constipation. Despite, evidences on constipation and the route of administration are limited, transdermal fentanyl could be a valid alternative in patients suffering from severe constipation. Nausea and vomiting are the other two most common gastrointestinal AEs. Nausea, that occurs in about 25% of patients, is often transient and pharmacological treatment such as antipsychotics, metoclopramide or serotonin antagonists are used especially in cases of vomiting. The most serious AE, fortunately uncommon, is respiratory depression because of the potentially fatal outcome, usually related to an overdose of opioids. The pharmacological treatment for respiratory depression is naloxone [36,37]. In some cases, the long-term use of opioids is associated with AEs such as tolerance and hyperalgesia. The increase in daily doses may overcome the tolerance effect of prolonged administration issue, but it may augment the risk of dependence and addiction [38]. Research efforts have focused on the development of new categories of opioids (e.g., tapentadol) to reduce the risk of addiction while maintaining the analgesic efficacy [39,40]. Moreover, the progressive increase of opioids dosage can cause hyperalgesia (opioid-induced hyperalgesia, OHI), a nociceptive sensitization, which often requires dose tapering or treatment discontinuation [38]. Therefore, the clinical management of opioids may be difficult based on the on identify patients who potentially could develop opioid use disorders [41].

5. Pharmacogenetics

5.1. CYP2D6

CYP2D6 has involved in the metabolism of most opioids, and the CYP2D6 gene is highly polymorphic, with more than 100 SNPs associated with significant variability with ethnicity and race [42]. Moreover, more than one CYP2D6 gene copy can be present on the same chromosome, resulting in an ultra-rapid metabolizer phenotype as depicted below [43,44]. The CYP2D6*1, *2, and *35 polymorphisms do not have any effect on enzyme activity, while others may result in alleles being missing (CYP2D6*3, *4, and *6) or deficient (CYP2D6*9, *10, *17, *29, and *41) in CYP2D6 activity. The CYP2D6*5 polymorphism causes gene deletion, resulting in an allele without function. There are four different phenotypes identified based on the allelic combination: poor (PM), intermediate (IM), extensive (EM), and ultra-rapid (UM) metabolizers [45,46]. CYP2D6 PMs are prevalent in European and Jewish subjects instead, IMs in African and African-American populations, and EMs in East Asians and South-Central Asians. CYP2D6 UMs are more frequent in Jewish and Middle Eastern subjects than in other ethnic groups [45]. Reduced or absent CYP2D6 activity may result in little or no conversion of opioid prodrugs to their active metabolites, which may require dose adjustment to maintain therapeutic effect. Conversely, UMs produce more active metabolites with a higher risk of developing adverse events (Table 2) [47,48].

5.2. CYP3A4/5

Most of the genetic polymorphisms found in the CYP3A4 gene result in a reduced enzyme activity, with CYP3A4*1b, *2, *3, and *22 being the most relevant in terms of phenotypic change [49]. For example, several lines of evidence demonstrated that heterozygous patients carrying the CYP3A4*22 allele had a 47% reduction in fentanyl clearance [50]. CYP3A5 metabolizes many of the same drugs as CYP3A4. High interethnic variability in CYP3A5 expression has been observed due in part to 4 different possible alleles for this gene *1, *3, *6 and *7 [51,52]. The *3, *6 and *7 alleles are responsible for the synthesis of a nonfunctional truncated protein while the *1 allele is associated with normal enzyme activity [53,54]. In 70% of Caucasians, the *3 variant is expressed resulting in null enzyme activity [55]. In Takashina et. al’s study of cancer patients who were shifted to transdermal administration of fentanyl, the CYP3A5*3 variant appears to be associated with increased plasma concentration of fentanyl and a higher incidence of CNS AEs than the *1 variant (Table 2) [32].

5.3. CYP2B6

CYP2B6 exhibits various polymorphisms and is mainly involved in methadone metabolism. The 516G>T and 785A>G polymorphisms in the CYP2B6*6 allele have been associated with reduced enzyme activity, and individuals homozygous for these variants may require lower doses than heterozygous or non-carriers subjects [56,57]. Studies on the impact of CYP2B6 genotype on pharmacokinetics have provided conflicting results (Table 2) [58,59].

5.4. UGT2B7

Another enzyme involved in opioid metabolism is UGT2B7. This enzymatic isoform can convert morphine into morphine-3-glucuronide (M-3-G) and M-6-G, the latter being the active metabolite responsible for the analgesic activity. The most studied polymorphisms are UGT2B7 802 T>C and 900G>A. Patients with the UGT2B7 802CC genotype appear to have an increased metabolism of morphine and a higher M-6-G/M-3-G ratio than those with the CT or TT genotypes, thus requiring a lower morphine dose. Furthermore, one study found that individuals carrying UGT2B7 802T had extensive analgesia compared with UGT2B7 802C homozygotes, most likely due to reduced glucuronidation activity; in contrast, other studies have found no correlation between the 802T variant and treatment response [60,61].
Moreover, while several lines of evidence suggest that the UGT2B7-900G>A variant is associated with higher enzymatic activity than wild-type UGT2B7-900G, other studies have shown no impact of this polymorphism on morphine pharmacokinetics [60,61,62].
Despite these findings, no statistically significant differences in the plasma concentration of morphine and its metabolites were observed between the different genotypes; however, multivariate stepwise linear regression models could identify a significant association between the CC genotype and morphine dose (Table 2) [63,64].

5.5. P-gp

Opioid pharmacokinetics can also be influenced by the activity of membrane transporters, such as P-gp (or ABCB1), which actively transports drugs out of CNS. Among the 50 SNPs identified, those of greatest interest are c.1236C>T, c.2677G>T/A, and c.3435C>T, located in exons 12, 21 and 26, respectively. These polymorphisms are more frequent in Caucasian and Asian populations than in Africans [60,61,62,63,64,65]. A study in healthy individuals carrying the c.3435TT genotype a reduced expression of the transporter at the duodenal level [66], which could potentially also influence P-gp expression at the blood-brain barrier. This correlates with the elevated concentration of morphine at the cerebrospinal fluid level observed after intravenous infusion in c.3435TT subjects. Consequently, patients harbouring this genetic variant have a higher risk of opioid-related AEs requiring dose reduction [67]. Rhodin et al. conducted a study in patients with chronic back pain treated with remifentanil and found an increased frequency of AEs such as sweating, sedation, tension, and stress in homozygous c.3435T/T carriers compared with heterozygotes c.3435C/T and homozygotes c.3435C/C [68]. Moreover, a study investigated the correlation between c.3435C/T SNP in the mdr1 gene and opioid consumption for controlling post-operative pain in 152 patients undergoing a nephrectomy. The involvement of mdr1 polymorphisms in opioid consumption provides evidence of their role in guiding acute pain therapy in post-operative patients [69]. Regarding the c.1236C>T polymorphism, Fujita et al. observed a higher frequency of fatigue after morphine intake in CC individuals compared with TT ones, and that finding was also confirmed by higher morphine clearance in c.1236TT individuals [70]. Another study demonstrated that the c.2677G>T/A and the c.1236C>T SNPs in the mdr1 gene were associated with a lower incidence of CNS Aes, such as drowsiness, confusion, and hallucinations, after morphine administration (Table 2) [71].

5.6. OPRs

The oprm1 gene encodes for the µ-opioid receptor. The c.118A>G polymorphism causes an exchange of amino acids in the extracellular domain of the receptor, with a reduced opioid binding affinity. The 118G allele is more frequent in Asian populations (40%-50%), moderate in European populations (15%-30%), and infrequent in African populations [56]. Clinical studies in postoperative pain treated with morphine or fentanyl showed that individuals carrying the polymorphic G allele required higher doses than wild-type AA homozygotes [72]. Another study showed that OPRM1 c.118A/A homozygotes had higher pain relief after opioid treatment than G/G homozygotes, whereas no difference was observed between A/G heterozygotes and G/G homozygotes. These findings suggest that individuals carrying at least one G allele may respond less to morphine than A/A homozygotes [60,73]. The 118G allele also appears to be associated with several phenotypes, including opioid dependence, while other drugs of abuse, i.e., alcoholism, may blunt the hypothalamus pituitary adrenal (HPA) axis response to stress, reducing the efficacy of opioids in clinics. Furthermore, some studies found a positive effect of the 118G allele on the response to treatment with naltrexone, an opioid antagonist [56,74,75]. KOR is an opioid receptor encoded by the oprk1 gene. KOR plays a role in pain perception and mediates the hypo-locomotor, analgesic, and adverse reactions of synthetic opioids. Variations in this gene have also been associated with alcohol dependence and opioid addiction. Genetic variability of OPRK1 has been shown to modulate methadone efficacy, and polymorphisms rs3802279 CC, rs3802281 TT, and rs963549 CC appear to be associated with lower methadone maintenance dose per day. The haplotypes rs10958350-rs7016778-rs12675595 are instead associated with withdrawal symptoms [76,77].

5.7. COMT

The comt gene encodes for the enzyme catechol -O- methyltransferase (COMT) that regulates µ-receptor (MOR) density in the brain by affecting pain perception [78,79,80]. In subjects with genotype c.472G>A, a lower concentration of met-enkephalin and higher expression of MOR was found [80]. In agreement with those findings, those individuals seemed requiring a lower dose of opioids for neoplastic and postoperative pain control [81,82,83,84,85,86]. Several SNPs in the comt gene, including c.1-98A>G (rs62699), 186C>T (rs4633), c.408C>G (rs4818), and c.472G>A (rs4680), are associated with a different response to opioids. In the study by Lotta et al. three genotypes associated with the c.472G>A variant corresponded to different levels of COMT enzyme activity. Individuals with homozygous AA genotype have higher pain sensitivity due to lower enzyme activity, in contrast, GA heterozygotes have intermediate activity and GG homozygotes have high enzyme activity and thus lower pain sensitivity [87]. This was also confirmed by Henker and coworkers in a study of opioid treatment of postoperative pain, in which GG homozygous and AG heterozygous patients showed lower pain scores than AA homozygous patients [88]. In contrast, another study related to morphine intake for the management of neoplastic pain found the use of a higher dose of opioid in individuals with the GG genotype compared with those with the AG and AA genotypes. This could be due to suppression of enkephalin production secondary to altered COMT enzyme activity resulting in upregulation of opioid receptors in homozygous AA patients in contrast to what was observed in G/G patients [89].

5.8. OCT

OCT1 is an influx transporter coded by the slc22a1 gene especially expressed in the liver that recognizes morphine and tramadol as substrates. The slc22a1 gene is highly polymorphic; the variants OCT1*2, *3, *4, *5, and *6, are associated with loss of OCT1 activity resulting in reduced hepatic uptake, increased plasma concentration of morphine and tramadol, and thus altered treatment efficacy. Children homozygous for variants associated with loss of function of OCT1 have significantly lower opioid clearance [60,90,91,92].

5.9. ARRB2-Dcc

A recent prospective, multicenter, open-label study investigating the correlation between polymorphisms in the β2-arrestin gene (ARRB2) and clinical response to methadone for pain relief in advanced cancer was carried out [93]. The results suggested that polymorphisms in ARRB2 influenced the response to methadone and pain severity. Furthermore, a translational study using mice focusing on the role of the mpdz gene showed that genotypic variants of this gene are associated with altered opioid tolerance and opioid-induced hyperalgesia [94]. Finally, heterozygous variants of the Netrin 1 Receptor Dcc gene are associated with a decreased tendency in developing opioid-induced hyperalgesia after chronic administration of morphine [95]. These studies highlighted the pivotal role of pharmacogenetics in opioids for determining the accurate dose to treat pain, especially in the era of personalized medicine [96]. For the above reasons more randomized controlled trials are critically needed to elucidate the potential role of these biomarkers to translate and enhance their use in clinical practice.

6. Opioids Interactions

6.1. Drug Interactions

Co-administration of drugs that induce or inhibit enzymes involved in opioid metabolism can generate interactions with clinical consequences. Induction of CYP450 isoenzymes that metabolize opioid prodrugs can lead to inadequate analgesia, as for oxycodone [97,98]. Conversely, inhibition of CYP3A4 and CYP2D6 can enhance the risk of opioid-induced toxicity when the enzymes catalyze the conversion of the active parent drug to inactive metabolites, as observed with methadone [99] and fentanyl [97].
Antidepressant drugs, including fluoxetine, paroxetine [100], and bupropion [101], have been found to increase plasma concentrations of tramadol through the inhibition of CYP2D6. This effect may decrease the analgesic efficacy of tramadol due to a reduced formation of the active metabolite O-desmethyl-tramadol (M1) [102] while enhancing the risk of serotonergic syndrome [103]. This is possible because the active metabolite O-desmethyl-tramadol (M1) is responsible for the complementary mechanisms that increase the analgesic effect of tramadol, while the levorotatory (-) enantiomer inhibits norepinephrine reuptake, affecting the adrenergic system, the dextrorotatory (+) enantiomer binds to opioid receptors and inhibits cellular reuptake of serotonin, increasing the risk of serotonergic syndrome [104]. In addition, the CYP2D6-mediated transformation of codeine to morphine may also be impaired by the concomitant use of selective serotonin reuptake inhibitors (SSRIs) resulting in a loss of analgesic efficacy [105,106], despite atypical opioids (e.g., tramadol and tapentadol) acts also through the inhibition of serotoninergic and noradrenergic descendent pathways that control nociception at the spinal level. The identical mechanism may explain the reduced analgesic efficacy observed in patients giving tramadol [97] or codeine [99] with the H2-receptor antagonist cimetidine. The antiarrhythmic drugs quinidine and amiodarone can also interact with opioids. Quinidine [107] and the active metabolite of amiodarone, N-derivative of monodesethyl-amiodarone [108], have been found to reduce the CYP2D6-mediated activation of codeine and tramadol, respectively [100]. Ondansetron, an antiemetic used to control tramadol-induced nausea and vomiting, may reduce the formation of the active metabolite of tramadol (M1) by a metabolic competition on CYP2D6 [103]. Therefore, it is important to evaluate whether patients could receive an adequate analgesic response and adjust the tramadol dose, accordingly. In addition, concurrent treatment should be stopped if serotonin syndrome occurs. Antiretroviral ritonavir is another potent CYP2D6 inhibitor that impairs the efficacy of codeine [101].
Unlike opioid prodrugs, oxycodone-induced analgesia is primarily due to the parent drug. Consequently, induction of CYP3A-mediated metabolism m[109,110ay lead to treatment failure, while enhanced opioid effects are expected when combining oxycodone with potent CYP3A inhibitors [97]. For example, the induction of CYP2D6 and CYP3A4 by rifampicin decreases the plasma concentrations of oxycodone after oral or intravenous administration [109,110]. Conversely, inhibition of hepatic and/or intestinal CYP3A activity by azole derivatives leads to increased exposure to oral oxycodone in healthy subjects enhancing its analgesic effects and increasing the risk of serious adverse reactions [85,86]. Methadone and fentanyl are potent analgesic opioids mainly metabolized by CYP3A4 [97,99]. Enzyme inhibition by antiretroviral and antimicrobial drugs or antibiotics leads to increased blood levels of fentanyl with a risk of respiratory depression (Table 3) [97]. Similar clinical consequences have been observed in patients taking methadone in combination with ritonavir, ketoconazole or itraconazole, ciprofloxacin, clarithromycin, and the Ca2+ antagonist, diltiazem [99].
In addition to respiratory depression, concomitant use of drugs that inhibit methadone metabolism may increase the incidence of QTc interval prolongation and torsades de pointes [111,112]. Conversely, induction of CYP3A4 activity by antibiotics, anticonvulsant/antiepileptic drugs, and barbiturates can lead to withdrawal syndrome symptoms [113]. The UGT is the other enzyme that metabolized opioids, especially morphine, as already mentioned. Nowadays, few evidence are available about drugs that can influence (inhibit or induce) the UGT activity. Some in vivo studies showed an alteration of morphine’s pharmacokinetic when co-administered with other drugs, like a decrease in active metabolites (M3G and M6G), but how much is the contribution of UGT on this effect remained unknown [114].

6.2. Herb-Food Interactions

CYP3A4 and CYP2D6 are the two main isoenzymes of the CYP450 family involved in opioid metabolism [18], which can be inhibited or induced by some herbs and food. The best-known interactions are those with grapefruit juice (a CYP3A4 inhibitor) and Saint John’s wort (a CYP3A4 inducer). Strong/moderate CYP3A4 inhibitors also include Sevilla orange, lime, cranberry, and goldenseal, while ginseng and licorice are CYP3A4 inducers. Ginkgo and piperine/pepper extracts are the exceptions due to their dual activity on CYP3A4. The likelihood of interaction between CYP2D6 substrates and herbs or foods is lower than with CYP3A4 substrates. Goldenseal and black seed are strong inhibitors of CYP2D6, while ginseng and kudzu are mild/moderate inhibitors; on the other hand, no inducers of CYP2D6 with clinically relevant activity were identified [115]. Furthermore, it is also important to point out that the likelihood of causing a significant interaction from herbs or food can depend on the strength of the active ingredient in them and the amount taken.

7. Conclusions and Future Directions

Opioids are the most potent analgesic drug class commonly used in clinical practice for pain management. They are mainly metabolized in the liver by CYP450 and UGTs enzymes and CYP2D6 and CYP3A4 isoenzymes. In this regard, the metabolism is responsible for producing inactivate metabolites or in improving their activities. For the above reasons, the induction or the inhibition of metabolism through the use of concomitant other drug classes or compounds which modulate the activity of CYP2D6 and CYP3A4 may produce drug-drug interactions which could be responsible for inadequate analgesia or toxicities. Thus, the concurrent use of inducers or inhibitors of these isoenzymes should be deeply investigated.
The presence of polymorphisms in CYP2D6 and CYP3A4 genes strictly related to ethnicity and race may influence opioid pharmacokinetics and great efforts are needed to personalize opioid treatments [6]. This appears to be a challenging goal in clinical practice due to the limited availability of clinical data regarding the correlation between opioid pharmacogenetics and clinical outcomes. Currently, the Clinical Pharmacogenetics Implementation Consortium (CPIC) guidelines recommend only CYP2D6 genotyping as a tool to identify the subset of patients who could benefit from codeine, tramadol, and hydrocodone treatment optimization [48]. Therefore, further evidence on the role of pharmacogenetics in the clinical management of opioids are urgently needed to translate this information into the real-life setting. Starting from the significant impact of CYP2D6 polymorphisms on opioid pharmacology and adoption of CYP2D6-guided prescriptions in which a body of literature has proved, some promising biomarkers are under investigation. For example, promising candidate biomarkers without therapeutic recommendations are CYP2D6 for oxycodone and methadone, and OPRM1 or COMT for opioids.
In closing remarks, the role of pharmacogenetics in pain relief has emerged in the last decade as pivotal for achieving multimodal approaches and tailored therapies for patient management. In this regard, dissecting biology through genetic fingerprinting would open a new avenue for pain treatment in terms of more accurate dosing and schedule to prevent treatment-related toxicities and maximize the effect in different patients and settings. The landscape of pain management is very wide and may vary from acute to chronic severe pain including all cancer, musculoskeletal, post-surgical, trauma, and dental pain. Thus, their use will grow up soon. For the above, there has been an emerging recognition that opioids should be tailored to each clinical indication and patients should be stratified to receive the appropriate dose. A more deepened use and combination of PGx and DDI analysis would definitely benefit for the management of patients with mild to severe pain.

Author Contributions

Conceptualization, C.D.S. and G.V.; methodology, X.X.; writing—original draft preparation, C.D.S., G.V., G.B., G.P., S.B., G.I.L.; writing—review and editing, A.D.V..; supervision, M.F., A.D.P., L.A. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflicts of interest

References

  1. C. Zöllner; C. Stein. Opioids. Handb Exp Pharmacol 2007, 177, 31–63. [Google Scholar] [CrossRef]
  2. B. R. Overholser; D. R. Foster. Opioid pharmacokinetic drug-drug interactions. Am J Manag Care 2011, 17 (Suppl. 11). [Google Scholar]
  3. N. E. Hagemeier. Introduction to the opioid epidemic: the economic burden on the healthcare system and impact on quality of life. Am J Manag Care 2018, 24, S200–S206. [Google Scholar]
  4. M. Trescot, S. Datta, M. Lee, and H. Hans. Opioid pharmacology. Pain Physician 2008, 11. [Google Scholar] [CrossRef]
  5. D. Vearrier and O. Grundmann. Clinical Pharmacology, Toxicity, and Abuse Potential of Opioids. J Clin Pharmacol 2021, 61 (Suppl. 2), S70–S88. [Google Scholar] [CrossRef]
  6. Owusu Obeng, I. Hamadeh, and M. Smith. Review of Opioid Pharmacogenetics and Considerations for Pain Management. Pharmacotherapy 2017, 37, 1105–1121. [Google Scholar] [CrossRef]
  7. Rosenblum, L. A. Marsch, H. Joseph, and R. K. Portenoy. Opioids and the treatment of chronic pain: controversies, current status, and future directions. Exp Clin Psychopharmacol 2008, 16, 405–416. [Google Scholar] [CrossRef] [PubMed]
  8. G. W. Pasternak. Opiate pharmacology and relief of pain. J Clin Oncol 2014, 32, 1655–1661. [Google Scholar] [CrossRef]
  9. N. T. Zaveri. Nociceptin Opioid Receptor (NOP) as a Therapeutic Target: Progress in Translation from Preclinical Research to Clinical Utility. J Med Chem 2016, 59, 7011–7028. [Google Scholar] [CrossRef] [PubMed]
  10. K. Lundstrom. The future of G protein-coupled receptors as targets in drug discovery - PubMed. IDrugs, 2005.
  11. M. Waldhoer, S. E. Bartlett, and J. L. Whistler. Opioid receptors. Annu Rev Biochem 2004, 73, 953–990. [Google Scholar] [CrossRef]
  12. Y. Shang and M. Filizola. Opioid receptors: Structural and mechanistic insights into pharmacology and signaling. Eur J Pharmacol 763, no. Pt B, 206–213, 2015. [CrossRef]
  13. J. E. Holden, Y. Jeong, and J. M. Forrest. The endogenous opioid system and clinical pain management. AACN Clin Issues 2005, 16, 291–301. [Google Scholar] [CrossRef] [PubMed]
  14. L. M. Bohn, R. J. Lefkowitz, R. R. Gainetdinov, K. Peppel, M. G. Caron, and F. T. Lin. Enhanced morphine analgesia in mice lacking beta-arrestin 2. Science 1999, 286, 2495–2498. [Google Scholar] [CrossRef]
  15. E. Kalso. Oxycodone. J Pain Symptom Manage 2005, 29, 47–56. [Google Scholar] [CrossRef]
  16. F. B. Ross and M. T. Smith. The intrinsic antinociceptive effects of oxycodone appear to be kappa-opioid receptor mediated. Pain 1997, 73, 151–157. [Google Scholar] [CrossRef]
  17. D. A. Volpe et al. . Uniform assessment and ranking of opioid μ receptor binding constants for selected opioid drugs. Regul Toxicol Pharmacol 2011, 59, 385–390. [Google Scholar] [CrossRef]
  18. S. Mercadante. Opioid metabolism and clinical aspects. Eur J Pharmacol 2015, 769, 71–78. [Google Scholar] [CrossRef]
  19. H. S. Smith. Opioid metabolism. Mayo Clin Proc 2009, 84, 613–624. [Google Scholar] [CrossRef] [PubMed]
  20. P. Dayer, J. Desmeules, and L. Collart. Pharmacology of tramadol. Drugs 1997, 53, 18–24. [Google Scholar] [CrossRef]
  21. K. Miotto, A. K. Cho, M. A. Khalil, K. Blanco, J. D. Sasaki, and R. Rawson. Trends in Tramadol: Pharmacology, Metabolism, and Misuse. Anesth Analg 2017, 124, 44–51. [Google Scholar] [CrossRef]
  22. W. Leppert. CYP2D6 in the metabolism of opioids for mild to moderate pain. Pharmacology 2011, 87, 274–285. [Google Scholar] [CrossRef]
  23. R. A. Lugo and S. E. Kern. The pharmacokinetics of oxycodone. J Pain Palliat Care Pharmacother 2004, 18, 17–30. [CrossRef]
  24. Elkader and, B. Sproule. Buprenorphine: clinical pharmacokinetics in the treatment of opioid dependence. Clin Pharmacokinet 2005, 44, 661–680. [Google Scholar] [CrossRef]
  25. S. Valtier and V. S. Bebarta. Excretion profile of hydrocodone, hydromorphone and norhydrocodone in urine following single dose administration of hydrocodone to healthy volunteers. J Anal Toxicol 2012, 36, 507–514. [Google Scholar] [CrossRef]
  26. M. M. Hughes, R. S. Atayee, B. M. Best, and A. J. Pesce. Observations on the metabolism of morphine to hydromorphone in pain patients. J Anal Toxicol 2012, 36, 250–256. [Google Scholar] [CrossRef]
  27. M. Hennessy and J. P. Spiers. A primer on the mechanics of P-glycoprotein the multidrug transporter. Pharmacol Res 2007, 55, 1–15. [Google Scholar] [CrossRef]
  28. F. Coluzzi, M. S. Scerpa, M. Rocco, and D. Fornasari. The Impact of P-Glycoprotein on Opioid Analgesics: What’s the Real Meaning in Pain Management and Palliative Care? Int J Mol Sci 2022, 23, 14125. [Google Scholar] [CrossRef]
  29. Wandel, R. Kim, M. Wood, and A. Wood. Interaction of morphine, fentanyl, sufentanil, alfentanil, and loperamide with the efflux drug transporter P-glycoprotein. Anesthesiology 2002, 96, 913–920. [Google Scholar] [CrossRef] [PubMed]
  30. J. Lötsch, C. Walter, M. J. Parnham, B. G. Oertel, and G. Geisslinger. Pharmacokinetics of non-intravenous formulations of fentanyl. Clin Pharmacokinet 2013, 52, 23–36. [Google Scholar] [CrossRef] [PubMed]
  31. E. Kesimci, A. B. Engin, O. Kanbak, and B. Karahalil. Association between ABCB1 gene polymorphisms and fentanyl’s adverse effects in Turkish patients undergoing spinal anesthesia. Gene 2012, 493, 273–277. [Google Scholar] [CrossRef]
  32. Y. Takashina, T. Naito, Y. Mino, T. Yagi, K. Ohnishi, and J. Kawakami. Impact of CYP3A5 and ABCB1 gene polymorphisms on fentanyl pharmacokinetics and clinical responses in cancer patients undergoing conversion to a transdermal system. Drug Metab Pharmacokinet 2012, 27, 414–421. [Google Scholar] [CrossRef]
  33. E. Kharasch. Role of P-glycoprotein in the intestinal absorption and clinical effects of morphine. Clin Pharmacol Ther 2003, 74, 543–554. [Google Scholar] [CrossRef]
  34. M. Rodriguez, I. Ortega, I. Soengas, E. Suarez, J. C. Lukas, and R. Calvo. Effect of P-glycoprotein inhibition on methadone analgesia and brain distribution in the rat. Journal of Pharmacy and Pharmacology 2010, 56, 367–374. [Google Scholar] [CrossRef]
  35. O., Levran; et al. . ABCB1 (MDR1) genetic variants are associated with methadone doses required for effective treatment of heroin dependence. Hum Mol Genet 2008, 17, 2219–2227. [Google Scholar] [CrossRef]
  36. M. Z. Imam, A. Kuo, S. Ghassabian, and M. T. Smith. Progress in understanding mechanisms of opioid-induced gastrointestinal adverse effects and respiratory depression. Neuropharmacology 2018, 131, 238–255. [Google Scholar] [CrossRef]
  37. J. M. SWEGLE and C. LOGEMANN. Management of Common Opioid-Induced Adverse Effects. Am Fam Physician 2006, 74, 1347–1354. [Google Scholar]
  38. S. Mercadante, E. Arcuri, and A. Santoni. Opioid-Induced Tolerance and Hyperalgesia. CNS Drugs 2019, 33, 943–955. [Google Scholar] [CrossRef] [PubMed]
  39. P. JK, F. P. JK, F. MA, and B. RJ. Pain Management and the Opioid Epidemic: Balancing Societal and Individual Benefits and Risks of Prescription Opioid Use. Pain Management and the Opioid Epidemic. [CrossRef]
  40. K. M. Raehal, C. L. Schmid, C. E. Groer, and L. M. Bohn. Functional selectivity at the μ-opioid receptor: implications for understanding opioid analgesia and tolerance. Pharmacol Rev 2011, 63, 1001–1019. [Google Scholar] [CrossRef]
  41. N. Nafziger and R. L. Barkin. Opioid Therapy in Acute and Chronic Pain. J Clin Pharmacol 2018, 58, 1111–1122. [Google Scholar] [CrossRef]
  42. M. Trescot. Genetics and implications in perioperative analgesia. Best Pract Res Clin Anaesthesiol 2014, 28, 153–166. [Google Scholar] [CrossRef] [PubMed]
  43. Gaedigk, G. P. Twist, E. G. Farrow, J. A. Lowry, S. E. Soden, and N. A. Miller. In vivo characterization of CYP2D6*12, *29 and *84 using dextromethorphan as a probe drug: a case report. Pharmacogenomics 2017, 18, 427–431. [Google Scholar] [CrossRef]
  44. K. E. Caudle et al.. Standardizing CYP2D6 Genotype to Phenotype Translation: Consensus Recommendations from the Clinical Pharmacogenetics Implementation Consortium and Dutch Pharmacogenetics Working Group. Clin Transl Sci 2020, 13, 116–124. [Google Scholar] [CrossRef]
  45. Gaedigk, K. Sangkuhl, M. Whirl-Carrillo, T. Klein, and J. Steven Leeder. Prediction of CYP2D6 phenotype from genotype across world populations. Genet Med 2017, 19, 69–76. [Google Scholar] [CrossRef]
  46. S. Packiasabapathy and S. Sadhasivam. Gender, genetics, and analgesia: understanding the differences in response to pain relief. J Pain Res 2018, 11, 2729–2739. [Google Scholar] [CrossRef]
  47. K. R. Crews et al.. Clinical Pharmacogenetics Implementation Consortium guidelines for cytochrome P450 2D6 genotype and codeine therapy: 2014 update. Clin Pharmacol Ther 2014, 95, 376–382. [Google Scholar] [CrossRef]
  48. K. R. Crews et al.. Clinical Pharmacogenetics Implementation Consortium Guideline for CYP2D6, OPRM1, and COMT Genotypes and Select Opioid Therapy. Clin Pharmacol Ther 2021, 110, 888–896. [Google Scholar] [CrossRef]
  49. K. Klein and U. M. Zanger. Pharmacogenomics of Cytochrome P450 3A4: Recent Progress Toward the ‘Missing Heritability’ Problem. Front Genet 2013, 4. [Google Scholar] [CrossRef]
  50. M. Saiz-Rodríguez et al.. Polymorphisms associated with fentanyl pharmacokinetics, pharmacodynamics and adverse effects. Basic Clin Pharmacol Toxicol 2019, 124, 321–329. [Google Scholar] [CrossRef] [PubMed]
  51. R. K. Bains et al.. Molecular diversity and population structure at the Cytochrome P450 3A5 gene in Africa. BMC Genet 2013, 14, 1–18. [Google Scholar] [CrossRef]
  52. S. -J. Lee et al.. Genetic findings and functional studies of human CYP3A5 single nucleotide polymorphisms in different ethnic groups*. Pharmacogenet Genomics 2003, 13. https://journals.lww.com/jpharmacogenetics/Fulltext/2003/08000/Genetic_findings_and_functional_studies_of_human.4.aspx. [Google Scholar]
  53. “The genetic determinants of the CYP3A5 polymorphism : Pharmacogenetics and Genomics.” https://journals.lww.com/jpharmacogenetics/Abstract/2001/12000/The_genetic_determinants_of_the_CYP3A5.5.aspx (accessed Jul. 03, 2023).
  54. P. Kuehl et al.. Sequence diversity in CYP3A promoters and characterization of the genetic basis of polymorphic CYP3A5 expression. Nature Genetics 2001, 27, 383–391. [Google Scholar] [CrossRef] [PubMed]
  55. R. H. N. van Schaik, I. P. van der Heiden, J. N. van den Anker, and J. Lindemans. CYP3A5 variant allele frequencies in Dutch Caucasians. Clin Chem 2002, 48, 1668–1671. [Google Scholar] [CrossRef]
  56. M. J. Kreek, O. Levran, B. Reed, S. D. Schlussman, Y. Zhou, and E. R. Butelman. Opiate addiction and cocaine addiction: underlying molecular neurobiology and genetics. J Clin Invest 2012, 122, 3387–3391. [Google Scholar] [CrossRef]
  57. S. C. Sim and M. Ingelman-Sundberg. The Human Cytochrome P450 (CYP) Allele Nomenclature website: a peer-reviewed database of CYP variants and their associated effects. Hum Genomics 2010, 4, 278–281. [Google Scholar] [CrossRef] [PubMed]
  58. U. M. Zanger and K. Klein. Pharmacogenetics of cytochrome P450 2B6 (CYP2B6): advances on polymorphisms, mechanisms, and clinical relevance. Front Genet 2013, 4. [Google Scholar] [CrossRef]
  59. S. C. Wang et al.. CYP2B6 polymorphisms influence the plasma concentration and clearance of the methadone S-enantiomer. J Clin Psychopharmacol 2011, 31, 463–469. [Google Scholar] [CrossRef]
  60. Ofoegbu and E., B. Ettienne. Pharmacogenomics and Morphine. J Clin Pharmacol 2021, 61, 1149–1155. [Google Scholar] [CrossRef]
  61. K. Meissner et al.. UDP glucuronosyltransferase 2B7 single nucleotide polymorphism (rs7439366) influences heat pain response in human volunteers after i.v. morphine infusion. Crit Care 2011, 15. [Google Scholar] [CrossRef]
  62. M. Matic et al.. Effect of UGT2B7 -900G>A (-842G>A; rs7438135) on morphine glucuronidation in preterm newborns: results from a pilot cohort. Pharmacogenomics 2014, 15, 1589–1597. [Google Scholar] [CrossRef]
  63. S. Bastami, A. Gupta, A. L. Zackrisson, J. Ahlner, A. Osman, and S. Uppugunduri. Influence of UGT2B7, OPRM1 and ABCB1 gene polymorphisms on postoperative morphine consumption. Basic Clin Pharmacol Toxicol 2014, 115, 423–431. [Google Scholar] [CrossRef]
  64. K. I. Fujita et al.. Association of UGT2B7 and ABCB1 genotypes with morphine-induced adverse drug reactions in Japanese patients with cancer. Cancer Chemother Pharmacol 2010, 65, 251–258. [Google Scholar] [CrossRef] [PubMed]
  65. Z. Zifei, C. Z. Zifei, C. Quanchui, Z. Dongqing, W. Hongsheng, H. Yingqi, and C. Zhengdong. ABCB1 (rs1128503) polymorphism and response to chemotherapy in patients with malignant tumors-evidences from a meta-analysis - PubMed. Int J Clin Exp Med, 2015.
  66. S. Hoffmeyer et al.. Functional polymorphisms of the human multidrug-resistance gene: Multiple sequence variations and correlation of one allele with P-glycoprotein expression and activity in vivo. Proceedings of the National Academy of Sciences 2000, 97, 3473–3478. [Google Scholar] [CrossRef]
  67. I., Meineke; et al. . Pharmacokinetic modelling of morphine, morphine-3-glucuronide and morphine-6-glucuronide in plasma and cerebrospinal fluid of neurosurgical patients after short-term infusion of morphine. Br J Clin Pharmacol 2002, 54, 592–603. [Google Scholar] [CrossRef]
  68. A., Rhodin; et al. . Combined analysis of circulating β-endorphin with gene polymorphisms in OPRM1, CACNAD2 and ABCB1 reveals correlation with pain, opioid sensitivity and opioid-related side effects. Mol Brain 2013, 6, 8. [Google Scholar] [CrossRef]
  69. K. Candiotti et al.. Single-nucleotide polymorphism C3435T in the ABCB1 gene is associated with opioid consumption in postoperative pain. Pain Med 2013, 14, 1977–1984. [Google Scholar] [CrossRef]
  70. K. I. Fujita et al.. Association of UGT2B7 and ABCB1 genotypes with morphine-induced adverse drug reactions in Japanese patients with cancer. Cancer Chemother Pharmacol 2010, 65, 251–258. [Google Scholar] [CrossRef]
  71. J. R. Ross et al.. Genetic variation and response to morphine in cancer patients: catechol-O-methyltransferase and multidrug resistance-1 gene polymorphisms are associated with central side effects. Cancer 2008, 112, 1390–1403. [Google Scholar] [CrossRef]
  72. L. M. Nielsen, A. E. Olesen, R. Branford, L. L. Christrup, H. Sato, and A. M. Drewes. Association Between Human Pain-Related Genotypes and Variability in Opioid Analgesia: An Updated Review. Pain Pract 2015, 15, 580–594. [Google Scholar] [CrossRef] [PubMed]
  73. Campa, A. Gioia, A. Tomei, P. Poli, and R. Barale. Association of ABCB1/MDR1 and OPRM1 gene polymorphisms with morphine pain relief. Clin Pharmacol Ther 2008, 83, 559–566. [Google Scholar] [CrossRef]
  74. J. E. Sturgess, T. P. George, J. L. Kennedy, A. Heinz, and D. J. Müller. Pharmacogenetics of alcohol, nicotine and drug addiction treatments. Addiction biology 2011, 16, 357–376. [Google Scholar] [CrossRef] [PubMed]
  75. Deb, J. Chakraborty, P. K. Gangopadhyay, S. R. Choudhury, and S. Das. Single-nucleotide polymorphism (A118G) in exon 1 of OPRM1 gene causes alteration in downstream signaling by mu-opioid receptor and may contribute to the genetic risk for addiction. J Neurochem 2010, 112, 486–496. [Google Scholar] [CrossRef]
  76. Q. Zhang, M. Shi, H. Tang, H. Zhong, and X. Lu. κ Opioid Receptor 1 Single Nucleotide Polymorphisms were Associated with the Methadone Dosage. Genet Test Mol Biomarkers 2020, 24, 17–23. [Google Scholar] [CrossRef] [PubMed]
  77. S. -C. Wang et al.. The Association of Genetic Polymorphisms in the κ-Opioid Receptor 1 Gene With Body Weight, Alcohol Use, and Withdrawal Symptoms in Patients With Methadone Maintenance. J Clin Psychopharmacol 2014, 34. [Google Scholar]
  78. T. D. Nascimento et al. . µ-Opioid Activity in Chronic TMD Pain Is Associated with COMT Polymorphism. J Dent Res 2019, 98, 1324–1331. [Google Scholar] [CrossRef]
  79. B. Meloto et al. . COMT gene locus: new functional variants. Pain 2015, 156, 2072–2083. [Google Scholar] [CrossRef]
  80. M. C. Kowarik et al.. Impact of the COMT Val(108/158)Met polymorphism on the mu-opioid receptor system in the human brain: mu-opioid receptor, met-enkephalin and beta-endorphin expression. Neurosci Lett 2012, 506, 214–219. [Google Scholar] [CrossRef]
  81. H. Matsuoka et al.. Expression changes in arrestin β 1 and genetic variation in catechol-O-methyltransferase are biomarkers for the response to morphine treatment in cancer patients. Oncol Rep 2012, 27, 1393–1399. [Google Scholar] [CrossRef]
  82. T. T. Rakvåg, J. R. Ross, H. Sato, F. Skorpen, S. Kaasa, and P. Klepstad. Genetic variation in the Catechol-O-Methyltransferase (COMT) gene and morphine requirements in cancer patients with pain. Mol Pain 2008, 4, 64. [Google Scholar] [CrossRef]
  83. T. T. Rakvåg et al.. The Val158Met polymorphism of the human catechol-O-methyltransferase (COMT) gene may influence morphine requirements in cancer pain patients. Pain 2005, 116, 73–78. [Google Scholar] [CrossRef]
  84. M. De Gregori et al.. Genetic variability at COMT but not at OPRM1 and UGT2B7 loci modulates morphine analgesic response in acute postoperative pain. Eur J Clin Pharmacol 2013, 69, 1651–1658. [Google Scholar] [CrossRef]
  85. Y. Kolesnikov, B. Gabovits, A. Levin, E. Voiko, and A. Veske. Combined catechol-O-methyltransferase and μ-opioid receptor gene polymorphisms affect morphine postoperative analgesia and central side effects. Anesth Analg 2011, 112, 448–453. [CrossRef]
  86. R. A. Henker et al.. The associations between OPRM 1 and COMT genotypes and postoperative pain, opioid use, and opioid-induced sedation. Biol Res Nurs 2013, 15, 309–317. [Google Scholar] [CrossRef]
  87. T. Lotta et al.. Kinetics of Human Soluble and Membrane-Bound Catechol O-Methyltransferase: A Revised Mechanism and Description of the Thermolabile Variant of the Enzyme. Biochemistry 1995, 34, 4202–4210. [Google Scholar] [CrossRef]
  88. R. A. Henker et al.. The associations between OPRM 1 and COMT genotypes and postoperative pain, opioid use, and opioid-induced sedation. Biol Res Nurs 2013, 15, 309–317. [Google Scholar] [CrossRef] [PubMed]
  89. H. Matsuoka et al.. Prospective replication study implicates the catechol-O-methyltransferase Val158Met polymorphism as a biomarker for the response to morphine in patients with cancer. Biomed Rep 2017, 7, 380–384. [Google Scholar] [CrossRef]
  90. S. Goswami, L. Gong, K. Giacomini, R. B. Altman, and T. E. Klein. PharmGKB summary: very important pharmacogene information for SLC22A1. Pharmacogenet Genomics 2014, 24, 324–328. [Google Scholar] [CrossRef]
  91. M. V. Tzvetkov, J. N. Dos Santos Pereira, I. Meineke, A. R. Saadatmand, J. C. Stingl, and J. Brockmöller. Morphine is a substrate of the organic cation transporter OCT1 and polymorphisms in OCT1 gene affect morphine pharmacokinetics after codeine administration. Biochem Pharmacol 2013, 86, 666–678. [Google Scholar] [CrossRef]
  92. M. V. Tzvetkov, A. R. Saadatmand, J. Lötsch, I. Tegeder, J. C. Stingl, and J. Brockmöller. Genetically Polymorphic OCT1: Another Piece in the Puzzle of the Variable Pharmacokinetics and Pharmacodynamics of the Opioidergic Drug Tramadol. Clin Pharmacol Ther 2011, 90, 143–150. [Google Scholar] [CrossRef] [PubMed]
  93. D., Ozberk; et al. . Association of polymorphisms in ARRB2 and clinical response to methadone for pain in advanced cancer. Pharmacogenomics 2022, 23, 281–289. [Google Scholar] [CrossRef]
  94. R. Donaldson et al.. The multiple PDZ domain protein Mpdz/MUPP1 regulates opioid tolerance and opioid-induced hyperalgesia. BMC Genomics 2016, 17. [Google Scholar] [CrossRef]
  95. D. Y. Liang et al.. The Netrin-1 receptor DCC is a regulator of maladaptive responses to chronic morphine administration. BMC Genomics 2014, 15. [Google Scholar] [CrossRef]
  96. S. Kumar, P. Kundra, K. Ramsamy, and A. Surendiran. Pharmacogenetics of opioids: a narrative review. Anaesthesia 2019, 74, 1456–1470. [Google Scholar] [CrossRef]
  97. S. Mameli, A. S. Mameli, A. Pili, G. M. Pisanu, M. Carboni, and E. Marchi. Opioids in chronic non cancer pain: rational and selection criteria. Phatos, 2011. https://www.pathos-journal.com/page_64.html (accessed Nov. 04, 2022).
  98. K. K. Lemberg et al. . Does co-administration of paroxetine change oxycodone analgesia: An interaction study in chronic pain patients. Scand J Pain 2010, 1, 24–33. [Google Scholar] [CrossRef]
  99. S. C. Armstrong and K. L. Cozza. Pharmacokinetic drug interactions of morphine, codeine, and their derivatives: theory and clinical reality, Part II. Psychosomatics 2003, 44, 515–520. [Google Scholar] [CrossRef]
  100. U. M. Stamer et al.. Impact of CYP2D6 genotype on postoperative tramadol analgesia. Pain 2003, 105, 231–238. [Google Scholar] [CrossRef]
  101. K. L. Cozza, S. C. K. L. Cozza, S. C. Armstrong, and J. R. Oesterheld. Concise Guide to Drug Interaction Principles for Medical Practice: Cytochrome P450s, Ugts, P-Glycoproteins. 2003.
  102. U. M. Stamer, F. Musshoff, M. Kobilay, B. Madea, A. Hoeft, and F. Stuber. Concentrations of tramadol and O-desmethyltramadol enantiomers in different CYP2D6 genotypes. Clin Pharmacol Ther 2007, 82, 41–47. [Google Scholar] [CrossRef] [PubMed]
  103. Hammonds, D. A. Sidebotham, and B. J. Anderson. Aspects of tramadol and ondansetron interactions. Acute Pain 2003, 5, 31–34. [Google Scholar] [CrossRef]
  104. U. M. Stamer, F. Musshoff, M. Kobilay, B. Madea, A. Hoeft, and F. Stuber. Concentrations of tramadol and O-desmethyltramadol enantiomers in different CYP2D6 genotypes. Clin Pharmacol Ther 2007, 82, 41–47. [Google Scholar] [CrossRef] [PubMed]
  105. K. L. Cozza, S. C. K. L. Cozza, S. C. Armstrong, and J. R. Oesterheld. Concise Guide to Drug Interaction Principles for Medical Practice: Cytochrome P450s, Ugts, P-Glycoproteins. 2003.
  106. P. Dayer, J. A. Desmeules, T. Leemann, and R. Striberni. Bioactivation of the narcotic drug codeine in human liver is mediated by the polymorphic monooxygenase catalyzing debrisoquine 4-hydroxylation (cytochrome P-450 dbl/bufI). Biochem Biophys Res Commun 1988, 152, 411–416. [Google Scholar] [CrossRef]
  107. S. C. Armstrong, K. L. Cozza, and N. B. Sandson. Med-psych drug-drug interactions update. Psychosomatics 2003, 44, 515–520. [Google Scholar]
  108. M. G. McDonald, N. T. Au, and A. E. Rettie. P450-Based Drug-Drug Interactions of Amiodarone and its Metabolites: Diversity of Inhibitory Mechanisms. Drug Metab Dispos 2015, 43, 1661–1669. [Google Scholar] [CrossRef]
  109. T. H. Nieminen et al.. Rifampin Greatly Reduces the Plasma Concentrations of Intravenous and Oral Oxycodone. Anesthesiology 2009, 110, 1371–1378. [Google Scholar] [CrossRef]
  110. C., Samer; et al. . Genetic polymorphism and drug interactions modulating CYP2D6 and CYP3A activities have a major impact on oxycodone analgesic efficacy and safety. Br J Pharmacol 2010, 160, 919–930. [Google Scholar] [CrossRef]
  111. S. Khalesi, H. Shemirani, and F. Dehghani-Tafti. Methadone induced torsades de pointes and ventricular fibrillation: A case review. ARYA Atheroscler 2014, 10, 339–342. [Google Scholar]
  112. Justo, A. Gal-Oz, Y. Paran, Y. Goldin, and D. Zeltser. Methadone-associated Torsades de Pointes (polymorphic ventricular tachycardia) in opioid-dependent patients. Addiction (Abingdon, England) 2006, 101, 1333–1338. [Google Scholar] [CrossRef]
  113. J. Lötsch, C. Skarke, I. Tegeder, and G. Geisslinger. Drug Interactions with Patient-Controlled Analgesia. Clin Pharmacokinet 2002, 41, 31–57. [Google Scholar] [CrossRef]
  114. S. C. Armstrong and K. L. Cozza. Med-psych drug-drug interactions update. Psychosomatics 2002, 43, 169–170. [Google Scholar] [CrossRef] [PubMed]
  115. P. Gougis, M. P. Gougis, M. Hilmi, A. Geraud, O. Mir, and C. Funck-Brentano. Potential cytochrome P450-mediated pharmacokinetic interactions between herbs, food, and dietary supplements and cancer treatments. Crit Rev Oncol Hematol. [CrossRef]
Table 1. Opioids’ major metabolites.
Table 1. Opioids’ major metabolites.
CYP3A4 CYP2D6 UGT2B7
Active Inactive Active Inactive Active Inactive
Codeine NORC Morphine C-6-G
Morphine M-6-G M-3-G
Tramadol M2 M1, M5
Fentanyl Norfentanyl
Hydromorphone* H-6-G, H-3-G
Buprenorphine Norbuprenorphine
Oxycodone Noroxycodone Oxymorphone
Methadone EDDP, EMDP
*Hydromorphone is in turn an active metabolite of hydrocodone and morphine. NORC: Norcodeine; C-6-G: Codeine-6-glucuronide; M-6-G: Morphine-6-glucuronide; M-3-G: Morphine-3-glucuronide; M2: N-desmethyl-tramadol; M1: O-desmethyl-tramadol; M5: O,N-didesmethyl-tramadol; H-6-G: Hydromorphone-6-glucoronide; H-3-G: Hydromorphone-3-glucuronide; EDDP: 2-ethylidene-1,5-dimethyl-3,3-diphenylpyrrolidine; EMDP: 2-ethyl-5-methyl-3,3-diphenylpyrroline.
Table 2. Polymorphisms in genes coding for enzymes responsible for opioids metabolism.
Table 2. Polymorphisms in genes coding for enzymes responsible for opioids metabolism.
Gene Polymorphism Drug
CYP2D6 *1, *2, *35 Tramadol
*3, *4, *6 Morphine, codeine
*9, *10, *17, *29, *41 Hydromorphone
CYP3A4 *1b, *2, *3, *22 Morphine, codeine, oxycodone, buprenorphine, fentanyl
CYP3A5 *1b, *2, *3, *22 Methadone, fentanyl, alfentanil
CYP2B6 *6 Methadone
ABCB1 1236C>T, 3435C>T and 2677G>T/A Morphine, fentanyl
UGT2BT 802T>C and 900G>A Morphine
Table 3. Opioid-drug interactions.
Table 3. Opioid-drug interactions.
Drug CYP3A4 CYP2D6 Clinical consequences
Inducer Inhibitor Inducer Inhibitor
Tramadol Antidepressants (fluoxetine, paroxetine, bupropion) Increased plasma concentration of tramadol and reduced analgesia
Codeine Antidepressants (fluoxetine, paroxetine, bupropion), Increased plasma concentration of tramadol and reduced analgesia
Antihistamines (cimetidine)
Antiarrhythmic drugs (amiodarone, quinidine)
Antiemetics (ondansetron)
Antiretrovirals (ritonavir)
Morphine Antiarrhythmic drugs (quinidine, amiodarone) Increased plasma level of morphine reduced analgesia
Oxycodone Antibiotic (rifampicin) Antibiotic (rifampicin) Reduced plasma concentration of oxycodone and reduced analgesia
Antimicrobial (voriconazole, itraconazole, ketoconazole) Increased plasma concentration of oxycodone and risk of serious adverse drug reaction
Fentanyl Antiretrovirals (ritonavir, nelfinavir) Increased plasma levels of fentanyl and risk of respiratory depression
Antimicrobials (voriconazolo, ketoconazole, itraconazole)
Antibiotics (ciprofloxacin, troleandomycin, clarithromycin)
Methadone Antibiotics (rifampicin), anticonvulsants (carbamazepine), antiepileptics (phenytoin), barbiturates (pentobarbital) Decreased of plasma level of methadone and increased risk of opioid withdrawal
Antiretroviral drugs (ritonavir, nelfinavir), antimicrobial (voriconazolo, ketoconazole, itraconazole), antibiotics (ciprofloxacin, troleandomycin clarithromycin), Ca2+ antagonist (diltiazem) Increased plasma level of methadone and risk of sedation, confusion, and respiratory depression and/or QT prolongation or torsade de pointes
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.
Copyright: This open access article is published under a Creative Commons CC BY 4.0 license, which permit the free download, distribution, and reuse, provided that the author and preprint are cited in any reuse.
Prerpints.org logo

Preprints.org is a free preprint server supported by MDPI in Basel, Switzerland.

facebook logotwitter logolinkedin logo
bsky
MDPI Initiatives
Important Links
Subscribe

Disclaimer

Terms of Use

Privacy Policy

Privacy Settings

© 2025 MDPI (Basel, Switzerland) unless otherwise stated