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Query: UMLS:C0030193 (pain)
 261,466 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A large number of women receive codeine for obstetric pain while breastfeeding. Following a case of fatal opioid poisoning in a breastfed neonate whose codeine prescribed mother was a CYP2D6 ultrarapid metabolizer (UM), we examined characteristics of mothers and infants with or without signs of central nervous system (CNS) depression following codeine exposure while breastfeeding in a case-control study. Mothers of symptomatic infants (n = 17) consumed a mean 59% higher codeine dose than mothers of asymptomatic infants (n = 55) (1.62 (0.79) mg/kg/day vs. 1.02 (0.54) mg/kg/day; P = 0.004). There was 71% concordance between maternal and neonatal CNS depression. Two mothers whose infants exhibited severe neonatal toxicity were CYP2D6 UMs and of the UGT2B7*2/*2 genotype. There may be a dose-response relationship between maternal codeine use and neonatal toxicity, and strong concordance between maternal-infant CNS depressive symptoms. Breastfed infants of mothers who are CYP2D6 UMs combined with the UGT2B7*2/*2 are at increased risk of potentially life-threatening CNS depression.
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PMID:Pharmacogenetics of neonatal opioid toxicity following maternal use of codeine during breastfeeding: a case-control study. 1909 67

The opioid class of drugs, a large group, is mainly used for the treatment of acute and chronic persistent pain. All are eliminated from the body via metabolism involving principally CYP3A4 and the highly polymorphic CYP2D6, which markedly affects the drug's function, and by conjugation reactions mainly by UGT2B7. In many cases, the resultant metabolites have the same pharmacological activity as the parent opioid; however in many cases, plasma metabolite concentrations are too low to make a meaningful contribution to the overall clinical effects of the parent drug. These metabolites are invariably more water soluble and require renal clearance as an important overall elimination pathway. Such metabolites have the potential to accumulate in the elderly and in those with declining renal function with resultant accumulation to a much greater extent than the parent opioid. The best known example is the accumulation of morphine-6-glucuronide from morphine. Some opioids have active metabolites but at different target sites. These are norpethidine, a neurotoxic agent, and nordextropropoxyphene, a cardiotoxic agent. Clinicians need to be aware that many opioids have active metabolites that will become therapeutically important, for example in cases of altered pathology, drug interactions and genetic polymorphisms of drug-metabolizing enzymes. Thus, dose individualisation and the avoidance of adverse effects of opioids due to the accumulation of active metabolites or lack of formation of active metabolites are important considerations when opioids are used.
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PMID:Role of active metabolites in the use of opioids. 1895 60

In managing pain, clinicians working with the more than 80 million people in the United States who suffer annually from serious pain face decisions about choosing the most appropriate pharmacologic agent, to contemplating nonpharmacologic modalities. This article focuses on opioid use for pain management, their risks of toxicity and addiction, adverse reactions, undertreatment for fear of addiction, and integration of novel diagnostics, such as the pharmacogenetic biomarkers CYP2D6 and OPRM1 as holding promise for assessing a patient's risk of adverse events or likelihood of efficacy. Incorporation of such biomarkers is emerging on the forefront of personalized medicine, and has the potential to dramatically improve the utility and efficacy of both current and future pain management strategies.
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PMID:The value of CYP2D6 and OPRM1 pharmacogenetic testing for opioid therapy. 1905 64

Oxycodone is O-demethylated by CYP2D6 to oxymorphone which is a potent micro-receptor agonist. The CYP2D6 oxidation polymorphism divides the Caucasian population in two phenotypes: approximately 8% with no enzyme activity, poor metabolizers (PM) and the remainder with preserved CYP2D6 activity, extensive metabolizers (EM). The objective of the study was to determine if the analgesic effect of oxycodone in human experimental pain depends on its metabolism to oxymorphone. The analgesic effect of oxycodone was evaluated in a randomized, placebo-controlled, double-blinded, crossover experiment including 33 (16 EM and 17 PM) healthy volunteers. Pain tests were performed before and 1, 2, 3 and 4 hr after medication and included pain detection and tolerance thresholds to single electrical sural nerve stimulation, pain summation threshold to repetitive electrical sural nerve stimulation and the cold pressor test with rating of discomfort and pain-time area under curve (AUC(0-2 min.)). For single sural nerve stimulation, there was a less pronounced increase in thresholds on oxycodone in pain detection (9% vs. 20%, P = 0.02, a difference of 11%, CI: 2%-20%) and pain tolerance thresholds (15% vs. 26%, P = 0.037, a difference of 10%, CI: 1%-20%) for PM compared with EM. In the cold pressor test, there was less reduction in pain AUC on oxycodone for PM compared with EM (14% vs. 26%, P = 0.012, a difference of 12%, CI: 3%-22%). The plasma oxymorphone/oxycodone ratio was significantly lower in PM compared with EM (P < 0.001). Oxycodone analgesia seems to depend both on oxycodone itself and its metabolite oxymorphone.
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PMID:The hypoalgesic effect of oxycodone in human experimental pain models in relation to the CYP2D6 oxidation polymorphism. 1928

We present a simplified stochastic model to investigate the mechanisms of action of tramadol, a centrally acting analgesic, used for treating pain. The model accounts for the process of metabolization through the cytochrome CYP2D6 and the interactions between molecules and target receptors. The proposed formulation is stochastic in nature and allows to speculate on the role of finite-size fluctuations. Analytically, the master equation, governing the process under scrutiny, is derived and studied in the mean-field limit. The analysis of the associated asymptotic behavior proves interesting for its potential medical implications. The analysis of fluctuations is carried on via the van Kampen expansion. Numerical simulations are also performed to confirm the adequacy of our theoretical prediction.
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PMID:A stochastic reaction scheme for drug/metabolite interaction. 1934 94

Activation of codeine by O-demethylation into morphine is a prerequisite for its analgesic effects and severe toxicity. Identifying patients in whom morphine is formed either at extremely low or at extremely high amounts may improve efficacy and safety of codeine therapy. To assess how well this identification is possible, we compared the performance of current CYP2D6 phenotype association systems (traditional genotype-based classification, a recently proposed CYP2D6 activity score, and the plasma dextromethorphan metabolic ratio) in 57 healthy Caucasians after oral administration of 30 mg dextromethorphan hydrobromide or 50 mg codeine. Most subjects (87.5%) at the lower 15% of morphine formation from codeine and thus likely to not to respond to codeine therapy were correctly identified by CYP2D6 genotype- or phenotype-based systems. In contrast, in subjects at the upper 15% of morphine formation being at risk for opioid toxicity, CYP2D6 genotyping predicted only the 50% who carried gene duplication, whereas dextromethorphan-based phenotyping identified 67.5% of the subjects with high morphine formation. However, satisfactory prediction (87.5%) of high morphine formation was only achieved when combining genotyping with phenotyping. In conclusion, insufficient morphine formation from codeine and thus likely failure of analgesia can currently be well predicted. However, to make codeine therapy safe, extremely high morphine formation has to be predicted as well, which has to be obtained at the effort of combining genotyping with phenotyping.
Pain 2009 Jul
PMID:Can extremely low or high morphine formation from codeine be predicted prior to therapy initiation? 1939 73

Inadequately treated acute and chronic pain remains a major cause of suffering and dissatisfaction in pain therapy. A cause for the variable success of pharmacologic pain therapy is the different genetic disposition of patients to develop pain or to respond to analgesics. The patient's phenotype may be regarded as the result of synergistic or antagonistic effects of several genetic variants concomitantly present in an individual. Variants modulate the risk of developing painful disease or its clinical course (e.g., migraine, fibromyalgia, low back pain). Other variants modulate the perception of pain (e.g., OPRM1 or GCH1 variants conferring modest pain protection by increasing the tone of the endogenous opioid system or decreasing nitric oxide formation). Other polymorphisms alter pharmacokinetic mechanisms controlling the local availability of active analgesic molecules at their effector sites (e.g., decreased CYP2D6 related prodrug activation of codeine to morphine). In addition, genetic variants may alter pharmacodynamic mechanisms controlling the interaction of the analgesic molecules with their target structures (e.g., opioid receptor mutations). Finally, opioid dosage requirements may be increased depending on the risk of drug addiction (e.g., DRD2 polymorphisms decreasing the functioning of the dopaminergic reward system). With the complex nature of pain involving various mechanisms of nociception, drug action, drug pharmacology, pain disease and possibly substance addiction, a multigenic or even genome wide approach to genetics could be required to base individualized pain therapy on the patient's genotype.
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PMID:Genetic modulation of the pharmacological treatment of pain. 1961 6

The aim of this study is to determine whether the inhibition of CYP2D6 and CYP3A4 enzyme activity with telithromycin affects the pharmacokinetics and pharmacodynamics of orally administered oxycodone in a randomized 2-phase crossover study. Eleven healthy subjects were pretreated with 800 mg of oral telithromycin or placebo for 4 days. On day 3, they ingested 10 mg of immediate-release oxycodone. Plasma concentrations of oxycodone and its oxidative metabolites were measured for 48 hours, and pharmacodynamic effects were evaluated. Telithromycin increased the area under the plasma concentration-time curve (AUC(0-infinity)) of oxycodone by 80% (P < .001) and reduced the AUC(0-infinity) of noroxycodone by 46% (P < .001). Most of the pharmacokinetic changes were seen in the elimination phase, with little effect by telithromycin on the peak concentration of oxycodone. Pharmacodynamic effects of oxycodone were modestly enhanced by telithromycin. In conclusion, telithromycin clearly reduces the N-demethylation of oxycodone to noroxycodone by inhibiting the CYP450 3A4 enzyme. The use of telithromycin in patients receiving multiple doses of oxycodone for pain relief may increase the risk of opioid adverse effects. Reduction of oxycodone dose by 25% to 50% followed by readjustment according to the clinical response might be appropriate.
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PMID:Effect of telithromycin on the pharmacokinetics and pharmacodynamics of oral oxycodone. 1975 14

The aftermath of sequencing the human genome has birthed many efforts to utilize an individual's genetic information in order to tailor optimal treatment strategies - so-called personalized medicine. An individual's genetic information may eventually help diagnosis and treatment, as well selecting optimal pharmacologic agents based partly on how well they reach their target, how well they will bind to and produce an effect at their targets, how well they will be metabolized, and the profile of their adverse effects. It also appears that clinicians may be able to utilize an individual's genetic information to ascertain a subject's risk or susceptibility of developing a particular medical condition. Although, this has not been widely utilized in pain medicine at this point, the future may revolutionize the role of genetic information in the evaluation and management of various pain conditions. One reason for variations in therapeutic outcomes from different pharmacologic pain treatments is the different genetic disposition of patient to develop pain or to respond to analgesics. The patient's phenotype may represent a conglomerate of several different genetic variants concomitantly present in an individual. Genetic variants may modulate the risk of developing a painful condition, or may modulate the perception of pain (e.g. OPRM1 or GCH1 variants conferring modest "protection" from pain by increasing the tone of the endogenous opioid system or decreasing nitric oxide formation). Other genetic polymorphisms may alter pharmacokinetic mechanisms (e.g. CYP2D6 related prodrug activation of codeine to morphine), alter pharmacodynamic mechanisms (e.g. opioid receptor mutations), or alter other analgesic effects (e.g. diminished euphoric effects from opioids potentially due to DRD2 polymorphisms decreasing the functioning of the dopaminergic reward system). This article theorizes that genetic alterations including functional polymorphisms of Nrf2 (a master regulator of the transcription of multiple antioxidants) may render certain subjects more or less susceptible to developing complex regional pain syndrome after surgery or trauma. If this hypothesis is correct, knowing this information may translate into significant and "far-reaching" effects on clinical decision-making surrounding the management of pain in patients who may be more susceptible to develop complex regional pain syndrome. Furthermore, it could lead to the development of novel prevention or intervention strategies, in efforts to prevent, abort, or ameliorate the development of and/or effectively treat complex regional pain syndrome.
Pain Physician
PMID:The role of genomic oxidative-reductive balance as predictor of complex regional pain syndrome development: a novel theory. 2011 66

Arachidonoyl ethanolamide (anandamide) is an endogenous amide of arachidonic acid and an important signaling mediator of the endocannabinoid system. Given its numerous roles in maintaining normal physiological function and modulating pathophysiological responses throughout the body, the endocannabinoid system is an important pharmacological target amenable to manipulation directly by cannabinoid receptor ligands or indirectly by drugs that alter endocannabinoid synthesis and inactivation. The latter approach has the possible advantage of more selectivity, thus there is the potential for fewer untoward effects like those that are traditionally associated with cannabinoid receptor ligands. In that regard, inhibitors of the principal inactivating enzyme for anandamide, fatty acid amide hydrolase (FAAH), are currently in development for the treatment of pain and inflammation. However, several pathways involved in anandamide synthesis, metabolism, and inactivation all need to be taken into account when evaluating the effects of FAAH inhibitors and similar agents in preclinical models and assessing their clinical potential. Anandamide undergoes oxidation by several human cytochrome P450 (P450) enzymes, including CYP3A4, CYP4F2, CYP4X1, and the highly polymorphic CYP2D6, forming numerous structurally diverse lipids, which are likely to have important physiological roles, as evidenced by the demonstration that a P450-derived epoxide of anandamide is a potent agonist for the cannabinoid receptor 2. The focus of this review is to emphasize the need for a better understanding of the P450-mediated pathways of the metabolism of anandamide, because these are likely to be important in mediating endocannabinoid signaling as well as the pharmacological responses to endocannabinoid-targeting drugs.
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PMID:Oxidation of the endogenous cannabinoid arachidonoyl ethanolamide by the cytochrome P450 monooxygenases: physiological and pharmacological implications. 2013 90


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