Oxycodone findings and CYP2D6 function in postmortem cases

Lucia Pellè,Robert Kronstrand,Ronja Larsson,Gerd Jakobsson,Henrik Gréen

doi:10.1016/j.fsigen.2021.102510

Abstract

Genetic disposition can cause variation in oxycodone pharmacokinetic characteristics and decrease or increase the expected clinical response. In forensic medicine, determination of cause of death or assessing time between drug intake and death can be facilitated by knowledge of parent and metabolite concentrations. In this study, the aim was to investigate if CYP2D6 genotyping can facilitate interpretation by investigating the frequency of the four CYP2D6 phenotypes, poor metabolizer, intermediate metabolizer, extensive metabolizer, and ultra-rapid metabolizer in postmortem cases, and to study if the CYP2D6 activity was associated with a certain cause of death, concentration, or metabolic ratio. Cases positive for oxycodone in femoral blood (n = 174) were genotyped by pyrosequencing for CYP2D6*3, *4, and *6 and concentrations of oxycodone, noroxycodone, oxymorphone, and noroxymorphone were determined by LC-MS/MS (LLOQ 0.005 µg/g). Digital droplet PCR was used to determine the copy number variation for CYP2D6*5. Cases were categorized by cause of death. It was found that poor and intermediate CYP2D6 metabolizers had significantly higher oxycodone and noroxycodone concentrations compared to extensive and ultra-rapid metabolizers. CYP2D6 phenotype were equally distributed between cause of death groups, showing that no phenotype was overrepresented in any of the cause of death groups. We also found that the concentration ratio between oxymorphone and oxycodone depended on the CYP2D6 activity when death was unrelated to intoxication. In general, a low metabolite to parent ratio indicate an acute intake. By using receiver operating characteristic (ROC) analysis, we conclude that an oxymorphone/oxycodone ratio lower than 0.075 has a high sensitivity for separating intoxications with oxycodone from other intoxications and non-intoxications. However, the phenotype needs to be known to reach a high specificity. Therefore, the ratio should not be used as a biomarker on its own to distinguish between different causes of death but needs to be complemented by genotyping.

Highlights

In postmortem toxicology, the interpretation of toxicological results requires knowledge of drugs’ pharmacokinetic and pharmacodynamic properties
The aim was to investigate if CYP2D6 genotyping can facilitate interpretation by investigating the frequency of the four CYP2D6 phenotypes, poor metabolizer, intermediate metabolizer, extensive metabolizer, and ultra-rapid metabolizer in postmortem cases, and to study if the CYP2D6 activity was associated with a certain cause of death, concentration, or metabolic ratio
Pharmacogenetics as a tool in forensic toxicology was investigated by Druid et al already in 1999 [10], followed by a number of publications concluding that genotyping of postmortem blood can be useful as a complement in the interpretation of toxico logical results [6, 11,12,13,14,15]

Summary

Introduction

The interpretation of toxicological results requires knowledge of drugs’ pharmacokinetic and pharmacodynamic properties. It has been suggested that metabolite-to-parent ratios can assist the interpretation and distinguish between acute and chronic administration or give information about time between last intake and death [6,7,8]. Pharmacogenetics as a tool in forensic toxicology was investigated by Druid et al already in 1999 [10], followed by a number of publications concluding that genotyping of postmortem blood can be useful as a complement in the interpretation of toxico logical results [6, 11,12,13,14,15]. Sajantila suggested that genotyping of post mortem cases and analysis of metabolite ratios may provide valuable insights, especially when the interpretation of the toxicological results is unclear [16]. Musshoff presented in a review that biomarkers such as DNA genotyping, together with forensic-toxicological analyses, can be used as a tool in forensic medicine [17]

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Discussion

Conclusion