The global population is becoming older, and prevalence of multimorbidity and polypharmacy is increasing.1 Most research into pharmacokinetic drug–drug interactions (DDIs) has focused on pairwise interactions between drugs and corresponding metabolites, while the impact of co-administration of multiple drugs has received less attention. More recently, the differences in DDI risk between population sub-groups has received increased attention (e.g., in pediatrics vs adults2, 3). It is well recognized that simultaneous inhibition of multiple different pathways of a drug's elimination can lead to much larger increases in drug exposure compared with inhibition of only the major pathway.4 The potential magnitude of DDI in this scenario is linked with the fraction metabolized (fm) of each pathway for the object (also known as “victim”) drug5, 6 (Equation 1). In contrast, there is a common misconception about the cumulative effects of multiple precipitant (also known as “perpetrator”) drugs that competitively inhibit the same enzyme. It is often mistakenly perceived that cumulative effects of multiple weak inhibitors are likely to lead to a strong DDI. This misconception arises despite the true relationship being governed by a simple concentration–response relationship, with a well-known theoretical basis (Equations 1 and 2),4, 5 analogous to the dose dependence of competitive inhibition. Surprisingly, there is very limited research on multiple inhibitors and their implications on clinical endpoints such as the ratio of area under the curve of the plasma concentration–time profiles (AUCR) in the interaction phase relative to the control,7 possibly contributing to such misunderstandings about polypharmacy–DDI risks. The ICH M12 Drug Interaction Studies Guidance defines weak, moderate, and strong CYP inhibitors as causing ≥1.25- to 0.7 may be of potential concern in the context of clinical polypharmacy effects (e.g., AUCR increasing by ∼50% with multiple inhibitors vs one inhibitor; Figure 2, pink dashed boxes). A 2-fold increase in ∑I/Ki leads to a modest increase in AUCR of ∼50% relative to the single inhibitor scenario, but this occurs only for substrates with very high fm (>0.9). However, few clinically used drugs have such high fm values. Another plausible but even less likely scenario that involves 4- or 5-fold increases in ∑I/Ki (i.e., more than four drugs that inhibit an enzyme with similar inhibition potential, Table 1) could lead to increase in AUCR of >2-fold compared with AUCR for the inhibitor with highest I/Ki (Figure 2, red dashed boxes). These theoretical changes in AUCR are consistent with reported dose-dependent DDIs.7 In conclusion, polypharmacy DDI risk for drugs that inhibit the same metabolic pathway for an object drug is typically of low concern, as previously suggested.4 The current analysis using a mechanistic static model has revealed the edge cases where additive effects of co-administration of multiple competitive inhibitors may cause clinical DDIs that have higher AUCR than those observed when only co-administering the inhibitor with highest I/Ki. Therefore, risk assessment for DDIs in polypharmacy scenarios should consider the properties of the object drug and each precipitant drug in a mechanistic manner. Preferably, physiologically based pharmacokinetic modeling should be applied to recognize time-varying interaction effects of each drug at different sites, interindividual variability in exposure, and the possibility that some drugs may act simultaneously as object and precipitants of DDI. The authors would like to thank Dr. Shaun Sutehall for his valuable assistance with proofreading and submission. The authors declare no conflicts of interest. No specific funding was received for this work. Matlab code to create the figures in this article are publicly available through the FigShare repository: https://doi.org/10.48420/29246777
Scotcher et al. (Fri,) studied this question.