Abstract
Introduction
The objective was to characterize real-world outcomes of drug–drug interactions (DDIs) between antiretrovirals (ARVs) and other drugs, including over-the-counter medications (OTC), and treatment outcomes in clinical practice.
Methods
www.clinicalcasesDDIs.com is an open-access website for healthcare providers to consult and briefly describe real-world clinical cases on DDI with ARVs. We reviewed all the clinical cases reported to the website between March 2019 and May 2023.
Results
A total of 139 cases were reported, mostly involving ritonavir or cobicistat (boosters; 74 cases), unboosted integrase inhibitors (InSTI; 29 cases), and non-nucleoside reverse transcriptase inhibitors (NNRTI; 23 cases). Central nervous system drugs (29 cases) and cardiovascular drugs (19 cases) were the most frequently described co-medications. Notably, OTC medications were implicated in 27 cases, including mineral supplements (11 cases), herbals (8 cases), weight loss drugs (4 cases), anabolic steroids (3 cases), and recreational drugs (1 case). OTC acted as the perpetrator drug in 21 cases, leading to loss of ARV efficacy in 17 instances (mineral supplements in 10 cases, weight loss drugs in 4 cases, herbals in 3 cases). Additionally, toxicity was reported in 4 out of 6 cases where OTC was considered the victim drug of the DDI (anabolic steroids in 3 cases, MDMA in 1 case).
Conclusions
Frequent unwanted outcomes resulting from DDIs between ARVs and OTC medications underscore the importance of integrating non-prescription drugs into medication reconciliation. The real-world data available through www.clinicalcasesDDIs.com serves as a valuable resource for assessing the clinical relevance of DDIs.
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Our analysis of reported real-world cases underscores the detrimental impact of drug–drug interactions (DDIs) between antiretrovirals (ARVs) and over-the-counter medications. | |
It emphasizes the critical necessity for comprehensive medication reconciliation, including non-prescription drugs. | |
It highlights the continued clinical significance of relevant DDIs associated with boosted ARV. | |
It highlights the importance of reporting real-world cases of DDIs. |
Introduction
A substantial number of persons with HIV (PWH) may use combinations of drug combinations that may result in clinically relevant drug–drug interactions (DDIs) [1], potentially increasing the risk of treatment failure or undesired adverse effects from antiretroviral (ARV) or concomitant medications. The risk of DDIs is highest for ARVs requiring pharmacokinetic (PK) enhancers, such as cobicistat or ritonavir [2]. However, unboosted ARVs may also be involved in relevant DDIs. Moreover, the progressive aging of PWH and the related higher risk of polypharmacy [3] increase the likelihood of having DDIs that can lead to unwanted clinical outcomes.
In addition to medically prescribed drugs, the use of over-the-counter (OTC) medications and other substances (e.g., vitamins/mineral supplements, anabolic steroids, recreational drugs) is also common among PWH [4, 5]. OTC medications may be either victim or perpetrator of DDIs with ARVs, thereby being a potential source for clinically relevant DDIs in PWH. However, formal PK studies assessing DDIs between ARVs and OTC are scarce, and clinical cases are infrequently collected and published in peer-reviewed medical journals.
There are multiple electronic resources available for checking DDIs. However, even HIV-specific DDIs databases mostly predict the risk of developing a DDI based on the metabolic pathway of the drugs and based on the DDI studies reported in the literature or in the prescribing information. Thus, while available resources mostly report the potential risk for a DDI they rarely report outcomes of DDIs based on real-world practice. Consequently, the clinical significance of many DDIs remains uncertain. Furthermore, discrepancies on the relevance of a particular DDI may be found between different databases, further complicating the interpretation of a given potential interaction [6].
Our aim was to describe real-world outcomes of DDIs between ARVs and other drugs/products, including OTC medications, based on voluntary reports in a dedicated website.
Methods
The website www.clinicalcasesDDIs.com is an open-access platform designed for healthcare providers to access and review concise descriptions of real-world clinical cases involving ARVs and their associated clinical harms. This resource is unique in its aim to compile clinical outcomes, share knowledge, and promptly alert prescribers to both common and emerging toxicities and adverse outcomes resulting from DDIs with HIV treatment.
The content on this platform is curated by an editorial team comprised of a multidisciplinary panel of experts in HIV medicine and clinical pharmacology from various countries, including Spain, Italy, the Netherlands, Switzerland, Serbia, the UK, Argentina, and Chile. Before being accepted, each case submitted for publication undergoes a rigorous review process, ensuring accuracy and plausibility. At least two independent panel members review and approve the cases, accompanied by editorial interpretation, classification, and commentary.
The clinical cases’ descriptions encompass details of the drugs engaged in the interaction, categorized as victim and perpetrator drugs, along with their respective daily doses and duration of co-administration. Additionally, these cases present clinical details and outcomes. The outcomes are categorized as either “no unwanted outcome” or “unwanted outcome,” indicating instances where toxicity or loss of efficacy of either ARV or co-medication occurred.
Data was extracted from the website dataset, and all the clinical cases reported between March 2019 and May 2023 were included in a descriptive analysis.
The study was conducted in accordance with the declaration of Helsinki. Specific data that could contribute to identify persons described in the clinical reports were deleted or modified to assure privacy of the patients. Data were obtained from an open-access platform (www.clinicalcasesDDIs.com) which is available to healthcare professionals, researchers, and patients.
Results
A total of 139 cases were reported on www.clinicalcasesDDIs.com between March 2019 and May 2023. Cases were mainly reported by HIV clinicians and pharmacists. Among these cases, 99 (71%) involved men with a median age of 50 years. The most frequently implicated ARV in DDIs were those requiring ritonavir/cobicistat (boosters, as perpetrators) accounting for 74 cases, followed by unboosted integrase inhibitors (InSTI) with 29 cases, and non-nucleoside reverse transcriptase inhibitors (NNRTI) with 23 cases. Additionally, 13 cases involved other ARVs, including 8 cases with protease inhibitors (PI) as victims of the co-medication, 4 cases with TAF (tenofovir alafenamide), and 1 case with ibalizumab. Regarding the clinical outcomes, 70 out of 139 cases (50%) reported “no unwanted outcome,” while “loss of efficacy” and “toxicity” were reported in 22% and in 28% of the cases, respectively (Table 1).
Among co-medications, central nervous system (CNS) drugs were the most frequently involved in DDIs, accounting for 29 cases. These included neuroleptics, antiepileptic drugs, benzodiazepines, antidepressants, and ergotamine derivatives. The reported interactions primarily occurred with boosted ARVs (19/29 cases), where the CNS drug acted as the victim drug in all instances. Outcomes varied with “no unwanted outcome” reported in 20 cases, “toxicity” in 6, and “loss of efficacy” in 3 cases.
Cardiovascular drugs were the second most commonly implicated medications (19 cases), encompassing antiplatelet and anticoagulant agents, beta-blockers, diuretics, and calcium channel antagonists. Boosted ARVs were involved in the majority of these cases (12/19). “No unwanted outcome” was noted in 8 cases, “toxicity” in 6, and “loss of efficacy” in 5 cases. As for CNS drugs, in all cases cardiovascular agents were the victim drug.
OTC medications contributed to 27 cases of DDIs (Fig. 1). These encompassed mineral supplements (11 cases), herbals (8 cases), weight loss drugs (4 cases), anabolic steroids (3 cases), and recreational drugs (1 case). Unwanted outcomes were reported in 21 (78%) cases. Of those, a loss of ARV efficacy, defined as detectable plasma HIV-RNA previously virologically suppressed individuals, was noted in 17 (63%) cases. Ten of these cases involved mineral supplements, primarily calcium and magnesium, all of which affected InSTI as victim drugs. However, one case involved coadministration with rifampicin and InSTI-resistance mutations, precluding its inclusion as more than one factor could be interfering with ART efficacy (Table 2). Weight loss drugs and herbals were implicated in 4 and in 3 cases reporting “loss of efficacy,” respectively, involving PIs and NNRTI as victim drugs. Toxicity was reported in 4 out of 6 cases where OTC medications were considered the victim of the DDI. These cases involved anabolic steroids in 3 instances and MDMA in 1 case.
Discussion
DDIs become more relevant as PWH are aging, due to a higher prevalence of chronic conditions leading often to polypharmacy [7]. Moreover, the escalating popularity and accessibility of OTC medications and recreational drugs among PWH further compound this issue [8, 9]. Despite the existence of specialized HIV DDI websites (such as https://www.hiv-druginteractions.org, http://www.interaccionesvih.com, or https://www.hivmedicationguide.com) designed to assist healthcare providers in managing of DDIs, their content predominantly revolves around theoretical risks associated with DDIs. Many of DDIs, however, have never been evaluated in formal PK studies or assessed in clinical practice, leaving the clinical significance and outcomes of these interactions largely unknown. This gap in understanding is especially prominent in DDIs involving OTC medications and substances like recreational drugs, whose use is frequently undisclosed to healthcare providers.
In our study, boosted ARVs emerged as the most prevalent contributors to DDIs, accounting for 74 cases (53%) reported. This predominance can be attributed to the potent inhibition of cytochrome P450 (CYP) metabolism by ritonavir and cobicistat, which are integral components of boosting strategies [10]. The shift from boosted PI to unboosted InSTI reflects current treatment guidelines, wherein unboosted InSTI serve as first-line therapies. Unlike boosted PI, unboosted InSTI do not exert inhibition or induction effects on drug-metabolizing enzymes or transporters, rendering them favorable in terms of their DDI profile, with added advantage of achieving rapid virological suppression [11,12,13]. However, despite this shift, boosted PIs maintain clinical significance due to their utility in specific scenarios. They remain the preferred combination for individuals experiencing failure in pre-exposure prophylaxis (PrEP) with long-acting cabotegravir (LA CAB) as well as for those individuals with virological failure and the subsequent selection of drug resistance mutations during therapy with LA CAB plus LA rilpivirine [14, 15]. Consequently, DDIs associated with boosted PI retain relevance in clinical practice and might potentially gain increased importance in the future.
Of significance is the involvement of OTC medications in 20% of the reported cases, notably resulting in “loss of ART efficacy” in 63% of these instances. These cases predominantly featured the combination of unboosted InSTI with mineral supplements containing divalent cations, known to interfere with intestinal absorption of InSTI by chelation in the gastrointestinal tract [16, 17]. In most of these cases, the viral load was successfully resuppressed to undetectable values, either by discontinuing the supplements or by separating their intake from ARVs (Table 2). Consequently, in managing cases of virological failure, it becomes paramount for HIV healthcare providers to meticulously review medications, including non-prescription drugs, especially mineral supplements. Equally crucial is the necessity to educate patients about potential interactions, as many individuals may not perceive minerals, herbal supplements, recreational drugs, or other OTC products as “traditional medications” and they may not be aware of possible DDIs [18].
This study may be affected by some limitations. Firstly, case reporting relied solely on self-motivation of HIV healthcare providers, potentially introducing bias in both the number and content of the reported cases. Furthermore, the majority of reports were PK-based, and drug concentrations were available in only a few of them. However, the reporting of real-world DDI data to www.clinicalcasesDDIs.com is highly encouraged as it serves as a valuable resource for assessing the clinical relevance of DDIs. This becomes particularly crucial given the occasionally theoretical and conflicting information present in available electronic databases [6, 19]. Documenting real-world cases helps bridge knowledge gaps, ultimately enhancing the quality of care for PWH. Notably, the integration of real-world cases for clinical decisions on DDIs has been recently incorporated into the EACS HIV treatment guidelines [20].
Conclusions
Our analysis of reported real-world cases underscores the detrimental impact of DDIs between ARVs and OTC medications, emphasizing the critical necessity for comprehensive medication reconciliation, including non-prescription drugs. Additionally, our analysis highlights the continued clinical significance of relevant DDIs associated with boosted ARV. Despite the emergence of newer antiretroviral drugs with more favorable DDI profiles, boosted PI remain essential in specific therapeutic scenarios.
The reporting of real-world data serves as a valuable complement to broaden our understanding of DDIs, ultimately enhancing healthcare for PWH.
Data Availability
The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.
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Acknowledgements
The author acknowledge all the healthcare professionals who reported cases to ClinicalCasesDDIs.com.
Medical Writing and Editorial Assistance.
ChatGPT version 3.5 was used to check for English grammar and style of the final version of the manuscript.
Funding
The authors did not received support from any organization for the submitted work or the publication fee. ClinicalCasesDDIs.com is funded by unrestricted grants from MSD, Viiv Healthcare, Gilead Sciences, and Johnson and Johnson.
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Juan Ambrosioni, Catia Marzolini, Gordana Dragovic, Arkaitz Imaz, Andrea Calcagno, Sonia Luque, Adrian Curran, Jesus Troya, Montse Tuset, Saye Khoo, David Burger, Claudia P Cortés, Nadia Naous, and Jose Molto contributed to the study conception and design. The first draft of the manuscript was written by Natalia Anahí Díaz and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
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Conflict of Interest
Juan Ambrosioni has received personal fees from and participated in advisory boards for ViiV, Gilead, Janssen, and MSD; has received funding for research from ViiV, Gilead, and MSD; and has been a member of data safety monitoring boards for HIPRA and Grifols, all outside the current work. Juan Ambrosioni is an Editorial Board member of Infectious Diseases and Therapy. They were not involved in the selection of peer reviewers for the manuscript nor any of the subsequent editorial decisions. Catia Marzolini has received speaker honoraria from ViiV, Gilead and MSD. Arkaitz Imaz has received financial compensation for lectures, consultancy work and educational activities, as well as funds for research, travel grants and non-financial support from Gilead Sciences, Janssen-Cilag, Merck Sharp & Dohme, Thera Technologies and ViiV Healthcare. Adrian Curran’s institution has received research grants from AbbVie, Gilead Sciences, Bristol Myers Squibb, Janssen-Cilag and ViiV Healthcare while Adrian Curran has received speaker and consultancy honoraria from Gilead Sciences, Janssen-Cilag, MSD, and ViiV Healthcare. Jesus Troya has received speaker and consultancy honoraria from Gilead Sciences, Janssen-Cilag, and MSD. Montse Tuset has received grants from Gilead, ViiV and MSD. Jose Molto has received research funding, consultancy fees and lecture sponsorships from and have served on advisory boards for various laboratories (MSD, Gilead Sciences, Viiv Healthcare, Johnson & Johnson). Natalia Anahí Díaz, Gordana Dragovic, Andrea Calcagno, Sonia Luque, Saye Khoo, David Burger, Claudia P Cortés, and Nadia Naous have no conflict of interest to declare.
Ethical Approval
The study was conducted in accordance with the declaration of Helsinki. Specific data that could contribute to identify persons described in the clinical reports were deleted or modified to assure privacy of the patients. Data were obtained from an open-access platform (www.clinicalcasesDDIs.com) which is available to healthcare professionals, researchers, and patients.
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Prior Presentation: Preliminary results of this work were presented at the European AIDS Clinical Society Conference, Warsaw, October 2023. Abstract # eP.B1.003.
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Ambrosioni, J., Díaz, N.A., Marzolini, C. et al. Outcomes of Drug Interactions Between Antiretrovirals and Co-Medications, Including Over-the-Counter Drugs: A Real-World Study. Infect Dis Ther 13, 609–617 (2024). https://doi.org/10.1007/s40121-024-00935-0
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DOI: https://doi.org/10.1007/s40121-024-00935-0