key: cord-0896511-ui5dej59 authors: Thangaraju, Pugazhenthan; Venkatesan, Nanditha; Venkatesan, Sajitha; Gurunthalingam, Meenalotchini Prakash; Thangaraju, Eswaran title: Can HCQ Be Considered a “Safe Weapon” for COVID-19 in the Indian Population? date: 2020-07-10 journal: SN Compr Clin Med DOI: 10.1007/s42399-020-00392-z sha: a29f89a48ae00d4c88d987e971c6cfa0a8f5a1fe doc_id: 896511 cord_uid: ui5dej59 With no drugs currently approved for treatment and cure of COVID-19 (coronavirus disease 2019), hydroxychloroquine is one of the many first-line drugs used in the management. However, given the life-threatening adverse effects of HCQ that have been reported, its use as a prophylactic treatment remains debated. HCQ has long been used in India for the treatment of malaria, auto-immune and inflammatory diseases, and even type 2 diabetes mellitus recently. We aimed to review existing literature and relevant Web sites regarding the safety profile of HCQ in the Indian subcontinent. A non-systematic critical analysis of all published literature/studies focused on the Indian population, recording on the use of HCQ for various indications up till April 2020 was done and frequency of occurrence of HCQ related life-threatening and cardiac side effects were noted. Results from PubMed database showed an incidence of 0.6% of cardiac-related side effects and 7.42% of other self-limiting and minor side effects among the Indian population on HCQ. Considering its minimal risk and favorable safety profile, cost-effectiveness, availability, and affordability in India, the use of hydroxychloroquine in the fight against COVID-19 appears rationale. Following the results of our study, we hypothesize that Indians might be less likely to suffer from cardiac-related side effects given their genetic make-up. However, this would need further studies, clinical trials, and a pharmacogenomic understanding of the subject. The World Health Organization declared the coronavirus disease 2019 (COVID-19) a pandemic on 11 March 2020 [1] . Given the nature of this global public health emergency, multiple drugs have been tried in the battle against this disease. Some of these include antimalarial drugs such as hydroxychloroquine, azithromycin, various anti-viral medications, and recently, even host-directed therapies [2] [3] [4] [5] . Although a majority of these drugs have been cited as potential candidates, their clinical efficacy and safety profile have not been completely evaluated. Chloroquine, an age old member of the WHO list of Essential medicines, has been studied extensively for its immunomodulatory properties and antiviral mechanisms [6] . Hydroxychloroquine is one such formulation which has come into light for its use in COVID-19 treatment given its proven efficacy in both laboratory and in vivo studies [7] . It has been observed to inhibit ACE2 receptor-mediated entry of the SARS-CoV2 virus through various actions such as raising of intravesicular pH, inhibiting lysosomal activity, and affecting antigen processing [8] [9] [10] . It has strong anti-inflammatory and immunomodulatory properties that are beneficial against the surge of cytokines that occur in the background of COVID-19 infection [7] [8] [9] [10] [11] . The reports of adverse effects, both minor and major, appear to be the limiting factor against the use of this drug [12] . Minor side effects range from nausea, vomiting, diarrhea, constipation, skin rash and itching, cutaneous hyperpigmentation, gastritis to name a few, while major side effects include retinal toxicity, maculopathies, acute pulmonary edema, reversible heart failure, and cardiac arrhythmias (QTc prolongation) [13] . Therefore, precautions needed while using these drugs include frequent monitoring of hematological parameters, serum electrolytes, blood sugar levels, renal and hepatic function tests, routine electrocardiography prior to initiation of the drug, and visual acuity testing. Sudden deaths reported in the West, following the administration of HCQ, are mainly due to the QT interval prolongation and torsades de pointes (TdP) in susceptible individuals [13] . The risk of TdP is not a linear function of basal QTc or drug-induced prolongation in QTc interval. Moreover, not all patients with drug-induced QTc prolongation will develop TdP. This side effect is rare, but co-prescription of other drugs such as azithromycin (which is also being recommended for the treatment of COVID-19) could amplify this risk [14, 15] . Although there are sporadic case reports of sudden deaths, cardiomyopathy, and reversible heart failure, a large metaanalysis of HCQ use in rheumatoid arthritis, contrary to popular belief, pointed to reduced cardiovascular risk [16, 17] . Acquired long QT syndrome (aLQTS), also known as drug-induced LQTS, has been studied to look for genetic variants associated with the condition. A number of studies have strongly supported the idea that variation, not only in KCNH2 (which codes for Potassium voltage gated channel) but also in other cardiac ion channels and associated genes, may predispose individuals to acquired LQTS [18, 19] . However, a lot of this data has been generated from Western literature. Firstly, data regarding response and reaction of Indians to HCQ is lacking despite its widespread use in malaria, autoimmune disorders, inflammatory conditions, dermatological complaints, and even type 2 diabetes mellitus. Secondly, mutations and variants in the channels in an Indian community based-sample will help bridge the gap between genetic factors, influence of the race thereby and other possible drug interaction and reactions. The measures to contain the spread of COVID-19 such as social distancing, hand hygiene, surveillance, and isolation of persons suspected or confirmed to have infection have been considered as mainstay. Government authorities have issued guidelines to healthcare workers and public, advising strict adherence to above measures and acknowledge the limited role of drugs in the treatment and prophylaxis. The use of HCQ and its efficacy in the treatment against SARS-CoV2arebasedonlaboratorystudies,pre-clinicaldata and risk-benefit considerations. The Indian National Taskforce for COVID-19 recommends the use of HCQ for prophylaxis of SARS-CoV2 infection for "all asymptomatic healthcare workers (containment and treatment), asymptomatic healthcare workers (non-COVID hospitals/non-COVID areas of COVID hospitals/blocks), and the asymptomatic frontlineworkers(surveillanceworkers-containmentzones and paramilitary/police personnel involved in COVID-19related activities)-400 mg twice a day on day 1, 400 mg once weekly for the next 7 weeks, taken with meals and asymptomatic household contacts of laboratory confirmed cases-400 mg twice a day on day 1, followed by 400 mg once weekly forthenext3weekstakenwithmeals" [20] .However,thedrugis contraindicated for prophylaxis in children under 15 years of age, known cases of retinopathy, hypersensitivity to the drug and other 4-aminoquinoline compounds, G6PD deficiency, and any preexisting cardiomyopathy and cardiac rhythm disorders. With available evidence for its safety and beneficial effect as a prophylactic drug against SARS-COV-2 during the earlier recommended 8-week period, the experts further recommended for its use beyond 8 weeks on weekly dosage with strictmonitoringofclinicalandECGparameterswhichwould alsoensurethatthetherapyisgivenundersupervision. A PubMed Database search was conducted. The search strate g y w a s c a r r i e d o u t u s i n g k e y w o r d s s u c h a s "Hydroxychloroquine," "Chloroquine," "Cardiac side effects," and "India." O u r s e a r c h s t r a t e g y w a s ( ( ( C h l o r o q u i n e O R Hydroxychloroquine)) AND (Deaths OR Fatal outcome OR, Cardiac OR heart OR side-effects OR side-effect OR side effects OR adverse event OR adverse reaction OR arrhythmia OR block OR QT prolongation OR QTc Prolongation)) AND India). We included clinical trials, research studies, case reports, and randomized control trials that employed the use of HCQ/ CQ at any point in the treatment of patients of Indian origin. In addition, we also searched the references section of the screened articles to extract information regarding Indian articles of relevance. Following our search strategy, the results were screened in a stepwise manner. Title screening, followed by relevant abstract, filtering, and finally, a full-text screening was done as per inclusion and exclusion criteria. -Patients: Indian patients both adult and pediatric population Three reviewers independently screened titles and abstract of relevant search results that met the inclusion criteria prior to screening full-text papers. Details that were extracted to included author and journal details, year of publication, sample s i z e , a g e , s e x , i n d i c a t i o n f o r r a t i o n a l u s e o f hydroxychloroquine, duration for treatment, the number of patients that reported various minor side effects, the number of patients that reported major side effects, and deaths, if any, during the period of the study. Our focus, however, was on side effects observed in the Indian population with HCQ use. Once this data was retrieved, we calculated the total number of subjects across all reports that received HCQ and the proportion which developed both minor and serious adverse reactions. The data were extracted in Google Sheets and Excel in numbers and converted later to percentages. With our aforementioned search strategy and a couple of other similar searches that were tried, we screened a total of 317 articles (Fig. 1 ). Of these, 105 articles were title-screened. A total of 3123 Indian patients were treated with either HCQ or CQ for different indications and at different doses, for different durations. We recorded a total 253 adverse reactions that were reported in these articles. Adverse reactions were further grouped as non-cardiac and cardiac. Non-cardiac reactions were 232 (Fig. 2 ) in all and included minor reversible ones such as urticaria, itching, epigastric pain, nausea, diarrhea, constipation, and also some that were potentially life-threatening, such as psychosis, mania, retinal toxicity, hypoglycemia, methem o g l o b i n e m i a , e x t r a p y r a m i d a l s y n d r o m e s , a n d Parkinsonism, to name a few. Cardiac-related adverse effects (Fig. 3) were 19 in all, 13 QTc prolongations, 2 chest pains, 1 cardiovascular collapse, 1 recurrent syncopal attack, 1 acute pulmonary edema, and 1 cardiomyopathy. Two deaths were reported whose causes were not mentioned or known (Table 1 ). Hydroxychloroquine came as a beacon of hope in the battle against the COVID-19 pandemic. Given its dubious safety profile, there are two schools of thought about using HCQ for chemoprophylaxis. However, we believe that there might be more to the story than that meets the eye. It might not be prudent to replicate the number of adverse reactions observed in Western population and superimpose them on the Indian patient. The Indian portal for reporting adverse events, also known as PvPI (Pharmaco-vigilance Programme of India) under the Indian Pharmacopeia Commission, Ghaziabad, was checked prior to the start of the search across PubMed for details regarding the ADRs developing from administration of CQ/ HCQ. However, we could not get any information available in the open public database. We also searched Vigiaccess [13] , the online database for ICSRs (Individual case Safety Reports) for information regarding geographic distribution of ADRs. However, it only gave data in broad headings of Africa, the Americas, Asia, Europe, and Oceania, thereby limiting our data collection. It was interesting to note that Americas noted 56% of the ADRs from use of hydroxychloroquine, Europe 27%, and Asia 14%. However, it should be borne in mind that underreporting could also be an attributing factor to this. The latest revised advisory released by Indian Council of Medical Research (ICMR) states that HCQ prophylaxis among 1323 HCWs indicated mild adverse effects such as nausea (8.9%), abdominal pain (7.3%), vomiting (1.5%), hypoglycemia (1.7%), and cardiovascular effects (1.9%). However, as per the data from the PvPI, there have been 214 reported instances of adverse drug reactions associated with prophylactic HCQ use. Of these, 7 were serious individual case safety reports with prolongation of the QT interval on ECG in 3 cases. Then again, the denominator for this value, that is, the overall number of healthcare workers who took prophylactic HCQ, is not available. Details regarding any underlying contraindications were also not mentioned. Including the ICMR data, 1.9% of the 1323 HCWs who took HCQ as prophylaxis developed cardiovascular risks (n = 25). Summing up both these samples (1323 + 3123), we get a total sample size of 4446 individuals who have been subjected to HCQ, both in therapeutic and prophylactic doses. About 0.98% is at risk of developing cardiovascular side effects according to this number. Based on the evidence released by ICMR and PvPI, they have opined that HCQ is relatively safe, when certain contraindications are avoided, and that it has considerable benefit as a prophylactic option. The advisory recommends HCQ administration under strict medical supervision and informed consent. Limitations faced during data collection included the following: & A number of adverse events were mentioned, but details of the same were not provided in the studies. So, data regarding types of minor reactions could not be extracted Records screened using relevant search strategy n= 317 Records identified through database screening n=1885 Records included in quantitative and qualitative analysis n=105 Abstract and full text assessed for eligibility n=106 Records excluded n=212 Full text articles excluded with reasons n=1 Fig. 1 Fig. 3 Frequency of various cardiac side effects following HCQ use from these papers. Many papers quoted these reactions as self-limiting and deemed it unimportant to report. & Multi-centric and multi-ethnic cohorts that were used for RCTs did not mention the race of the individual whose ADR was recorded. We have, however, included the number of events mentioned because we believed it was better to err on the higher side (for example, this was true for one of the deaths that were reported by a multi-centric study conducted across Asia, Table 1 ). & Similarly, the case report that mentioned recurrent syncopal attacks as a drug reaction lacks the proof for the same. It was hypothesized that it could be from the disease process (rheumatoid arthritis-nodule in the heart tissue, in this case) or from cardiotoxicity due to the drug. We, however, included the event in the study, in an attempt to be more inclusive of possible adverse reactions (Table 1 ) & We also found an article that reported ADRs of many different drugs in a tertiary care during a specified period of time, but we could not use this article due to lack of information on the denominator, that is, the total number of patients receiving the drug in the study setup. & Lastly, an important data that was elusive in these studies was details pertaining to demographic variables, comorbidities, any underlying structural heart diseases, history of co-administration with other QT interval prolonging medications such as macrolides, quinolones, antihistaminics, antiviral, antiarrhythmic, or antifungal drugs. & Apart from these limitations, it is important to note that chloroquine is more widely available in the Indian context given its continued use against malaria, while HCQ is more often prescribed for inflammatory conditions. Therefore, this further impedes our data collection with reference to HCQ adverse effects. While several intervention trials are currently underway with HCQ in COVID-19 patients at different doses in the international level, we believe it would be wise to conduct similar large-scale trials on both COVID-19 patients and others taking HCQ for multiple other indications among the Indian patient subgroup. Also, a pharmacogenomic study to understand the interplay of HCQ and genetic factors will throw light on Indians and their propensity to develop cardiac morbidities and other potentially life-threatening side effects following the administration of HCQ. In the possibility that race might prove to be protective against the ill-effects of HCQ, it will help in allaying the fear among the public and putting to rest any panic regarding the use of the drug in prophylaxis against COVID-19. However, in the absence of the same, physicians must be urged to be more cautious and watchful during the period of drug administration and carry out the required monitoring. Conflict of Interest The authors declare that they have no conflict of interest. Ethical Approval This article does not contain any studies with human participants or animals performed by any of the authors. Informed Consent Not applicable. This article does not contain any studies with human participants or animals performed by any of the authors. 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