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Cardiol Ther. 2021 Dec; 10(2): 429–444.
Published online 2021 Sep 4. doi: 10.1007/s40119-021-00239-1
PMCID: PMC8555097
PMID: 34480745

Effect of Amlodipine in Stroke and Myocardial infarction: A Systematic Review and Meta-analysis

Associated Data

Data Availability Statement

Abstract

Introduction

Hypertension is a progressive cardiovascular condition arising from complex aetiologies. Progression is strongly associated with functional and structural abnormalities that lead to multi-organ dysfunction. Stroke and myocardial infarction are two of the major complications of hypertension in India. Various anti-hypertensive drugs, such as calcium channel blockers (CCBs), beta-blockers, diuretics, angiotensin-converting enzyme inhibitors and angiotensin receptor blockers, have been the medications of choice for disease management and are known to be effective in reducing the complications of hypertension. CCBs, such as amlodipine, are also currently being used and proven to be effective, although their beneficial effects in the management of complications of hypertension like stroke and myocardial infarction (MI) have yet to be proven. Therefore, the aim of this systematic review was to evaluate the effect of amlodipine on stroke and MI in hypertensive patients.

Methods

A systematic search of English electronic databases was performed for studies with sufficient statistical power that were published between 2000 andl 30 August 2020, following the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) criteria. A total of 676 papers were screened, and 13 were found eligible to be included in the meta-analysis. Studies that included patients who suffered from MI or stroke and were under amlodipine treatment were included in the analysis. The odds ratio and the risk ratio of amlodipine compared to active control/placebo were noted from the studies and statistically analyzed.

Results

Amlodipine had a significant effect in reducing stroke and MI in hypertensive patients. Similar to results published in reports, this systematic review proved that the hazard ratio for amlodipine was < 1 for stroke (0.69–1.04) and MI (0.77–0.98), showing that amlodipine accounted for better prevention of stroke and MI.

Conclusion

In the pooled analysis of data from 12 randomised controlled trials and one double-blinded cohort study measuring the effect of CCBs, we found that the CCB amlodipine reduced the risk of stroke and MI in hypertensive patients. Superior results for amlodipine were found in ten of the 13 studies included in this meta-analysis.

Keywords: Amlodipine, Hypertension, Stroke, Myocardial infarction, Hazard ratio, Risk ratio

Key Summary Points

Stroke and myocardial infarction (MI) are two significant complications of hypertensive patients in India.
Various anti-hypertensive drugs, such as calcium channel blockers, have been the first choice for managing and effectively reducing the complications of hypertension. Amlodipine, a calcium channel blocker, is also currently being used and has proven to be effective in treating patients with stroke, although its beneficial effects on MI have yet to be demonstrated.
The aim of this systematic review was to evaluate the effect of amlodipine on stroke and MI in hypertensive patients.
Pooled analysis of data from 12 randomised controlled trials and one double-blinded cohort study measuring the effect of amlodipine demonstrated that amlodipine significantly reduced the risk of stroke and MI in hypertensive patients. Superior results for amlodipine were found in ten of the 13 studies included in the systematic review.

Introduction

Hypertension is a multi-factorial disorder that results from a complex interplay of environmental and genetic factors. The complexity of blood pressure (BP) control mechanisms has significant implications for an individual’s responsiveness to anti-hypertensive drugs, such as like calcium channel blockers (CCBs), beta blockers, angiotensin-converting enzyme (ACE) inhibitors, angiotensin II receptor blockers (ARBs), diuretics, among others.

Uncontrolled hypertension may increase the risk of stroke and myocardial infarction (MI) by fivefold. Stroke and MI are the leading causes of mortality and morbidity in the world, affecting both younger and older individuals [1]. The effective treatment of hypertension and its associated risk factors reduces the risk of hypertensive complications, such as stroke, MI, cardiac failure and renal failure. However, despite current treatment possibilities, hypertension remains a potential risk factor for MI as well as fatal and nonfatal strokes [2]. The authors of a meta-analysis of nine trials concluded that CCBs were associated with a 10% lower risk of stroke when compared with treatment with different anti-hypertensive drugs [3]. The conclusion arrived at in another meta-analysis was that CCBs, when compared with diuretics and beta-blockers, provided a 13.5% reduction in the risk of stroke [4].

According to the European Society of Cardiology/European Society of Hypertension (ESC-ESH) 2018 guideline for arterial hypertension, ACE inhibitors, ARBs, diuretics and CCBs as monotherapy or in combination with each other are used extensively and are listed as the first-line agents for treating hypertension and its complications like stroke and MI [5].

Calcium ions are the culprit that lead to damage of the tissues in the heart and other organs, causing stroke and MI. Massive calcium influx into hypoxic cells is a final common pathway, leading to cell death, and this influx needs to be effectively blocked and managed [6]. Calcium antagonists facilitate this process by decreasing the influx of calcium ions through voltage-sensitive calcium channels [7].

A meta-analysis of 17 randomised controlled trials showed that CCBs reduced the relative risk of stroke by 39% as compared to placebo [8]. Another meta-analysis that included 6752 patients with a previous history of cerebrovascular disease (stroke or transient ischaemic attack) showed that anti-hypertensive therapy resulted in a 28% reduction in risk for stroke recurrence [9]. Following ischaemic stroke, CCB treatment has been associated with a reduction in mortality (odds ratio [OR] 0.38, 95% confidence interval [CI] 0.17–0.88 vs. no CCB treatment) and improvements in the stroke impact scale.

Amlodipine has a strong affinity for cell membranes, modulating calcium influx by inhibiting selected membrane calcium channels. In the landmark ASCOT-BPLA study, amlodipine was associated with a lower risk of stroke than atenolol (hazard ratio [HR] 0.78, 95% CI 0.67–0.90). These authors also noted that amlodipine was more effective in reducing BP variability [10]. An analysis of six active controlled trials involving an amlodipine treatment group showed that amlodipine provided more protection against stroke than other anti-hypertensive agents (OR 0.81, 95% CI 0.75–0.87; P < 0.0001) [11, 12]. Similarly, a study performed by Skolnick et al. reported that CCBs have a significant effect on the reduction of MI and its complications [13]. A RCT conducted by Dahlof et al. studied the efficacy of an amlodipine-based regimen compared with an atenolol-based regimen, with the authors ultimately concluding that the patients on the amlodipine-based regimen showed reduction in incidence of fatal stroke (HR 0.90) [14].

The findings of previous studies have proved that CCBs are efficacious medications in terms of hypertension control, as well as the risks of hypertension, such as stroke and MI [6, 7, 15]. Given the high prevalence of hypertension in India, an analysis of current data is essential to obtain a thorough understanding of the properties of CCBs to reduce the risk for stroke and MI. Such information could aid healthcare practitioners in selecting a better treatment option for their hypertensive patients. Therefore, we performed this systematic review and meta-analysis with the aim to evaluate the effect of amlodipine on complications of hypertension, such as stroke and MI.

Methods

Search Strategy

Comprehensive systematic searches of online electronic databases, including PubMed, Cochrane database and Google Scholar (Advanced Google search), were performed to identify studies in which amlodipine was used for the management of stroke and MI. We searched the literature using the following keywords: “Stroke” OR “Cerebro Vascular Accident” OR “CVA” OR “Cerebro Vascular Accident (CVA)” OR “Ischaemic Stroke” OR “Myocardial Infarction” OR “MI” OR “Myocardial Infarction (MI)” OR “Coronary Infarction”; “Amlodipine” OR “FRC-8653)” OR “Calcium Channel Blockers” OR “CCBs”; “Randomised” OR “Randomized” OR “Prospective” OR “Controlled” OR “Uncontrolled” “Blinded” OR “Open Label” OR “Retrospective” OR “Cross-sectional” studies. A total of 676 papers were screened, of which 13 were found to be eligible for inclusion in the study. The studies included participants who suffered from MI or stroke and were receiving amlodipine treatment. The OR and the risk ratio (RR) of amlodipine in comparison to active control/placebo were noted from the studies and statistically analysed.

Study Selection and Data Abstraction

The search of databases was restricted to English publications. No limitation was set for age of participants in the searched articles. The references of identified papers were screened for any additional article which was not identified in the original search. One reviewer checked all the titles and abstracts and another reviewer checked the article. Both investigators independently reviewed the full text of potential studies for inclusion in the systematic review and no inconsistency was discovered. Hand searching was not performed, and authors of the included articles were not contacted for further information on the studies.

Quality Assessment

Eligible studies met the following inclusion criteria: (1) in the case of overlapping studies, then only the study with larger/largest sample size was selected; (2) the numbers of hypertension and stroke and MI cases were provided; (3) data on CCBs and/or placebo were available; (4) the research design was RCTs and parallel arm, double blinded studies, and compared the efficacy of different treatments. Studies were excluded if: they did not provide the ORs, the study population considered was different for different drugs, no specific age criteria were established and study populations were not randomised.

Data Management

We screened titles, abstracts and full texts according to the inclusion criteria and data were extracted.

Statistical Analysis

Initially after the screening process had been completed, data extracted from the articles, including the ORs, HRs and RRs, with corresponding 95% CIs, were entered into an Excel spreadsheet (Microsoft Corp., Redmond, WA, USA). STATA software version 16.0 (StataCorp, College Station, TX, USA) was used for further analysis of the data. We applied logs and converted the values accordingly to the collected ORs, HRs, RRs and 95% CIs. A standard error variable was estimated based on the log-transformed values of ratios and their corresponding 95% CI values. Multiple forest plots were generated for stroke and MI using the data collected from the studies based on the ORs, HRs, RRs and respective 95% CI. Estimated log values and standard error values were also presented obtained along with the weight (%) given to the studies in the forest plots.

Compliance with Ethics Guidelines

This article is based on previously conducted studies and does not contain any new studies with human participants or animals performed by any authors.

Results

Characteristics of the Articles

Our search identified 676 citations up to 30 August 2020. After a title review and removal of duplicate studies, 584 articles were excluded by screening and 92 full-text articles remained. Some articles did not meet the inclusion criteria; on this basis, 66 full-text papers that had insufficient data for extraction were excluded. After screening for all the probable factors, 13 papers were assessed to be eligible for inclusion in the systematic review. Details on the selection process are shown in Fig. 1

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Flow chart of study selection according to Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines

Search Results

Table Table11 provides a summary of the 13 articles included in the systemic review and their methodology. The results of each study are given in the last column toether with the acceptable HRs and ORs. All 13 articles focused on amlodipine and stroke, whereas five articles focused on both MI and stroke with intake of amlodipine. Forest plots were generated to assess the effect of amlodipine treatment on risk reduction of stroke and MI. Head-to-head comparison of available ratios (ORs, HRs, RRs) in the studies selected was performed individually for stroke and MI. Figure 2 provides the ORs for stroke comparing amlodipine and placebo. Figure 3a summarises the HRs of studies on stroke which compared treatment with amlodipine with treatment with other drugs used to control hypertension; Fig. 3b summarises the HRs of studies on stroke in which amlodipine treatment was compared with placebo. Figure 4a summarises the HRs of studies on MI in which amlodipine treatment was compared with treatment with other drugs used to control hypertension; Fig. 4b summarises the HRs of studies on MI in which amlodipine treatment was compared with placebo. Figure 5a summarises the RRs of studies on stroke in which amlodipine treatment was compared with treatment with other drugs used to control hypertension; Fig. 5b summarises the RRs of studies on stroke in which amlodipine treatment was compared with placebo. Figure 6 summarises the RR of studies on MI in which amlodipine treatment was compared with placebo.

Table 1

Details on the studies considered for the systematic review

Study no.First author of study (study name) [reference no.]Patient characteristicsMasking and primary outcomeStudy designAmlodipine dosageResults reported
1Nissen et al. (CAMELOT) [16]Amlodipine or enalapril with placebo in 1991 patients with angiographically documented CAD (> 20% stenosis by coronary angiography) and DBP< 100 mm HgDouble blinded; CV death + MI + StrokeRandomised trial24 month trial: amlodipine: 10 mg

Stroke: HR 0.69; 95% CI 0.54–0.88; p = 0.003

Amlodipine showed beneficial effects over Enalapril

2Dahlöf et al. (ASCOT) [14]

Three groups.

Group 1: 19,257 patients with hypertension: aged 40–79 years; (amlodipine-based regimen; n = 9639) with at least 3 other CV risk factors

Group 2: Perindopril 4–8 mg as required (amlodipine-based regimen; n = 9639) or

Group 3: Atenolol 50–100 mg adding bendroflumethiazide 1.25–2.5 mg and potassium as required (atenolol-based regimen; n = 9618)

Open; CV death + MI + strokeMulticentre, prospective, randomised trialAmlodipine: 5–10 mg

Non-fatal MI and fatal CHD (429 vs. 474):

unadjusted HR 0.90, 95% CI 0.79–1.02; p = 0.1052)

Fatal and non-fatal stroke (327 vs. 422): unadjusted HR 0.77, 95% CI 0.66–0.89; p = 0.0003)

Amlodipine showed beneficial effects over perindopril and atenolol

3ALLHAT study [17]Three different anti-hypertensive regimens (amlodipine (A), chlorthalidone (C) and lisinopri(L) in 33,357 patients with stage 1 or 2 hypertension; age > 55 yearsDouble blinded; Coronary death and MIRandomised trialAmlodipine: 2.5–10 mg/day (n = 9048)

Stroke: RR 1.23, 95% CI 1.08–1.41; p < 0.003 (comparing A and L); RR 0.93, 95% CI 0.82–1.06) (n = 897) comparing C and A

Thiazide-type diuretics proved to be beneficial and superior in preventing 1 or more major forms of CVD than amlodipine

4Leonetti et al. [18]Multicentre, parallel study 828 elderly (aged  ≥ 60 years); lercanidipine 10 mg/day (n = 420), amlodipine 5 mg/day (n = 200),or lacidipine 2 mg/day (n = 208)Double blindedRandomised trial

Amlodipine 5–10 mg

Treatment duration: 24–104 weeks

n = 200; women %: 58

Stroke: weight (%) 48.80, RR 0.49, 95% CI 0.32–0.74

Lercanidipine and lacidipine have an better antihypertensive effect comparable to that of amlodipine

5Lund-Johansen et al. [19]

Postmenopausal hypertensive patients (n = 92)

10 mg/day lercanidipine (n = 48) or 5 mg/day amlodipine (n = 44)

Double blindedRandomised trial

Amlodipine: 5–10 mg

Treatment duration: 8 weeks

n = 44; women %: 100

Stroke: weight (%) 15.98, RR 0.29, 95% CI 0.10–0.83

Lercanidipine proved to be better and beneficial to amlodipine

6Jamerson et al. [20]Enrolled patients had hypertension and were at high risk for CV events (n = 11,506);Double blindedRandomised trial

Amlodipine 5 mg

Valsartan

Stroke: absolute risk reduction with benazepril–amlodipine therapy of 2.2% and a relative risk reduction of 19.6%;HR 0.80, 95% CI 0.72–0.90; p < 0.001

MI: HR 0.79, 95% CI 0.67 to 0.92; p = 0.002

The benazepril–amlodipine combination was superior to the benazepril–hydrochlorothiazide

7Julius et al. [21] (value)Patients treated with amlodipine (n = 789) compared with therapy based on valsartan or amlodipineDouble blinded; MI + heart failureRandomised trialAmlodipine: 5 mg

Stroke: 10.4%, 24.7 per 1000 patient-years; HR 1.04, 95% CI 0.94–1.15; p = 0.49

Amlodipine proved to be more beneficial than valsartan

8Tepel et al. [22]Investigator-designed study with 251 hypertensive haemodialysis patientsDouble-blind, placebo-controlled, multicentre trial; Ischaemic stroke and dementiaRandomised trialAmlodipine—5 mg

MI: RR 0.72, 95% CI 0.39–1.30

Stroke: RR: 0.60, 95% CI 0.36–0.99

Amlodipine proved to be beneficial effect over placebo

9Kalar et al. [23]A cohort of 18,906 hypertensive patients from the Swedish Dementia Registry (SveDem), 2008–2014Double blinded. Longitudinal cohort study; CV eventsCohort studyAmlodipine 5–10 mg

MI: adjusted HR 0.89, 95% CI 0.80–0.98; p < 0.05

Stroke: sdjusted HR 0.63, 95% CI 0.44–0.89; p < 0.05

Amlodipine was associated with reduced mortality risk compared to other CCB'

10Li et al. [24]A total of 320 acute cerebral infarction patientsRandomised, prospective, controlled; cerebrovascular eventsRandomised trialAmlodipine besylate 5–10 mg or 150 mg of irbesartan once a day

Stroke: OR 0.795, 95% CI 0.210, 3.016; p = 0.9994

Amlodipine proved to be more beneficial than irbesartan

11Berl et al. [25]Adult patients (n = 1715)Double-blindRandomised trial; placebo-controlled trialAmlodipine, 5 mg

MI: HR 0.58, 95% CI 0.37–0.92; p = 0.02

Patients receiving amlodipine had significant effect than other drugs

12Pitt et al. (PREVENT) [26]A total of 825 patients were enrolled; Amlodipine (n = 417), Placebo (n = 408); aged 30–80 years with angiographic evidence coronary lesion, DBP < 95 mmHg, total cholesterol < 325 mg/dl and fasting blood glucose < 200 mg/dl 

Double blinded

Rate of coronary Atherosclerosis

Randomised trial

Amlodipine 5–10 mg

Amlodipine-based regimen; n = 9639

Stroke: HR 0.99, 95% CI 0.29–3.41

Amlodipine proved to be more beneficial

13Ogihara et al. (CASE-J) [27]Hypertension and high CV risk (19.8% with the history of stroke)Open; CV death + MI + heart failure + cerebrovascular diseaseRandomised trialComparing candesartan and amlodipine

Stroke: HR 1.28, 95% CI 0.88–1.88

Candesartan proved to be more beneficial to amlodipine

CAD Coronary artery disease, CCB calcium channel blockers, CHD coronary heart disease, CI confidence interval, CV cardiovascular, DBP diastolic blood pressure, HR hazard ratio, MI myocardial infaction, OR odds ratio, RR risk ratio

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Forrest plot of the odds ratio and 95% confidence interval (CI) of stroke (amlodipine vs. placebo). SE Standard error

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a Forest plot of the hazard ratio (HR) of stroke (amlodipine vs. other drugs), b Forest plot of HR of stroke (amlodipine vs. placebo)

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a Forest plot of hazard ratio (HR) of myocardial infarction (MI) (amlodipine vs. other drugs), b Forest plot of HR of MI (amlodipine vs. placebo)

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a Forest plot of risk ratio (RR) of stroke (amlodipine vs. other drugs), b Forest plot of RR of stroke (amlodipine vs. placebo)

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Forest plot of risk ratio of MI (amlodipine vs placebo)

Publication Bias

No evidence of publication bias has been found in the current systematic review.

Meta-Regression Analysis

Only stroke and MI were taken as drug-modifying aspects or diseases with amlodipine. Multiple factors or diseases were not considered, and meta-regression analysis was not performed.

Discussion

To the authors’ knowledge, this is one of the first study to report the effect of amlodipine on stroke and MI in hypertensive patients. This systematic review and meta-analysis evaluated the impact of amlodipine on stroke and MI in hypertensive patients. CCBs are the drugs of choice for treating hypertension and its complications. Uncontrolled hypertension leads to complications such as stroke and MI, which can be controlled and treated by the appropriate use of anti-hypertensive drugs [28, 29].

In this systematic review and meta-analysis, we considered the ORs, HRs, and RRs and constructed forest plots. The results of the selected studies revealed that the risk of stroke and MI events were reduced with the use of CCBs, such as amlodipine. The results presented in the tables of these studies provide new evidence on CCBs that shows that Amlodipine can be beneficial and reduce the incidences of stroke and MI in hypertensive patients.

In the CAMELOT study, a decrease in BP of 3–5 mmHg in patients receiving amlodipine treatment was accompanied by a 31% relative reduction in morbidity, although initial BP appeared to be “normal” [18]. The HR and 95% CI for this study were 0.69 and 0.54–0.88, respectively (p = 0.003).

In the Valsartan Antihypertensive Long-term Use Evaluation (VALUE) trial, hypertensive patients, of whom 46 and 20% had a history of cornary heart disease or stroke, respectively, the patients were randomised to an ARB or a CCB treatment group. The median follow-up was 4.9 years. The patients who were treated with the ARB valsartan had 2.2 mmHg higher systolic BP than those treated with amlodipine; in addition, the ARB-treated group had a significantly higher rate of stroke and MI by 91 and 15% compared to the amlodipine group [24]. The overall HR favored amlodipine for the reduction of stroke and MI in this study.

Cilnidipine is a novel CCB drug which was recently introduced into clinical use. However, clinical data on long-term outcomes trials on stroke and MI with cilnidipine are still lacking. Cilnidipine is also a long-acting CCB, like amlodipine, but it has a shorter half-life (2.1–2.5 vs. 35–50 h) [30]. Amlodipine has an excellent pharmacokinetic and pharmacodynamic profile and provides with good BP control for 24 h longer than cilnidipine. The varied effects of its anti-anginal and anti-atherosclerotic properties have made it a classical drug of choice compared with the newer CCBs like cilnidipine [30]. Amlodipine is relatively cheaper than cilnidipine and minimises BP variability, thereby reducing the risk of cardiovascular and cerebrovascular events, whereas data from human trials with cilnidipine are still lacking [31]. Due to limited data available on the effect of cilnidipine on stroke and MI, a comparative analysis with amlodipine was not performed in the present systematic review.

Multiple published research studies have proven the advantages of amlodipine over other drugs. As evidenced by the ALLHAT [14] and ASCOT [20] studies, an amlodipine-based anti-hypertensive regimen might confer more outcome benefits than other drug regimens, possibly by lowering central systolic BP by 4.3 mm of Hg [32] or ambulatory BP over 24 h. It is also beneficial in reducing nocturnal BP and prevents intima-media thickening. Another reason for using amlodipine is its effect on systolic BP variability, a recognised risk factor, and marker for cardiovascular diseases.

Limitations of the Study

This study has a number of limitations. Although this meta-analysis included all long-term outcome trials, small-scale intermediate endpoint studies were excluded, possibly resulting in a deviation from the meta-analysis. The definition of cardiovascular events and stroke differed between the studies. Only studies of the English language were included in this review which might make it open to language bias. Also, the treatment follow-up duration of studies included varied greatly, which could result in bias.

One additional limitation found with this study that deserves mention is the use of different ratios, such as RR, HR and OR. Different studies reported different risks, i.e. uniformity was not maintained. Risk in the present study was minimised through an extensive search of the available literature. Although the statistical tests did not indicate publication bias, there is clearly limited power to detect such bias, given the relatively small number of studies examined. More studies with fewer limitations should be conducted to verify the results of the present study.

Conclusion

Findings of the present meta-analysis lead to the conclusion that amlodipine has beneficial effects in reducing the incidence of stroke and MI in hypertensive patients. Its high tolerability and minimal side effects compared to other classes of anti-hypertensive drugs have made it an agent of choice in both single and combination drug treatment to reduce the burden of stroke and MI across the globe. The results from this systematic review and meta-analysis may help physicians determine the best treatment options for their hypertensive patients for stroke and MI prevention. However, more studies are required to corroborate the findings of our study.

Acknowledgements

Compliance with Ethics Guidelines

This article is based on previously conducted studies and does not contain any new studies with human participants or animals performed by any authors.

Medical Writing, Editorial and Other Assistance

The authors thank Dr. Shri L (Medical Writer) from QREC Clinical Research LLP, India for support in the preparation of the manuscript.

Funding

The study was funded by Dr Reddy’s Laboratories. The sponsor is also funding Journal’s Rapid Service fee.

Disclosures

This study represents original work. It was completed recently and has not been published elsewhere. All the authors of this paper have contributed equally to the work and preparation of the manuscript. All authors, Shamanna S Iyengar, Jagdish C Mohan, Saumitra Ray and Srinivasa Rao M are on the advisory board members for Dr Reddy’s Laboratories Ltd. Yunus Khan, Kumar Gaurav and Usha Rani Patted declare that they work in the Medical Affairs Department in Dr Reddy’s Laboratories Ltd, Hyderabad, India.

Authorship

All named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this article, take responsibility for the integrity of the work as a whole, and have given their approval for this version to be published. All the authors of this paper have contributed equally to the work and preparation of the manuscript.

Authorship Contributions

All authors contributed to the study conception and design. Material preparation, data collection and analysis were performed by Mohammed Yunus Khan, Usha Rani H Patted and Kumar Gaurav. Shamanna S Iyengar, Jagdish Chander Mohan, Saumitra Ray and Srinivasa Rao M reviewed and approved the final results of analysis. The first draft of the manuscript was written by Mohammed Yunus Khan, Usha Rani H Patted and Kumar Gaurav and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.

Data Availability

Data sharing is not applicable to this article as no datasets were generated or analyzed during the current study.

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