Introduction
Heart failure (HF) is one of the leading causes of morbidity, mortality, and rehospitalization [
1]. According to the American Heart Association, HF is a chronic and progressive disease in which the heart muscle is unable to pump enough blood to meet the body’s needs for blood and oxygen [
2]. Symptoms of the disease and its complications over time cause limitations in the patients’ normal course of life so that the quality of life of patients with HF is lower than patients with other chronic diseases and they increase the risk of hospitalization and death [
3,
4]. The American Heart Association (2014) reports that about 7.3% of all deaths from cardiovascular diseases are due to HF [
5]. By 2030, it is predicted that more than 23.3 million people will die due to cardiovascular diseases annually, and the prevalence of HF is expected to increase by 25% [
6].
Also, according to the results of a study conducted at the University of Utrecht in the Netherlands, about 64.3 million people worldwide live with HF [
7]. According to other published statistics, the prevalence of this disease in the United States (2018) has been about 2.5% [
8], in Germany (2013) over 4% [
9], in the United Kingdom (2014) 1.6% [
10], and in Belgium (2015) has been 1.3% in women and 1.2% in men [
11]. The prevalence of HF in Iran in 2013 was reported to be 8%, which has been higher than that reported in other Asian countries, including Japan (0.8%), China (3.5%), and India (0.3%) [
3,
7,
12]. While the incidence of HF is decreasing in developed countries, the prevalence is increasing due to the aging of the population, and the availability of effective treatment [
13].
On the other hand, this disease is one of the common diseases that impose a great financial burden on individuals and communities [
14]. The results of Harkness’s study (2015) showed that HF was related to high mortality, frequent hospitalizations, and a heavy financial burden on the health system [
15]. Wu et al. (2013) have stated in their study that it is expected that by 2030, about 8 million Americans will suffer from HF, with costs related to their treatment amounting to 53 billion United States Dollars (USD) [
16]. In Iran also about 23% of the burden of diseases has been related to cardiovascular diseases [
17] and the annual cost of each patient with cardiovascular diseases has been reported as about $ 7,736.19 Purchasing Power Parity (PPP) [
18]. Also, the rate of patients with HF in Iran is 3.3 per 100 people, and the hospitalization rate due to HF is about 0.3% per year. In recent years, the economic burden of HF in less developed countries has increased up to two times, and in Iran is about 400 billion rials (equal to 9,445,100 USD) per year [
19,
20].
But the prevention of cardiovascular diseases, including HF, is applied at different levels. Preventive interventions and activities lead to a 20 to 30% reduction in the incidence of cardiovascular diseases and their mortalities as well as an increase in the quality of life [
21]. One of the preventive interventions is pharmacological interventions which can be used to reduce the complications of cardiovascular diseases such as HF [
22,
23]. One of the most important pharmacological interventions in patients with HF is the use of antihypertensive drugs such as candesartan and valsartan, which belong to a family of medicines called Angiotensin Receptor Blockers (ARBs) and enalapril (an angiotensin-converting enzyme (ACE) inhibitor). ACE reduces the angiotensin level. This decreases the overall peripheral resistance without increasing the oxygen demand of the heart [
24]. Also, the binding of angiotensin to the receptors causes vasoconstriction and increased blood pressure. By blocking the angiotensin receptor, valsartan and candesartan dilates blood vessels and lowers blood pressure [
25].
These medicines, with their three main mechanisms of nitric oxide release, potassium channel opening, and calcium channel occlusion, reduce vascular resistance and pressure and may reduce the risk of hospitalization for HF [
26‐
28]. The safety and effectiveness of these three medicines in reducing mortality and morbidity have been investigated in various studies, and the use of these medicines is recommended by European and American medical guidelines [
29‐
31]. However, although the benefits of these medicines have been proven for populations around the world, including Asian countries, it is necessary to obtain the necessary information to determine the most cost-effective medicines [
32].
The cost-utility analysis is one of the most common forms of full economic evaluation studies in the health sector, which compare both costs and quality-adjusted life years (QALYs) of alternative interventions. These studies include both costs and outcomes. Outcomes are expressed as the incremental cost-effectiveness ratio (ICER), where differences in costs and outcomes are compared between two treatment options [
33].
In this regard, some studies have been conducted in the world on the cost-utility of medicines related to HF. For example, a study by Ademi Zanfinaae et al. (2017) in Switzerland showed that valsartan, compared to enalapril, reduced the number of hospitalizations by about 6% per year and the lifetime hospital costs by 8% and improved the QALYs by 0.42. Also, the ICER for sacubitril/valsartan.
treatment versus ACE was CHF $25,684 per QALY gained [
34]. In a study by Gazziano et al. (2016) in adult patients with HF in the United States, the results showed that the number of patients admitted to hospitals in people taking valsartan was 230 per 1,000 people less than those taking enalapril and, compared with enalapril, the strategy of using sacubitril/valsartan had an ICER of $45,017 per QALY gained [
35]. Also, the results of a study conducted by Granstrom et al. in Sweden (2012) showed that candesartan, compared to losartan, had more effectiveness and QALYs and lower costs in patients with hypertension [
27].
It is worth mentioning that despite the production of three medicines of candesartan, enalapril, and valsartan in Iran, an economic evaluation study on the cost-utility of these medicines was not found by researchers. Therefore, the present study was conducted to compare the cost-effectiveness of candesartan, enalapril, and valsartan in patients with HF from the payers’ perspective using the Markov model with the lifetime time horizon in Iran in 2020. In the current study, direct medical costs were considered and the effectiveness measure was the QALYs.
The results of this study can lead to determining the cost-effective medicine among the three medicines to be used by clinical specialists to control and treat the disease of patients with HF and also to be used in making decisions and designing clinical guidelines for proper planning for prevention and control of HF in the country.
Discussion
HF is one of the leading causes of morbidity, mortality, and readmission to the hospital. The economic burden of the disease has increased dramatically over the past two decades, leading to the waste of resources and increases in the costs of health care systems [
56]. In the last three decades, pharmaceutical treatments based on current clinical guidelines, including the use of Angiotensin Receptor Blockers, have shown significant success in reducing hospitalization, morbidity, and mortality associated with HF [
57]. On the other hand, economic evaluation studies play an important role in the optimal allocation of resources and appropriate decision-making in health systems, and cost-utility studies are usually considered the gold standard for economic evaluations [
58]. This study aimed to compare the cost-utility of candesartan, enalapril, and valsartan in patients with HF using the Markov model in Iran in 2020.
The results of the present study showed that valsartan was cost-effective compared to two other studied medicines. Moreover, the results of the current study showed that ICU had the highest cost among different cost items, which is in line with those of the Jabbari et al. in Iran (2020) and Van der Pol et al. in the Netherlands (2017) [
37,
59].
Moreover, the results of the current study showed that the amounts of QALYs for valsartan were estimated to be 16.15, and 15.16 and 15.06 for enalapril and candesartan. The results of this study are in line with those of the studies by Gaziano et al. (2020) in the United States [
60], Margarida Borges et al. (2020) in Portugal [
61], Van der Pol et al. in Germany (2019) [
38], Pradelli et al. (2009) in Italy [
62], McMurray et al. (2018) in the three countries of the UK, Denmark and Colombia [
63], and the Ademi et al. (2017) in Switzerland [
34]. In their study, King et al. (2016) found that valsartan had higher cost and effectiveness for patients with HF than enalapril and that the valsartan’s higher cost-effectiveness depended on the patients’ duration of treatment [
64]. However, the results of the Krittayaphong and Permsuwan’s study (2018) showed that valsartan, compared to enalapril, did not represent good value because of its high price in Thailand [
32]. Liang et al. (2018) also concluded in their study that valsartan did not represent good value, compared to enalapril, in reducing morbidity and mortality in patients with HF in Singapore [
65]. The results of these two studies are not in line with those of the present study.
In the current study, sensitivity analyses were performed to show the robustness of the results relative to the model parameters and the results of the Tornado diagram showed that the results of the study were highly sensitive to the cost of HF, the discount rate of the outcome, the discount rate of cost, and the utility of no hospitalization. Moreover, the results of the cost-effectiveness acceptability curve showed at the threshold of 7,256 USD, valsartan had a 60% chance of being cost-effective compared to enalapril. and with an increase in willingness to pay to 10,000$, the probability of being cost-effective increases to 85%.
Given that valsartan is easily available at a reasonable price in Iran, it can be a good treatment option for patients with HF in this country. However, because of differences in cost coverage by health insurance organizations, differences in the effectiveness of diagnostic tests such as echocardiography and exercise testing, patients’ willingness to pay, and different prevalence of HF in different countries, it is necessary to be cautious in generalizing the results of the present study to other countries.
The strengths of the present study were the use of the lifetime time horizon, the use of the Markov model that was validated and used in previous studies, and the extraction of utility and cost values of the Markov states from internal studies.
However, the current study, like other studies, had some limitations. One of the limitations of the present study was to use cohort simulation and for future study, it is suggested the researchers apply other simulation techniques such as system dynamics, discrete event simulation, and agent-based simulation.
Due to the lack of internal and Iranian studies on the transition probabilities, the required data were extracted from external studies. Another study limitation was that the payers’ perspective did not take into account the patients’ direct non-medical and indirect costs, and therefore it is suggested to use the societal perspective that examines all types of costs in future studies. It should be noted that in the present study, the costs extracted from other studies were updated and adjusted according to their study time, and the effect of changes in costs and utility values was investigated using sensitivity analyses. Overall, it is very necessary to conduct economic evaluation studies on medicines in low- and middle-income countries due to their severe limitations of health resources and the need to make optimal use of the resources available. To evaluate and determine the cost-effectiveness of new medicines in such countries and to provide guidance in decision-making, it is suggested that more economic evaluation studies, such as the present study, be conducted in these countries in various fields.
Although medicines such as telmisartan, azilsartan, olmesartan, and irbesartan are alternative medicines to valsartan, because these medicines were not included in the Iran pharmacopeia, they were not investigated in the current study and it is suggested that in future studies in countries where these medicines are part of their pharmacopeia, they should also be studied and compared.
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