Abstract
Purpose of Review
Acute myeloid leukemia (AML) is a costly disease, and its impact is greater in developing countries (DC). We will review the current concept of what are DC, compare the differences in the epidemiology and economic burden of this disease between developed and DC, and finally, analyze the barriers and possible solutions that DC should implement to achieve better results.
Recent Findings
DC is a frequently misunderstood name. The way we use to measure human development is changing, and multidimension metrics better define what are DC. With this in mind, we show the differences in the AML epidemiology and the impact of economic burden in DC. We analyze the barriers to access therapy from a clinician point of view, to show that most DC shared similar challenges but with a diverse healthcare structure. Finally, we provide several possible solutions for a more integrated and timely treatment that allows better results not only in terms of survival but with a better quality of life.
Summary
The economic burden of AML treatment in DC is high, and the results are poor. It is crucial to face this challenge and propose new treatment approaches to achieve better results.
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Introduction to AML
Acute myeloid leukemia (AML) has the highest incidence of adult acute leukemias in developed countries, with an estimated incidence of 4.3 new cases per 100,000 in the United States (US) in 2018 [1].
Acute myeloid leukemia (AML) is a hematologic malignancy characterized by clonal, abnormally differentiated cells of the hematopoietic system accumulating in the bone marrow, blood, and possibly other organs [2•]. Without treatment, survival is measured in days to weeks [2•]. Fit people with AML are usually offered induction chemotherapy, which results in the achievement of complete remission (CR) in most cases. Still, despite post-remission chemotherapy and/or allogeneic hematopoietic cell transplantation (HCT), relapses are common and only a minority of the affected individuals will be long-term survivors [2•].
The 5-year overall survival (OS) rate for all AML patients in the US has improved modestly over several decades from 6.4% in 1975–1977 to 28.1% for patients diagnosed in 2008–14 [3]. Even in the selected patient population receiving intensive therapy, 5-year OS rate ranges between 25 and 40% and declines for older and intensive therapy ineligible patients where the long-term OS rate is less than 10% [4, 5].
After decades of minimal therapeutic progress, the pace of approvals has steeply accelerated with eight novel agents being approved in the US by the Food and Drug Administration (FDA) for subsets of patients with AML [6].
Given the heterogenous treatment approaches, the cost of AML has been difficult to estimate. Previous studies have shown that costs of AML treatment depend not only on treatment modality either intensive chemotherapy (HIC), HSCT, low-intensity treatment (LIT), or supportive care (SC), but also on insurance status and country of residence [7] and are largely driven by healthcare resources utilization [2, 4].
Further, complexity is increased because health care resource varies between different countries. Developing countries (DC) faced many difficulties to treat cancer, and the high economic burden of AML is a big challenge for them. Nevertheless, DC is an ambiguous term, and first, we need to clarify it and then analyze the barriers and possible solutions to obtain better results in the treatment of AML in these countries.
AML Data in DC
Defining Developing Countries: What We Should Know
Several studies performed in either DC, such as Brazil, or those with high ethnic and demographic diversities, such as the United States or the UK, demonstrated the association of the socioeconomic status (SES) with the access to HSCT and mortality after transplantation [8]. The distribution of some modalities of treatment in AML, like HSCT, varies strongly among countries, which, in major part, depends on economic conditions defined by the Gross National Income per capita [8]. On the other hand, it may be speculated that the background determining availability of diverse therapies may be more complex and may include socioeconomic factors other than gross national income [8]. In 1990, the Human Development Index (HDI) was launched with this underlying principle: National development should be measured not only by income per capita, as had long been the practice, but also by health and education achievements. HDI was commissioned by the United Nations Organization to evaluate a country’s socioeconomic achievements in 3 basic aspects of human development: longevity, knowledge, and standard of living [9•]. Thus, HDI is a composite index focusing on three basic dimensions of human development: the ability to lead a long and healthy life, measured by life expectancy at birth; the ability to acquire knowledge, measured by mean years of schooling and expected years of schooling; and the ability to achieve a decent standard of living, measured by gross national income per capita. Nevertheless, assessing inequalities in human development (HD) demands a revolution in metrics. Over the years, additional indices have been developed to capture other dimensions of human development to identify groups falling behind in human progress and to monitor the distribution of human development [9•]. Recently, to measure HD more comprehensively, the Human Development Report presents four other composite indices: (1) The Inequality-adjusted HDI (IHDI) discounts the HDI according to the extent of inequality, in other words, with perfect equality the HDI and the IHDI are equal. Nevertheless, when there is inequality in the distribution of health, education, and income, the HDI in a society is less than the aggregate HDI. The greater the inequality, the lower the IHDI (and the greater the difference between it and the HDI). The average loss in the global HDI value due to inequality is about 20% [10], but it is higher in countries with low HD; in these countries, the average HDI is 30% lower, but could be as wide as 45% lower in some regions of the world like Comoros in Africa [9•]. For health, vast inequalities exist across countries with different levels of HD. (2) The Gender Development Index compares female and male HDI values, worldwide; the average HDI value for women is 5.9% lower than for men, and the gender gap is widest in low HD countries, where the average HDI is 13.8% lower for women than for men. (3) The Gender Inequality Index was proposed in 2014 and highlights women’s empowerment. (4) The Multidimensional Poverty Index (MPI) measures non-income dimensions of poverty. For instance, in low HD countries 47.5% of adults are illiterate and only 17% of the population has access to internet. The latest edition of HDI [9•] proposed four human development groups according these composite indexes: very high (HDI 0.894), high (HDI 0.757), medium (HDI 0.645), and low HDI (HDI 0.504). DC as a whole were placed between medium and high HDI with 0.681 and were divided by regions: Europe and Central Asia (HDI 0.771), Latin America and Caribbean (HDI 0.758), East Asia and the Pacific (HDI 0.733), Arab states (HDI 0.699), South Asia (HDI 0.638), and Sub-Saharan Africa (HDI 0.537) (Table 1) [9•]. Several proxies for the quality of health exist and can be divided into input and output indicators; the differences in access to physicians and hospital beds both are input indicators. Europe and Central Asia have 24.7 physicians per 10,000 people, South Asia 7.8, and Sub-Saharan Africa 1.9. The average number of hospital beds per 10,000 people is 58 in high human development countries, compared with 9 in medium human development countries and 13 in low human development countries [9•].
In summary, as it was shown, it is very complex to classify different regions or countries according to HD because HD is multifactorial, and very heterogenous. In addition, the data of poorer countries is limited. The last update of Human Development Indices and Indicators (the 2018 Statistical Update) published for the United Nations Development Program reflects human development progress over 1990–2017. After 28 years since the launch of the first human development report, we have a better integrated way to evaluate the human development [10]. It is important for health workers to know this integrated information in order to better understand publications from all over the world. The data discussed in this article come from several of these DC, and are compared, in some instances, with data from developed countries, mainly US.
AML Epidemiologic Data in DC: Are They Different From Developed Countries?
Approximately 70% of deaths from cancer occur in low- and middle-income countries (LMIC) [11]. Late-stage presentation and inaccessible diagnosis and treatment are common in these regions [12•]. In 2015, only 35% of low-income countries reported having pathology services generally available to the public sector. More than 90% of high-income countries reported that treatment services are available, compared with less than 30% of LMIC [12•]. Only 1 in 5 LMIC have the necessary data to drive cancer policy [12•] The GDP of all the high-income countries in 2010 was 45.2 trillion US dollars compared with 20.4 trillion US dollars for the GDP of all the middle-income countries and 0.3 trillion US dollars for the low-income countries [12•]. Overall, high-income regions spend 5–10 times more on cancer control on a per capita basis than LMIC [12•]. Concerning access to the new treatments, the gap between high-income countries and LMIC is increasing, especially since low-income countries must treat more frequently patients in advanced stages in which the great majority of the new drugs are registered [12•].
AML incidence rates in world populations generally ranged from 3.0 to 4.0 cases per 100,000 person-years in adult populations, with the highest incidence rates occurring in US, Europe, and Australia, while DC had about one-third the incidence of AML [1, 13].
The median age at diagnosis in DC has been observed 10 years earlier than in developed countries [14,15,16,17], with a mean age of 32–44 years compared with a median of 60–70 years in some developed countries like US or UK [1, 3].
The low incidence of AML in specific groups is showed in the US studies that found a higher frequency of acute lymphoblastic leukemia (ALL) in Latin American (LA) adults, in comparison with other ethnicities (Caucasian, Asian, African American) [1, 18,19,20]. Descriptive epidemiologic studies have reported a higher incidence of ALL in the LA population compared with other racial/ethnic groups [18]. For instance, in Mexico there is a slightly higher incidence of ALL than AML in the population over 16 years of age [18]. The origin of these differences in incidence and age is unclear. Socio-economic factors including the aging population in developed countries and reduced access to healthcare in elderly patients in developing countries could explain these variations [18]. Other factors including differences in genetics, molecular pathways, environmental exposition, and diet should be explored [18, 19].
Nevertheless, acute promyelocytic leukemia (APL) deserves attention because of the higher incidence observed in some developing DC. LA population living in the US have a greater frequency of APL compared with non-LA Caucasian population (24.3 vs 8.3%) and younger at presentation (31.5 vs 46 years) [20]. This finding has also been observed in other LA countries such as Mexico (35.5%) [18, 19], Brazil (28.2%) [21], Venezuela (27.8%), and Peru (22%) [22]. The geographic variation suggests a possible genetic predisposition or environmental exposures to specific risk factors. Other conditions such as obesity and dietary patterns have been linked to APL [23]. The distribution of the breakpoint cluster regions of the PML/RARa fusion gene has been shown to be different in Mexican patients with APL than in Caucasians and similar to those observed in Asians [24]; this observation suggests genetic differences in the features of PML, with a higher predisposition for this disease in Mexico or, alternatively, a protective effect of these differences in Caucasians. As a result of the increased prevalence of APL in LA, multicenter studies employing a simplified treatment of the disease have been conducted, with results like those obtained in other populations employing more complicated treatment schedules [25•]. APL is the AML subtype with the highest cure rate if it is treated with the best and timely treatment, so the negative impact of inappropriate therapy in DC is huge. It is also interesting that the prevalence of acute megakaryoblastic leukemia, the M7 variant of the FAB classification of AML, has also been described as more frequent in Mexicans than in Caucasians [26].
Economic Burden and Quality of Life in AML
Overall Costs of Acute Myeloid Leukemia
AML accounts for approximately 1.1% of new cancer cases each year in the United States [1]. Despite the relatively low incidence rate of AML compared with other cancers, the economic burden of AML to commercial insurers in the United States is substantial; total average costs were more than $300,000 per person year [27]. For patients with AML, the driving cost component is hospitalization-related costs during induction chemotherapy (IC) and hematopoietic stem cell transplantation (HSCT)-related costs [28••]. Even at centers where outpatient management after IC is available, readmissions are frequent and inpatient charges are rarely completely avoided [29]. In addition, intense outpatient monitoring, transfusion support, and antimicrobial prophylaxis are standard among those who achieve remission after IC or among patients receiving less aggressive treatments [30]. However, patients with AML who are not candidates for standard IC have different clinical profiles than those who are [31], and real-world assessments are needed for both younger and older patients with AML due to their different prognoses and profiles [32].
Although it can be difficult to make direct comparisons among studies because of methodologic differences, treatment approach, and variable costs across centers of care, they all show that AML is costly. AML drugs are comparable to other cancer drugs that tend to have higher cost-effectiveness thresholds than non-cancer medications [33]. Several potential explanations for this higher cost-effectiveness threshold for oncology medications have been suggested that include the greater severity of the disease, extended exclusivity protection, and a very narrow indication for a specific indication which creates a quasi-monopoly situation [33].
QoL and Psychological Considerations in AML
In addition to cost-effectiveness proper analysis, it is necessary better quality of life (QoL) studies because some of the most difficult challenges facing patients with AML and those treating and caring them are related to health-related quality of life (HRQoL) and psychosocial well-being [28••]. Systematic reviews have demonstrated that HIC is associated with an overall improvement in HRQoL despite an initial reduction associated with hospitalization. In patients with AML who are ineligible for HIC, HRQoL is compromised, and LIT has been shown to maintain, not improve HRQoL, indicating the need for new treatments which improve QOL as well as duration of survival in patients ineligible for HIC [30]. These studies have demonstrated that poorer HRQoL at diagnosis is associated with poor survival. [30]. The impact of treatment, either HIC, LIC, or SC, is heterogenous and depends on the time when it is measured. Further, QoL is a complex issue, scales are variable, and results differ from one study to another.
In the same way, several studies have shown the psychological burden of AML in both younger and older patients [28••, 30]. Due to the sudden onset and need to treat rapidly, patients with AML also reported feeling overwhelmed and had trouble processing the large quantity of information regarding their diagnosis and potential treatment options, which may have contributed to increases in psychological distress and feelings of helplessness [34]. In a recent publication, anxiety and depression are frequent in adult patients with AML and both predict unfavorable survival [35].
Further research is required to better understand the overall value of new treatments to both patients and healthcare providers as costs and HRQoL become increasingly important in the evaluation of new treatments [30].
Barriers to Access to Therapy in Developing Countries
As previously stated, the data in this report come from DC as defined in the HD Report [8]. Most of available information is derived from middle HDI countries because reliable information is very limited from low HD countries. The focus in this report is mainly LA population; nevertheless, the obstacles are similar in all DC. In these countries, we face several challenges and barriers for therapy access.
AML is not a common cancer, and it is a costly disease [27]. The large economic weight that AML demands affects not only the healthcare system at large but may also lead to financial hardship and high-stress burden among AML patients. AML affects mainly older adults over the age of sixty, and the treatment results until today are disappointing. This scenario, in DC with limited health resources, favors the health authorities to use their low budget preferentially in another illness that have higher incidence and a better chance to achieve higher social impact. Even among neoplastic disorders, leukemia is not as common as solid tumors and frequently more money is allocated to treat other types of more prevalent cancer. Sometimes the social impact of a relative higher number of survivors of solid tumors favors the health authorities to minimize the treatment of leukemias, mainly in older adults. Nevertheless, the median age of AML in DC is strikingly different from that routinely reported in the literature from developed countries, and consequently, the economic impact on economically active population is larger.
Different studies have shown that socioeconomic factors (insurance, race, education, and occupation) are related with outcomes [36,37,38,39]. A large study in the US population, analyzing 2992 AML-patients, showed that education level (but not income) was associated with survival. Higher education in younger patients with AML was associated with a higher HSCT rate and a longer OS. Interestingly, the group of patients with a high-education level had a clear OS improvement in the most recent years, with the 5-year OS increasing from 39 to 58% (between 2000–2004 vs 2010–2014) in comparison with the group of patients with a low and medium education level with no improvements in the 5-year OS in the same period of time [40]. Conversely, a recently published study in France showed that in older AML-adults, socioeconomic status was not significantly associated with OS when adjusted with other prognostic factors [41].
The reported outcomes in DC are poor when compared with developed countries. A study from Brazil showed that AML-patients treated with intensive chemotherapy had a 5-year OS of 22% with an early mortality of 22% [42•]. In México, we recently showed the results of a multicenter experience of 525 adult-AML patients where the outcomes of patients treated with intensive chemotherapy are also inferior in comparison with developed countries with a 3-year OS of 34.8% and an early-mortality of 17.8% [43]. The high rate of induction-related mortality is very frequent in DC; it uses to be around 25% or as high as 39% in India [44, 45]. The main early-mortality cause in these reports was infection [42•, 43,44,45]. The post-induction outcome is poor as well, with an early high relapse rate, 43% at a median time of 7 months in Brazil [42•], and an overall survival of 42% at 1 year in India [44]. The number of patients rejecting treatment is high in DC, and the causes are multifactorial: advanced age; live further away from the hospital; lack of social support; concerned about toxicity to chemotherapy, apathy and fatalistic attitude, alternative medicine (homeopathy, herbalism); and mainly lack of financial support [44].
Results in the elderly patients are even worse. In a recent publication from India, from a total of 402 AML elderly patients (mean age 68 years) only 188 patients (46.7%) received either low-dose cytarabine (LDAC), hypomethylating agents, or best supportive care (BSC). The reported survival was 3.9, 6.4, and 1.2 months with LDAC, HMA, or BSC, respectively. The remaining patients, 213 (53.3%) refused care [46].
In AML, the single most important factor for not proceeding with treatment was lack of financial resources (81%). A small proportion of patients (22%) that did not opt for treatment in reference centers went on to receive IC from smaller facilities, but clearly, the vast majority did not receive further treatment and succumbed to their disease. Another frequent cause of rejecting treatment in DC is access to alternative medicine [44].
Delayed diagnosis may decrease the number of complete remissions (CR) mainly in younger patients when AML diagnosis to treatment is longer than only 5 days [47], the delay to receive treatment in DC is usually greater than 5 days, and it is not unusual that, at diagnosis, patients have an active infection.
Apart from leukemia high relapse deaths, infection is an important cause of mortality in DC. Infection not only jeopardizes survival but is the main cause of longer length of hospital stay. Because of the inappropriate conditions for AML treatment, higher incidence of bacterial and fungal infections is frequently reported. These inappropriate conditions could be associated to the tropical climate, lack of enough beds in rooms with positive-pressure laminar flow, and difficulties in the access to the workup for invasive mold disease [48]. Neutropenic fever (NF) is a very common complication during induction therapy and even after consolidation. In a real-world report from India, all patients developed NF during induction [44]. A big challenge is the increased incidence of multidrug resistant bacteria, recognized as a global phenomenon. Nevertheless, invasive fungal infections (IFI) are increasing and are responsible of at least one third of infections in acute leukemia. In some DC, like India, as much as 44% patients who died in induction had evidence of a possible or definitive IFI [44] which clearly exceeds rates reported in developed countries [49]. In a recent publication from Southeastern Asia, predisposing factors for IFI were shown in multivariate analysis: deep/prolonged neutropenia (˃ 30 days) and receipt of parenteral nutrition [50]. IFI incidence is magnified due to the limited resources to both the insufficient number of pathogen isolates and the restricted access to costly modern antifungal therapy.
On the other hand, health system coverage is very heterogeneous between DC. In comparison with some developed countries as the Nordic nations, where all the cancers are fully covered by a unique national health system, in some DC health systems are fragmented and the access is inequitable. For instance, in India, 85% of expenditure on health happens from noninsured, out-of-pocket spending and different treatment centers are likely to have diverse costing structures, based on whether they are private for-profit, private non-profit and fully or partly government subsidized hospitals. Similarly, it seems to be significant heterogeneity between hospitals with regard to diagnostic facilities available, allogeneic SCT facility, and access to trained personnel and supportive care [44]. Likewise, in México, 23.1% is treated in private medical services, 36.8% under social security (fractionated in different systems), and 40.1% has no insurance [51]. Patients with private insurances have access to all the diagnostic tests and new drugs, whereas patients with no insurance have a very limited access to both diagnostic tests and drugs. In Brazil, according to data from 2012, most of hospitals (66%), hospital beds (70%), and specialized hospitals for AML treatment (87%) were private. In addition, 95% of diagnostic support and therapy establishments were owned by the private sector. Nevertheless, around 80% of the population still rely on the publicly funded healthcare system, which has major hurdles in AML successful treatment, including limited or no access to immunophenotyping, cytogenetic and molecular tests, drug unavailability and lack of beds for intensive chemotherapy, and delayed or no access to transplantation when indicated [42•].
Finally, the access to clinical trials is very limited in DC. Eight new drugs have been approved in the last 3 years for AML [52,53,54,55,56,57,58,59,60]. As we can see in Table 2, the clinical trials that led to the approval of these drugs were carried out mainly in developed countries [61]. Most of these drugs are not yet approved or available in many countries outside US and Europe. In the same way, the number of AML clinical trials registered in clinicaltrials.gov (recruiting or not yet recruiting) is very limited in DC (Table 3) [62].
In conclusion, the clinical course for adult patients with AML treated in DC points to significant disparities compared with developed countries; this difference lies in multifactorial reasons not only attributed to the disease per se but rather to socioeconomic factors and public health policies-related issues [42•]. It is also important to note that most of the data from DC refer to a “real world scenario,” which is in sharp contrast to those commonly reported by clinical trials. In DC, treatment of patients with AML is substantially hampered by the delayed start of induction chemotherapy (because of delayed diagnosis), drug unavailability, and lack of adequate infrastructure for chemotherapy and/or stem cell transplantation. A high proportion of patients reject treatment and the causes are multifactorial, but mainly, financial. To further complicate this scenario, not only there are barriers to afford the expensive direct and indirect costs of AML but diagnostic procedures like standard cytogenetic and molecular analyses are still not routinely performed in most institutions specialized in hematological malignancies treatment [42•]. In many DC, the biggest constraint is the cost of the treatment and the absence of a universal health security net to treat all patients with this diagnosis [44].
Possible Solutions
DC should aspire to have better human development; health is only part of a global well-being, and improving is only possible with better evaluation of the HDI and a global effort to achieve a more equitable wealth distribution. In the meantime, there are several ways to enhance the different problems that DC faced with new causes of morbidity and mortality, mainly thrombotic, and cancer diseases. This is the case of AML; as noted above, the first step should be to identify the main difficulties that are related with the poor outcomes of AML in DC. It is crucial that public health systems in these countries turn to a more efficient structure integrating the fragmented institutions and carry out more epidemiological studies to better understand how the disease characteristics interact with socioeconomic factors. This more appropriate health system would shorten the time from diagnosis to treatment and allow a better outcome of induction therapy. The interaction with developed countries could contribute to a more successful result in AML. An example is the report of the International Consortium on Acute Promyelocytic Leukemia (IC-APL) [25•]. Patients with APL in DC have significantly worse outcomes when compared with developed countries, mainly related with a high rate of early mortality. The main objective of the IC-APL was to create a network of institutions in DC that would share knowledge and data as well as receiving support from experts from US and Europe. The initiative included the standardization of diagnostic tests, treatment, and supportive care. This resulted in a decrease of almost 50% in early mortality and an improvement in OS of almost 30% compared with historical controls, resulting in similar OS to those reported in developed countries. The use of a cheaper anthracycline daunorubicin instead of idarubicin does not compromise these good results. Some of the lessons learned by this initiative were that establishing clinical networks involving developed and DC may be a very useful strategy. It favors simpler diagnosis methods, the implementation of national reference laboratories allowing training of laboratory personnel in new technologies, and quality control routines as well as foster medical education by training clinical staff and creating exchange of experiences and guidelines [63]. This kind of collaboration could be extrapolated to other scenarios, for instance, reduce the higher morbidity and mortality rates from infection in AML through the implementation of better diagnostic methods that allowed more properly designed studies evaluating the bacterial and fungal epidemiology of each country.
In several DC, there are university facilities where the healthcare quality is usually better. In developed as in DC, academic centers mostly offer better patient security and reach major improving in healthcare quality [64, 65]. The influence of these academic centers can help to get better healthcare through teaching, guidelines, and even changing inappropriate healthcare policies.
Newer laboratory methods may allow DC to have access to modern laboratory techniques; for instance, the procedure of dried blood spots enable sending samples to reference laboratories in a cheaper way, for both mutation detection [66] and more precise and rapid diagnosis of opportunistic infections [66, 67]. Likewise, the WHO has recently introduced the ASSURED standards for developing assays for low-resource areas [67]. These electricity-free systems and point of care devices would be of potential applicability.
One of the biggest obstacles to healthcare in low-resource settings is getting the patient to the clinic. This can be expensive at the onset, and if the travel takes several days, it can be economically untenable. Why not take the test to the patient? The isothermal methods, like LAMP (loop-mediated isothermal amplification), are promising. Studies using LAMP to detect the promyelocytic leukemia/retinoic acid receptor a transcript in acute promyelocytic leukemia reliably demonstrate the feasibility of isothermal PCR for rapid and simple diagnostics [68].
Another strategy is the use of telemedicine and mobile technology. An average annual growth rate of 1.9% between 2018 and 2025 will bring the total number of mobile subscribers to 5.8 billion (71% of the population). Of the 710 million people expected to subscribe to mobile services for the first time over the next 7 years, half will come from the Asia Pacific region and just under a quarter will come from Sub-Saharan Africa [69]. There were preliminary reports on the use of telemedicine in hematology [70] and recent reports of the use of smartphone apps in cancer patients [71]. In addition, tumor board teleconferences could provide a valuable tool for continuing medical education in the management of AML and other malignancies [72]. Current COVID-19 pandemia had showed us the huge advantage of virtual academic teaching and the relevance of better telemedicine improvements.
Regarding novel drugs to treat AML, it is an exciting area for clinicians since the last 2 years, when we have an increasingly number of drugs to treat AML. Unfortunately, until today, several DC are far from the routine use of these drugs. The efforts of the past 18 years to provide access to TKI therapy to CML patients in low-middle income countries, the GIPAP (Glivec International Assistance Program) have shown us that it is possible to run a humanitarian access program for an oncology product, extending survival of patients in these countries and achieving overall survival close to that of patients in the western world. The experience also shows how the original impact of one original donor can foster an environment where other stakeholders are more likely to join the efforts [73].
While it would seem obvious that expensive pharmaceuticals would inevitably drive costs upward, actuality, a few unknowns exist [2•]. First, will these drugs provide “value” to the healthcare system and patients, a model which has traditionally considered the cost of achieving not only increased quantity but also quality of additional life? Second, will drugs that are more effective at getting patients into CR lead to a reduction in the costs accrued from transfusion support, hospitalizations, antibiotic use, and even the need for allo-HCT? And third, as many of the new drugs are given orally or with simplified administration schedules, will the reduced need for inpatient administration abate the cost associated with the drugs themselves? [2•].
It is therefore important to judge the cost-benefit of new AML treatments not only by the clinical benefit they may provide but also by how they will affect the downstream costs of AML care [2•]. Due to the novelty and lack of randomized trial data available for most of these drugs, very few budget impact and cost-effectiveness analyses are currently available [2•].
These assessments weigh the affordability and cost of a particular treatment not only against efficacy outcomes (i.e., remission rates, duration of remission, overall survival benefit) but also how achievement of these goals may translate to improvement in the quality of life and cost reduction by leading to symptom relief and treatment-free intervals [2•]. For AML, the ultimate economic value of new drugs will be determined by these variables in addition to considering the larger, but perhaps more indirect impact they may have on the use of healthcare resources [2•].
If these analyses prove that novel drugs have a better cost-effectiveness and they improve the quality of life and indirect costs of AML, certainly they are a better treatment also for DC. The availability of these drugs then be reinforced because they will save resources in DC as well.
Finally, the inclusion of more patients from DC in clinical trials will allow them to access new drugs earlier and allows these regions to discover if there are differences in efficacy or toxicity from a more global perspective.
Conclusions
AML is a costly disease anywhere. In DC the costs are higher as well, but results are poorer. Nevertheless, DC is a name designation that is frequently misunderstood. It is crucial to better understand the human development metrics in order to have a more properly evaluation of the socioeconomic scenario of each DC. Indeed, the main barrier in AML is lack of financial resources, but epidemiological data in DC are critical not only to achieve better knowledge of the health structure of each country and change public health structures and policies, but to manage the causes that impact in the poorer results of treatment, like delayed diagnosis, high early mortality, rejecting therapy, high prevalence of infections, and better access to transplant as well. The interaction with developed countries, like the IC-APL, would contribute to a more successful treatment results in AML. The contribution of technology with simpler and cheaper diagnostic methods as well as telemedicine is another aid. Finally, novel oral and targeted drugs that are now approved and available in developed countries might be of significant value in DC if they could be affordable by AML patients in these regions.
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Luis Antonio Meillon-Garcia has received speaker’s honoraria from Amgen, Celgene, Pfizer, Boehringer Ingelheim, Pint Pharma GmbH, Novartis, Bayer, Roche, AbbVie, Aspen Pharmacare, Janssen, and Teva. Roberta Demichelis-Gómez declares that she has no conflict of interest.
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Meillon-Garcia, L.A., Demichelis-Gómez, R. Access to Therapy for Acute Myeloid Leukemia in the Developing World: Barriers and Solutions. Curr Oncol Rep 22, 125 (2020). https://doi.org/10.1007/s11912-020-00987-8
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DOI: https://doi.org/10.1007/s11912-020-00987-8