Abstract
Background
Although G6PDd individuals are generally asymptomatic throughout their life, the clinical burden of this genetic condition includes a range of haematological conditions, including acute haemolytic anaemia (AHA), neonatal jaundice (NNJ) and chronic non-sphaerocytic anaemia (CNSA). In Latin America (LA), the huge knowledge gap regarding G6PDd is related to the scarce understanding of the burden of clinical manifestation underlying G6PDd carriage. The aim of this work was to study the clinical significance of G6PDd in LA and the Caribbean region through a systematic review.
Methods
A systematic search of the published literature was undertaken in August 2013. Bibliographies of manuscripts were also searched and additional references were identified. Only original research was included. All study designs were included, as long as any clinical information was present. Studies were eligible for inclusion if they reported clinical information from populations living in LA or Caribbean countries or about migrants from these countries living in countries outside this continent.
Results
The Medline search generated 487 papers, and the LILACS search identified 140 papers. After applying the inclusion criteria, 100 original papers with any clinical information on G6PDd in LA were retrieved. Additionally, 16 articles were included after reading the references from these papers. These 116 articles reported data from 18 LA and Caribbean countries. The major clinical manifestations reported from LA countries were those related to AHA, namely drug-induced haemolysis. Most of the published works regarding drug-induced haemolysis in LA referred to haemolytic crises in P. vivax malaria patients during the course of the treatment with primaquine (PQ). Favism, infection-induced haemolysis, NNJ and CNSA appear to play only a minor public health role in this continent.
Conclusion
Haemolysis in patients using PQ seems to be the major clinical manifestation of G6PDd in LA and contributes to the morbidity of P. vivax infection in this continent, although the low number of reported cases, which could be linked to under-reporting of complications. These results support the need for better strategies to diagnose and manage G6PDd in malaria field conditions. Additionally, Malaria Control Programmes in LA should not overlook this condition in their national guidelines.
Keywords: Glucose-6-phosphate dehydrogenase deficiency, Primaquine, Haemolysis, Malaria, Plasmodium vivax
Background
Glucose-6-phosphate dehydrogenase (G6PD) is an important enzyme that catalyses the first reaction in the pentose-phosphate pathway. Within the erythrocyte, G6PD is the sole source of enzymatic activity that protects against the build-up of super-radicals and, thus, oxidative stress [1,2]. G6PD deficiency (G6PDd) is an X-linked, hereditary genetic defect caused by mutations in the G6PD gene, resulting in protein variants with different levels of enzymatic activity that are associated with a wide range of biochemical and clinical phenotypes [2]. G6PDd heterozygosity and hemizygosity have been associated with approximately 50% protection against severe Plasmodium falciparum malaria [3,4]. Therefore, the high prevalence rates of G6PDd in many parts of the world can most likely be accounted for by the selection pressure exerted by malaria. The current estimated prevalence of G6PDd across malaria-endemic countries is approximately 8%, which corresponds to circa 350 million affected individuals in these countries. The lowest prevalence is known to occur in the Americas, while the highest prevalence is observed in tropical Africa, Middle East and the Mediterranean basin [5].
Although G6PDd individuals are generally asymptomatic throughout their life, the clinical burden of this genetic condition includes a range of haematological conditions, including acute haemolytic anaemia (AHA), neonatal jaundice (NNJ) and chronic non-sphaerocytic anaemia (CNSA) [1,2]. Because AHA is the most common manifestation of G6PDd, it is critical to understand how such episodes can be prevented. In G6PDd individuals, these complications are usually triggered by the advent of specific infections or the intake of certain food products, typically fava beans. As such, this inherited disorder is also known by the alternative name “favism”. Complications can also be triggered by drugs, the prime example of which is the anti-malarial primaquine (PQ). The prevention of food-induced haemolytic crises, such as in favism, should theoretically be fully preventable by avoiding the triggering foods. In contrast, the prevention of infection-induced haemolysis is obviously more difficult. In most cases, the prevention of drug-induced haemolysis is possible by choosing alternative drugs, but this may be difficult when no alternatives are available. This difficulty becomes particularly relevant when attempting to treat Plasmodium vivax infections, as radical cures, including the specific treatment of the latent hepatic stages that are mainly responsible for subsequent relapses after the first clinical episode, require the use of PQ for 7 to 14 days. In some individuals, this treatment can lead to life-threatening anaemia and acute renal failure [6]. In these cases, administration of a lower dosage for a longer time is the recommended approach, but only in those patients with mild-to-moderate enzymatic activity. In such patients, haemolysis will still occur, but under appropriate surveillance, it will be of an acceptably mild degree [1]. Importantly, the use of PQ in patients with a low enzymatic activity is contraindicated. It is critical to understand that the risk is variant-dependent and dose-dependent and cumulative. PQ is also the only currently available drug that is effective against P. falciparum stage V gametocytes. The potentially hazardous effect of this drug in G6PDd individuals jeopardizes any population-wide effort to reduce malaria transmission via drugs such as PQ due to the impossibility of performing rapid population-wide screening for the deficiency and the hazards associated with the blind administration of such drugs [7]. More recently, the World Health Organization has recommended 0.25 mg/kg of PQ in a single dose for patients with P. falciparum, as this dose is efficacious as a gametocytocidal drug without the risks of inducing haemolysis in G6PD patients [8].
A thorough understanding of the clinical burden related to G6PDd could be of great value for understanding whether particular drug regimens could be used safely at a population level with or without prior knowledge of the individuals’ G6PD status, or whether the development of field-deployable and electricity-independent rapid diagnostic tests, resembling those that already exist for malaria diagnosis, is indispensable. Some authors have recently proposed maps of the G6PDd global distribution, including LA countries, highlighting the small amount of published works regarding this deficiency in this continent [5,9]. Large swathes of the American malaria endemic areas were predicted to have median G6PDd frequencies ≤1% (40.8% land area), with G6PDd being virtually absent from northern Mexico, Costa Rica, Peru, Bolivia, and much of Argentina. The prevalence increased towards coastal regions, peaking in Venezuela, where the majority of the continent’s predictions of >5% prevalence were located [5]. Only a limited repertoire of variants was observed across LA countries, and surveys indicated relatively low genetic heterogeneity, which was predominated by the African variant [10]. Moreover, in the Americas, the huge knowledge gap is related to the scarce understanding of the burden of clinical manifestation underlying G6PDd carriage. The aim of this work was to study the clinical significance of G6PDd in LA and the Caribbean region through the systematic review of available published data.
Methods
Geographic coverage of the study
South America, Central America, Mexico and the Caribbean area constitute a vast territory formed by 33 independent countries and 20 autonomous or semi-autonomous territories. They cover a territorial area of over 20 million km2, which included a population of approximately 580 million inhabitants in 2008. With regards to ethnicity, in some countries, mainly Chile, Argentina and Uruguay, white people of European origin predominate. In others, such as Venezuela, Brazil, Paraguay, Nicaragua and Colombia, white immigrants mixed noticeably with the Amerindians. Finally, in some countries, such as Mexico, Guatemala, El Salvador, Honduras, Panama, Peru, Bolivia and Ecuador, the Amerindians still constitute a numerically important portion of the population. Additionally, the continent has received multiple waves of African immigrants, especially to the Caribbean area.
Systematic review
Potentially relevant papers in all languages were accessed from Medline and LILACS to review their full texts. A broad free text search using the combination of Medical Subject Heading (MeSH) terms and keywords presented in Table 1 was utilized.
Table 1.
Database | Search terms |
---|---|
Medline |
(favism OR glucosephosphate dehydrogenase OR glucosephosphate dehydrogenase deficiency OR G6PD OR g6pd deficiency OR G-6-PD OR g-6-pd deficiency OR glucose-6-phosphate dehydrogenase OR glucose-6-phosphate dehydrogenase deficiency) AND (Antilles OR Latin America OR South America OR Central America OR Caribbean OR Anguilla OR Antigua OR Aruba OR Barbuda OR Argentina OR Bahamas OR Barbados OR Belize OR Bolivia OR Brazil OR Chile OR Colombia OR Costa Rica OR Dominica OR Dominican Republic OR Ecuador OR El Salvador OR Grenada OR Grenadines OR Guadeloupe OR Guatemala OR Guyana OR Haiti OR Honduras OR Jamaica OR Martinique OR Mexico OR Montserrat OR Nevis OR Nicaragua OR Panama OR Paraguay OR Peru OR Puerto Rico OR Saint Kitts OR Saint Lucia OR Saint Vincent OR Suriname OR Surinam OR Trinidad OR Tobago OR Uruguay OR Venezuela) [MeSH] |
LILACS | (favism OR glucosephosphate dehydrogenase OR glucosephosphate dehydrogenase deficiency OR g6pd OR g6pd deficiency OR g-6-pd OR g-6-pd deficiency OR glucose-6-phosphate dehydrogenase OR glucose-6-phosphate dehydrogenase deficiency) |
Only original research of all study designs (clinical trials, cohort studies, case–control studies, cross-sectional studies, case series and case reports) was included, as long as any clinical information was present. Additional articles were obtained through citation tracking of reviews, opinion articles and original papers. Studies were eligible for inclusion if they reported clinical information from populations living in LA or Caribbean countries or about migrants from these countries living in countries outside this continent. An individual was considered to have G6PDd if they presented with any positive diagnostic test, such as DNA analysis, enzyme activity assay, NADPH fluorescent spot, brilliant cresyl blue, gel electrophoresis, methylene reduction test or phenazine methosulphate-3-(4,5-dimethylthiazal-2-yl)-2,5-diphenyltetrazolim bromide. In this study, clinical information refers to G6PDd manifestations, such as AHA, NNJ and CNSA, as well as G6PDd coexisting with other genetic disorders and association of G6PDd with susceptibility or clinical presentations of metabolic disorders or other infectious diseases than malaria. In this study, a history of jaundice or red cell transfusion after drug therapy was used as a proxy for AHA. To identify relevant papers, the titles, abstracts and the full texts of the studies were examined by two independent reviewers. The data were directly extracted from the full-length articles to structured table and figures containing all the descriptive variables and relevant outcomes.
Results
The Medline search generated 487 papers, and the LILACS search generated 140 papers. After applying the inclusion criteria to those papers, 100 original papers with any clinical information on G6PDd in LA were retrieved. Additionally, 16 articles were included after reading the references of the 100 articles and reviews/ opinion articles that were obtained from the Medline and LILACS searches (Figure 1). These 116 articles reported data from 18 LA countries.
Clinical manifestations of G6PDd in LA and Caribbean populations
Acute haemolytic anaemia (AHA)
Additional file 1 and Figure 2 summarize the AHA findings. Data on AHA were reported from 39 publications, including 34 regarding drug-induced haemolysis, five favism and three infection-induced haemolysis. Some included publications presented two or more clinically relevant G6PDd manifestations. A total of 107 characterized cases of AHA in LA were found. Out of these cases, for 30 (28.0%), it was not possible to identify the triggering cause. Drug-induced haemolysis was responsible for 65 cases (60.7%), with PQ responsible for 47 (43.9%) and other drugs/substances for 18 (16.8%) cases. Nine (8.4%) cases of AHA were due to favism, and three (2.8%) cases were attributed to infection-induced haemolysis.
Figure 2 shows that the AHA cases were mostly reported in men (105/107; 98.1%). PQ-induced haemolysis, favism and infection-induced haemolysis were reported uniquely in males. Only 2 cases of haemolysis (one triggered by naphthalene poisoning and one by salicylates), were registered in females. Although AHA was observed in all ages, most of the cases were reported in the young population, with the median age ranging from 8 to 17 years for infection-induced haemolysis and PQ-induced haemolysis, respectively. Case fatalities were reported only among PQ-induced haemolysis cases, with a 4.3% rate.
Among the 107 cases of AHA, it was possible to identify the ethnicity for only 24 (22.4%) subjects, being 8 (17.0%) presenting PQ-induced haemolysis, 8 with haemolysis induced by other drugs/substances (44.4%), 6 with favism (66.7%) and 2 (66.7%) with infection-induced haemolysis. PQ-induced haemolysis cases predominated among admixed individuals (7/8; 87.5%). Haemolysis induced by other drugs/substances (6/8; 75%) and infection-induced haemolysis (2/2;100%) predominated among black individuals. Favism was recorded in white individuals only (6/6; 100%).
Figure 3 shows the geographic distribution of the AHA cases in which it was possible to identify the triggering haemolytic cause. The highest number of cases was reported in Brazil (26; 33.8%), followed by Cuba (19 cases; 26.7%) and Chile (18 cases; 23.4%). Primaquine-induced haemolysis was reported in Brazil (23 cases; 48.9%), Cuba (18 cases; 38.3%), El Salvador (three cases; 6.4%), Puerto Rico (two cases; 4.3%), and Trinidad and Tobago (one case; 2.1%).
Drug-induced haemolysis
Some cross-sectional studies with a recall approach showed an absence of signs of haemolysis among the G6PD deficient population [11-14]. One study showed that patients who received blood donated by G6PDd individuals did not develop haemolysis, even though some were using drugs that could potentially trigger this complication [15]. Some studies showed a higher frequency of previous history of jaundice in G6PDd in relation to non-G6PDd individuals [16], or a higher frequency of G6PDd in patients with history of acute haemolytic crises in comparison with the general population [17]. However, haemolysis caused by G6PDd was generally mild [16,18,19].
Reports of occasional moderate haemolytic anaemia were reported in Brazil [20], Costa Rica [21] and Mexico [18,22,23], with poor clinical descriptions and no identification of the stressor. No complication was reported in patients using the single dose of PQ (0.75 mg/kg) for P. falciparum gametocytes. In Mexico [24], Ecuador [25] and Chile [26], the frequency of G6PDd in patients with haemolytic anaemia was 30.3, 8.6 and 39.5%, respectively, but the authors did not detail the haemolysis-triggering causes for all patients. Haemolytic episodes in G6PD deficient subjects related to naphthalene intoxication, use of salicylates, transfusion of G6PDd blood into recipients with leprosy under sulpha drug therapy and excessive intake of rum or wine were reported in Curaçao [27]. In LA countries, there were reports of drug-induced haemolytic episodes triggered by nalidixic acid [28], chloramphenicol [26], aspirin [26,29], sulphadiazine [26,30,31], sulphazoxazole plus nitrofurantoin [32] and acetaminosalol [26]. In Brazil, G6PDd did not seem to be associated with a higher risk of haemolysis in patients who were being treated with sulphone [33], ketoconazole [34], or who were under spinal anaesthesia with bupivacaine or general intravenous anaesthesia with propofol [35]. In Saint Lucia, G6PD-deficient children infected with S. mansoni were given a single intramuscular dose of hycanthone, but their subsequent serial haematocrit and reticulocyte counts showed no evidence of haemolysis [36].
In 1970, three patients from El Salvador who presented with PQ-induced haemolysis were confirmed as G6PD deficient, and one of these patients required an exchange transfusion [29]. Two cases of PQ-induced haemolysis were reported from Puerto Rico [32]. Haemolysis appeared in 87.5% of 16 G6PD-deficient patients from Cuba. This effect occurred mainly on the fifth day of treatment, after the administration of 105 mg of PQ [37]. In Trinidad, the management of two imported cerebral malaria cases was complicated by their G6PD-deficient status, with the occurrence of blackwater fever, cerebral manifestations, renal impairment, hyperglycaemia and thrombocytopaenia [38]. In Cuba, there were reports of haemolysis in six of eight (87.5%) G6PDd patients treated with PQ, three of whom could not finish the treatment [39]. Treatment discontinuation was also described in cases from Brazil, where three G6PDd patients with vivax malaria in a chloroquine plus PQ regimen presented with AHA [40]. In a similar regimen, 18 G6PD-deficient patients presented with AHA that required red blood cell transfusions and finally developed acute renal failure [41]. In the Brazilian Amazon, G6PDd was associated with a considerably higher risk of malaria-related transfusions likely triggered by the treatment for malarial infection [42,43]. In Manaus, an autopsy series of deceased patients with confirmed P. vivax infection could only attribute the cause of death to PQ-induced haemolysis, demonstrating the lethal potential of this condition [44].
The use of chloroquine alone did not trigger haemolysis in 8 G6PD-deficient subjects [45].
Favism
The search identified five publications from Chile that reported a total of nine cases of favism in LA [26,46-49]. All cases occurred in males, and most were in children. In three cases, blood transfusions were needed, and one individual evolved to acute renal failure. There was no record of case fatalities.
Infection-induced haemolysis
In Cuba, recurrent viral and bacterial infections were indicated as possible causes of haemolysis in an 8-year-old boy [19]. In Curaçao, one case of haemolytic anaemia in a G6PD-deficient subject was related to a febrile non-defined viral infection [27]. In El Salvador, one episode of haemolysis was reported in a patient with an infection without defined aetiology, but the stressor was not characterized because the subject was taking aspirin [29]. A clear aetiological trigger could not be confirmed in any of these cases.
Neonatal jaundice (NNJ)
Neonatal jaundice was reported in 30 original articles. The frequency of NNJ in G6PD-deficient new-borns ranged from 38.5 to 100% [50-56]. However, excluding other causes, the aetiology of jaundice was attributed to G6PDd in 5 [57] to 15% [58] of the new-borns. On the other hand, G6PDd was detected in 3.4% of male new-borns with NNJ in the absence of foetal-maternal incompatibility in Costa Rica [59] and in 69.6% of a group of neonates who had unexplained moderate to severe jaundice [60]. Four studies reported no severe complications in G6PD-deficient new-borns with NNJ [53,54,56,59], while three works described the need for exchange transfusions [50,51,55], three described the occurrence of kernicterus [51,60,61], and two described fatal outcomes [29,60].
Some cross-sectional studies have demonstrated that NNJ cannot be solely attributed to G6PDd [62] or a lack of association between G6PDd and NNJ [24,63-67]. In Trinidad, a similarity between the frequencies of enzyme defects in normal children and those with cerebral palsy suggested that neonatal jaundice associated with G6PDd may be a factor of little significance in the development of kernicterus and subsequent cerebral palsy, even in a community with a high prevalence of this enzyme deficiency [68]. In a prospective study from Brazil, G6PDd did not appear as a risk factor for moderate hyperbilirubinaemia [69], and in a case–control study in the same country, G6PDd was not found to be related to severe hyperbilirubinaemia [70]. Other reports have found contradictory results about the relationship between G6PDd and NNJ in LA, suggesting that there was a positive association between G6PDd and NNJ [71-77]. In a work from Mexico, the prevalence of NNJ was only linked to G6PDd in male babies [52].
Chronic non-sphaerocytic anaemia (CNSA)
Data concerning the association between G6PDd and anaemia, including chronic non-sphaerocytic anaemia, were presented in 18 articles. Only 8 defined cases of CNSA were recorded from Latin America, with 2 from Brazil [78,79], 2 from Chile [80] and 1 each from Cuba [81], Costa Rica [82], Mexico [24] and Puerto Rico [32]. However, in general, these publications had poor clinical descriptions, as they were primarily aimed at characterising the enzyme. Of these cases, those from Chile had more detailed clinical data and highlighted persistent anaemia with the need for blood transfusions, reticulocytosis, jaundice and splenomegaly [80]. Cholelithiasis is a complication that can follow CNSA, but in Brazil, there was no association between the need for cholecystectomy and G6PDd [83]. In a study from Brazil [84] and in another from Colombia [85], G6PD-deficient subjects showed a lower level of haemoglobin than the normal individuals.
Most of the published reports describing haematological parameters in LA, which covered several distinct geographical areas, showed similar haematimetric indexes in G6PDd individuals and non-deficient ones [86-92]. In Brazil, a low incidence of anaemia conferred no important haematological changes in individuals in which G6PDd was found [93].
Coexistence of G6PDd with other genetic disorders
The coexistence of G6PDd with other genetic disorders was reported in 14 articles. In Argentina, beta-thalassemia was detected in 4.8% of the G6PD-deficient subjects [94], and the concurrence of haemoglobin S and congenital sphaerocytosis with G6PDd was detected in 4 and 2% of the subjects, respectively [50]. In Brazil, haemoglobin S was detected in 11.1% of the G6PD-deficient individuals [95]. In Costa Rica, the frequency of G6PDd among male HbAS carriers ranged from 2.3 [96] to 15% [97]. However, controlled studies have shown that G6PDd is independent from the occurrence of abnormal haemoglobin [27,98-100], HbS or HbC [101] sickle cell trait [102] and sickle cell disease [103]. In Jamaica, difference in G6PD status did not affect the total haemoglobin concentration, reticulocyte count, unconjugated serum bilirubin, Hb F concentration, plasma haemoglobin concentration and frequencies of clinical severity and of leg ulceration in patients with sickle cell disease [104]. In Brazil, G6PDd was absent in nine children with clinical diagnosis of glycogenoses [105].
G6PDd and malaria susceptibility
An association between G6PDd and malaria susceptibility was reported in 8 articles. In a traditionally malaria-endemic area of South-eastern Brazil, the frequency of G6PDd and average G6PD activity was similar between the groups with and without a history of malaria [106]. Plasmodium falciparum infections were recorded at the same proportion in G6PDd and normal individuals in the Southern Brazilian Amazon [107]. In Brazil, an absence of association between G6PD phenotypes and the number of previous episodes of malaria in men was reported [108]. However, in Ecuador, G6PDd prevalence was higher in provinces that were non-endemic for malaria, compared to endemic provinces, suggesting an ecological association between G6PDd and some degree of protection against P. falciparum[109]. Colombian individuals with a complete G6PD deficiency had a lower density of P. falciparum parasitaemia than persons without this condition [110]. In Colombia, the mean G6PD activity was lower, and G6PDd was more prevalent among men without P. vivax malaria than in those presenting with the disease [111]. In the Brazilian Amazon, where P. vivax predominates, G6PDd individuals were less likely to report the occurrence of malaria episodes after adjusting for age [42,43]. In the same area, the protective effect was related to the enzymatic activity, with carriers of the African variant presenting an 88% reduction and carriers of the Mediterranean variant presenting a 99% lower risk compared to non-deficient individuals [43].
G6PDd and metabolic disorders
The presence of metabolic disorders in G6PDd patients was investigated in three articles. Significantly lower insulin levels were observed for G6PDd Brazilian men compared to the controls in both the intravenous and oral tolerance tests [112]. In Mexico, two diabetic G6PDd individuals did not show cataracts, whereas cataracts were identified in six other diabetic patients [113]. In Brazil, the mean cortisol levels observed in the first hour after ACTH stimulation in the G6PD-deficient patients were significantly lower than in the control group [114].
Other findings
Other findings were mentioned in 10 original articles. A significant increase in methaemoglobinaemia was observed following oral therapy with PQ in patients with P. vivax presenting G6PDd [115,116]. Additionally, in Colombia, an association between haemolysis and physical exercise was observed in individuals with reduced G6PD activity [117]. In Brazil, G6PDd was suggested to contribute to haemolysis in patients with the viscerocutaneous form of loxoscelism, a condition produced by the bite of the recluse spiders of genus Loxosceles[118]. In Brazil, there have been reports of recurrent infections in children diagnosed with G6PDd [119,120]. In contrast, increased rates of urinary tract infections and neonatal jaundice were not substantiated among pregnant women from Puerto Rico, Dominican Republic, Mexico and other Caribbean areas living in the United States. However, the same authors reported increased rates of abortions, low-birth-weight infants and puerperal drops in red cell volumes in this population [64]. Transfusions of G6PDd blood that has been typed as the African variant seems to be safe, as a study carried out in Brazil had no reports of major haemolysis in recipients [121]. In Brazil, there was a lack of association between G6PDd and S. mansoni[122] and leprosy susceptibility [123].
Discussion
Mapping studies have demonstrated that P. vivax is more widely distributed than P. falciparum and that this species is a potential cause of morbidity and mortality amongst the 2.85 billion people living at risk of infection, most of whom live in Central and South East Asia and LA [124]. In LA and the Caribbean, most of the countries remain endemic for malaria. Only Chile, Uruguay, Cuba, Bahamas, Jamaica and other small countries in the Caribbean are now considered malaria-free. Mexico, Haiti, Costa Rica, El Salvador, Panama, Argentina and Paraguay are classified as ‘malaria-eliminating’ countries. The others are still in phases of control [125]. The predominance of vivax malaria in these countries is especially relevant because the radical cure of P. vivax infections requires the use of PQ, which can lead to acute intravascular haemolysis in G6PDd individuals, resulting in severe anaemia and acute renal failure [6]. The public health consequences of this condition deserve special attention due to the impossibility of using PQ in regions where there is a high prevalence of this deficiency, further hampering transmission control efforts for this parasite species [7]. Despite the clinical and epidemiological significance of the interaction between G6PDd and malaria, the extent of its clinical consequences has not been properly measured in LA populations. In countries such as Brazil, where PQ is systematically prescribed at a dose of 0.5 mg/kg/day for 7 days with chloroquine to all patients with microscopic confirmation of vivax malaria, the cumulative risk of adverse events in G6PDd patients could be even more relevant.
The most commonly reported clinical manifestations reported from LA countries were those related to AHA, namely drug-induced haemolysis. In patients with haemolytic anaemia, the reported frequency of G6PDd could be higher than 30% [24,26,126]. Favism and infection-induced haemolysis appear to play only a minor public health role in this continent. In general, in population-based studies carried out in regions where malaria is not endemic, individuals did not show a great risk of developing G6PDd-related haemolysis in their lifetimes [11-14,16,18,19], despite the establishment of an association between jaundice or history of haemolysis with G6PDd by some authors [16,17]. Another important finding in this context is the difficulty in linking G6PDd-related haemolysis with a specific stressor drug [20,22,23,25,26,126,127]. As reported, only a few sporadic haemolytic episodes were triggered by nalidixic acid, chloramphenicol, aspirin, salicylates, sulfadiazine, sulphazoxazole and nitrofurantoin and by naphthalene poisoning. These drugs or their metabolites are already known to be haemolysis triggers, most likely due to the production of free radicals, which in turn oxidize glutathione (GSH) and eventually lead to cell damage [128].
Most of the published works regarding drug-induced haemolysis in LA referred to haemolytic crises in patients diagnosed with P. vivax malaria during the course of the treatment with PQ. Reports of the need for red cell transfusions were common in these cases. In this continent, complications such as severe anaemia and renal failure also seem to be common and are of public health concern. Likewise, lethality was reported in the Brazilian Amazon, highlighting the impact on the local public health systems. Most strikingly, the results of two studies showed that the frequency of haemolysis in G6PDd patients was almost 90% [37,39]. Specifically, the most feared complication of PQ administration is the precipitation of haemolysis in G6PDd individuals. Other major PQ side effects that were identified in this review included methaemoglobinaemia, which again, mostly occurred among G6PDd patients. In this context, discontinuation of PQ treatment was observed in some countries, strongly suggesting that G6PDd in LA is hampering the transmission control efforts for P. vivax.
American countries contribute to 4.5% of the G6PDd male population from malaria endemic countries, corresponding to an estimated 10 million males, according to population data from 2010 [5]. Based on this estimation of G6PDd males living at risk of vivax malaria and consequently, of PQ-induced haemolysis, the number of AHA cases most likely is deeply underestimated, considering the literature data presented here. Firstly, this bias is likely related to a failure to recognize or properly diagnose AHA episodes among the malaria-affected population. In LA, malaria diagnosis and treatment are mostly made by technicians and only a few cases, especially complicated cases, are referred to tertiary-care centres. Accordingly, there is a lack of systematic diagnosis and surveillance of PQ-induced haemolysis in these countries, possibly leading to a significant proportion of under diagnosed cases. Secondarily, this lack of attention could lead to publication bias, as not many research groups are working in units linked to the tertiary health services located in malaria endemic areas. Therefore, published studies may not be truly representative of all of the information about G6PDd in LA, thus introducing a limitation to this systematic review.
This review points to the need for systematic testing of G6PDd in LA malaria endemic countries. Only with this result would it be possible to appropriately guide treatment, adjusting the PQ dosage or even contraindicating the drug, depending on the enzymatic activity of G6PD. The exposed population is extremely large in many endemic areas, and testing for G6PD status in all individuals would be a costly exercise, the cost-effectiveness of which remains to be evaluated. Furthermore, only a small number of investigations estimating G6PDd prevalence and the relative frequencies of the different genetic variants were carried out in LA malaria-endemic areas. Studies developed in the Brazilian Amazon found an estimated prevalence of 4%, with the African and Mediterranean variants predominating [43]. This review found that in publications from LA, PQ-induced haemolysis was only reported among males. This observation is in agreement with previous reports that clinically relevant G6PDd is much more common in males than in females because of the genetic nature of this condition. This result is of great significance for public health programmes because hemizygous females carrying G6PDd variants seem to be at reduced risk of PQ-induced haemolysis. The distinctive regional-specific character of the G6PDd clinical picture may help in the development of more targeted diagnostic approaches and PQ therapeutic strategies. In this regard, only testing the male population for G6PDd may be a more efficient and cheaper measure for minimising the risk of clinically relevant haemolysis after PQ administration in LA malaria-endemic areas.
A sound analysis on the role of the ethnicity in the geospatial distribution of G6PDd-related events was greatly impaired by the lack of information on ethnicity background for research subjects. It is known that global prevalence of G6PDd, and probably of its clinical manifestations, is geographically correlated with areas inhabited by populations historically exposed to endemic malaria, including Africa, Middle East, Mediterranean Europe and South-East Asia [5]. In this work, PQ-induced haemolysis predominated among admixed individuals, reflecting probably the ethnic composition of population living in P. vivax malaria endemic areas, and consequently the areas where PQ is prescribed, namely the Amazon. Favism was recorded in white individuals, in agreement with the literature that points that this is a condition typical of males of Mediterranean descent.
As previously demonstrated, the combination of G6PDd with the sickle cell trait was no more frequent than that expected by chance [129]. Several studies have shown that there are no significant differences in a variety of clinical and haematologic parameters between two otherwise comparable groups of patients with sickle cell anaemia, those with and without G6PD deficiency [130,131]. However, it must be borne in mind that acute intravascular haemolysis superimposed with chronic severe extravascular haemolysis is an added risk within this association. The combination of G6PDd with the β-thalassaemia trait has been found to cause a significant increase in mean corpuscular volume [132], although it remains below the normal range.
In LA, there are results suggesting that G6PDd prevalence could be a marker of the selective pressure exerted by malaria. The geographic distribution of G6PDd suggests that some polymorphisms confer resistance to falciparum malaria [5]. This phenomenon has been investigated mainly for the African variant, which has been shown to confer protection against lethal falciparum malaria [4]. In P. falciparum infections, it has been demonstrated that the shorter half-life and rapid clearance of red cells of G6PDd individuals make them less susceptible to malarial attacks from these parasites [133], and it is likely that a similar pathophysiological mechanism could occur in P. vivax-infected cells. However, there is a need to further explore and comprehend the mechanisms by which individuals with G6PDd are rendered less susceptible to infection. P. vivax preferentially invades reticulocytes, but P. falciparum can invade erythrocytes of all ages. This erythrocyte invasion is a significant phenomenon because G6PD activity is markedly reduced in older erythrocytes. Thus, red cells infected with P. vivax are most likely less vulnerable to the oxidant stress produced by the parasite. The precise mechanism by which G6PDd promotes reduced susceptibility to vivax malaria remains to be established.
Concluding remarks
Currently, the only drug available for the elimination of P. vivax hypnozoites is PQ. Tafenoquine is another drug of the same group that is being evaluated in clinical trials [134]. This unique therapeutic class of drugs is extremely useful in the control and eventually, in the elimination of malaria. However, in the absence of a rapid diagnostic test to detect G6PDd, the potential for toxicity in individuals with this condition limits the safe and effective use of such drugs because of the hazardous and even life-threatening side effects. Indeed, this work shows that haemolysis in patients using PQ is not infrequent and contributes to the morbidity of infection caused by P. vivax in LA, thus representing the major clinical complication of G6PDd in this continent. PQ-induced haemolysis was only reported in males, thus indicating that testing only this population for G6PDd may be a more efficient and cheaper measure for minimising the risk of clinically relevant haemolysis after PQ administration in LA malaria endemic areas.
It is likely that the real impact of G6PDd in terms of malaria-related complications has been heavily underestimated, and further research should be devoted to clarifying the real burden that these complications impose on the health systems. Finally, this study highlights the need to improve current strategies for diagnosing and managing G6PDd in malaria field conditions. Malaria control programmes in LA need to take this condition into serious account in their national guidelines if measures such as massive PQ administration are considered as part of regional malaria elimination agendas.
Abbreviations
AHA: Acute haemolytic anaemia; CHSA: Chronic non-sphaerocytic anaemia; G6PD: Glucose-6-phosphate dehydrogenase; G6PDd: Glucose-6-phosphate dehydrogenase deficiency; LA: Latin America; NNJ: Neonatal jaundice; PQ: Primaquine.
Competing interests
MVGL was one of the principal investigators of the multicentre tafenoquine phase II trial, which is funded by GSK. The other authors declare that they have no competing interests.
Authors’ contributions
WMM and MVGL conceived and designed the study. WMM and GPF performed a systematic review of the primary literature. WMM, GPF, ALMQ and GCM drafted the manuscript. MB, MRFO, HP, GASR. QB and MVGL directed the organisation and edited the manuscript. All authors read and approved the final version of the manuscript.
Supplementary Material
Contributor Information
Wuelton M Monteiro, Email: wueltonmm@ibest.com.br.
Gabriel P Franca, Email: gabrielpfranca@gmail.com.
Gisely C Melo, Email: cardosogisely@gmail.com.
Amanda LM Queiroz, Email: amandalmq@hotmail.com.
Marcelo Brito, Email: marceloambrito@gmail.com.
Henry M Peixoto, Email: henrymaiap9@gmail.com.
Maria Regina F Oliveira, Email: reginafernan@gmail.com.
Gustavo AS Romero, Email: romgustavo@gmail.com.
Quique Bassat, Email: quique.bassat@cresib.cat.
Marcus VG Lacerda, Email: marcuslacerda.br@gmail.com.
Acknowledgements
This study was supported by the Brazilian Council for Scientific and Technological Development (CNPq) (PRONEX Malaria; grant number 575788/2008-9) and the Amazonas Research Support Foundation (FAPEAM) (HEMOVIVAX; grant numbers 1027/2011 and 3140/2012). GASR received a visiting fellowship from the Strategic Program for Science, Technology & Innovation of FAPEAM (PECTI-SAÚDE). MVGL is a level 1 fellowship from the National Council for Scientific and Technological Development (CNPq). QB has a fellowship from the program Miguel Servet of the ISCIII (grant number: CP11/00269).
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