- Open Access
Glucose-6-phosphate dehydrogenase activity measured by spectrophotometry and associated genetic variants from the Oromiya zone, Ethiopia
- Nora Kießling†1,
- Joaquin Brintrup†2,
- Ahmed Zeynudin3,
- Nuredin Abduselam3,
- Sylvia Götz2,
- Margith Mack2,
- Michael Pritsch1, 4,
- Andreas Wieser1, 3, 4,
- Elisabeth Kohne†2 and
- Nicole Berens-Riha†1, 4Email authorView ORCID ID profile
© The Author(s) 2018
- Received: 29 June 2018
- Accepted: 8 October 2018
- Published: 12 October 2018
The study aimed to gain first data on the prevalence of G6PD enzyme deficiency measured by spectrophotometry and associated genetic variants in Jimma and surroundings, Ethiopia. The area is a Plasmodium vivax endemic region, but 8-aminoquinolines such as primaquine are not recommended as G6PD testing is not available.
Healthy volunteers were recruited at Jimma University, Ethiopia. Enzyme activity was tested by spectrophotometry at the University of Ulm, Germany. A G6PD RDT (Binax NOW® G6PD, Alere, USA) was additionally performed. The G6PD gene was analysed for polymorphisms in a sub-population. Tests for haemoglobinopathies and the presence of malaria parasites were conducted.
No severe or moderate (cut-off 60%) G6PD deficiency was found in 206 volunteers. Median male activity was 6.1 U/g Hb. Eleven participants (5.4%) showed activities between 70 and 80%. No haemoglobinopathy was detected. None of the subjects showed asymptomatic parasitaemia. One G6PD-A+ variant (A376G) and one new non-synonymous mutation (G445A) were found.
As the prevalence of G6PD deficiency seems low in this area, the use of 8-aminoquinolines should be encouraged. However, reliable G6PD testing methods have to be implemented and safe cut-off levels need to be defined.
Malaria is endemic in 75% of Ethiopia. For this parasitic disease, the predominant species is Plasmodium falciparum followed by Plasmodium vivax with regional variations. In Jimma zone, Southwestern Ethiopia, transmission is seasonal and unstable with a peak of infection after the rainy season in autumn. A study conducted by this group showed that 36–70% of the malaria infections in Jimma zone were caused by P. vivax, depending on the study location .
After the worldwide implementation of artemisinin-based-combination therapy (ACT), a general decline in falciparum malaria and a relative increase of vivax malaria was reported . For a long time, P. vivax malaria was considered a harmless form of malaria compared to P. falciparum . However, over the past few years, an increase of fatal and severe disease outcomes were described . As a single vivax infection can result in multiple episodes due to relapses caused by the liver stages (hypnozoites), treatment of the liver stage is essential for controlling the disease. Additionally, increasing resistance of P. falciparum to ACT resulted in a containment strategy including the treatment of gametocytes to stop spread of resistance . This strategy goes along with elimination efforts. The only recommended treatment by the World Health Organization (WHO) against P. vivax hypnozoites and P. falciparum gametocytes is the 8-aminoquinoline primaquine (PQ). A full 14-day course of primaquine (0.25 mg/kg/day) is required for radical cure of P. vivax, whereas a single-low-dose regimen is recommended for the elimination of P. falciparum gametocytes. The United States Food and Drug Administration (FDA) has now approved, under priority review, a single-dose regimen of tafenoquine for the radical cure of P. vivax in patients ≥ 16 years. Tafenoquine is a long-acting analogue of primaquine and as such an 8-aminoquinoline as well . Unfortunately, the use of 8-aminoquinolines is compromised by the potential haemolysis in individuals with the enzyme deficiency of glucose-6-phosphate dehydrogenase (G6PD). In consequence, enzyme activity testing of G6PD is essential before the administration of 8-aminoquinolines.
Affecting over 400 million people, it is one of the most common enzyme deficiencies in the world that is probably protective against malaria especially severe malaria outcomes . G6PD is an essential enzyme in the pentose phosphate pathway assuring normal oxidizing processes in the red blood cells (RBC). Although the inherited enzyme deficiency is mainly asymptomatic, it can cause neonatal hyperbilirubinaemia and chronical anaemia. The exposure to oxidative stress can provoke destruction of red blood cells and haemolysis, triggered by even small amounts of oxidants like primaquine, dapsone, paracetamol, fava beans and many more .
The size of the G6PD gene is 18.5 kB. It consists of 13 exons, 12 introns and is located on the long arm of the X-chromosome on the genloci Xq28. Over 217 Mutations have been characterized to date [9, 10]. Most of them are single base substitutions. The most common mutations described in Africa are A+, A− (202A) and Mediterranean. Non-synonymous mutations can cause different degrees of enzyme deficiency by activity or stability loss of the enzyme. As the gene is located on the X-chromosome, women are either homozygous deficient, heterozygous deficient (one gene encoding a normal enzyme and one gene encoding a deficient enzyme) or homozygous normal. The phenotype of heterozygous females varies between normal and deficient due to the X-chromosome inactivation in females expressing only one gene copy in each cell (mosaicism). Males are either hemizygous normal (normal phenotype) or hemizygous deficient (deficient phenotype) . A prevalence of 0.5–2.9% of G6PD deficiency in the male hemizygote population was generally assumed for Ethiopia [12, 13]. However, a recent study in Southwestern Ethiopia reported higher prevalence of G6PD deficiency of up to 14.3% depending on the ethnic group of the patient . A genetic study from Jimma detected A+ in 23.3% of the individuals and other uncommon mutations .
PQ is not part of the national Ethiopian policy as G6PD testing is not implemented at healthcare facility level. Population screening is recommended in regions with a G6PD deficiency prevalence ≥ 3–5% to guide decision-making for 8-aminoquinoline treatment in order to minimize the risk of drug-induced complications but population-based G6PD studies in Ethiopia are patchy .
This small study intended to collect first data on G6PD deficiency measured by spectrophotometry in combination with the analysis of associated genetic variants in healthy participants in Jimma zone. Test methods, procedures and logistics were additionally evaluated.
Recruitment and selection of samples
From March to June 2014, 206 participants without any life-threatening diseases and with unknown G6PD activity status were recruited on a voluntary basis at Jimma University, Ethiopia. Jimma is the capital of the Oromiya region and is situated 1780 m above sea level. Malaria is seasonal with higher prevalence from October to December (major peak) and from April to May (minor peak) .
The inclusion criteria for the G6PD study in Jimma were: age above 18 years, written informed consent, and permanent residency in the study area. The exclusion criteria involved acute or life-threatening illness, pregnancy and breastfeeding, simultaneous participation in another research study.
All data was reported and saved in specific questionnaires (Additional file 1) and transferred to an electronic data base via double entry. Questionnaires were regularly checked by the study coordinator and stored with restricted access. All study personnel had to sign a confidentiality agreement. Study results were communicated and explained to the participants and a G6PD card (Additional files 2, 3 and 4) with name and enzyme activity level was handed out. The study was approved by the ethical committee of the Jimma University and the Ludwig-Maximilians-University of Munich.
Venous blood was collected in 2.7 ml tubes containing ethylenediaminetetraacetic acid (EDTA), and following tests were performed within 6 h: the haemoglobin concentration in 15 μl blood was measured by rapid diagnostic test according to the manufacturer’s instructions (Haemocue AB, Ängelholm, Schweden). A thin (10 μl) and thick smear (10 μl) were prepared for microscopy. Rapid diagnostic tests for malaria (Binax NOW® Malaria, Alere, USA) and G6PD enzyme activity (Binax NOW® G6PD, Alere, USA) were performed according to the manufacturer’s instructions. Blood (6 × 15 µl) was dropped on filter papers (Whatman® No 3, Sigma-Aldrich, Germany) for molecular investigations of the G6PD gene, air-dried, packed in plastic bags and stored at − 20 °C. During transport the filter papers were stored at room temperature for a maximum of 48 h.
Determination of G6PD activity via G6PD rapid diagnostic test, BinaxNOW, Alere, USA
In brief, 10 µl of EDTA blood and 70 µl of lysis reagent (red dyed buffer) were mixed in a microcentrifuge tube. Afterwards 50 µl of the mixture were placed in the middle of the reaction pad of the test device. After 7 min the result could be read through the viewing window. All procedures were done between 18 and 25 °C and protected from direct light. The results were read visually and were evaluated as positive/G6PD-deficient when the colour did not change and stayed light red. Negative/non-deficient samples changed the colour into a brownish dark colour on the upper part of the reaction pad.
Determination of G6PD-activity via spectrophotometry
An EDTA tube was stored at 4 °C until shipment to the University of Ulm, Germany. Samples were shipped via DHL or transported directly by study staff. Samples were stored at ambient temperature during transport and were immediately processed after arrival in Ulm. In Ulm, spectrophotometry for G6PD was performed by trained laboratory technicians. Haemoglobin was again measured during the process.
G6PD enzymatic activity in erythrocytes was measured by the method of Löhr and Waller . A reaction mix of 1350 µl TRAP buffer (triethanolamine 50 mM, ethylenediaminetetraacetic acid 5 mM pH 7.5), 50 µl of magnesium chloride 1 M, 25 µl of haemolysate (0.9% w/v sodium chloride saline washed erythrocytes disrupted with a saturated solution of digitonine), 25 µl of NADP (nicotinamide-adenine-dinucleotide phosphate 30 mM) was started by finally adding 25 µl of G6P (glucose 6 phosphate, 50 mM). Photometric extinction rate compared to a blank without haemolysate was recorded at 37 °C. Results of the G6PD testing values were calculated in units per µMol metabolic rate/1011 erythrocytes/min (normal value: 30.5 ± 4.5). Activity was then converted into Units per g Haemoglobin (U/g Hb, Trinity Biotech for 37 °C at 366 nn, normal range 4.6–13.5 U/g Hb) by the following formula: (activity in μmol metabolic rate/1011 erythrocytes/min * RBC M/µL * 0.66)/Hb g/dL.
Primers used for sequencing
For each PCR product the respective exons were sequenced with specific primers (Table 1) by a Beckman Coulter CEQ 8800 Analyzer (Beckman Coulter CEQ 8800, DTCS Kit). Sequences were compared to GenBank Accession Number X55448.1
The thalassaemia screening was performed with hydragel electrophoresis with pH 8.6.
Questionnaire data and laboratory results were analysed by using Stata 14 (Statacorp, College Station, USA). Relevant continuous data were summarized by the following parameters: range, median and quartiles or mean and standard deviation if normally distributed. Categorical data are presented in contingency tables with frequencies and percentages of each value. The G6PD median activity value for normal males was calculated as previously described . For the adjusted median activity, males with severe G6PD deficiency defined as ≤ 10% of the G6PD median value have to be excluded. Different cut-off levels of activity were defined according to previous recommendations (i.e., 10%, 30%, 70% and 80%). Individuals were classified as G6PD-deficient or normal based on these levels. Correlations were calculated by linear regression models.
The confidence level was 0.3–5.7%, if a prevalence of 3% in the male population was assumed and a sample size of 150 male participants and a confidence level of 95% were chosen. The power was 91% to detect between 1 and 6 cases if the prevalence was 3%. To compensate possible decay or other problems with some samples, the collection of 160 male samples was planned.
General information, n = 206
Female, n (%)
Age in years, median (IQR)
22 (21; 24)
Origin, n (%)
Oromiya zone (w/o Jimma Town)
Malaria positive, n (%)
Haemoglobin in g/dl, median (range)
Haemoglobin, male in g/dl, median (range)
Anaemia, male (< 14 g/dl), n (%)
High haemoglobin, male (> 18 g/dl), n (%)
Haemoglobin, female in g/dl, median (range)
Anaemia, female (< 12 g/dl), n (%)
High haemoglobin, female (> 16 g/dl), n (%)
None of the participants had fever or any relevant disease. Two subjects reported malaria in the medical history. No participant reported known G6PD deficiency or haemolytic crises in the medical history. Side effects after drug intake were reported for norfloxacin (1), ciprofloxacin (1), quinine (1), erythromycin (1), amoxicillin (2), cotrimoxazole (1), but could not further be specified.
The median haemoglobin (Hb) for males and females was 17.1 (range 14.2–23.3) g/dl and 14.3 (11.9–23.0) g/dl, respectively (Table 2). There was only one slightly anaemic female in the whole population (11.9 g/dl). 23.0% of the males and 11.6% of the females showed elevated Hb levels. The mean Hb measured in Jimma directly by HemoCue (Haemocue AB, Ängelholm, Schweden) was 16.4 g/dl (95% CI 16.08–16.69) compared to 16.9 g/dl (95% CI 16.65–17.23) measured in Ulm. For further calculations, the Hb values measured in Ulm were used.
No asymptomatic parasitaemia was detected by rapid test or microscopy.
No thalassaemia or any known haemoglobinopathy were found.
Determination of G6PD activity
Reference values for G6PD activity in the study population
G6PD activity in μmol metabolic rate/1011 erythrocytes/mina; in U/g Hbb
All (n = 204)
Male (n = 163)
Female (n = 41)
(26.9; 32.0); (5.6; 6.7)
(26.9; 32.3); (5.6; 6.6)
(27.2; 31.9); (6.0; 6.9)
G6PD genotypes and associated G6PD activity values of 34 sequenced samples
G6PD activity in μmol substrate/1011 erythrocytes/mina
G6PD activity in U/g Hbb
G6PD activity in %d
Origin (malaria endemic ±)
There was no difference between the gender and spectrophotometry results measured in μmol metabolic rate/1011 erythrocytes/min (p = 0.7922). Measured in U/g Hb, women (6.4 U/g Hb) had significantly higher values of enzyme activity than men (6.1 U/g Hb; p = 0.0315).
Storage time and G6PD activity in U/g Hb, n = 204
Time in days from blood drawing to spectrophotometry
Median G6PD activity in U/g Hb [IQR]
5.9 [5.0; 6.3]
6.2 [5.6; 6.8]
5.9 [5.3; 6.3]
6.4 [6.1; 6.8]
5.4 [4.5; 6.3]
6.1 [5.6; 6.6]
6.2 [5.5; 6.8]
5.9 [5.5; 6.7]
6.5 [6.1; 7.0]
6.4 [5.7; 7.4]
6.1 [5.7; 6.4]
6.1 [5.5; 6.4]
6.1 [5.5; 7.0]
6.3 [5.6; 6.9]
G6PD rapid test
The RDT showed negative (= normal) results for all samples. The false positive rate was 0%. There was no discrimination between lower and higher values in this study group. All samples with slightly diminished but normal enzyme activity (70–80%) in spectrophotometry indicated normal activity by RDT. The two control samples from the University of Ulm with severe deficiency (< 10% enzyme activity) were correctly discriminated.
Mutations of the g6pd gene found in the study population
Amino acid substitution
A → G
G → A
The median activity in the study population was 6.1 U/g Hb (range 4.3–10.8 U/g Hb). No activity below 70% or 4.27 U/g Hb could be detected. A prevalence of 0.5–2.9% of G6PD deficiency in the male hemizygous population is generally assumed for Ethiopia. In comparison, prevalence of G6PD deficiency in the male population in other African countries are reported as follows: Somalia: 0.5–2.9%, Sudan: 7.0–9.9%, Uganda, Kenya: 10.0–14.9%, Tanzania, Congo, Gabon and Cameroon: 15.0–26.0% [12, 13]. As Tsegaye et al. published before, the prevalence of G6PD deficiency in Gambella, Ethiopia, varied between ethnic groups. Overall prevalence of G6PD deficiency measured by CareStart™ G6PDd screening test (Access Bio, Inc., New Jersey, USA) was 7.3%. Gambella is low land area (300–500 m above sea level) characterized by high malaria transmission. They reported high prevalence among the indigenous group of Nuer (14.3%) and Anuak (12.0%) in rural areas and no deficiency in 46 patients from Oromiya . This corresponds to the 0% prevalence in the presented study. Patients from other “highland” regions like Amhara, Hadya and Tigre showed also no deficiencies . According to genetic studies, the Oromo and Amhara people appear more similar to Europoids (particularly to the South Arabians) and quite different from the Negritic people. Intermixture of Europoid and Negritic populations seem to have resulted in the present day Cushitic (and Semitic)-speaking group of eastern Africa .
As there are no other studies published from Ethiopia measuring the G6PD activity by spectrophotometry, a local comparison of the median level in U/g Hb had to be omitted. A study from the US examining participants with Afro-American origin reported a median G6PD activity of 7.30 U/g Hb. Male median was unadjusted 7.06 and adjusted 7.18, female median was 7.70 U/g Hb . The female median was higher than the male. This is in accordance to the results here. Measured in U/g Hb, women (6.4 U/g Hb) had significantly higher values of enzyme activity than men (6.1 U/g Hb; p = 0.0315) as the haemoglobin value differed significantly (p < 0.0001) between the sexes, with women having lower Hb levels than men. There was no difference between the sexes when the enzyme activity was expressed in μmol metabolic rate/1011 erythrocytes/min.
In another study from Bangladesh with 999 participants, the adjusted male median derived by spectrophotometry was 7.03 U/g Hb . Compared to the two studies above, the overall median in the presented study was lower. Several reasons are possible. The conversion formula used is an approximation only. Furthermore, G6PD testing in the field poses many challenges to the study team. Loss of enzyme activity during the process cannot be excluded. As Ley and colleagues point out, the duration between blood collection and spectrophotometry and the storage conditions in between are the crucial factors to maintain a stable enzyme activity .
G6PD enzyme activity and degradation are temperature dependent, EDTA blood should be cooled at least at 4–8 °C. The possible duration without loss of activity is unknown . One study reports a loss of a maximum of 5% of activity after 21 days storage at 4 °C . However, others report loss of activity of 15–21% after 21 days, 6% after 7 days and 40% after 7 days at 4 °C . Cryopreservants and storage at − 80 °C  or replacing plasma with an additive  are recommended.
The samples of this study were constantly cooled at 4 °C until shipment. Transport via DHL express (4–7 days) or by study members (2 days) was at ambient temperature. Shipment via DHL was problematic due to logistical problems and customs issues and cannot be safely recommended. Overall mean storage time was 12.2 days (SD 5.2, range 4–21 days). Storage duration and G6PD activity levels showed no evident correlation to indicate a systematic significant loss of activity over time. Haemolysis and significant loss of enzyme activity was only suspected in two samples with overall low activities for nine measured control enzymes and a storage time of 14 and 19 days. Median G6PD activity in samples stored 14 and 19 days was 6.5 and 6.1 U/g Hb, respectively.
Assuming a normal male median of 7.0 U/g Hb [19, 21] a median of 6.1 U/g Hb would mean a loss of 13% in enzyme activity. The real absolute values in the study could be slightly higher than the presented values. On the other hand, the haemoglobin level was relatively high with 17.1 g/dl for males and 14.3 g/dl for females. Twenty percent of the study population had elevated haemoglobin levels. All participants, though originating from different villages, were living in Jimma town that is situated at 1780 m above sea level. Higher haemoglobin levels result in lower G6PD values as the calculation with the formula used is haemoglobin-dependent. The two studies cited above presented no haemoglobin levels for comparison but were conducted with participants living at sea level [19, 21]. In conclusion, activity loss cannot be excluded but relevant loss seems unlikely; relative values in per cent should not be affected in any way.
Genotyping of the G6PD gene revealed two mutations in the small sub-population. The G6PD-A+ mutation (A376G) was found in one male (2.9%). Enzyme activity was 4.3 U/g Hb (70.5%). He reported an intolerance to norfloxacin that was not further specified but no haemolysis was reported in the medical history. G6PD-A−, the combination of A376G and G202A, and C563T (G6PD-Mediterranian) are common variants in Africa, the Mediterranean region and the Middle East but G202A and C563T could not be found in this study. This is in accordance with another study from Southwestern Ethiopia, Malo, genotyping 555 samples for G202A and C563T. None of the variants were detected . A recent paper reported G6PD genetic variants in malaria patients from Jimma zone . They found G6PD-A+ in 23.3% of the 86 individuals whereas G202A and C563T were absent. They reported other mutations: G535A in two females and two additional mutations in the intronic region in one male (485 + 37 G → T, rs370658483, chrX: 154535131).
While G6PD-A+ is usually regarded as variant with normal enzyme function, G6PD-A− was associated with a milder degree of enzyme deficiency. However, recent reports suggest that G6PD-A− was associated with severe illness after administration of primaquine [25, 26]. Primaquine sensitivity has only been reliably characterized for the variants Mediterranean and Mahidol with severe and moderate degrees of sensitivity to primaquine, respectively . The second mutation that was observed in this study was the substitution G445A. The male participant showed an enzyme activity of 75.4%. He originated directly from Jimma town. This variant was not observed before.
Considering the results presented, would there be any consequences concerning radical cure of P. vivax for the subjects of the study? A generally adopted method and its corresponding cut-off for G6PD deficiency would simplify comparison and implementation of standards. The recommended thresholds concerning malaria treatment are indicated in percent. PQ treatment for radical cure in vivax malaria (0.25–0.5 mg/kg/day for 14 days) should not be given in individuals with G6PD activity below 30% of the adjusted male median (AMM). This level excludes severe deficiency and seems safe to discriminate homozygous females and hemizygous men from heterozygous females or variants causing only moderate deficiency . For the long-acting tafenoquine, the recommended threshold in the approval studies was 70% of the AMM for all participants and 90% for anaemic females (7–10 mg/dL)  to exclude moderate deficiencies.
According to the WHO, heterozygote females are classified in activity levels of < 30%, 30–80% and > 80% correlating in a deficient, intermediate or normal phenotype, respectively. Sensitivity to primaquine seems possible in heterozygote females with the intermediate phenotype and unlikely in heterozygote females with the normal phenotype . Eleven patients showed activities between 70 and 80% of the male median in this study: three females and eight men with the normal genetic variant and two hemizygote men with the stated mutations above. Both showed a borderline intermediate phenotype. Sensitivity to 8-aminoquinolines seems at least possible.
If the above-mentioned thresholds of 30% for PQ and 70% for tafenoquine are used, both regimens could be administered to the study population. However, the males with the G6PD variants should be treated with caution and closely monitored. There is few or no information about 8-aminoquinoline sensitivity concerning these mutations.
From a clinician’s perspective, a cut-off of 80% would prevent any possible, probably mild harm in two cases (1.0%) but nine healthy patients (4.4%) would miss the valuable radical cure. From a public health point of view, this approach lacks efficiency and a lower cut-off should be considered, but a general recommendation to treat without testing in this population would be irresponsible as the study population is not representative enough to safely exclude severe deficiency. However, in absence of a better drug the low prevalence of G6PD deficiency should encourage further malaria elimination efforts in this area, as the chances of an effective and broadly applicable use of 8-aminoquinolines are high.
No parasitaemia was found by RDT or microscopy in this study. Recruitment was between March and May during and after the smaller rainy season. A recent study from rural Southwestern Ethiopia conducted in a similar mountainous region with seasonal malaria found asymptomatic sub-microscopic parasitaemia with P. falciparum in 5.2%, P. vivax in 4.3% and mixed infection in 0.2% of 555 individuals by PCR . Microscopy and RDT were negative in all samples. Therefore, sub-microscopic parasitaemia cannot be excluded in the underlying study group although probability seems lower as all participants lived in Jimma town in contrast to rural areas. Microscopy and RDT (Binax NOW® Malaria, Alere, USA) correlated well so far.
Evaluation of the G6PD RDT (Binax NOW® G6PD, Alere, USA) was impossible due to the small sample size in combination with zero prevalence of deficiency. Discrimination of slightly diminished enzyme activity (70–80%) and normal activity was impossible as expected.
The low prevalence of G6PD deficiency was unsurprising as individuals originating mainly from a highland area of Ethiopia were investigated. Though, genetic variants with enzyme activity between 70 and 80% could be detected. The zero prevalence of severe deficiency might not encourage population-based screening studies or routine screening projects of newborns for G6PD deficiency. However, routine screening for G6PD deficiency during a malaria infection should be implemented in vivax endemic areas to enable the administration of the relatively cheap radical cure regimen that would enormously booster elimination efforts. Administration of 8-aminoquinolines in G6PD-A− and G6PD-A+ individuals and others with common variants should be further investigated to safely determine a feasible and safe cut-off. At the moment, the cut-off of 70% for tafenoquine is only safely measurable by spectrophotometry. The G6PD RDT was unable to discriminate at this cut-off and seems only valuable for excluding severe deficiency.
The WHO recommends incorporation of G6PD testing into national guidelines and available services possibly with referral of patients from lower to higher level health facilities where both G6PD testing and radical cure can be provided . As a first step, spectrophotometry could be introduced at Jimma University and other high-level healthcare facilities and radical cure offered in their out-patient departments and hospitals. A referral system could be developed in the future. Health facilities in rural areas could benefit from new field-approved alternatives that have to be enhanced and evaluated. Cheap discrimination tests to exclude severe deficiency could be an interim solution as other drugs than 8-aminoquinolines can cause haemolytic crises in case of deficiency.
In this study, participants received a G6PD card explaining their individual enzyme activity. The attractiveness of genetic tests is based on the fact that a patient once tested and familiar with the test result has not to be tested twice.
NK was responsible for the recruiting, the collection of blood and questionnaire data and performed all laboratory tests in Jimma. She organised shipment of the samples to Germany. She entered the data in the data bank and assisted in drafting the manuscript. JB performed genotyping of the samples and assisted in drafting the manuscript. AZ was supervising the recruitment and the laboratory work in Jimma and assisted with the ethical clearance in Jimma. NA and WA were assisting with the recruitment and laboratory performance in Jimma and handed out the G6PD Cards. SG and MM were performing the spectrophotometry and the haemoglobin screening in Ulm. MP assisted in drafting the study and the manuscript. AW was supervising logistics and laboratory work in Jimma and assisted with the ethical clearance in Jimma. NBR designed the study and drafted the manuscript, she was responsible for the ethical clearance in Munich and supervised all processes of the study. She cleaned the data and performed the statistical analysis. EK assisted in drafting the manuscript and supervised all test performances in Ulm. All authors read and approved the final manuscript.
We thank the health personnel were involved in the study and the staff of the parasitological Department at Jimma University Hospital for support and assistance and participating patients for their cooperation. Financial support was received from the University of Munich through an internal grant and studentship (FöFoLe 57/2013).
The authors declare that they have no competing interests.
Availability of data and materials
The datasets used and/or analysed during the current study are available upon reasonable request from the corresponding author.
Ethics approval and consent to participate
The study was reviewed and approved by the ethical committee of the Jimma University and the Ludwig-Maximilians-University of Munich. Written informed consent was given prior to enrolment.
Financial support was received from the Ludwig-Maximilians-University of Munich through an internal grant and studentship (FöFoLe). The content of this manuscript is the sole responsibility of the authors.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
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- Eshetu T, Abdo N, Bedru KH, Fekadu S, Wieser A, Pritsch M, et al. Open-label trial with artemether–lumefantrine against uncomplicated Plasmodium falciparum malaria three years after its broad introduction in Jimma Zone, Ethiopia. Malar J. 2012;11:240.View ArticleGoogle Scholar
- Bousema T, Drakeley C. Epidemiology and infectivity of Plasmodium falciparum and Plasmodium vivax gametocytes in relation to malaria control and elimination. Clin Microbiol Rev. 2011;24:377–410.View ArticleGoogle Scholar
- Hay SI, Guerra CA, Tatem AJ, Noor AM, Snow RW. The global distribution and population at risk of malaria: past, present, and future. Lancet Infect Dis. 2004;4:327–36.View ArticleGoogle Scholar
- Naing C, Whittaker MA, Wai VN, Mak JW. Is Plasmodium vivax malaria a severe malaria?: a systematic review and meta-analysis. PLoS Negl Trop Dis. 2014;8:e3071.View ArticleGoogle Scholar
- WHO. World malaria report 2016. Geneva: World Health Organization; 2016. http://www.who.int/malaria/publications/world-malaria-report-2016/report/en/. Accessed 29 Jan 2017.
- WHO. Guidelines for the treatment of malaria 2015. Geneva: World Health Organization; 2015. http://www.who.int/malaria/publications/atoz/9789241549127/en/. Accessed 11 Sept 2015.
- Ley B, Bancone G, von Seidlein L, Thriemer K, Richards JS, Domingo GJ, et al. Methods for the field evaluation of quantitative G6PD diagnostics: a review. Malar J. 2017;16:361.View ArticleGoogle Scholar
- Luzzatto L, Seneca E. G6PD deficiency: a classic example of pharmacogenetics with on-going clinical implications. Br J Haematol. 2014;164:469–80.View ArticleGoogle Scholar
- Gómez-Manzo S, Marcial-Quino J, Vanoye-Carlo A, Serrano-Posada H, Ortega-Cuellar D, González-Valdez A, et al. Glucose-6-phosphate dehydrogenase: update and analysis of new mutations around the world. Int J Mol Sci. 2016;17:e2069.View ArticleGoogle Scholar
- Minucci A, Moradkhani K, Hwang MJ, Zuppi C, Giardina B, Capoluongo E. Glucose-6-phosphate dehydrogenase (G6PD) mutations database: review of the “old” and update of the new mutations. Blood Cells Mol Dis. 2012;48:154–65.View ArticleGoogle Scholar
- Cappellini MD, Fiorelli G. Glucose-6-phosphate dehydrogenase deficiency. Lancet. 2008;371:64–74.View ArticleGoogle Scholar
- WHO. Glucose-6-phosphate dehydrogenase deficiency. WHO Working Group. Bull World Health Organ. 1989;67:601–11.Google Scholar
- Howes RE, Piel FB, Patil AP, Nyangiri OA, Gething PW, Dewi M, et al. G6PD deficiency prevalence and estimates of affected populations in malaria endemic countries: a geostatistical model-based map. PLoS Med. 2012;9:e1001339.View ArticleGoogle Scholar
- Tsegaye A, Golassa L, Mamo H, Erko B. Glucose-6-phosphate dehydrogenase deficiency among malaria suspects attending Gambella hospital, southwest Ethiopia. Malar J. 2014;13:438.View ArticleGoogle Scholar
- Carter TE, Mekonnen SK, Lopez K, Bonnell V, Damodaran L, Aseffa A, et al. Glucose-6-phosphate dehydrogenase deficiency genetic variants in malaria patients in Southwestern Ethiopia. Am J Trop Med Hyg. 2018;98:83–7.View ArticleGoogle Scholar
- WHO. Guidelines for the treatment of malaria 2010. Geneva: World Health Organization; 2010. http://apps.who.int/medicinedocs/en/d/Js19105en/. Accessed 8 Mar 2018.
- Löhr GW, Waller HD. Glucose-6-phosphat-dehydrogenase (Zwischenferment). In: Bergmeyer HU, editor. Methoden der enzymatischen Analyse. Weinheim: Chemie-Verlag; 1962. p. 744–51.Google Scholar
- Kahn M, LaRue N, Zhu C, Pal S, Mo JS, Barrett LK, et al. Recombinant human G6PD for quality control and quality assurance of novel point-of-care diagnostics for G6PD deficiency. PLoS ONE. 2017;12:e0177885.View ArticleGoogle Scholar
- LaRue N, Kahn M, Murray M, Leader BT, Bansil P, McGray S, et al. Comparison of quantitative and qualitative tests for glucose-6-phosphate dehydrogenase deficiency. Am J Trop Med Hyg. 2014;91:854–61.View ArticleGoogle Scholar
- Tartaglia M, Scano G, De Stefano GF. An anthropogenetic study on the Oromo and Amhara of central Ethiopia. Am J Hum Biol. 1996;8:505–16.View ArticleGoogle Scholar
- Ley B, Alam MS, O’Donnell JJ, Hossain MS, Kibria MG, Jahan N, et al. A comparison of three quantitative methods to estimate G6PD activity in the Chittagong Hill Tracts, Bangladesh. PLoS ONE. 2017;12:e0169930.View ArticleGoogle Scholar
- Kahn M, Ward WH, LaRue N, Kalnoky M, Pal S, Domingo GJ. Maintaining specimen integrity for G6PD screening by cytofluorometric assays. J Histochem Cytochem. 2015;63:454–8.View ArticleGoogle Scholar
- Kahn M, LaRue N, Bansil P, Kalnoky M, McGray S, Domingo GJ. Cryopreservation of glucose-6-phosphate dehydrogenase activity inside red blood cells: developing a specimen repository in support of development and evaluation of glucose-6-phosphate dehydrogenase deficiency tests. Malar J. 2013;12:286.View ArticleGoogle Scholar
- Tadesse FG, Pett H, Baidjoe A, Lanke K, Grignard L, Sutherland C, et al. Submicroscopic carriage of Plasmodium falciparum and Plasmodium vivax in a low endemic area in Ethiopia where no parasitaemia was detected by microscopy or rapid diagnostic test. Malar J. 2015;14:303.View ArticleGoogle Scholar
- Pamba A, Richardson ND, Carter N, Duparc S, Premji Z, Tiono AB, et al. Clinical spectrum and severity of hemolytic anemia in glucose 6-phosphate dehydrogenase-deficient children receiving dapsone. Blood. 2012;120:4123–33.View ArticleGoogle Scholar
- Shekalaghe SA, ter Braak R, Daou M, Kavishe R, van den Bijllaardt W, van den Bosch S, et al. In Tanzania, hemolysis after a single dose of primaquine coadministered with an artemisinin is not restricted to glucose-6-phosphate dehydrogenase-deficient (G6PD A−) individuals. Antimicrob Agents Chemother. 2010;54:1762–8.View ArticleGoogle Scholar
- von Seidlein L, Auburn S, Espino F, Shanks D, Cheng Q, McCarthy J, et al. Review of key knowledge gaps in glucose-6-phosphate dehydrogenase deficiency detection with regard to the safe clinical deployment of 8-aminoquinoline treatment regimens: a workshop report. Malar J. 2013;12:112.View ArticleGoogle Scholar
- Green J. GSK, Tafenoquine & G6PD, HCMC 28 of November 2011. Power Point Presentation. http://sites.path.org/dx/files/2012/11/01_Green_Tafenoquine.pdf. Accessed 16 Mar 2018.
- WHO. Testing for G6PD. Geneva: World Health Organization; 2016. http://www.who.int/malaria/publications/atoz/WHO-testing-for-G6PD-2016-presentation.pdf. Accessed 28 Sept 2018.