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. Author manuscript; available in PMC: 2019 Jan 1.
Published in final edited form as: Pediatr Blood Cancer. 2017 Aug 17;65(1):10.1002/pbc.26745. doi: 10.1002/pbc.26745

Lack of mortality in 22 children with sickle cell anemia and severe malarial anemia

Robert O Opoka 1, Paul Bangirana 2, Richard Idro 1, Estela Shabani 3,4, Ruth Namazzi 1, Chandy C John 3,4
PMCID: PMC6072279  NIHMSID: NIHMS973182  PMID: 28834130

Abstract

Retrospective studies suggest that there is high mortality in children with sickle cell anemia (SCA) and severe malaria. We assessed mortality in Ugandan children with severe malarial anemia (SMA, n= 232) or cerebral malaria (CM, n= 267) by HbS genotype. Admission and 2-year follow-up mortality did not differ among children with SMA who had HbSS vs HbAA (admission, 0/22, 0%, vs. 1/208, 0.5%; follow-up, 1/22, 4.5%; 7/207, 3.4%, respectively, all P>0.6). The single child with CM and HbSS survived. The study findings highlight the need for large prospective studies of malaria-related mortality in children with SCA.

Keywords: severe malaria, sickle cell disease, mortality

Introduction

Sickle cell hemoglobin (HbS) is the most common pathological hemoglobin variant worldwide (1). Heterozygotes (HbAS) are usually asymptomatic and protected against malaria (2, 3), whereas homozygotes (HbSS, sickle cell anemia, SCA) are prone to end organ damage (46) and, in many parts of sub-Saharan Africa, early death (4). Children with HbSS may not have an increased risk of developing malaria, but two studies with small numbers of children with SCA and severe malaria (n=5 and n=21, respectively) suggest they have a high mortality rate with severe malaria (7, 8). To further address the question of mortality with severe malaria in children with SCA, we compared risk of inpatient and follow-up mortality according to HbS genotype in a prospectively enrolled cohort of children with severe malaria (cerebral malaria [CM] or severe malarial anemia [SMA]) and healthy community controls (CC).

Methods and Results

Study participants

The study was carried out at Mulago National Referral Hospital in Kampala, Uganda. All participants were enrolled in a study assessing neurodevelopmental impairment in severe malaria, conducted from November 2008 to December 2013. Details of the methods of the primary study including inclusion criteria and study enrollment are described elsewhere (9). Briefly, children 18 months – 12 years of age were enrolled. CM was defined as a child with unarousable coma and Plasmodium falciparum parasitemia on blood smear. SMA was defined a child with a hemoglobin level ≤ 5 g/dL and P. falciparum parasitemia on blood smear. Community children were healthy children from the neighborhoods of children with severe malaria children. Children with known chronic disease, including known SCA, were excluded.

Clinical management

Children with CM or SMA were managed according to Ugandan Ministry of Health treatment guidelines for malaria, which at time of study included intravenous quinine treatment followed by oral quinine. All children with SMA received a blood transfusion (20ml/kg of whole blood or 10ml/kg of packed red blood cells), usually within 2 hours of admission.

Follow up

Study participants were followed up for 2 years after discharge from hospital to assess for illness, including malaria, readmissions and deaths.

HbS testing

Genomic DNA was isolated from whole blood samples for SMA & CM patients or filter papers for CCs using the DNeasy Blood and tissue kit (Qiagen, Valencia, CA). The beta hemoglobin region of interest was amplified using specific primers. Children with HbSS were referred to the Mulago Hospital Sickle Cell Clinic, and HbSS was confirmed by hemoglobin electrophoresis.

Statistical analysis

Analysis was done in STATA 12 (Stata Corporation). Proportions were compared with χ2 analysis and mean or median values with Student’s t-test or the Wilcoxon rank-sum test, respectively. Incidence rates were compared between groups by negative binomial regression.

Ethical review

Written informed consent was obtained from parents or guardians of study participants. Institutional Review Boards for human studies at Makerere University and the University of Minnesota granted ethical approval for the study.

Admission findings

267 children with CM, 232 children with SMA and 216 CC were enrolled and had samples available for HbS genotyping. HbAS was more frequent in CC (41, 19.0%) than in SMA (2, 0.9%) or CM (2, 0.8%), confirming the protective effect of HbAS against severe malaria. HbAS as compared to HbAA reduced the risk of severe malaria (SMA or CM) by 96% (odds ratio, [OR], 0.04, 95% confidence interval (CI), 0.01, 0.10). HbSS was more frequent in SMA (22, 9.5%) than CM (1, 0.4%) and was not present in CC. HbSS as compared to HbAA increased risk of SMA 28-fold (OR 27.9, 95% CI, 3.7, 208.7).

Among children with SMA, children with HbSS were older and had a higher white blood count than children with HbAA, however P. falciparum parasite density was similar in the two groups (Table 1). Among children with SMA, mortality did not differ between children with HbSS (0%) and children with HbAA (0.5%, Table 1). The one child with CM and HbSS survived.

Table 1.

Demographic and clinical characteristics of children with severe malarial anemia, according hemoglobin AA (HbAA) or hemoglobin SS (HbSS) genotype

HbAA, n=208 HbSS, n=22 P valuee
Age, mean (SD) 2.7 (2.0, 4.1) 4.6 (3.7, 5.7) 0.007
Sex, n male (%) 127 (61.1%) 13 (59.1%) 0.86
Hemoglobin, g/dL, mean (SD) 3.7 (0.9) 3.7 (0.6) 0.38
WBC, mean (SD) 12.9 (8.2)a 32.7 (16.0) < 0.001
Thrombocytopenia, n (%) 109 (52.9%)a 8 (36.4%) 0.14
P. falciparum parasite density, parasites/µL, median (25th, 75th percentile) 49,813b (14,678, 229,046) 41,586c (2,261, 140,672) 0.18
Required oxygen, n (%) 19 (9.1%) 1 (4.6%) 0.47
Blood culture, n positive (%) 22 (12.4%)d 1 (5.6%)d 0.39
Given antibiotics, n (%) 63 (30.3%) 10 (45.5%) 0.15
Death, n (%) 1 (0.5%) 0 (0%) 0.56
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WBC, white blood cell count; thrombocytopenia = platelet count < 100,000/µL

a

n for HbAA =206,

b

n for HbAA = 205,

c

n for HbSS = 21

d

n for HbAA = 177, n for HbSS = 18

e

Continuous variables compared by Student’s t-test except P. falciparum parasite density, compared by Wilcoxon rank-sum test. Categorical variables compared by χ2 analysis.

Follow up

Among CM survivors, 2/234 children (0.9%) died during 2-year follow-up. Both had HbAA. Among SMA survivors, 9 children (3.9%) died during follow-up, 1/22 with HbSS (4.6%), 7/207 with HbAA (3.4%, P=0.77) and 1/2 with HbAS (50%). Compared to children with SMA and HbAA, children with SMA and HbSS had significantly higher incidence of post-discharge readmissions and a higher incidence of uncomplicated malaria that approached significance (P=0.06), but incidence of severe malaria readmissions did not differ significantly between children with HbSS and HbAA (Table 2).

Table 2.

Deaths, readmissions and outpatient clinic visits for children with SMA and HbAA or HbSS during 2-year follow up

HbAA
N= 207		 HbSS
N= 22		 P value
Died, n (%) 7 (3.4%) 1 (4.5%) 0.77a
Incidence of death per 1000 person years 17.29 25.36 0.33b
Incidence of all cause readmissions per 1000 person years 51.89 126.81 0.05b
Incidence of severe malaria readmissions per 1000 person years 42.01 25.36 0.35b
Incidence of uncomplicated malaria visits per 1000 person years 106.26 202.90 0.06b
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Children with HbAS not shown because of low numbers (n=2)

a

Compared by χ2 analysis

b

Incidence rates compared by negative binomial regression.

Discussions

We found, in contrast to previous studies (7, 8), that children with SCA did not have increased inpatient mortality with severe malaria compared to children with HbAA. Even post-discharge mortality in children with HbSS and severe malaria did not differ significantly from that of children with HbAA (4.5% vs. 3.6%, P=0.77), though incidence of all-cause readmissions was higher with HbSS. The findings bring in to question whether children with HbSS have an increased risk of mortality with severe malaria compared to children with HbAA. The findings must be interpreted with caution as the study did not include children with known SCA at the time of admission, and all children were >18 months of age, both factors which could select for a healthier population of children with SCA, as children with SCA in this setting are reported to have significant morbidity and mortality in the first 2 years of life (10, 11).

Previous studies have shown that if blood transfusion service is readily available, as was the case in this study, mortality in SMA is generally low (12, 13). In the present study, this was the case regardless of the presence of concurrent SCA. Prior studies of severe malaria in children with SCA have shown a range of mortality: from 4/86 (4.6%) (14) to 2/21 (9.5%) (8) of children with SCA admitted with parasitemia to 4/5 children (80%) admitted with WHO criteria for severe malaria (7). In the only other study assessing mortality in children with SMA and SCA, SMA was the primary complication of malaria, and none of the 38 children with SMA and SCA died (0% mortality) (14), a finding identical to the present study. Sample sizes of children with both severe malaria and SCA have been small in all studies, emphasizing the need for large prospective studies of malaria morbidity and mortality in SCA. However, studies such as the present study, in which children with severe malaria are assessed for SCA, are another way of getting at the question, as these studies may “enrich” for children with severe malaria, which appears to be a relatively uncommon complication of SCA.

In conclusion, our study findings suggest that in children >18 months of age with SCA, inpatient mortality from SMA, the most common form of severe malaria, is low and similar to that of children with HbAA if timely blood transfusion is provided, and that post-discharge mortality in children with SMA is also similar in children with HbSS vs. HbAA. However, the exclusion of children with known SCA is an important study limitation, as is the limited study sample size. Therefore, the present study is a call for large prospective studies of malaria morbidity and mortality in children with SCA to definitively address the extent to which severe malaria causes mortality in SCA.

Acknowledgments

We thank the children and their parents who participated in this study, and the study team for their dedicated effort in treating the children and collecting these data.

Financial support

This work was supported by the National Institute of Neurological Disorders and Stroke and the Fogarty International Center (grants R01NS055349 and D43 NS078280)

Abbreviation

CC

Community Control

CM

Cerebral Malaria

DNA

De-oxyribonucleic Acid

SCA

Sickle cell anemia

SMA

Severe Malarial Anemia

HbS

Sickle cell hemoglobin

HbSS

Homozygous form of sickle cell hemoglobin

HbAS

Heterozygous form of sickle cell hemoglobin

HbAA

Normal form of adult hemoglobin

Footnotes

Abstract of this work was previously presented at the 65th Annual American Society of Tropical Medicine & Hygiene (ASTMH) meeting in Atlanta, USA, in November 2016 (15).

Contributions

ROO, PB, RI, RN and CCJ were involved in the design and conduct of this study. ES carried out the HbS genotyping and critical review of the manuscript. ROO wrote the first draft of the paper. All authors commented on and approved the final version of the manuscript.

Competing interests: All authors report no conflict of interests.

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