Iron stores in pregnant women with sickle cell disease: a systematic review

Two investigators (DA and BMK) performed independent literature searches. After the initial database search, the available data was de-duplicated. DA and BMK independently reviewed titles and abstracts of the studies obtained for eligibility. Each investigator produced a list of potentially eligible studies, and the lists were harmonised into a single list. DA and BMK then independently assessed the full texts of the harmonised list of potentially eligible studies for inclusion. Once more, their findings were harmonised and a comprehensive list of included studies was produced. A third investigator – TN, arbitrated during disagreements between DA and BMK. For publications with ambiguous data, the authors were contacted by email for clarity. For articles without full texts that were potentially eligible for inclusion, the authors were contacted via email or other platforms such as ResearchGate. Constant weekly reminders were sent to these authors and the studies were automatically excluded if no response was received after 1 month [18, 21].

Potentially eligible studies excluded were documented with the various reasons for exclusion. A detailed PRISMA flow chart was used to depict the selection process as shown in Fig. 1.

Two reviewers (DA and BMK) independently assessed the methodological quality and the risk of bias for each study. Assessment was done using the Quality Assessment Tool for Observational Cohort and Cross-Sectional Studies of the National Health Institute/National Heart, Lung, and Blood Institute (Additional file 1: Appendix 2) for the observational studies and the Cochrane Risk of Bias Tool for Randomized Controlled Trials (Additional file 1: Appendix 3 and 4) for the randomized control trial [13].

A data extraction sheet produced on Microsoft excel and pretested by investigators was used to extract the data from selected studies. The following data were extracted; socio-demographic information (country of study population and study setting), study characteristics (the name of the first author, year of publication, study design and setting, mean age, sickle cell genotype, gestational age distribution, transfusion history, sample size and method used to assess body iron stores) and study findings (iron status, prevalence of iron deficiency anaemia, intervention and the outcome of the foetus and mother). The abstracted data was recorded on Microsoft excel 2017 spread sheet. Only five articles were retained for full text review. These articles had varied study designs and very small sample sizes. More so, the studies included women at varying gestational ages and different biomarkers were used to assess iron stores With such heterogeneity in only 5 studies, performing a meta-analysis was not justified. A descriptive approach was thus adopted for data analysis and synthesis. Prevalence of iron deficiency anaemia among PWSCD was sorted generally, by method of diagnosing iron deficiency and by study design. Prevalence was described for each category. Determinants of iron deficiency anaemia were not assessed as none of the 5 articles studied this objective. Information on the maternal/foetal outcomes of iron deficiency anaemia among PWSCD was described as only one study assessed this objective.

No patient involved.

All studies were hospital-based, single centre studies done in tertiary healthcare facilities. The studies were conducted from 1972 to 1997 and were conducted in 3 countries across 3 continents. Four studies were observational (3 cross sectional [22‐24] and 1 case control [14]) and one was a randomized control trial [13]. For the randomized control trial, fourteen pregnant women with sickle cell disease (11 Haemoglobin SS and 3 Haemoglobin SC) were randomized into one of two arms to receive routine antenatal supplementation with ferrous gluconate or with identical placebo tablets. Their haemoglobin levels and bone marrow iron content were measured prenatally and at 6 weeks postpartum. The birth weights and the number of pain crisis in both groups were also recorded [13]. The case control study evaluated Iron stores using transferrin saturation, total iron binding capacity, serum ferritin and bone marrow stainable iron in 22 pregnant and 18 non-pregnant women with SCD. Only the latter was used for this study to estimate prevalence as only mean values were provided for transferrin saturation, total iron binding capacity and serum ferritin. The mean gestational age of participants was 23.3 weeks [14]. Roopnarinesingh evaluated iron stores using bone marrow staining for 6 Negro women with singleton pregnancies in a Spanish General Hospital. Their mean gestational age was 28.7 weeks and none of the participants had been transfused recently [23]. In Jamaica, Anderson assessed the iron stores of 15 PWSCD with a mean gestational age of 16.9 weeks using total iron binding capacity, serum iron and bone marrow stainable iron [22]. None of the 5 studies reported the study period and the study duration. Iron stores were assessed using serum iron (n = 2), serum ferritin (n = 1), total iron binding capacity (n = 1) and bone marrow stainable iron (n = 4). Aken’ova et al. used both serum iron and serum ferritin and was the only study that did not use bone marrow stainable iron [24]. The observational studies had a fair risk of bias while the interventional study had mostly an unclear determination of bias risk. A summary of study characteristics and bias assessment is provided on Table 1.

The prevalence of iron deficiency anaemia among PWSCD ranged from 6.67 ± 0.87–83.33 ± 25.04%. Prevalence varied across study design (cross sectional (6.67 ± 0.87–83.33 ± 25.04%) [22‐24], case control (63.34 ± 12.78%) [25] and randomized control trial (21.43 ± 4.49%) [13]) and by diagnostic method of iron stores (serum iron (6.67 ± 0.87 & 30 ± 8.52%), serum ferritin (30 ± 8.52%), total iron binding capacity (6.67 ± 0.87%) and bone marrow stainable iron (21.43 ± 4.49% – 83.33 ± 25.04%)). For the case control study, fourteen of the 22 pregnant women (63.6%) and 9 of the 18 non-pregnant women (50%) had scanty or no iron in the bone marrow; the serum ferritin levels increased progressively with greater amount of haemosiderin in the bone marrow. Anderson et al. using total iron binding capacity, serum iron and bone marrow stainable iron had prevalence of 6.67,6.67 and 66.7% respectively [22] Details on the sample size, number of participants with iron deficiency anaemia and prevalence in each category is available on Table 1.

None of the studies included in this review provided information on factors associated with iron deficiency anaemia among PWSCD.

Only one study followed women through to the postpartum period and provided outcome data [13]. Following initial iron store measurements, all women with SCD were randomized to receive iron gluconate or an identical placebo. At birth, birth weights of the children were measured and at 6 weeks postpartum repeat measurements of the iron stores of the women were done. Three of the 14 participants with low antenatal iron stores did not have any change in their postpartum iron stores in both the trial and control groups. The placebo group showed an aggregate loss of 4 grades of iron repletion in the post natal period while the iron supplemented group showed an aggregate gain of 2 grades. There were no significant differences between the birth weight or the incidence of pain crises in both groups. All three iron deficient women had normal foetal birth weights [13].