مستوى احلديد يف املصل لألطفال املصابني بأمراض القلب اخللقية
يف الغوس، نيجرييا

اديجوموكي اإتيول، بركات انيما�صاهون، اولي�صاميدوا جنوكامنا

abstract: Objectives: Cyanotic congenital heart disease (CCHD) predisposes patients to iron deficiency due 
to compensatory secondary erythrocytosis. This study aimed to determine the serum iron status and prevalence 
of iron deficiency among children with cyanotic congenital heart disease attending the Paediatric Cardiology 
outpatient clinic of Lagos State University Teaching Hospital, Lagos, Nigeria. Methods: This cross-sectional case-
control study took place between May and October 2015 at the Lagos State University Teaching Hospital. A total of 
75 children with cyanotic congenital heart disease and 75 apparently healthy age-, gender- and socioeconomically-
matched controls were analysed to determine serum iron status and the prevalence of iron deficiency as defined 
by the World Health Organization criteria. Results: The mean age of the children was 47.5 ± 2.9 months (range: 
6–144 months old). Iron deficiency was significantly more frequent among CCHD patients compared to control 
subjects (9.3% versus 0%; P = 0.006). While latent iron deficiency was more prevalent among children in the control 
group compared to those with CCHD, this difference was not statistically significant (13.3% versus 9.3%; P = 0.303). 
No cases of iron deficiency anaemia were observed in the studied sample. Conclusion: Neither the children in the 
control group nor those with CCHD had iron deficiency anaemia. However, iron deficiency was significantly more 
prevalent among children with CCHD in Lagos. Periodic serum iron status screening is therefore recommended 
for this population.

Keywords: Congenital Heart Defects; Cyanosis; Iron Deficiency Anemia; Children; Case-Control Studies; Nigeria.

امللخ�ص: الهدف: يوؤهب مر�ض القلب اخللقي املزمن املر�صى لنق�ض احلديد ب�صبب كرثة كريات الدم احلمراء التعوي�صية. هدفت هذه الدرا�صة 
اإىل حتديد حالة احلديد يف امل�صل وانت�صار نق�ض احلديد بني الأطفال امل�صابني باأمرا�ض القلب اخللقية امل�صحوبه بالزرقة الذين يح�رسون 
اإىل العيادة اخلارجية لأمرا�ض القلب لدى الأطفال يف م�صت�صفى جامعة ولية لجو�ض التعليمي، لجو�ض، نيجرييا. الطريقة: اأجريت هذه 
من  يعانون  طفاًل   75 جمموعه  ما  حتليل  مت  التعليمي.  لجو�ض  ولية  جامعة  م�صت�صفى  يف   2015 واأكتوبر  مايو  بني  امل�صتعر�صة  الدرا�صة 
اأمرا�ض القلب اخللقية امل�صحوبه بالزرقة و 75 طفال كمجموعه �صابطة مطابقة يف العمر واجلن�ض واأي�صا احلالة الجتماعية والقت�صادية 
لتحديد حالة احلديد يف الدم وانت�صار نق�ض احلديد بينهم على النحو املحدد يف معايري منظمة ال�صحة العاملية. النتائج: كان متو�صط عمر 
الأطفال 2.9 ± 47.5 �صهر )املدى: 144-6 �صهًرا(. كان نق�ض احلديد اأكرث تواجدا ب�صكل ملحوظ بني مر�صى اأمرا�ض القلب اخللقية امل�صحوبه 
بالزرقة مقارنة مع الأ�صخا�ض يف املجموعه ال�صابطة )%9.3 مقابل P = 0.006 ،0%(. بينما كان نق�ض احلديد الكامن اأكرث انت�صاًرا بني 
الأطفال يف املجموعة ال�صابطة مقارنة باأولئك الذين يعانون من اأمرا�ض القلب اخللقية امل�صحوبه بالزرقة، ومل يكن ذو دللة اإح�صائية 
)%13.3 مقابل %9.3؛ P = 0.303(. مل تكن هناك حالت فقر الدم ب�صبب نق�ض احلديد يف كل عينة الدرا�صة. اخلال�صة: مل يتم ت�صجيل اأي 
حالت فقر الدم الناجم عن نق�ض احلديد لدى الأطفال يف املجموعة ال�صابطة ول الأطفال امل�صابني باأمرا�ض القلب اخللقية امل�صحوبه 
بالزرقة. ومع ذلك، كان نق�ض احلديد اأكرث انت�صارا ب�صكل ملحوظ بني الأطفال الذين يعانون من اأمرا�ض القلب اخللقية امل�صحوبه بالزرقة 

يف لجو�ض. لذلك ين�صح فح�ض حالة احلديد يف امل�صل الدوري لهذه الفئة من ال�صكان.
الكلمات املفتاحية: عيوب القلب اخللقية؛ زرقة؛ فقر الدم بعوز احلديد؛ الأطفال؛ درا�صات احلالت واملجموعة ال�صابطة؛ نيجرييا.

Serum Iron Status of Children with Cyanotic 
Congenital Heart Disease in Lagos, Nigeria

Adejumoke Y. Itiola,1 *Barakat A. Animasahun,2 Olisamedua F. Njokanma3

Sultan Qaboos University Med J, November 2019, Vol. 19, Iss. 4, pp. e345–351, Epub. 22 Dec 19
Submitted 24 Feb 19
Revisions Req. 10 Apr & 30 May 19;  Revisions Recd. 24 Apr & 19 Jun 19
Accepted  11 Jul 19

Advances in Knowledge
- This study found iron deficiency to be significantly more prevalent among children with cyanotic congenital heart disease (CCHD) 

compared to a matched control group. 
- No cases of iron deficiency were noted among children in the control group according to the criteria of the World Health Organization; 

however, latent iron deficiency was more common in the control group.

Application to Patient Care
- Based on these findings, periodic serum iron status assessment and treatment is recommended for children with CCHD in this setting. 
- As children of both groups were found to have latent iron deficiency, routine counselling would also be beneficial for the caregivers of 

children to stress the importance of iron-rich foods and meal fortification.

1Department of Paediatrics, Faith City Hospital, Lagos, Nigeria; 2Department of Paediatrics & Child Health, College of Medicine, Lagos State University, 
Lagos, Nigeria; 3Department of Paediatrics, Lagos State University Teaching Hospital, Lagos, Nigeria
*Corresponding Author’s e-mail: deoladebo@yahoo.com

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.2019.19.04.010

clinical & basic research

https://creativecommons.org/licenses/by-nd/4.0/


Serum Iron Status of Children with Cyanotic Congenital Heart Disease in Lagos, Nigeria

e346 | SQU Medical Journal, November 2019, Volume 19, Issue 4

Cyanotic congenital he art dise ase (CCHD) is characterised by hypoxia resulting in physiologically-increased erythropoiesis 
which, if unabated, leads to iron deficiency.1 This 
predisposes children to growth retardation, impaired 
immune function, delayed behavioural, mental and psy- 
chomotor development and decreased work capacity.2–5 
The extreme manifestation of iron deficiency is an 
anaemic state.6 However, the clinical detection of 
anaemia based on pallor is hampered by the occurrence 
of hypoxia-induced polycythaemia in CCHD.7 Labor- 
atory tests and periodic screening are therefore manda- 
tory for diagnosis.8 

Overall, CCHD accounts for an estimated third 
of congenital heart disease cases.9 Treatment is usually 
surgical, with the cost of repair ranging from $10,000–
$50,000 USD, depending on setting.10 Unfortunately, 
this is often beyond the economic means of the average 
Nigerian family; as such, surgical correction of the 
defect is usually delayed due to financial constraints.10,11 
Accordingly, CCHD-related comorbidities such as 
iron deficiency should be treated promptly to improve 
clinical outcomes in affected children. However, 
there is a paucity of local studies on the iron status of 
Nigerian children with CCHD, particularly in settings 
where iron deficiency and iron deficiency anaemia are 
reportedly common.11–13 A recent study reported that 
the prevalence of iron deficiency among children with 
CCHD in Ibadan, Nigeria, was high (35%).11 

Conventional tests for iron deficiency such as 
mean corpuscular volume, serum ferritin levels and 
transferrin saturation (TSAT) have limited value due 
to varying sensitivities and specificities, especially 
as results may be affected by acute or chronic 
inflammatory conditions, genetic polymorphisms and 
sickle cell disease states.12,14,15 Other researchers have 
also reported that expected microcytic, hypochromic 
and erythrocyte findings are often absent in cyanotic 
patients with iron deficiency.16 This study aimed to 
assess serum iron status and the prevalence of iron 
deficiency among children with CCHD in Lagos, 
Nigeria, in comparison to a matched control group. 
The research questions for the study were: (1) what 
is the prevalence of iron deficiency in children with 
cyanotic congenital heart disease; and (2) what is the 
prevalence of iron deficiency anaemia in children with 
cyanotic congenital heart disease. The null hypotheses 
were: (1) there is no statistically significant difference 
between the prevalence of iron deficiency in children 
with cyanotic congenital heart disease and those of the 
appropriate age- and gender-matched controls; and (2) 
there is no statistically significant difference between 
the prevalence of iron deficiency anaemia in children 
with cyanotic congenital heart disease and those of 

the appropriate age- and gender-matched controls. 
These findings are expected to increase awareness 
regarding the need for routine monitoring and prompt 
treatment, thereby reducing morbidity in this patient 
group. 

Methods

This cross-sectional case-control study was carried out 
between May and October 2015 at the Department 
of Paediatrics at Lagos State University Teaching 
Hospital which is an urban tertiary healthcare centre 
in Ikeja, Lagos, Nigeria. A total of 150 children were 
recruited consecutively over the six-month period, 
including 75 consecutive children with CCHD and 
75 control subjects matched for age, gender and 
socioeconomic status. Classification and matching 
for the latter variable was performed according to 
previous research.17

The estimated sample size was determined 
according to the following equation for comparative 
studies:18

where Zα is the normal standard deviation corresp- 
onding to a 95% confidence interval (1.96), Zβ is the 
power set at 80% (0.84), p is the average of previously 
reported prevalence rates of iron deficiency in children 
with CCHD (16.9%) and controls (27.5%) and d is 
the minimum difference to be detected by the study 
(20%).19 This calculation resulted in a minimum of 67 
subjects; however, as the non-response rate was set at 
10%, the final number of subjects was calculated to be 
74. This was then rounded up to 75 subjects for ease of 
calculation, each of whom were subsequently matched 
for age, gender and socioeconomic class with a control 
subject.

In terms of inclusion criteria, the case group 
included patients diagnosed with echocardiography-
confirmed CCHD attending the outpatient paediatric 
cardiology clinic who had not undergone corrective 
surgery and who were between six months and 12 years 
old. Only subjects who had had no symptoms or signs 
attributable to an acute illness within the preceding 
four weeks were included in the study. Children who 
had undergone a partial exchange transfusion, blood 
transfusion or repeated phlebotomy in the past three 
months were excluded, as well as those who had 
received iron supplementation prior to recruitment 
or had been diagnosed with sickle cell anaemia or 
other chronic illnesses. The control group comprised 
of apparently healthy children recruited from general 

N = (Zα + Zβ)
2 × 2p (1–p)

[Equation 1]
d2



Adejumoke Y. Itiola, Barakat A. Animasahun and Olisamedua F. Njokanma

Clinical and Basic Research | e347

outpatient clinics and other specialty clinics within the 
same age range. Children were deemed healthy if they 
had had no symptoms or signs attributable to illness 
within the preceding four weeks.

Children in both the case and control groups 
underwent venepuncture performed according to the 
guidelines of the World Health Organization (WHO).20 
An LH 750 Hematology Analyser (Beckman Coulter 
Inc., Brea, California, USA) was used to perform an 
automated complete blood count using whole blood 
samples with ethylenediaminetetraacetic acid added. 
Serum ferritin levels were measured using a human 
ferritin enzyme immunoassay test kit with a calibration 
range of 0–800 ng/mL (Ferritin AccuBind ELISA Kit, 
Monobind Inc., Lake Forest, California, USA). Serum 
iron levels and total iron-binding capacity (TIBC) were 
measured using a reagent set (TECO Diagnostics, 
Anaheim, California, USA). Unsaturated iron-binding 
capacity was determined by adding ferrous iron ions 
to the serum so that they would bind to transferrin at 
unsaturated binding sites.21

As per the WHO criteria, a diagnosis of iron 
deficiency was defined according to cut-off serum 
ferritin levels of <12 ng/L or <15 ng/L for children 
aged <5 years old and ≥5 years old, respectively.8 In 
turn, iron deficiency anaemia was diagnosed for 
subjects with serum ferritin levels of <12 ng/L or 
<15 ng/L for children aged <5 years old and ≥5 years 
old, respectively, in the presence of haemoglobin 
concentrations at least two standard deviations below 
that of the normal population at the same age.22

All data collected were stored on a personal 
computer. Statistical analysis was performed using an 
Excel spreadsheet, Version 2010 (Microsoft Inc., Red- 
mond, Washington, USA) and the Statistical Package 
for the Social Sciences (SPSS), Version 20.0 (IBM Corp., 
Armonk, New York, USA). Means, medians, standard 
deviations and ranges were calculated for continuous 
variables, while categorical variables were represented 
as frequencies and percentages. Continuous variables 
were compared using a Student’s t-test, while categ- 
orical variables were compared with Fisher’s exact 
test. A Kolmogorov-Smirnov nonparametric test was 
used to determine the normality of continuous data; 
subsequently, a Student’s t-test was used to compare 
normally-distributed data, while a Mann-Whitney U test 
was used for skewed or non-normally distributed data. 
The degree of agreement between different methods 
used to evaluate the same parameter was estimated 
using Kappa statistics. A P value of 0.050 was deemed 
statistically significant.

Ethical approval for this study was obtained from 
the Ethics Committee of Lagos State University Teaching 

Hospital (LREC/10/06/398). Written informed consent 
was obtained from the parents/caregivers of participants. 
Moreover, all children found to be iron-deficient during 
the course of the study received prompt and appropriate 
treatment.

Results

This study included 150 children, of which 75 were 
CCHD patients and 75 were apparently healthy 
controls [Equation 1]. The mean age of the children 
was 47.5 ± 2.9 months (range: 6–144 months old). 
In terms of age distribution, 26 children with CCHD 
(34.7%) were <24 months old, 30 (40%) were between 
24–59 months old and 19 (25.3%) were ≥60 months old. 
As the controls were age-matched, there were equal 
numbers of children in each age group in the control 
group. In the CCHD group, Tetralogy of Fallot (TOF) 
was the most common heart lesion (52%), followed 
by double-outlet right ventricle (DORV; 12%). The 
least common diagnoses were Ebstein anomalies and 
complex heart disease (1.3% each) [Table 1]. Although 
all of the study population had normal haemoglobin 
concentrations, mean haemoglobin concentrations 
were significantly higher among children with CCHD 
compared to those in the control group (13.8 ± 3.9 g/dL 
versus 10.3 ± 0.8 g/dL; P <0.001). 

Mean serum iron, serum ferritin, TIBC and TSAT 
values were compared between children with CCHD 
and apparently healthy controls according to age group. 
Among children aged 6–23 months, mean serum 
iron levels were significantly lower in the CCHD group 
compared to the control group (162.8 ± 10.8 µg/dL 

Table 1: Frequency of heart lesions among children with 
cyanotic congenital heart disease in Lagos, Nigeria (N = 75)

Lesion n (%)

Tetralogy of Fallot 39 (52)

Double-outlet right ventricle 9 (12)

TGA 6 (8)

Critical pulmonary stenosis 4 (5.3)

Eisenmenger complex 4 (5.3)

Pulmonary atresia with VSD 4 (5.3)

Truncus arteriosus 3 (4)

Tricuspid atresia 2 (2.7)

TAPVC 2 (2.7)

Ebstein anomaly 1 (1.3)

Complex heart disease 1 (1.3)

TGA = transposition of the great arteries; VSD = ventricular septal defect; 
TAPVC = total anomalous pulmonary venous connection.



Serum Iron Status of Children with Cyanotic Congenital Heart Disease in Lagos, Nigeria

e348 | SQU Medical Journal, November 2019, Volume 19, Issue 4

versus 171.6 ± 5.6 µg/dL; P <0.001); a similar finding 
was documented for TSAT (48.7 ± 24.9% versus 52.6 ± 
15.0%; P = 0.040). However, there were no significant 
intergroup differences regarding mean TIBC and serum 
ferritin levels [Table 2]. 

For the 24–59-month-old age group, serum iron 
levels were also significantly lower in the CCHD group 
compared to controls (167.7 ± 39.7 µg/dL versus 
169.7 ± 7.3 µg/dL; P <0.001), although none of the other 
biochemical parameters were significantly different 
between the CCHD and control groups [Table 3]. Similar 
findings were noted for 60–144-month-old children, 
with serum iron levels significantly reduced in the CCHD 
group (163.1 ± 5.6 µg/dL versus 169.6 ± 10.3 µg/dL; 
P = 0.001), while none of the other biochemical parameters 
differed significantly [Table 4].

The prevalence rates of frank and latent iron 
deficiency are shown in Figure 1. Overall, seven (9.3%) 
children with CCHD had an iron deficiency whereas 

 
Figure 1: Prevalence of iron deficiency among children with 
cyanotic congenital heart disease and age-matched controls 
in Lagos, Nigeria (N = 150).
CCHD = cyanotic congenital heart disease.

Table 2: Iron status parameters among 6–23-month-old children with cyanotic congenital heart disease and age-matched 
controls in Lagos, Nigeria (N = 52)

Parameter Mean ± SD; median (range) Z score P value*

CCHD group (n = 26) Control group (n = 26)

Serum iron in µg/dL 162.8 ± 10.8; 166.4 (130.3–175.9) 171.6 ± 5.6; 173.9 (154.8–176.4) 3.555 <0.001†

Serum ferritin in ng/dL 80.4 ± 56.3; 62.0 (2.0–200.0) 52.5 ± 27.2; 43.0 (18.0–110.0) 1.678 0.093

TIBC in µg/dL 379.8 ± 111.5; 414.2 (111.7–579.3) 351.7 ± 98.4; 344.8 (182.8–577.8) 1.206 0.228

TSAT in % 48.7 ± 24.9; 39.4 (30.2–149.9) 52.6 ± 15.0; 50.8 (29.9–91.2) 2.050 0.040†

SD = standard deviation; CCHD = cyanotic congenital heart disease; TIBC = total iron-binding capacity; TSAT = transferrin saturation.
*Using a Mann-Whitney U test.  †Statistically significant at P <0.050.

Table 3: Iron status parameters among 24–59-month-old children with cyanotic congenital heart disease and age-matched 
controls in Lagos, Nigeria (N = 60)

Parameter Mean ± SD; median (range) Z score P value*

CCHD group (n = 30) Control group (n = 30)

Serum iron in µg/dL 167.7 ± 39.7; 161.4 (141.4–357.6) 169.7 ± 7.3; 170.7 (148.0–179.4) 3.818 <0.001†

Serum ferritin in ng/dL 61.9 ± 52.1; 39.0 (2.0–205.0) 87.7 ± 63.2; 4.0 (12.0–220.0) 1.504 0.133

TIBC in µg/dL 392.1 ± 98.1; 396.1 (209.9–500.5) 352.5 ± 81.5; 338.8 (224.3–582.1) 1.637 0.102

TSAT in % 45.3 ± 14.0; 40.9 (26.1–80.0) 60.4 ± 10.9; 50.7 (30.3– 76.1) 1.904 0.057

SD = standard deviation; CCHD = cyanotic congenital heart disease; TIBC = total iron-binding capacity; TSAT = transferrin saturation.
*Using a Mann-Whitney U test.  †Statistically significant at P <0.050.

Table 4: Iron status parameters among 60–144-month-old children with cyanotic congenital heart disease and age-matched 
controls in Lagos, Nigeria (N = 38)

Parameter Mean ± SD; median (range) Z score P value*

CCHD group (n = 19) Control group (n = 19)

Serum iron in µg/dL 163.1 ± 5.6; 162.1 (152.0–178.9) 169.6 ± 10.3; 173.3 (138.5–179.1) 3.338 0.001†

Serum ferritin in ng/dL 82.5 ± 61.5; 8.0 (7.0–201.0) 62.2 ± 58.3; 40.0 (13.0–215.0) 1.306 0.174

TIBC in µg/dL 394.5 ± 112.7; 407.7 (218.1–632.8) 370.7 ± 96.6; 381.4 (133.9–524.9) 0.554 0.580

TSAT in % 44.9 ± 14.6; 39.6 (26.9–82.0) 50.4 ± 20.9; 46.2 (30.9–129.2) 0.932 0.351

SD = standard deviation; CCHD = cyanotic congenital heart disease; TIBC = total iron-binding capacity; TSAT = transferrin saturation.
*Using a Mann-Whitney U test.  †Statistically significant at P <0.050.



Adejumoke Y. Itiola, Barakat A. Animasahun and Olisamedua F. Njokanma

Clinical and Basic Research | e349

iron deficiency was not documented among the control 
group (9.3% versus 0%; P = 0.006). In contrast, latent 
iron deficiency was found to be more common in 
controls compared to subjects with CCHD; however, 
this difference was not significant (13.3% versus 9.3%; 
P = 0.303). No cases of iron deficiency anaemia were 
documented in the study population in either group. 
In terms of specific heart diseases, three (7.7%) out of 
39 children with TOF, two (33.3%) out of six with TGA 
and one (11.1%) out of nine with DORV were iron-
deficient. The remaining iron-deficient child was the 
only patient with an Ebstein anomaly. With regards to 
age, iron deficiency occurred in five (8.9%) out of 56 
and two (10.5%) out of 19 children who were <5 and ≥ 
5 years old, respectively.

In the CCHD group, mean serum ferritin levels 
were significantly lower in iron-deficient subjects 
compared to those who were iron-sufficient (7.7 ± 4.6 
ng/dL versus 84.0 ± 11.7 ng/dL; P <0.001), while the 
mean TIBC was significantly higher in iron-deficient 
subjects (479.5 ± 98.7 µg/dL versus 377.2 ± 104.7 
µg/dL; P = 0.017). However, there was no significant 
difference in mean serum iron levels and TSAT 
between iron-deficient and iron-sufficient children 
with CCHD [Table 5].

Discussion

The overall prevalence of iron deficiency among 
children with CCHD in the current study was 9.3%. 
Other researchers have reported comparable prevalence 
rates of 12.5% and 16.9% in Italy and Kenya, respectively.19,23 
Similarities in these rates may be related to the age 
groups of the targeted populations, as both of the 
aforementioned studies recruited children up to 12 
years of age.19,23 However, much higher rates have been 
reported in Turkey (52.5–63.6%).24,25 This may again 
be due to population variation, as iron deficiency is 
reportedly higher in children under five years.13 
Nevertheless, when the analysis in the present study 
was limited to under-five-year-olds, the prevalence 
rate was 8.9%, which is still much lower than that 
reported in Turkey.24,25

Aside from methodological differences, other 
explanations for differing prevalence rates may be due 
to local geographical and nutritional factors beyond 
the scope of the present study. It is unlikely that the 
difference is due to the specific CCHD type, as both 
the current study and previous studies reported similar 
frequencies of various heart lesions.22–25 In the present 
study, the spectrum of CCHD followed expected 
patterns, with TOF accounting for more than half 
of all patients. Other heart diseases identified were 
consistent with those reported in previous research 
from Nigeria.26

Although the prevalence of iron deficiency 
among children with CCHD was low in the present 
study, it was still significantly higher than that noted 
among the age-, gender- and socioeconomically-
matched controls, in whom no documented case of 
iron deficiency was observed. This finding supports 
the theory that chronic hypoxia results in increased 
haemopoiesis and iron depletion in children with 
CCHD.7 Nevertheless, it is worth noting that even 
though none of the control group met the WHO 
criteria for diagnosing frank iron deficiency, latent 
iron deficiency was more frequently diagnosed in this 
group compared to the CCHD group (13.3% versus 
9.3%). 

Frank and latent iron deficiency refer to the 
progressive depletion of iron stores on a continuum. 
The deterioration of iron status from iron sufficiency 
to latent deficiency has been demonstrated in a 
longitudinal study of patients with CCHD.24 It is 
therefore pertinent to address the importance of iron 
fortification in the general population and iron supple- 
mentation in iron-deficient children with CCHD. 
Such measures will help to reduce the morbidities to 
which children with iron deficiency are predisposed, 
including growth retardation, impaired immune 
function, impaired behavioural, mental and psycho- 
motor development and decreased work capacity.2–5

In the present study, children with CCHD had 
significantly higher mean haemoglobin concentrations 
in comparison to healthy controls. This finding is 
in line with previous research.11 An uncorrected 

Table 5: Iron status parameters according to iron sufficiency among children with cyanotic congenital heart disease in 
Lagos, Nigeria (N = 75)

Parameter Mean ± SD t value P value

Iron-deficient children (n = 7) Iron-sufficient children (n =68)

Serum iron in µg/dL 163.8 ± 6.2 165.1 ± 9.9 0.123 0.573

Serum ferritin in ng/dL 7.7 ± 4.6 84.0 ± 11.7 3.664 <0.001*

TIBC in µg/dL 479.5 ± 98.7 377.2 ± 104.7 2.460 0.017*

TSAT in % 43.0 ± 17.7 46.5 ± 14.1 0.598 0.522

SD = standard deviation; TIBC = total iron-binding capacity; TSAT = transferrin saturation.  *Statistically significant at P <0.050.



Serum Iron Status of Children with Cyanotic Congenital Heart Disease in Lagos, Nigeria

e350 | SQU Medical Journal, November 2019, Volume 19, Issue 4

congenital cyanotic heart lesion keeps the body in 
a state of constant hypoxia.27 Hypoxia, in turn, triggers 
the physiological release of erythropoietin which 
stimulates the bone marrow to produce more erythro- 
cytes, leading to an increase in oxygen-carrying 
capacity.28 Moreover, mean serum iron levels in the 
current study were significantly lower in the CCHD 
group compared to the controls, regardless of age. 
Previously documented studies have reported similar 
findings.5,24

In CCHD, low serum iron levels can be explained 
by the presence of hypoxaemia in which adaptive 
mechanisms increase the delivery of oxygen to the 
tissue, resulting in a rightward shift in the oxygen-
haemoglobin dissociation curve. Persistent hypoxia 
and the corresponding increase in red cell mass place 
a continuous demand on iron stores, predisposing 
children with CCHD to iron deficiency.27 Mean TIBC 
values were also higher in the present study among 
iron-deficient compared to iron-sufficient children 
with CCHD; Soliman et al. reported similar findings.2 
As a parameter, TIBC indicates the maximum amount 
of iron needed to saturate transferrin, the primary 
protein involved in iron transport.6 Thus it is not 
surprising that mean TIBC is higher in the presence 
of iron deficiency.

The findings of the current study answered the 
previously posed research questions. There was a 
significant difference in the number of CCHD cases 
with iron deficiency compared to the controls, allowing 
for the rejection of the null hypothesis proposed 
for the first research question. Moreover, a pattern 
suggestive of progressive iron depletion was observed, 
with patients manifesting both latent and frank iron 
deficiency. However, none of the subjects had iron 
deficiency anaemia; hence, the null hypothesis can be 
accepted for the second research question. 

This study was subject to certain limitations. 
C-reactive protein, a marker of inflammation was not 
measured; this could have been a confounding cause 
of elevated serum ferritin. However, efforts were made 
to exclude subjects with symptoms and or signs of 
infections within four weeks preceding the study. In 
addition, it would have been ideal to perform bone 
marrow aspiration, which is the gold standard test 
for iron deficiency, however the invasive nature of 
this procedure was not feasible, acceptable or cost-
effective in the present study. 

The current study was able to demonstrate the 
occurrence of iron deficiency in subjects with CCHD 
and document the presence of latent iron deficiency in 
children with CCHD and apparently healthy controls. 
This emphasises the need for periodic iron status 
checks of these children and nutritional counselling 

for parents of children attending the Lagos State 
University Teaching Hospital.

Conclusion

In Lagos, Nigeria, the prevalence of iron deficiency 
among children with CCHD was 9.3%. Routine serum 
iron status assessment should therefore be carried out 
periodically in this setting, with those children found 
deficient referred for treatment. Latent iron deficiency 
was also fairly common among both CCHD subjects 
and apparently healthy controls. Accordingly, parents 
and caregivers should be routinely counselled on the 
importance of iron-rich foods and the benefits of meal 
fortification, regardless of disease status.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

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