Althea Vol 3 No 1 full text Final.indd


Althea Medical Journal. 2016;3(1)

152     AMJ March 2016

Correlation between Oxygen Saturation and Hemoglobin and 
Hematokrit Levels in Tetralogy of Fallot Patients

Farhatul Inayah Adiputri,1 Armijn Firman,2 Arifin Soenggono3
1Faculty of Medicine Universitas Padjadjaran, 2Department of Child Health Faculty of Medicine, 
Universitas Padjadjaran/Dr. Hasan Sadikin General Hospital Bandung, 3Department of Anatomy 

and Cell Biology Faculty of Medicine Universitas Padjadjaran

Abstract

Background: Hemoglobin and hematocrit levels increase in Tetralogy of Fallot (TOF) but the oxygen 
saturation declines. Reduced hemoglobin in circulating blood as a parameter of cyanosis does not indicate 
rising hemoglobin due to the ‘not-working’ hemoglobins that affect the oxygen saturation. Increasing 
hematocrit is the result of secondary erythrocytosis caused by declining oxygen level in blood, which is 
related to the oxygen saturation. This study was conducted to find the correlation between oxygen saturation 
and hemoglobin and hematocrite levels in TOF patients.
Methods: This study was undertaken at Dr. Hasan Sadikin General Hospital in   the period of January 2011 to 
December 2012 using the cross-sectional analytic method with total sampling technique. Inclusion criteria 
were medical records of TOF patients diagnosed based on echocardiography that included data on oxygen 
saturation, hemoglobin, and hematocrite. Exclusion criteria was the history of red blood transfusion. 
Results: Thirty medical records of TOF patiens from Dr. Hasan Sadikin General Hospital Bandung were 
included in this study. Due to skewed data distribution, Spearman correlation test was used to analyze 
the data. There was a significant negative correlation between oxygen saturation and hematocrit level (r= 
-0.412; p=0.024) and insignificant correlation between oxygen saturation and hemoglobin (r=-0.329; p= 
0.076).
Conclusions: There is a weak negative correlation between oxygen saturation and hematocrite levels. 
[AMJ.2016;3(1):152–5]

Keywords: Hematocrit, hemoglobin, oxygen saturation, tetralogy of fallot

Correspondence: Farhatul Inayah Adiputri, Faculty of Medicine, Universitas Padjadjaran, Jalan Raya Bandung-
Sumedang Km.21, Jatinangor, Sumedang, Indonesia, Phone: +6285720471165  Email: tijannisa@gmail.com

Introduction

Tetralogy of Fallot (TOF) is the most frequent 
disease found in patients with cyanotic 
congenital heart disease. Nevertheless, 
not all TOF patients experience cyanosis 
because it depends on the severity of the 
disease.1 Cyanosis occurs due to several 
factors, including decreased pulmonary 
blood flow resulting in the obstruction of 
the pulmonary valve, known as pulmonary 
stenosis, making oxygen distribution to the 
tissue inadequate and increasing right to 
left shunt.2 In addition, another factor that 
may cause cyanosis is drastically reduced 
hemoglobin level in circulating blood that 
affects oxygen saturation.3 Oxygen saturation 
indicates the amount of oxygen bound by 
hemoglobins in a percentage of maximum 

binding at the time of measurement. One of 
the variables that affect oxygen saturation is 
hemoglobin concentration. However, it is not 
sure whether there is a correlation between 
oxygen saturation and hemoglobin in TOF.

Hematocrit increases in TOF patients as a 
response to hypoxia. The  oxygen delivery to 
tissues depends on many factors, particularly 
the total number of circulating erythrocytes, 
systemic arterial oxygen tension (PaO2), 
oxygen saturation, oxygen-hemoglobin 
dissociation curve position, cardiac output, 
and regional blood flow.4,5 Theoretically, rising 
hematocrit with declined oxygen saturation 
indicate increase in erythrocyte production 
to supply increased demand of oxygen in 
the tissue.5 It is postulated that there might 
be a correlation between oxygen saturation 
and hematocrit. This study aimed to find the 



Althea Medical Journal. 2016;3(1)

153

correlation between oxygen saturation with 
hemoglobin and hematocrit levels in patients 
with TOF.

Methods

This study was performed in October 2013 
through the use of secondary data, i.e. medical 
records. This study has been approved by the 
Health Reasearch Ethics Committee, Faculty 
of Medicine, Universitas Padjadjaran and Dr. 
Hasan Sadikin General Hospital Bandung. The 
inclusion criterion in this study was medical 
records from patients with tetralogy of Fallot 
diagnosed by echocardiography that includes 
information on hemoglobin, hematocrit, 
and saturation oxygen levels. The exclusion 
criteria were incomplete medical record 
and TOF patients who received packed red 
cell transfusion. In this study, data were not 
classified by age or sex. 

From the medical records, we obtained 
data on oxygen saturation and hematologic 
examination (hemoglobin level and 
hematocrit level) in which the results of 
hematologic data were taken from the Clinical 
Pathology Department of Dr. Hasan Sadikin 
General Hospital, Bandung. Oxygen saturation 
was measured using pulse oximeter by the 
examiner. Oxygen saturation value collected 
was the first value noted in the medical record 
by the examiner. Data were analyzed using 
Statistical Product and Service Solutions 
(SPSS) with a normality test by Shapiro-Wilk. 
Since two of the variables did not have normal 
distribustion, Spearman correlation test was 
then used. 

Table 1 Baseline Characteristics of the 
   Subjects

Characteristics n (%)

Age 
0-28 days 1
1-12 months 10
1-2 years 4
2-6 years 3
6-12 years 12
Sex
Boy 14
Girl 16

Table 2 Mean and Standard Deviation of the Variables

Variable Mean Standard Deviation

Oxygen Saturation (%) 82.45 9.88
Hemoglobin (g/dL) 15.55 11.34
Hematocrit (%) 48 10.63

Results

There were thirty medical records of TOF in 
Dr. Hasan Sadikin General Hospital Bandung 
during the period of January 2011–December 
2012 that were included in this study. One 
patient was excluded because he received 
packed red cell transfusion. The age range of 
the subjects when they first visited the hospital 
was very large. The youngest was 15 days old 
and the oldest was 12 years old. The average 
age of the samples was 4.44 years. The sample 
consisted of 14 boys and 16 girls. Before the 
correlation was analyzed, data were tested 
for the the normality of their distribution 
using Shapiro-Wilk test. It was revealed 
that the data distribution of hematocrit was 
normal, but the data on oxygen saturation and 

Table 3 Spearman Correlation Test between Oxygen Saturation and Hemoglobin and 
   Hematocrit Levels

Hemoglobin (g/dL) Hematocrit (%)

 r -0.329 -0.412
Oxygen Saturation p 0.076 0.024

n 30 30
Note: r = correlation coefficient; p = p-value; n = sample size

Farhatul Inayah Adiputri, Armijn Firman, Arifin Soenggono: Correlation between Oxygen Saturation and 
Hemoglobin and Hematokrit Levels in Tetralogy of Fallot Patients



Althea Medical Journal. 2016;3(1)

154     AMJ March 2016

hemoglobin level were not normal. Data were 
then  analyzed using bivariate analysis.

Most of the subjects were in 6–12 years old 
category. The mean for the oxygen saturation 
was low with the normal range of healthy 
children’s oxygen saturation of 96–100%.7

Table 2 shows that the oxygen saturation 
correlated negatively with  hemoglobin (r=-
0.329); however, the the correlation was not 
statistically significant (p>0,05). There was 
a significant correlation between the oxygen 
saturation and hematocrit (p<0.05). Both 
correlative values revealed negative and 
moderate correlations.

Discussion
 
The statistic results showed that oxygen 
saturation and hematocrit correlated inversely. 
This is in line with a study that reveals that the 
best correlation was obtained between oxygen 
saturation and hematocrit, r=-0.74.5 The 
increased hematocrit level due to secondary 
erythrocytosis usually occurs in cyanotic 
congenital heart disease (CCHD) because of 
the physiological response when the tissue 
experiences hypoxia. Patients experience 
hypoxemia due to reduced oxygenated blood 
which is represented as the oxygen saturation. 
Consequently, this stimulates bone marrow 
to produce erythrocytes by first excreting 
erythropoietin from kidney. Increased 
erythrocyte level, known as erythrocytosis, will 
increase red blood cell mass, hematocrit, and 
viscosity. This condition causes hyperviscosity 
in cyanotic congenital heart diseases, marked 
by increased hematocrit.4 Iron deficiency 
anemia also becomes a preciptitating factor 
for hyperviscosity.9 Finally, hiperviscosity 
can decrease blood flow to the tissue; thus, 
the amount of oxygen delivered to the tissue 
declines.

Furthermore, in TOF patients, the 
pulmonary blood flow (PBF) decreases 
because of the anatomy malformation in 
the development of heart during pregnancy, 
i.e. pulmonary stenosis. It causes reduced 
perfussion to the tissue. The manifestation 
includes cyanosis, in addition to the rising 
of hematocrit.10 Therefore, the inverse 
correlation between the oxygen saturation 
and hematocrit level in Tetralogy of Fallot was 
moderate in this study. 

Clinically, the increased hemoglobin can 
decrease the degree of right to left shunt 
and systemic vascular resistance as well as 
increasing the pulmonary blood flow, oxygen 
transport to the tissue, and aortic oxygen 

saturation as the physiologic responses to 
cyanosis.11 Thus, oxygen saturation often 
relates to hemoglobin as the compensation 
because decreased oxygen saturation will led 
to higher erythrocyte production to comply to 
the oxygen need. However,  the statistical test 
results showed  no correlation between oxygen 
saturation and hemoglobin level despite the 
fact that studies on cyanotic congenital heart 
diseases reveals that correlation between 
oxygen saturation and hemoglobin has the 
same pattern as the correlation between  
oxygen saturation and hematocrit.5 This 
means that there was a correlation between 
oxygen saturation and hemoglobin level albeit 
insignificant. 

In another study, cyanosis affects the 
rise in hemoglobin level but no significant 
change in oxygen saturation. The increased 
hemoglobin level will increase the oxygen 
capacity binding without any change in 
oxygen saturation and provide greater 
oxygen supply for the tissue. However, clinical 
manifestations, such as cyanosis, still exists in 
an even more severe state despite the  clinical 
improvement in this phase. This is known as 
relative anemia phenomenon.3 This occurrs 
due to many factors. Not all TOF patients 
experience cyanosis or relative anemia. If 
cyanosis presents, the degree of cyanosis is 
different among patients depending on the 
severity of the obstruction pulmonary valve, 
the degree of right ventricular outflow tract 
obstruction (RVOTO), and the status of the 
systemic vascular resistance relative to the 
degree of right ventricular obstruction.2 The 
ratio of pulmonary to systemic blood flow 
leads to patient’s condition, which can be fully 
saturated, cyanotic, or severely cyanotic.3 The 
irregular changes in oxygen saturation and 
hemoglobin level result in different degree of 
cyanosis. 

In conclusion, this study shows that TOF 
oxygen saturation correlates negatively with 
hemoglobin and hematocrit levels. Patient’s 
condition can be monitored and the cause of 
cyanosis, whether it is due to heart disease or 
not, can be determined using this correlation. 
Further research on oxygen saturation, 
hemoglobin, and hematocrit levels as the 
parameters for selecting the best management 
for TOF patients, either by surgery or blood 
transfusion, is needed.

References

1. Bailliard F, Anderson RH. Tetralogy of 
fallot. Orphanet J Rare Dis. 2009, 4:2



Althea Medical Journal. 2016;3(1)

155Farhatul Inayah Adiputri, Armijn Firman, Arifin Soenggono: Correlation between Oxygen Saturation and 
Hemoglobin and Hematokrit Levels in Tetralogy of Fallot Patients

2. Qu JZ. Congenital heart diseases with 
right-to-left shunts. Int Anesthesiol Clin 
2004;42(4):59–72.   

3. Rudolph AM, Nadas AS, Borge WH. 
Hematologic adjustment to cyanotic 
congenital heart disease. Pediatricts. 
1953;11: 454–464.

4. Puspitasari F, Harimurti GM. 
Hyperviscoucity in cyanotic congenital 
heart disease. Jurnal Kardiologi Indonesia. 
2010;31:41–7.

5. Haga P, Cotes P, Till J, Minty B, 
Shinebourne E. Serum immunoreactive 
erythropoietin in children with cyanotic 
and acyanotic congenital heart disease. 
Blood.1987;70(3):822–6.

6. Soetjiningsih S. Tumbuh kembang anak. 
Jakarta: EGC; 2007.

7. Balfour-Lynn DJF, Gringras P, Hicks B, 
Jardine E, Jones RC, Magee AG,, et al. BTS 
guidelines for home oxygen in children. 

Thorax. 2009;64(Suppl 2):ii1–26. 
8. Adamson JW, Longo DL. Anemia and 

polycythemia.  In: Longo DL, Fauci AS, 
Kasper DL, Hauser AL, Jameson JL, 
Loscalzo J. Harrison’s principles of internal 
medicine. 18th ed. New York: Mc Graw Hill; 
2012. p. 450.

9. Rose SS, Shah AA, Hoover DR, Saidi P. 
Cyanotic congenital heart disease (CCHD) 
with symptomatic erythrocytosis. J Gen 
Intern Med. 2007;22(12):1775–7

10. Murphy PJ. The fetal circulation. 
Contin Educ Anaesth Crit Care Pain. 
2005;5(4):107–12.

11. Beekman RH, Tuuri DT. Acute of 
hemodynamic effects of increasing 
hemoglobin concentration in children 
with right to left ventricular and relative 
anemia. J Am Coll Cardiol. 1985;5(2 
Pt1):357–62.