Evaluation of Hemoglobin Concentration in Pregnancy and Correlation with Different Altitude: A Study from Balochistan Plateau of Pakistan

Abstract

Background:

Anemia refers to a condition having low hemoglobin concentration. Anemia is considered a major risk factor for unfavorable pregnancy outcomes. This is the first study describing the pattern of hemoglobin concentration during pregnancy and its relationship to areas of high and low altitudes in Balochistan (the largest of Pakistan’s four provinces). The main objective of this study was to observe hemoglobin levels and prevalence of anemia among pregnant women living in the high or low altitude areas of Balochistan.

Methods:

A randomized survey was conducted and blood samples were collected from 132 healthy full term pregnant women subjects and 110 unmarried females. The subjects of the current study were selected from two different areas of Balochistan (Quetta and Uthal). Hemoglobin levels of the subjects were analyzed on Microlab 300 by Merck kit. Dietary status of the subjects was assessed based on simplified associated food frequency questionnaire. The factors effecting hemoglobin in full term pregnancy at different altitudes were multi gravidity/parity (increased number of pregnancies/children), age, socio-economic and educational status.

Results:

Anemia was highly prevalent in low-altitude region (68.33%). We found statistically significant difference in mean hemoglobin level at high-altitude region (11.81 ± 1.02) and low-altitude region (10.20 ± 1.28) in pregnant females of Balochistan plateau (P < 0.001). Higher maternal age (> 35 years) has shown significantly higher anemic frequency at both high (57.89%; p < 0.002) and low (41.46%; p = 0.067) altitudes. A balanced-diet that is rich in meat products has also shown significant correlation with reduced incidences of anemia among pregnant women at both altitudes.

Conclusion:

Hemoglobin concentration increases in the body with elevated altitudes and, thus, anemia was less frequent at high-altitude region. Factors affecting hemoglobin concentration in full term pregnancy at different altitudes included old maternal age, low body-mass index, education and diet.

Keywords: Anemia, altitude, diet, hemoglobin, pregnancy. .

INTRODUCTION

Anemia is a common health problem during pregnancy all around the world [1-2], in developing as well as developed countries [3-5]. The World Health Organization has defined anemia as a condition in which hemoglobin content of blood is lower than the normal, i.e., 11 g/dL of blood, as a result of deficiency of one or more essential nutrients [3, 6, 7]. The prevalence of anemia is 30.2% innon-pregnant women and 41.8% in pregnant woman around the world [8].

Anemia in pregnancy is a serious condition that contributes to increased rates of maternal and fetus morbidity as well as mortality. Patients of anemia show various symptoms such as generalized weakness, breathlessness and perceived paleness or change in skin colour (especially nails and lips colour turned to yellow), rapid heartbeat, headache and irritability [6].

At higher altitudes (above 1000 meters) from the sea level, the partial pressure of oxygen is decreased in the atmosphere leading to lower oxygen saturation of the blood. Thus, hemoglobin levels increase as an adaptive response to the decreased partial pressure of oxygen and reduced oxygen saturation of blood [1, 9]. Hemoglobin levels vary with age, sex, nutrition, socio-economic status, ethnicity and race [10]. Aggravating factors that increase the risk of anemia include poor diet, low socio-economic status [11-13], insufficient health facilities and lack of education in rural areas [14], lack or deficiency of some essential elements (like, iron, vitamin B12 and folic acid which are essential for hemoglobin synthesis) [15], vitamin A deficiency [16, 17], recurrent pregnancies, suppression of RBC production due to bone marrow defects, rheumatoid arthritis, tuberculosis and chronic blood loss, worm infestation [8, 11, 12] and malaria [18, 19]. High levels of hemoglobin concentrations, i.e., less than 14.5 g/dL are associated with hypertension and pregnancy-induced hypertension. Growth retarding effects are also observed among high altitude dwellers [20].

To date no scientific study has been conducted describing the pattern of hemoglobin concentration during pregnancy and its relationship with altitude in the regions of Baluchistan. This present cross-sectional study was designed to determine and compare the hemoglobin levels among pregnant as well as unmarried females living at high-altitude region (HA) (Quetta City) and low-altitude region (LA) (Uthal City). This current study also assessed the effects of other factors such as socioeconomic status, education, gravidity, body-mass index (BMI), smoking and maternal age on hemoglobin concentration.

MATERIALS AND METHODS

Setting and Study Area

The study was conducted in Quetta and Uthal cities of Balochistan plateau of Pakistan. This plateau has an average altitude of 2,000 feet and the mountains of this region attain the average height of 6,000-11,000 feet. Mean altitudes of Quetta city (HA) and Uthal city (LA) are 1,675 meters and 24 meters above the sea level. The conditions of the plateau are dry and arid. The people here usually live nomadic life and have adapted themselves to the life of high altitude and dry environment. A randomized survey was conducted and samples were collected at the Bolan Medical Complex Hospital and Sandeman Civil Hospital, Quetta and at the Uthal Medical Centre, Uthal, Balochistan, Pakistan. Healthy, pregnant women subjects were selected from the same region.

Sample and Data Collection

In the present hospital-based study, 132 healthy pregnant women (72 from HA and 60 from LA) and 110 unmarried (non pregnant) female (55 from HA and 55 from LA) were enrolled from the cities of Balochistan, Pakistan, between November 2009 to November 2011. The subjects were interviewed by professionally trained lady doctors, using a standard and detailed questionnaire that include participant’s name, age, gravidity, clinical signs and symptoms, education, monthly income and living style, ethnicity, smoking or tobacco chewing habit and dietary intake. On the basis of ages ranging from 18-45 years, the subjects were divided into young (15-25), middle (26-35) and old (36-45) age groups. Based on monthly income, the subjects were distributed into three classes: upper class ($300 US dollars), middle class ($100-299 US dollars) and poor class (< $100 US dollars). In terms of literacy level, the subjects were divided into illiterate and literate (applying minimum 5 years of primary education as the cutoff). Smoking habit was evaluated based on whether the subject used tobacco or its products like cigarette, snuff (naswar) or gutka.

The general characteristics of pregnant and anemic females from HA and LA areas were shown in Table 1. Diet-related information, food type and its frequency of intake were collected to estimate the specific nutrient intake by the subjects and the association of those parameters with anemia (Table 3). Clinical signs and symptoms including breathlessness, pallor of skin, pale conjunctiva, and koilonychea (spoon-shaped nails) were recorded (Table 4). Maternal weight (kg), height (cm) and upper mid arm circumference (UMAC) (cm) were also measured. Weights were recorded in kilogram (kg) with sensitivity of 0.25kg (Weighing Balance, Tanita, China) and heights were recorded in centimeters. Maternal BMI is calculated as weight in kilograms divided by square of height in meters. BMI less than 18.5 was categorized as underweight, 18.5-24.9 as normal, and >25 as over-weight (Stephen, 2009). The upper mid arm circumference of the upper left arm was measured at the midpoint between the tip of the shoulder and tip of the elbow. Mean and standard deviations of BMI-related information are summarized in Table 5.

Blood Collection and Laboratory Investigation

Skin was cleaned thoroughly and sterilized with 70% isopropyl alcohol swab (Kandall HealthCare, USA) and dried before withdrawing 2 mL peripheral blood using 5cc disposable syringe (Becton Dickinson Pak) from enrolled subjects. The blood was transferred to ethylenediamine tetra acetic acid (EDTA) coated purple-top test tube. The blood was mixed in the test tubes with 5 complete inversions and tubes were marked with codes and immediately taken to the laboratory for investigation. Hemoglobin concentrations were analyzed with the Chemical Analyzer (Microlab 300) by using Merck Kit. Hemoglobin derivatives in blood are converted quantitatively to hemoglobin cyanide (cyanomethoglobin) and measured on photometer.

Hb Adjusted for Altitude

Three altitude correction methods, the CDC, 1994, Dirren et al., 1996 and Dallman et al., 1980 were used in our study to adjust the hemoglobin concentration for altitude. They can be expressed as: CDC correction method: ΔHb = -0.032×(Alt)+0.022×(Alt)2, where δHb is the increment of Hb by increased altitude above sea level, and Alt is the altitude (1000 m×3.3); Dirren et al., correction method: Hb sea-level = Hb measured - 3.44×(e (0.000 633×Alt) -1), where Hb sea level stands for the concentration after adjustment, and Alt for altitude (m); and in Dallman et al., correction method: Hb increased by 4 g/L per 1000 m elevation above sea level [21-23].

Data Analysis

Sigmastat 3.5 and SPSS ver.18 were used for statistical analysis. Results were expressed by mean and standard deviation. Between the two groups, all results were checked by unpaired t-test and one way ANOVA. P values < 0.05 were considered as statistical significant.

RESULTS

A total of 242 subjects were enrolled in this study: 132 pregnant (72 from HA and 60 from LA) and 110 unmarried females (55 from HA and 55 from LA). According to the World Health Organization, anemia is defined as a condition in which the hemoglobin level is lower than the normal. Based on hemoglobin levels, the subjects were categorized as anemic (< 11g/dL) or non-anemic (> 12g/dL). Among the pregnant women, 26.39% were found to be anemic versus 73.63% non-anemic at HA while 68.33% were found to be anemic versus 31.67% non-anemic at LA (Table 1). Among the unmarried females, 5.45% and 21.82% were anemic at HA and LA, respectively. Higher percentage of non-anemic subjects (94.55%) at HA clearly indicates body’s adaptation to high altitude by increased concentrations of hemoglobin.

The ages of the subjects ranged from 18-45 years. At HA, the mean age of pregnant and unmarried females was 31.83 and 24 years whereas at LA, it was 30.70 and 23 years, respectively. The age group distribution was as follows: young (< 25 years), middle (26-35 years) and old (> 35 years). It was observed that old age group females were more prone to anemia (52.38%), followed by young (27.27%) and the least number of females were found in the middle age group (6.90%), showing high level of significance (p< 0.002) at high altitude. Similar trend was also recorded at low altitude (p< 0.07), with 85.00% anemic among the old age group, followed by young (70.00%) and middle (50.00%) age group females (Table 1). We did not found any significant correlation with maternal age across the altitudes (p value 0.7062).

Recurrent pregnancy is reported to be associated with decreased hemoglobin. We found anemia in 20.00% and 28.85% of subjects with primi-gravida and multi-gravida at HA, respectively. In addition, it was found that 69.23% and 68.08% primi-gravida and multi-gravida women were anemic at low altitude. The results from our study have shown that multi-gravida pregnant females have higher risk of anemia. However, we did not find any significant correlation between gravidity and hemoglobin concentration at any altitude (Table 1).

Socioeconomic and lifestyle data were obtained by a questionnaire that was administered in Quetta and Uthal. It elicited information on occupation, family income, education, smoking and tobacco chewing. Socioeconomic status had also shown to play a role in anemia frequency, with majority of the anemic subjects coming from middle/poor class families: 18/19 at HA and 41/41 at LA. Anemia prevalence in middle/poor class might be due to non-availability of the essential elements in their diet (Table 1).

Lack of education is one of the major risk factors for anemia. In general, uneducated (illiterate) females are unaware of balanced diet and hygienic conditions, which results in anemia and many other diseases. The results of this study demonstrate that most of the anemic subjects were illiterate in Uthal city (78.26%, p value < 0.006). Likewise, in Quetta city, 17 out of 19 anemic pregnant subjects were illiterate (Table 1). Full term pregnant females were categorized according to their tobacco use or smoking habits. Analysis of smoking frequency revealed that 62.50% smokers in Quetta and 86.96% smokers in Uthal city were anemic, showing strong correlation between smoking and anemia at HA (p< 0.02) and LA (p< 0.02) (Table 1).

Table 2 shows the hemoglobin levels of all subjects selected from high and low altitude. We found statistically significant difference in the mean hemoglobin levels among all groups: A and B, A and C, C and D, B and D. Our results confirmed that mean hemoglobin levels of pregnant as well as non-pregnant women were positively correlated with living at high or low altitude, i.e. 11.81 ± 1.02 (HA) vs 10.20 ± 1.28 (LA) (P < 0.001) in pregnant women while 14.75 ± 2.06 (HA) vs 13.4 ± 2.34 (LA) (P < 0.002) in non-pregnant women.

Table 3 shows the effects of diet and food consumption frequency on anemia incidences among pregnant women of HA and LA. Our results demonstrate a significant correlation between meat consumption and increased hemoglobin concentration (p < 0.01), that is, subjects consuming more beef/mutton or poultry products in their food had less anemic incidences whereas subjects with low or no intake of meat products more often suffered from anemia at both Quetta and Uthal city.

All the selected subjects were interviewed and examined for the signs and symptoms of anemia. It was observed that signs and symptoms were not the same in all pregnant females. Table 4 shows that at high altitude, the incidence of symptoms such as breathlessness, palpitation, pallor, pale conjunctiva and koilonychias were 27.77%, 18.05%, 25.00%, 18.05%, and 4.16% respectively, among all pregnant women subjects in general while higher incidences of the same symptoms were recorded among anemic pregnant women with a frequency of 60%, 61.54%, 55.56%, 76.92%, and 100% respectively. Except koilonychias symptom at low altitude, all studied signs and symptoms of anemia showed high significant correlation with anemia (p < 0.05).

Table 5 shows some important basic characteristics of pregnant women at high and low attitudes. Pregnant women at high altitude had significantly higher mean BMI (P < 0.001) and weight (P < 0.009) but significantly lower mean UMAC (P < 0.001). No statistical significance was found in systolic and diastolic blood pressure of pregnant women at HA and LA.

DISCUSSION

Anemia was more prevalent in LA Uthal area (68.33%) while results obtained from HA Quetta city showed lesser incidences of anemia (26.39%). We found 30 subjects (41.65%) of HA population had high hemoglobin concentration in comparison to 7 (11.67%) among the low altitude subjects. Studies have confirmed that at higher altitudes, i.e. above 1000 meters, hemoglobin levels increase as an adaptive response to hypoxic atmosphere, to the decreased partial pressure of oxygen and decreased oxygen saturation of blood [24-25]. Previous results have confirmed that mean hemoglobin levels were higher in pregnant women living at high altitudes, showing a positive association between hemoglobin and altitude [1, 26]. Our results support findings from previous studies that concentrations of hemoglobin are elevated in high-altitude populations.

Maternal age, multi parity, low BMI, and cigarette smoking have been reported in literature as risk factors for anemia during pregnancy [12]. Bhargawa et al., (2001) found that hemoglobin levels decrease with age and hemoglobin status is positively associated with height and UMAC (where height is a sign of good early nutritional state, while UMAC is dependent on the body mass). Our results showed that anemia was present in all maternal age groups with high prevalence in old maternal age, 52.38% for HA and 85% for LA [27].

Sharma et al., (2003) concluded that anemia in pregnancy is highly prevalent and it might be dependent on nutrition intake and mother’s health, genetic factors, and socioeconomic culture. Education is also an important factor since educated females are aware of anemia and the importance of nutrition during pregnancy. We found anemia to be common in illiterate subjects, 17/19 and 36/41 at HA and LA respectively. Agarwal et al., (2008) found that anemic mothers were illiterate and belonged to poor socioeconomic backgrounds. Our finding also matches with previous finding as 66.67% of LA anemic mothers belonged to poor socioeconomic backgrounds. In most underdeveloped and in many developed countries, iron deficiency is the main cause of anemia among women and studies have shown that iron supplementation can prevent or correct the anemia [3, 28]. Our study supports the statement that low socio economic status, poor diet and nutritional deficiencies are associated with anemia [4, 14, 29].

CONCLUSION

Anemia is very much prevalent worldwide and it happens mainly during pregnancy. Hemoglobin concentration is significantly correlated with altitude, increasing with elevated altitude. BMI (under weight) and smoking are also significantly related to altitude with high anemic incidence rates at LA. Maternal age is directly related to anemia. Occurrence of anemia is common in illiterate females of poor populations. Balanced diet with adequate meat products may reduce the risks of anemia among pregnant women.

APPENDIX

Table 1..

General Characteristics of anemic pregnant women residing at high and low altitudes.

Characteristics  High Altitude P value   Low Altitude P value
Hemoglobin Concentration Total
N = 72
Anemic (n = 19) Non Anemic (n = 53) Total
N = 60
Anemic (n = 41) Non-anemic
(n = 19)
Gravidity  
Primi-gravidity 20 04 (20.00%) 16 (80.00% 0.5581 13 09 (69.23%) 04 (30.77%) 1.000
Multi-gravidity 52 15 (28.85%) 37 (71.15%) 47 32 (68.08%) 15 (31.92%)
Maternal Age (years)  
15-25 22 06 (27.27%) 16 (72.73%) 0.0026* 20 14 (70.00%) 06 (30.00%) 0.0768
26-35 29 02 (06.90%) 27 (93.10%) 20 10 (50.00%) 10 (50.00%)
36-45 21 11
(52.38%)
10 (47.62%) 20 17 (85.00%) 03 (15.00%)
Education  
Illiterate 58 17
(29.31%)
41
(70.68%)
0.3275 46 36
(78.26%)
10 (21.74%) 0.0066*
Literate 14 2
(14.29%)
12
(85.71%)
14 5
(35.71%)
9
(64.29%)
Scio-economic status  
Upper Class 9 1
(11.11%)
08 (88.89%) 0.4284 2 0
(0%)
02
(100%)
0.0966
Middle Class 36 10
(27.78%)
26
(72.22%)
22 17
(77.27%)
05 (22.73%)
Lower Class 27 08 (29.63%) 19 (70.37%)   36 24
(66.67%)
12
(33.33%)
 
BMI (Kg/m2)  
< 18.5 (under weight) 5 03
(60.00%)
02
(40.00%)
0.1109 17 13
(76.47%)
04
(23.53%)
0.0018*
18.5-25 (normal) 38 08
(21.05%)
30 (78.95%) 27 13
(48.15%)
14
(51.85%)
< 25 (over weight) 29 08 (27.59%) 21
(72.41%)
16 15
(93.75%)
01
(06.25%)
Smoking  
Smokers 8 05
(62.50%)
03
(37.50%)
0.0261* 23 20 (86.96%) 3
(13.04%)
0.0216*
Non smokers 64 14
(21.88%)
50
(78.12%)
37 21 (56.76%) 16
(43.24%)

Significant (P < 0.05)

Table 2..

Comparative cross-sectional statistical analysis of Hemoglobin levels in pregnant women and unmarried females at high and low altitudes.

Parameters N Mean + Sth P Value
Group A
Group B
72
60
11.81 ± 1.02
10.20 ± 1.28
0.001*
Group A
Group C
72
55
11.81 ± 1.02
14.75 ± 2.06
0.001*
Group C
Group D
55
55
14.75 ± 2.06
13.40 ± 2.34
0.002*
Group B
Group D
60
55
10.20 ± 1.28
13.40 ± 2.34
0.001*

Significant (P < 0.05)

A= Hemoglobin level in pregnant women at high altitude

B= Hemoglobin level in pregnant women at low altitude

C= Hemoglobin level in unmarried women at high altitude

D= Hemoglobin level in unmarred women at low altitude

Table 3..

Dietary nature and anemia incidences among pregnant women at high and low altitudes.

Dietary Nature Frequency High Altitude Low Altitude
Total pregnant women N = 72 Anemic
N = 19
Non-anemic N = 53 P value Total pregnant women N = 60 Anemic
N = 41
Non-anemic N = 19 P value
Beef/ Mutton Don’t or low 12 (16.67%) 07 (58.33%) 05 (41.67%) 0.011* 45 (75.00%) 35 (77.78%) 10 (22.22%) 0.010*
  Weekly or daily 60 (83.33%) 12 (20.00%) 48 (80.00%)   15 (25.00%) 06 (40.00%) 09 (60.00%)  
Poultry Don’t or low 24 (33.33%) 11 (45.83%) 13 (54.17%) 0.011* 35 (58.33%) 30
(85.71%)
5 (14.29%) 0.001*
  Weekly or daily 48 (66.67%) 08 (16.67%) 40 (83.33%)   25 (41.67%) 11
(44.00%)
14
(56.00%)
 
Vegetables Don’t or low 05 (6.94%) 02 (40.00% 03 (60.00%) 0.6024 01 (1.67%) 0
(0%)
01 (100.00%) 0.3167
  Weekly or daily 67 (93.06%) 17 (25.37%) 50 (74.62%)   59 (98.33%) 41 (69.49%) 18 (30.51%)  
Pulses Don’t or low 13 (18.06%) 02 (15.38% 11 (84.62%) 0.4913 11 (18.33%) 06
(54.55 %)
05 (45.45%) 0.3007
Weekly or daily 59 (81.94%) 17 (28.81%) 42 (71.19%) 49 (81.67%) 35 (71.43%) 14 (28.57%)

Significant (P < 0.05)

Table 4..

Signs and symptoms of anemia among pregnant females of Balochistan.

Symptoms Status High Attitude N = 72 Low Attitude N = 60
Total N = 72 Anemic
N = 19
Non-anemic N = 53 P value Total
N = 60
Anemic
N = 41
Non-anemic N = 19 P value
Breathlessness + 20 (27.77%) 12 (60.00%) 8 (40.00%) 0.0002* 23 (38.33%) 22 (95.65%) 1 (4.35%) 0.0004*
- 52 (72.22%) 7 (13.46%) 45 (86.54%) 37 (61.67%) 19 (51.35%) 18 (48.65%)
 
Palpitation + 13 (18.05%) 8 (61.54%) 5 (38.46%) 0.0035* 20 (33.33%) 19 (95.00%) 1 (5.00%) 0.0013*
- 59 (81.95%) 11 (18.64%) 48 (81.36%) 40 (66.67%) 22 (55.00%) 18 (45.00%)
 
Pallor + 18 (25.00%) 10 (55.56%) 8 (44.44%) 0.0038* 29 (48.33%) 26 (89.66%) 3 (15.79%) 0.0008*
- 54 (75.00%) 9 (47.37%) 45 (84.90%) 31 (51.67%) 15 (48.39%) 16 (51.61%)
 
Pale Conjunctiva + 13 (18.05%) 10 (76.92%) 3 (23.08%) 0.0001* 39 (65.00%) 37 (94.87%) 2 (05.13%) 0.0001*
- 59 (81.95%) 9 (15.25%) 50 (84.75%) 21 (35.00%) 4 (19.05%) 17 (80.95%)
 
Koilonychias + 03 (4.16%) 03 (100%) 0 (0%) 0.0162* 07 (11.67%) 07 (100%) 0 (0%) 0.0859
- 69 (95.84%) 16 (23.19%) 53 (76.81%) 53 (88.33%) 34 (64.15%) 19 (35.85%)

Significant (P < 0.05)

Table 5..

Some other important study parameters.

Characteristics Pregnant women P Value Anemic Pregnant women P Value
  HA (n = 72)
Mean + Sth
LA (n = 60)
Mean + Sth
HA (n = 19)
Mean + Sth
LA (n =41)
Mean + Sth
Age 30.70 ± 7.24 31.83 ± 8.04 0.46 32.47 ± 8.34 31.92 ± 8.40 0.81
BMI 25.05 ± 4.52 22.31 ± 4.20 0.001* 24.41 ± 5.24 21.73 ± 4.10 0.038*
Weight 64.86 ± 12.22 59.08 ± 12.70 0.009* 60.31 ± 11.08 57.29 ± 13.16 0.38
Blood Pressure (Systolic) 116.66 ± 13.73 125.50 ± 102.56 0.471 118.42 ± 20.34 109.02 ± 15.13 0.050
Blood Pressure (Diastolic) 75.34 ± 9.54 73.00 ± 12.25 0.218 77.63 ± 14.56 72.92 ± 4.28 0.17
UMAC 28.30 ± 4.69 31.38 ± 5.51 0.001* 27.31 ± 3.99 30.4 ± 5.35 0.052

Significant (P<0.05)

ABBREVIATIONS

LA  =  low-altitude region
HA  =  high-altitude region
BMI  =  body-mass index
UMAC  =  upper mid arm circumference

CONFLICT OF INTEREST

The authors declare no conflict of interest.

ACKNOWLEDGEMENTS

Declared none.

AUTHORS’ CONTRIBUTIONS

ZU1 has performed the experiments. MA3 and AM4 have supervised the study. MR2 and AM7 have designed the study. MA3 and MR2 have written the manuscript. SK2, GM5 and MAK6 analyzed the data and reviewed the manuscript critically.

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