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. 2018 Winter;9(1):54–59. doi: 10.22088/cjim.9.1.54

Relationship between β-Thalassemia minor and Helicobacter pylori infection

Mohammad Zamani 1,2, Amin Vahedi 1, Ahmad Tamaddoni 3, Ali Bijani 4, Mojgan Bagherzade 5, Javad Shokri-Shirvani 2,6,*
PMCID: PMC5771361  PMID: 29387320

Abstract

Background:

Until now, no study has been reported investigating the association between β-thalassemia minor and Helicobacter pylori (H. pylori) infection. This study was designed to compare H. pylori infection rate between β-thalassemia minor patients and healthy controls.

Methods:

A number of 100 β-thalassemia minor patients (50 males, 50 females) and 100 gender-matched healthy controls were prospectively recruited in this study in a period of 3 months. The study population consisted of the people who referred to a health center in Babol, North of Iran, for premarital counseling. H. pylori status was assessed by measuring the anti-H. pylori IgG antibodies using enzyme-linked immunosorbent assay. Demographic information and informed consent were collected from all participants.

Results:

The overall H. pylori infection rate was 43%. The infection was significantly more prevalent in thalassemia patients (53%) than in the controls (33%) in both univariate (OR=2.29, 95% CI: 1.3-4.06) and multivariable analyses (OR=2.05, 95% CI: 1.12-3.76). Age was the only significant factor which was positively correlated with the infection in β-thalassemia minor cases (OR=1.11, 95% CI: 1.02-1.2). Gender, blood groups, residency, and education level were not related to the infection.

Conclusions:

According to the results, it can be concluded that β-thalassemia minor patients are possibly more susceptible to H. pylori infection than healthy people. Further studies are needed to discover more about the exact mechanisms of increased susceptibility to H. pylori infection in β-thalassemia minor patients.

Key Words: Helicobacter pylori, thalassemia minor, prevalence

Thalassemia is a common genetic disorder characterized by a point mutation on globin gene expression(1). β-thalassemia is the result of impaired production of β-globin chains. This hemoglobinopathy has three principal forms, including thalassemia major, thalassemia intermedia and thalassemia minor (2). The clinical manifestations, such as mild microcytic and hypochromic anemia, are fully related to level of production of β-globin chain (3). The prevalence of β-thalassemia is seen more frequently in the Mediterranean countries, the Middle East and Central Asia (1, 4). Helicobacter pylori (H. pylori), a gram-negative bacterium, colonizes the human gastric mucosa. This pathogen is the main cause of chronic gastritis, peptic ulcer, gastric cancer and dyspepsia (5, 6). The prevalence of H. pylori infection is seen in about half of the worldwide population and it is higher in the developing countries than in the developed countries (7, 8). Iran, a country, in the Middle East is an endemic region of thalassemia. About 20,000 homozygote β-thalassemia and 3,750,000 carriers have been identified in this country (9). All couples should be checked for β-thalassemia before marriage in Iran and those who are both carriers receive premarital counselling (10, 11).

In North of Iran, β-thalassemia minor is the most frequent state of β-thalassemia and is estimated about 10% of the population(12). Taking into account the remarkable concurrent prevalence of β-thalassemia minor and H. pylori infection in northern Iran(10, 12, 13), and considering the high rate of gastric diseases among these thalassemia patients in this area, it appears that there may be an association between H. pylori and β-thalassemia minor. There have been some articles showing a probable relationship between H. pylori and recurrent abdominal pain (RAP) in people with hemoglobinopathies, such as sickle cell anemia and β-thalassemia (14, 15).

In a survey by Karimi et al.(16), H. pylori infection in the β-thalassemia major patients with RAP was more common than in non-thalassemic controls with RAP. Although the difference was not significant, the authors suggested that H. pylori can possibly increase the risk of RAP in thalassemia patients (16).

In the present study, we aimed to compare the prevalence of H. pylori infection between β-thalassemia minor patients and normal controls in Babol, north of Iran.

Methods

Study population and data collection: This prospective study was performed on the people who refered to one of the health centers in Amirkola, Babol. This place is the major referral center for premarital thalassemia sreening in Babol.

A series of 100 persons who were confirmed diagnosis of β-thalassemia minor were consecutively included in the study (50 males, 50 females) during December 2015-February 2016. To confirm β-thalassemia minor, all participants' blood samples were checked initially for complete blood count (mean corpuscular volume<80 and mean corpuscular hemoglobin<27) and then for hemoglobin A2 using high-performance liquid chromatography (hemoglobin A2>3.5).

An equal number of controls, whose genders were compatible, were enrolled in this survey. The recruited controls were those who referred to the same health center. Demographic information (age, gender, blood group, residency, and education level) was obtained from all individuals.

Serum samples of the groups were collected and transmited to the immunology laboratory of Babol University of Medical Sciences and stored frozen at -20°C. To determine the infection, anti-H. pylori IgG antibodies were measured using enzyme-linked immunosorbent assay (ELISA) kits (IBL, Hamburg, Germany). Samples were considered positive for H. pylori when the antibody levels were more than 12 U/ml.

The study was approved by the Ethics Committee of Babol University of Medical Sciences and Health Services, the reference number is MUBABOL.REC.1395.71. Written informed consent was taken from all participants.

Chi-square and student's t-test were used to compare the demographic factors between case and control groups. To evaluate the association between H. pylori infection and β-thalassemia minor, we used the multivariable logistic regression analysis adjusted for residency and education by calculating odds ratio (OR) and 95% confidence interval (CI). The univariate analysis was performed to determine the relationship between the demographic variables and H. pylori infection in the β-thalassemia minor patients. A p<0.05 was considered statistically significant.

Results

The mean age of β-thalassemia minor and control subjects was 25.21±5.92 (range, 14-46) and 26.12±7.13 (range, 14-68) years, respectively. Fifty-one percent of the individuals had blood type O, and majority of them (97%) were RH positive. Forty- eight percent of β-thalassemia minor patients and 65% of controls were urban inhabitants, and the difference was significant (P=0.015). There were significant differences between the two groups in the educational status and thalassemia subjects have lower level of education than controls (p<0.001) (table 1).

Table 1.

Demographic characteristics of the participants

Thalassemia
n(%) 		Control
n(%) 		P-value
Gender 1
Male 50 (50) 50 (50)
Female 50 (50) 50 (50)
Age (year) 25.21±5.92 26.12±7.13 0.327
ABO Blood group 0.972
A 15 (15) 17 (17)
B 28 (28) 27 (27)
AB 6 (6) 5 (5)
O 51 (51) 51 (51)
Rhesus (Rh) blood groups 1
Rh Positive 97 (97) 97 (97)
Rh Negative 3 (3) 3 (3)
Residency 0.015
Urban 48 (48) 65 (65)
Rural 52 (52) 35 (35)
Education level 0.0001
Below diploma 36 (36) 12 (12)
Diploma 20 (20) 28 (28)
Bachelor’s degree 44 (44) 60 (60)
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*

100 subject in each group

Overall, the prevalence of H. pylori was 43% in the study population. This rate was higher in β-thalassemia minor group (53%) compared with controls (33%), and the difference was significant (odds ratio [OR]=2.29, 95% CI: 1.3-4.06, P=0.005). This significant difference was observed between the groups even after adjustment for residency and education (OR=2.05, 95% CI: 1.12-3.76, P=0.02) (table 2).

Table 2.

Comparison of H. pylori infction between β-thalassemia minor and normal subjects

H. pylori positive
N (%) 		Univariate
OR (95% CI) 		P-value Adjusted a
OR (95% CI) 		P-value
Normal 33 (33) 1 1
β-thalassemia minor 53 (53) 2.29 (1.3-4.06) 0.005 2.05 (1.12-3.76) 0.02
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a

Adjusted for residency and education. CI: confidence interval; OR: odds ratio

Table 3 shows the association between H. pylori infection and risk factors in the β-thalassemia minor cases. Age was the only factor significantly positively associated with the infection (OR=1.11, 95% CI: 1.02-1.2). No significant correlation was found between H. pylori infection and other variables, including gender, ABO and Rh blood groups, residency, and education.

Table 3.

Relationship between H. pylori infection and sociodemographic factors of β-thalassemia minor patients

H. pylori positive
n(%) 		H. pylori negative
n(%) 		OR (95% CI) P-value
Gender
Male 30 (60) 20 (40) 1
Female 23 (46) 27 (54) 0.57 (0.25-1.25) 0.16
Age - - 1.11 (1.02-1.2) 0.009
ABO Blood group
A 9 (60) 6 (40) 1
B 14 (50) 14 (50) 0.66 (0.18-2.37) 0.532
AB 4 (66.7) 2 (33.3) 1.33 (0.18-9.72) 0.777
O 26 (51) 25 (49) 0.7 (0.21-2.23) 0.539
Residency
Urban 23 (48) 25 (52) 1
Rural 30 (57.7) 22 (42.3) 1.49 (0.67-3.26) 0.329
Education level
Below diploma 23 (64) 13 (36) 1
Diploma 11 (55) 9 (45) 0.7 (0.22-2.1) 0.515
Bachclors degree 19 (43) 25 (57) 0.43 (0.17-1.06) 0.067
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CI: Confidence Interval; OR: Odds Ratio

Discussion

According to the results of this study, the prevalence of H. pylori infection was significantly higher in β-thalassemia minor patients than in the normal subjects. This is the first study reporting a significant association between β-thalassemia minor and H. pylori infection. In the past, few studies were performed to investigate the relationship between H. pylori infection and hemoglobinopathies, such as sickle cell anemia and β-thalassemia major, mostly based on determining the role of this pathogen in the occurrence of RAP in the patients with such diseases. Regarding sickle cell anemia, studies demonstrated controversial results about the relationship between H. pylori infection and this anemia (15, 17, 18). On the other hand, in relation to β-thalassemia major, surveys revealed no significant association between the infection and thalassemia. In their study, Karimi et al.(16) reported that the rate of H. pylori positivity in the β-thalassemia major patients with RAP was a little higher than in the healthy controls with the same symptoms (68% compared with 60%, p>0.05). Although the difference was not statistically significant, the authors proposed this pathogen as a potential cause of the RAP in the thalassemia patients(16). Also, the study by Balci et al.(14) indicated no significant differences between β-thalassemia major patients and non-thalassemic controls, both presenting with RAP, neither in serum anti-H. pylori IgG ELISA test (58.1% in comparison with 48.8%) nor in urea-breath test (48.4% compared with 39%). Nevertheless, there was not any report about the association of β-thalassemia minor with H. pylori infection and additional investigations are needed.

We believe that higher H. pylori infection rate in the β-thalassemia minor patients compared with controls in our study, may be related to the overload of iron. It is well-documented that iron is one of the essential factors for the pathogens to thrive in the host environment (19, 20), and H. pylori is no exception. Some published data proposed that H. pylori infection may cause iron-related diseases, such as anemia, iron deficiency, and iron deficiency anemia, in both children and adults (21-23), although other reports were not in accordance with these findings (24, 25). Considering that previous studies suggested a correlation between iron overload and increased risk of infections in the β-thalassemia patients (4, 26, 27), and also given that the iron excess can be seen mildly in the β-thalassemia minor patients(28, 29), it can be concluded that the overload of iron may lead to increase susceptibility to H. pylori infection. However, there is still no evidence supporting the hypothesis that iron overload is responsible for H. pylori infection in the β-thalassemia minor patients. So, more surveys should be done to uncover this dilemma.

In our study, it was observed that the seroprevalence of H. pylori had a positive correlation with age. This finding is in agreement with the previous literature showing the effect of birth cohort on H. pylori infection (30-32). By contrast, the prevalence of H. pylori was not different between two genders. There are no compatible findings on this topic. Moreover, the question of who is more susceptible to infection has remained open, that is, it is not clear if the infection occurred more frequently in males or in females (33-36). Regarding blood groups, no significant relationships were found between H. pylori positivity and blood groups ABO and Rh in the present study. While some previous reports alluded to these correlations (37, 38), others refuted them (39, 40).

Besides, there were no associations found between H. pylori infection and residency and education. With regard to this subject, previous surveys indicated that low socioeconomic status can increase the risk of infection. Yet, there were inconsistent results whether the infection rate is higher in inhabitants of rural areas or in people living in the cities (41, 42). Furthermore, H. pylori infection has been identified less frequently in people with higher levels of education than persons with lower education in most of the studies (43-45). These different findings show that high literacy of the individuals can cause them to pay more attention to health and hygiene issues.

A limitation of our survey was that the sample size was relatively small for assessing the relation between infection and variables in the thalassemia group. Definitely, the number of sample size was enough for evaluating the main purpose of the study, given that a significant correlation was found between beta-thalassemia minor and H. pylori infection.

In conclusion the results indicated that β-thalassemia minor patients are about two times more at risk of H. pylori infection in comparison with controls. The infection was significantly associated with age and not with type of blood, residency and education among the thalassemia patients. Further studies are needed to be designed for a more precise investigation of the mechanisms leading to increased susceptibility to H. pylori infection in β-thalassemia minor patients.

Acknowledgments

The authors would like to thank the staff of the Health Center of Amirkola, Babol, for their kind efforts.

Funding:

This study was financially supported by the Vice-Chancellery for Research and Technology of Babol University of Medical Sciences.

Competing Interests:

The authors declare no conflict of interest.

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