Helicobacter pylori, metabolic syndrome (MetS), and non-alcoholic fatty liver disease (NAFLD) are major public health problems globally. H. pylori are the most prevalent chronic bacterial infection of humankind, affecting more than 50% of the world's population.¹ Although the H. pylori prevalence has decreased mainly in developed countries, it is still high in many developing countries.¹ H. pylori infection is primarily associated with gastroduodenal diseases.² However, it may play an important role in various extraintestinal diseases such as MetS and NAFLD.³ MetS mainly includes hyperglycemia, hypertension, dyslipidemia, and central obesity.⁴ NAFLD is closely associated with MetS, obesity, and insulin resistance.⁵ The estimated global prevalence of MetS is 20–25%.⁶ The prevalence of MetS was found to be 32.5% in South Asia.⁷ NAFLD is one of the leading causes of chronic liver disease that affects 25.24% of the global population.⁸ The prevalence of NAFLD in Asia is 29.6%.⁹

H. pylori, MetS, and NAFLD have common pathogenetic mechanisms such as chronic inflammation, oxidative stress, and counterregulatory hormones.^10,11 MetS is a cluster of interconnected, co-occurring metabolic abnormalities that share a common pathophysiological mechanism.¹² Various inflammatory markers, particularly tumor necrosis factor-alpha (TNF-α), interleukin–6 (IL-6), and C-reactive protein (CRP), are elevated in MetS.¹² H. pylori infection releases proinflammatory and vasoactive mediators, promotes platelet activation and platelet–leukocyte aggregation, and produces reactive oxygen species.^10,11 It has recently been reported that H. pylori can cause hepatic insulin resistance, which is considered a crucial pathophysiological basis for MetS and NAFLD.¹³ NAFLD is considered the hepatic manifestation of MetS. An international consensus panel has proposed to rename NAFLD as metabolic-associated fatty liver disease (MAFLD).^14–16 NAFLD has also been found to be associated with gut dysbiosis.¹⁷ H. pylori infection causes changes in the gut microbiota.^18,19 Obesity and other metabolic syndrome parameters are related to alterations of gut microbiota.^20,21 Hence, there may be a possible connection between H. pylori infection, NAFLD, and MetS or components of the MetS.

The association of H. pylori with MetS and NAFLD is controversial. Nevertheless, such an association is plausible, particularly in areas where the prevalence of H. pylori, MetS, and NAFLD is high. Although the seroprevalence among the general adult population is currently unknown, selected population-based studies in Bangladesh reported high seroprevalences of H. pylori.^22,23 The prevalence of MetS and NAFLD was also found to be high in Bangladesh. A recent systematic review of the prevalence of MetS in Bangladesh found that 37% of the population had MetS.²⁴ The prevalence of NAFLD was found to be 34% in population-based studies in Bangladesh.²⁵ Establishing an association between H. pylori, MetS, and NAFLD has important clinical implications. If such an association is proved, H. pylori eradication may have a beneficial effect on MetS- and NAFLD-related morbidity and mortality. Therefore, we have conducted a study among a rural community of Bangladesh with the aims to : (i) estimate the seroprevalence of H. pylori, (ii) find the association between H. pylori and MetS, (iii) observe the association between H. pylori and the factors associated with MetS, and (iv) find the association between H. pylori and NAFLD.

This was a cross-sectional study with a house-to-house survey conducted among the adult population (≥18 years) of two villages, namely, Charcharia of Nawabganj upazila of Dhaka district and Kharrah of Srinagar upazila of Munshiganj district, in Bangladesh from April 2014 to February 2015. Three trained research assistants (RAs) conducted the interviews using a structured questionnaire and anthropometric measurements. The investigators performed clinical examinations. Ultrasonography of the hepatobiliary system and biochemical tests were carried out after overnight fasting. Figure 1 shows the study outline. One investigator entered the data, 10% of which were cross-checked by another investigator. The study protocol was approved by the Institutional Ethics Committee, and written informed consent was obtained from the participants.

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Figure 1. Study outline.

A structured questionnaire was used during interviews with the participants. The questionnaire had two subsections: (i) sociodemographic information and (ii) history of chronic disease and history of medication use. Sociodemographic data included age, gender, occupation, monthly family income, education, marital status, religion, smoking, and alcohol intake. History of chronic disease included DM, hypertension, dyslipidemia, chronic hepatitis B and C infections, autoimmune hepatitis, primary biliary cholangitis, and drug-induced liver injury. Medication history also included drugs taken for DM, hypertension, and dyslipidemia.

The trained RAs took anthropometric measurements that included height (cm), weight (kg), and waist circumference (cm). The investigators performed the clinical examinations to assess the presence of stigmata of chronic liver disease. Pulse, systolic (mm Hg) and diastolic (mm Hg) blood pressure (BP) were measured in the resting position and were recorded.

Venous blood samples were collected from fasting subjects using sterile disposable syringes and needles in an aseptic manner. Blood samples were centrifuged (4000 rpm), and serum samples were collected and stored at −20°C until assay for serum glucose, triglyceride (TG), total cholesterol (TCh), high-density lipoprotein cholesterol (HDL-C), and low-density lipoprotein cholesterol (LDL-C) using an automatic biochemistry analyzer (Roche, Rotkreuz, Switzerland). Serum samples were also tested for Immunoglobulin G (IgG) antibody responses to an H. pylori membrane protein (MP) antigen (Hel 305 MP) using an enzyme-linked immunosorbent assay (ELISA). A commercially available ELISA kit was used following the manufacturer's (Human, Wiesbaden, Germany) instructions.

Abdominal ultrasonography (Wuxi Haiying International Trade Co. Ltd., Wuxi, China) was performed by a senior radiologist trained in ultrasound on fasting patients in a community health service center to detect NAFLD. Fatty liver was diagnosed in the presence of two of the three following criteria: (i) increased hepatic echogenicity compared to the spleen or the kidney, (ii) blurring of liver vasculature, and (iii) deep attenuation of the ultrasonographic signal.²⁶

MetS was defined as per the Revised National Cholesterol Education Program, Adult treatment panel III (revised NCEP ATP III), which required the presence of three or more of the following features: (i) waist circumference ≥ 90 cm in men or ≥ 80 cm in women; (ii) TG level of 150 mg/dL or higher; (iii) HDL-C level less than 40 mg/dL in men and less than 50 mg/dL in women; (iv) systolic blood pressure (SBP) of 130 mm Hg or higher or diastolic blood pressure (DBP) of 85 mm Hg or higher; and (v) fasting plasma glucose level of 110 mg/dL or higher.²⁷ Obesity was defined as per the World Health Organization (WHO) criteria. Body mass index (BMI) ≥25, 25.0–29.99, and >30 kg/m² were defined as overweight, preobese, and obese, respectively.²⁸ Lean NAFLD and nonobese NAFLD were defined by BMI <23 kg/m² and <25 kg/m², respectively.²⁹ Diabetes mellitus (DM) was diagnosed if the fasting blood glucose (FBG) value was ≥7.0 mmol/L or the subject already had medications for DM. Impaired fasting glucose (IFG) was diagnosed if the FBG was between ≥6.1 and <7.0 mmol/L.³⁰

All statistical analyses were performed using STATA (Stata Statistical Software: Release 13. College Station, TX, USA: StataCorp LP). Descriptive statistics, such as proportion for categorical variables and mean and standard deviation for quantitative variables, were used to summarize the data. Chi-square and proportion tests were used to observe the association between two categorical variables, and a t-test was used to find the mean difference between two groups of a normally distributed continuous variable. A linear regression model was used after adjusting for age, gender, religion, marital status, smoking habit, education, and occupation to observe the adjusted mean difference of parameters of MetS between H. pylori serology-positive and -negative subjects. Multiple logistic regression was used to assess the association between H. pylori serology and gender, religion, BMI, DM, marital status, smoking, occupation, education, MetS, and NAFLD.

Of 1021 subjects, 781 (76.49%) responded, and 767 were included in the final analysis after excluding 14 subjects who had a history of any amount of alcohol consumption (Fig. 1). Of them, 495 were female (64.5%). The mean age of the study subjects was 40.35 ± 15.56 years.

Overall, positive IgG-specific anti-H. pylori antibodies in serum were found in 418 of 767 (54.5%) participants. There was no difference in age between subjects with and without H. pylori (mean age 39.77 ± 14.65 years vs mean age 40.97 ± 16.48; P = 0.25). Age- and gender-specific seroprevalence of H. pylori is shown in Figure 2.

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Figure 2. Age- and gender-specific prevalence of Helicobacter pylori. *Pvalue > 0.05. ([Image omitted. See PDF.]), Male; ([Image omitted. See PDF.]), female; ([Image omitted. See PDF.]), overall.

Table 1 shows the sociodemographic characteristics and presence of MetS and NAFLD of the subjects with and without H. pylori seropositivity. The prevalence of seropositivity among males was higher than females (59.6 vs 51.7%, P = 0.037). The prevalence of seropositivity of H. pylori was more common among married individuals compared to a single person (57.4 vs 42.2%, P = 0.001), cultivators compared to homemakers and other occupations (54 vs 52.2%, P = 0.038), and smokers compared to nonsmokers (63.2 vs 52.7%, P = 0.039).

Table 1 Sociodemographic characteristics, metabolic syndrome, and non-alcoholic fatty liver disease among Helicobacter pylori seropositive and seronegative subjects

H. pylori seropositivity was more common among participants with underweight (66.4%) compared to those with normal weight (56.1%) and overweight (46.9%) and obesity (44.8%) (P = 0.003). The mean BMI of the H. pylori seropositive persons was lower than the seronegative person (22.7 ± 4.45 kg/m² vs 23.85 ± 4.45 kg/m², P < 0.001). Overall, MetS was present in 254 (33.1%) participants. There were no differences in the frequencies of DM or MetS between H. pylori seropositive and seronegative subjects, as shown in Table 1.

NAFLD was present in 141 (18.4%) participants. The frequency of NAFLD was lower among the H. pylori seropositive subjects compared to the seronegative subjects (14.8 vs 22.6%), as shown in Table 1. Among the NAFLD subjects, 42 (29.8%) were nonobese, 99 (70.2%) were obese, 19 (13.5%) were lean, and 122 (86.5%) were nonlean. There were no differences in the frequency of H. pylori seropositivity among the participants with nonobese compared to obese NAFLD (19/42 [45%] vs 43/99 [43.4%], P = 0.844) and lean compared to nonlean NAFLD (9/19 [47.4%] vs 53/122 [43.4%], P = 0.784).

On multivariate analysis, the presence of underweight and being married was found to be the risk factor for H. pylori seropositivity, as shown in Table 2.

Table 2 Multivariate analysis of risk factors of Helicobacter pylori seropositivity

Table 3 shows the comparison of H. pylori seropositive with seronegative subjects regarding waist circumference, systolic blood pressure (SBP), diastolic blood pressure (DBP), FBG, fasting TCh, HDL-C, LDL-C, and TG. Mean SBP and serum LDL-C were significantly lower among subjects with H. pylori seropositivity on univariate analysis (Table 3). After adjusting for age, gender, religion, marital status, smoking status, education, and occupation in the linear regression model, SBP and LDL-C were 2.95 mm Hg and 7.79 mg/dL lower, respectively, among H. pylori seropositive subjects compared to seronegative subjects (Table 4).

Table 3 Helicobacter pylori serostatus and parameters of metabolic syndrome

Table 4 Effects of H. pylori serostatus on metabolic syndrome-related variables

This cross-sectional study was conducted in a population living in a rural community in Bangladesh. High seroprevalence (54.5%) of H. pylori among the adult population was observed. H. pylori seropositivity was more common among the underweight than normal or overweight-obese subjects. The H. pylori serostatus was not associated with MetS, NAFLD, or DM. However, after adjusting for age, gender, religion, marital status, smoking status, education, and occupation in the linear regression model, H. pylori seropositive subjects had significantly lower SBP and serum LDL-C compared to seronegative subjects.

The prevalence of H. pylori infection among the selected population has been reported to be high in Bangladesh. A urea breath test-based study among the young population has demonstrated that 84% of children become infected with H. pylori by 6–9 years in Bangladesh.²³ Another pilot study conducted in 1995 reported 92% seropositivity of H. pylori among the asymptomatic adult overseas job seekers.²² A study, conducted two decades later, on similar overseas job seekers reported 71% seropositivity for H. pylori infection.³¹ Although there was a methodological limitation with small sample size, those studies nevertheless demonstrated that the seroprevalence was high among the asymptomatic adult population in Bangladesh and highlighted the need for a large-scale community-based study. This study addressed the issues and surveyed a community with a larger population group, which we believe to be a representative sample from Bangladesh's perspective. Compared to those previous studies, the present study demonstrated a lower rate of seropositivity in the adult population. Improved health awareness, personal hygiene, and socioeconomic or educational status over the past few years³² or widespread use of the antimicrobial drugs in Bangladesh could be the reason for this lower seropositivity observed in the present study. This finding of the current seroprevalence of H. pylori is consistent with a recent systematic review and meta-analysis on the global prevalence of H. pylori, which found that the prevalence varied from 43.1 to 79.5% in Asia with a prevalence rate of 61.6% in Southern Asia.¹

MetS is a cluster of metabolic abnormalities for which insulin resistance (IR) plays a pivotal role.¹² The potential association of H. pylori infection with MetS and its components, including obesity, dyslipidemia, DM, and NAFLD, is controversial. There are several plausible mechanisms of such associations. H. pylori infection causes hepatic insulin resistance through the c-jun/suppressor of cytokine signaling (SOCS) 3 pathway.¹³ H. pylori releases proinflammatory and vasoactive mediators like IL-1, IL-6, IL-8, IL-10, IL-12, TNF-α, interferon ϒ, leukotrienes, and prostaglandins and acute phase reactants like fibrinogen and CRP, which are also involved in the pathogenesis of IR. H. pylori infection promotes platelet activation and aggregation, which may also play a role in IR. In addition, H. pylori infection produces reactive oxygen species involved in the pathogenesis of IR syndrome.^10,11,13,33

The present study did not find any association of H. pylori seropositivity and MetS. Similar findings were reported by Naja et al., who did not find any association of H. pylori infection with IR and MetS among the Lebanese adults.³⁴ Although a meta-analysis with significant heterogeneity found an association between H. pylori and MetS,³⁵ an inverse relationship was found between CagA-positive H. pylori infection and fatal cardiovascular events, according to a population-based cohort study in Germany.³⁶ High frequency of H. pylori-associated virulence factors, particularly in the present study population, has been reported earlier.³⁷

Association of H. pylori with NAFLD remains controversial as some of the epidemiological studies found an association,^38,39 whereas others did not.^40,41 Possible mechanisms of pathogenesis of NAFLD induced by H. pylori include (i) insulin resistance; (ii) inflammatory cytokines or adipokines, particularly CRP, TNF-α, and IL-6; (iii) altered lipid profile; and (iv) altered intestinal permeability and gut microbiota.⁴² H. pylori seronegativity was associated with NAFLD in univariate analysis but not in multivariate analysis in the present study. A few recent meta-analyses of observational studies suggest a positive association between H. pylori and NAFLD.^5,43,44 However, there are concerns due to moderate to high heterogenicity and significant publication bias in those studies.⁵

No relationship was found between H. pylori infection and DM, and this finding corroborated sufficiently with previous findings.^45,46 Although a meta-analysis of case–control studies found a significant association between H. pylori and DM, the authors acknowledged significant heterogenicity.⁴⁷ Therefore, the association between H. pylori infection and DM remains inconclusive.

Some epidemiological studies found an association of H. pylori infection with obesity,^48,49 whereas others have failed to show such an association.^50,51 In the present study, H. pylori infection was associated with underweight rather than obesity. In a case–control study in Taiwan, H. pylori were more common among normal or underweight subjects than in obese subjects.⁵² The low BMI or underweight among H. pylori-infected patients may result from persistent gastric inflammation, resulting in the dysregulation of appetite and calorie homeostasis, mediated by the gut hormone ghrelin. It has been shown that childhood acquisition of H. pylori infection may cause decreased appetite and low BMI.^53,54 H. pylori-associated dyspepsia may further deteriorate nutritional status in infected subjects, without such an infection occurring in adult life. Moreover, it has been found that, after eradication, H. pylori-infected patients gained weight.^55,56 Most of the H. pylori infection occurs in childhood in Bangladesh.²³ Such H. pylori acquisition in childhood may result in low BMI among the seropositive subjects in adult life. A recent study from Bangladesh found an association between H. pylori infection and fecal biomarkers of environmental enteric dysfunction among children. These findings suggest that the acquisition and persistence of H. pylori infection in the early years of life may exert an adverse impact on intestinal health and induce gut inflammation, resulting in increased intestinal permeability, and may cause malnutrition in adult life.⁵⁷

Gut microbiota has been found to play an essential role in the pathogenesis of obesity.^20,21 Dysregulated production of inflammatory adipokines caused by excess or dysfunction of adipose tissue can contribute to the development of IR and obesity-related metabolic diseases, including NAFLD.⁵⁸ Alterations of gut microbiota or dysbiosis have also been demonstrated in H. pylori infection.^18,19 The present study indicates more common seropositivity among underweight populations, therefore, suggesting a need for further study elucidating relationship betwee H. pylori and dysbiosis.

In the present study, H. pylori seropositivity was associated with low LDL-C and low SPB. Such a relationship may result from low BMI and underweight among the H. pylori seropositive subjects. The effects of eradication of H. pylori on lipid profiles have been found to be contradictory. An open-label study among dyspeptic patients found a significant decrease in the serum levels of total cholesterol and LDL-C 3 months after H. pylori eradication.⁵⁹ On the other hand, a case–control study found that eradication of H. pylori significantly increases the incidence of hyperlipidemia and obesity in patients with a peptic ulcer.⁵⁶ In another study, eradication of H. pylori was associated with a significant increase in total cholesterol, TGs, and HDL-C.⁶⁰

The inconsistent findings of the association between H. pylori and MetS and its components, including DM, NAFLD, obesity, and dyslipidemia, may be attributed to few factors. First, there are differences in study populations, such as diseased patients, elderly subjects, healthy volunteers, or the general population. Second, there are concerns about the methodology used to diagnose H. pylori infection, such as serology or urea breath test. Third, there are differences in the definition of MetS used in different studies. Fourth, there are differences in the BMI cutoff points used to define weight status. Fifth, there are differences in study settings, such as hospital versus community. Finally, there are variations of the degree of adjustment for potential confounders. Such adjustment is essential as the pathogenesis of MetS and its component parameters are multifactorial, which includes genetic susceptibility, environmental factors, immune response, personal habit, and phenotypic expression.⁶¹

One of the present study's limitations is that it was conducted in a selected area in Bangladesh. As Bangladesh is a small country, and 80% of the population lives in rural areas, the seroprevalence of H. pylori as observed may represent the majority of the population of the country. Moreover, this study attempts to find an association between H. pylori and MetS and NAFLD in a rural South Asian population. Such data from a rural region is notably less or unreported. Another limitation may be that the dietary assessment of the study participants was not investigated in this study. To the best of our knowledge, this is the first study demonstrating about half of the population being seropositive for H. pylori infection in Bangladesh. This finding has important implications for selecting the appropriate management strategies for H. pylori infection.

In conclusion, although just above half of the rural community population is seropositive to H. pylori infection, it is not associated with MetS, including DM and NAFLD in Bangladesh.

We are thankful to the Bangladesh Medical Research Council for partial funding of the study. We thank Gastroliver Foundation, Bangladesh; Popular Diagnostic Center, Dhaka, Bangladesh; and Mukti Specialized Hospital, Dhaka, Bangladesh, for support in conducting this study.