https://orcid.org/0000-0001-6904-8828
Figures
Abstract
Helicobacter pylori infection does not belong to the spectrum of opportunistic infections in people living with HIV (PLHIV). To evaluate the Helicobacter pylori infection prevalence rate trends in HIV co-infected individuals in comparison to the HIV-negative population, we compared histopathological findings of H. pylori positive gastritis (gastritis topography and histopathology) between 303 PLHIV and 2642 HIV-negative patients who underwent esophagogastroduodenoscopy (EGD) between 1993 and 2014 due to dyspeptic symptoms. The prevalence of H. pylori infection was significantly higher in HIV-negative controls than in PLHIV (50.2% vs. 28.1%). A significantly positive linear trend of H. pylori co-infection in PLHIV was revealed in the observed period (b = 0.030, SE = 0.011, p = 0.013), while this trend was significantly negative in HIV-negative patients (b = - 0.027, SE = 0.003, p < 0.001). Patients with HIV/H. pylori co-infection had significantly higher CD4+ T cell counts and more often had undetectable HIV viremia, due to successful anti-retroviral therapy (ART). Stomach histopathological findings differed between HIV co-infected and H. pylori mono-infected patients. Our findings confirm that the ART has changed the progression of HIV infection, leading to a significant increase in the prevalence of H. pylori infection in dyspeptic PLHIV over time. Our data also suggests that a functional immune system may be needed for H. pylori-induced human gastric mucosa inflammation.
Citation: Spurnic AR, Bukumiric Z, Jevtovic D, Brmbolic B, Pekmezovic T, Salemovic D, et al. (2021) Helicobacter pylori infection rates in dyspeptic Serbian HIV-infected patients compared to HIV-negative controls. PLoS ONE 16(3): e0248041. https://doi.org/10.1371/journal.pone.0248041
Editor: Giuseppe Vittorio De Socio, Azienda Ospedaliera Universitaria di Perugia, ITALY
Received: May 30, 2020; Accepted: February 18, 2021; Published: March 10, 2021
Copyright: © 2021 Spurnic et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: The authors received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Helicobacter pylori (H. pylori) is the most common bacterial infection in the world [1]. It is estimated that nearly half of the world population harbors this bacteria [2]. Several factors are essential for the infection establishment, and they include environmental, bacterial, and host factors [3, 4].The acute infection is mostly asymptomatic [5]. However, most of the infected individuals cannot overcome the infection, so it may persist for decades, causing chronic gastritis that can sometimes lead to gastric ulcer, or even gastric adenocarcinoma [6] or mucosa-associated lymphoid tissue (MALT) lymphoma, along with various extra-gastrointestinal manifestations of the disease [7].
It has been observed that the prevalence of H. pylori infection varies over time in different geographical regions, even within the same population. The prevalence is rather low in industrialized countries, while it reaches much higher levels in developing and underdeveloped countries, mostly among children. There are no available data for its prevalence in the Republic of Serbia, while in the neighboring Republic of Croatia it is 60.4% [8].
Human Immunodeficiency Virus (HIV) was isolated and identified as the causative agent of the Acquired Immunodeficiency Syndrome (AIDS) in 1985, at the same time when H. pylori was discovered [9, 10]. HIV primarily causes the impairment of cell-mediated immunity, which makes the infected individuals highly susceptible to the development of opportunistic infections and opportunistic tumors. It has been shown that H. pylori does not belong to the spectrum of HIV-related opportunistic infections. H. pylori may occur in early phases of HIV infection, when the immune function is still relatively preserved [11, 12]. According to the published data, the prevalence of H. pylori infection among people living with HIV (PLHIV) varies between 10–80% in different geographical regions and pertinent populations [13–17]. We have previously reported that the prevalence of H. pylori infection among Serbian AIDS patients was 25.8% [18]. Most of the clinical studies aiming to compare the H. pylori infection in HIV co-infected and in HIV negative patients, demonstrated lower prevalence of this infection among PLHIV than in the HIV negative population. However, the increase of H. pylori co-infection prevalence was observed in the era of highly active antiretroviral therapy (HAART) [19–21].
The role of HAART and the consequent immune reconstitution, use of antibiotics, as well as proton-pump inhibitors (PPI) and H2 blockers, along with hypochlorhydria, body mass index (BMI) and lifestyle on H. pylori prevalence among PLHIV have all been addressed in numerous studies [11].
The study presented here aimed to analyze the H. pylori infection incidence among dyspeptic HIV co-infected individuals and HIV negative patients during the period between January 1st 1993 and December 31st 2014, encompassing both the pre-HAART and HAART era.
We also compared histopathological findings of H. pylori-positive gastritis (gastritis topography and histology) in PLHIV and HIV negative patients.
Materials and methods
This retrospective case-control study was conducted at the Belgrade University Hospital for Infectious and Tropical Diseases, the reference center for HIV and AIDS management in Serbia.
The Study was approved by the Ethics Committee of Clinical Centre of Serbia and granted by the Ministry of Education, Science and Technological Development of the Republic of Serbia [No. 175073].
The survey protocol was conducted according to the Declaration of Helsinki. All survey participants signed informed consent forms before EGD was performed.
Study population
Study inclusion and exclusion criteria.
All patients who had dyspeptic symptoms lasting up to three months before esophagogastroduodenoscopy (EGD) and who underwent their first EGD between January 1993 and December 2014 were included in the study. Dyspeptic symptoms comprised epigastric discomfort (pain), nausea, vomiting, heartburn, burping, body weight loss, bloating and stomach cramps. The study group were PLHIV, while the controls consisted of HIV negative patients from the general population. Patients with gastrointestinal bleeding (haemathemesis, melena), odynophagia, dysphagia (indicating possible opportunistic diseases), chest pain, and those younger than 18 years were excluded from the study.
Each patient/control was enrolled in the study only once.
Data collection and instruments.
We collected demographic data (age, gender), risk factors for HIV acquisition, duration of HIV, CD4+ cell counts, HIV viral load, and the history of antiretroviral therapy (ART) from the hospital database. The CD4+ cell counts and HIV viral loads were considered relevant if the blood sample for their determination was taken within 1 month before or after EGD. Histopathological data were collected from the database of the Institute of Pathology, Faculty of Medicine, University of Belgrade.
The HIV status was determined using commercial immunoassays, in accordance with the manufacturer´s protocol. The CD4 cells were quantified by flow cytometry (Becton Dickinson BD FACS Count). Plasma HIV-1 RNA loads were measured with EDTA collected plasma samples, frozen at -20°C, using commercial RT-PCR tests. The usage of PCR tests and their limits of detection, expressed as copies per milliliter (cps/ml), varies over time according to what was available on the market. From 1997 to 2008 Roche Amplicor HIV-1 Monitor Test was used, with the range of detection of 400 cps/ ml– 750000 cps/ml, while from 2008 to 2016 COBAS AmpliPrep/CobasTaqMan HIV version 1.5, with the range of detection from 48 cps/ml– 10 000 000 cps/ml was used, and recently, in 2016, COBAS HIV-1 4800/6800/8800 with the range of detection from 20 cps/ml– 10 000 000 cps/ml of plasma was introduced.
Endoscopy and histopathology
All patients underwent EGD after the informed consent was signed. EGD was performed in the standard manner using Olympus video endoscope. Four gastric biopsy specimens were taken from each patient (two from the corpus and two from the antrum). Endoscopic diagnosis was recorded using standard terminology. Biopsies were taken from macroscopically normal tissue and macroscopically pathological areas. Biopsy samples were fixed in formalin, embedded in paraffin, cut into 4-μm sections, and stained by hematoxylin and eosin (H&E) and modified Giemsa stain. The stage of gastritis was scored in accordance with the Sydney classification [22].
H. pylori diagnosis
Diagnosis of H. pylori infection was conducted by histopathological examination using a modified Giemsa staining protocol outlined by Gray S et al. [23].
Statistical analyses
All analyses were performed using an electronic database organized in the IBM SPSS Statistics 22 (SPSS Inc., Chicago, IL, USA) statistical package. Patients’ demographic characteristics were analyzed using descriptive statistical methods, while non-parametric variables were analyzed using Fisher’s exact test and Wilcoxon signed-rank test, as appropriate.
While the differences between the groups were analyzed with the chi-square or Fisher`s exact test for the categorical variables, Wilcoxon test was used for the qualitative (2 classes) and numeric variables.
Joinpoint regression program (version 4.3.1) was used to identify trend rates of the prevalence of H. pylori infection.
The level of significance (alpha level) was set at 0.05.
Results
We included 2642 patients in this retrospective case-control study. All patients underwent EGD due to various dyspeptic symptoms. In total, 303 HIV-positive patients and 2339 HIV-negative patients were included as cases and controls, respectively.
Joinpoint regression analysis revealed that from 1993 to 2014 there was a significant positive linear trend of H. pylori co-infection among PLHIV (b = 0.030, SE = 0.011, p = 0.013), while the trend of H. pylori infection in the general population control group was significantly negative (b = - 0.027, SE = 0.003, p < 0.001). Annual percent change (APC) in H. pylori infection rates in PLHIV was 3.0 (95% CI 0.7 to 5.4), while in controls it was– 2.7 (95% CI –3.3 to –2.0). However, the APC was not significant in either of the two groups (Fig 1).
Statistically significant trend; APC—annual percent change.
In the HIV-positive group, there were 221 (72.9%) males and 82 (27.1%) females, with the mean age of 40.2±10.7 years (age range 18–83). H. pylori infection was diagnosed in 85 (28.1%) participants. PLHIV with and without H. pylori co-infection were of similar age (p = 0.903). There was no significant difference between sexes (p = 0.565), CD4+ T cell counts at the time of HIV diagnosis (p = 0.287), nor the risk factors for HIV infection between the two subgroups (p = 0.512).
At the time of EGD, CD4+ T cell counts were shown to be significantly higher in the PLHIV subgroup with H. pylori co-infection, than among those without this co-infection (p<0.001) (Table 1).
HIV viremia was more frequently undetectable in patients with H. pylori co-infection, due to successful ART [10 (15.9%) vs. 63 (50.8%) p <0.001], while detectable viremia was more common in the subgroup without H. pylori co-infection [0 (0–21000) cp/ml vs. 20 (0−107) cp/ml (p<0,001)]. PLHIV with H. pylori co-infection had significantly lower prevalence of AIDS (65.9 vs. 80.7%, p = 0.008) (Table 1).
In PLHIV with H. pylori co-infection, the CD4+ T cell counts were significantly higher at the time of EGD compared to the time when HIV infection was detected (p <0.001) (Table 2).
In PLHIV with H. pylori co-infection, the CD4+ T cell count was not related to gastritis topography (p = 0.470), H. pylori density (p = 0.807), gastritis activity (p = 0.333), nor the presence of lymphoid follicles (p = 0.365) and intestinal metaplasia (p = 0.331) (Table 3).
The control group consisted of 2339 HIV-negative patients from the general population. Their gender ratio was 1012 (43.3%) males vs. 1327 (56.7%) females, with a mean age of 46.3±14.7 years (age range 18–86). H. pylori infection was detected in 1174 (50.2%) participants. H. pylori-infected subjects were significantly older than those without this infection (47.5±13.6 vs. 45.0±15.5 years, p<0.001). H. pylori infection did not show any gender-related correlation (p = 0.241) (Table 4).
H. pylori infection was significantly more prevalent in the HIV-negative group of patients in comparison to PLHIV (50.2% vs. 28.1%). The control group of patients with H. pylori infection was significantly older than the PLHIV group with H. pylori co-infection (47.5±13.6 vs. 40.9±9.9; p≤0.001). The histopathological grading of gastritis activity differed significantly between those two subgroups (p = 0.006). The mildest cases prevailed in PLHIV, while in the control group there were more patients with moderate and severe activity. There was no difference between two H. pylori positive subgroups in gastritis topographical localization (p = 0.452), H. pylori density (p = 0.905), presence of lymphoid follicles (p = 0.074) nor intestinal metaplasia (p = 0.817) (Table 5).
Discussion
Considering the already published research data on H. pylori infection among PLHIV, this is the first report in which the joinpoint regression analysis was performed. Also, to the best of our knowledge, this is the first EGD-based morphological comparison of histopathological findings in H. pylori-positive patients with and without HIV co-infection covering 21 years.
Our data suggest that the prevalence of H. pylori infection is significantly lower among PLHIV in comparison with the HIV-negative population, over 21 years covered by our study. These data are in concordance with those already published addressing this issue [11, 12, 14, 15, 17, 19–21]. In addition, we found that the prevalence rates of H. pylori infection during more than 20 years of EGD follow-up among patients with dyspeptic symptoms, had opposed linear trends between the two investigated groups. Decreasing prevalence rates of H. pylori infection over time were observed in the HIV-negative population, contrary to the increasing trend in PLHIV. Moreover, the APC increase was 3% in the PLHIV group while in the general population the APC decrease was 2.7%. Even though we did not demonstrate any significant changes in two APCs, which converge towards similar prevalence rates during last two years of the observed period, we may speculate that these changes in the two observed linear trends could be related to the gradual ART introduction in HIV-positive patients, as well as the eradication therapy for H. pylori among controls.
The first patient with AIDS in Serbia was diagnosed in 1985, while ART, including mono and dual therapy, became available in 1987 and was in use up to 1998, when HAART became widely available [24]. We demonstrated that HAART reduces HIV-related morbidity and mortality, both in men and women, as shown in other observational studies in developed and developing countries, where this treatment is available [25]. By providing durable viral suppression, HAART corrects many of the immune defects caused by HIV, including restoration of opportunistic pathogen-specific immune responses and subsequent regression or prevention of opportunistic infections [26, 27]. Immune reconstitution may allow for inflammatory response-related unmasking of some previously silent infections, the phenomenon called Immune Restoration Inflammatory Syndrome (IRIS) [28, 29].
Standard and highly efficient triple H. pylori eradication therapy has been available in Serbia since it had been advocated by most guidelines, and this treatment approach has led to the decreased shedding of the pathogen, along with the decreased prevalence of the infection in the general population [30]. This epidemiological phenomenon is rather different than what has been observed among PLHIV during both the pre-HAART and HAART eras. The rising linear trend of H. pylori infection in the PLHIV population over time could probably be explained by the less effective mono and dual ART in comparison to HAART with respect to immune reconstitution, which we consider to be important for the pathogenesis of H. pylori-induced gastric mucosa inflammation.
It seems that the most important factor related to the occurrence of H. pylori infection in PLHIV is the immune restoration, corresponding to the CD4+ T cell count. In this study we showed that there was no difference in the CD4+ T cells counts between PLHIV with and without H. pylori co-infection at the time of HIV diagnosis. Contrary to this, at the time when EGD was performed, PLHIV with H. pylori co-infection had a significantly higher CD4+ T cell counts, mostly over 200/mm3, and less progression to AIDS. However, once a higher CD4+ T cell count is achieved, suggestive of immune reconstitution, it does not affect the histopathological findings of the gastric mucosa. The topographic localization of gastritis, H. pylori density, activity, the presence of lymphoid follicles and intestinal metaplasia in patients with HIV/H. pylori co-infection was not dependent on the level of immune restoration, monitored by the CD4+ T cell counts. Definitely T cell subpopulations affect H. pylori colonization, but there is not yet sufficient evidence that T cell deficiency causes H. pylori removal.
When we compared histopathological findings between HIV-positive and HIV-negative subjects with H. pylori infection, we only found the difference in activity: most of the PLHIV had mild gastritis activity (58%) while HIV-negative patients mostly had moderate/severe gastritis activity (53.6%), which may be attributed to the incomplete immune recovery in co-infected patients. However, in our previous investigation, where we enrolled 212 HIV/H. pylori co-infected patients, we concluded that most of the patients treated in the pre-HAART era had mild gastritis activity while those on HAART mostly had mild/moderate gastritis activity [21].
In this retrospective study we did not evaluate if the usage of antibiotics affected the prevalence of H. pylori infection over time. Antibiotics are used for H. pylori eradication in both PLHIV and HIV-negative patients. H. pylori eradication therapy consists of simultaneous usage of two antibiotics from different classes along with proton pump inhibitor [31], and antibiotic monotherapy had only minor efficacy in H. pylori eradication [32].
In addition, some PLHIV in our cohort had been taking antibiotics earlier to treat opportunistic infections, such as Mycobacterium tuberculosis infection. Rifampicin has an excellent in vitro and good efficacy in vivo against H. pylori [33], but does not necessarily result in eradication of H. pylori infection [34]. While we cannot rule out clearance of H. pylori infection in some of our PLHIV patients previously treated for tuberculosis, the available published studies do not provide a definitive answer on the effect of rifampicin use on the incidence of H. pylori infection in PLHIV treated for tuberculosis. Their findings, however, suggest that progressive HIV disease rather than antibiotic usage may be responsible for the diminution in frequency of H. pylori co-infection [35]. We can speculate that in the era of less effective antiretroviral therapy, when tuberculosis incidence in PLHIV was higher, the use of rifampicin might have contributed to the lower incidence of H. pylori infection in PLHIV more significantly than in the HAART era. Still, we cannot exclude immunodeficiency of these patients as an important contributing factor to their lower incidence of H. pylori infection. It is important to note that not all of the patients included in this study had been treated for tuberculosis. Future research is needed to clarify the impact of previous antibiotic therapy, primarily antituberculosis therapy, on the incidence of H. pylori infection in PLHIV. Co-trimoxazole has not been reported to have activity against H. pylori [36].
Since H. pylori induced gastric inflammation is less severe in PLHIV, it is possible that H. pylori infection in these patients was underdiagnosed due to mild symptoms, especially before HAART introduction. In addition, dyspeptic symptoms are common in PLHIV and are usually not associated with H. pylori as they may be due to opportunistic infections and/or tumors, diet, ART side effects, etc., with peptic ulcer disease and gastroesophageal reflux disease frequently detected by EGD [18, 37].
Our previous studies demonstrated that the prevalence of H. pylori gastritis was higher among PLHIV with less advanced HIV infection and hence more preserved immune function. We previously demonstrated that the prevalence of H. pylori gastritis had been increasing in concert with the HAART efficacy evolution and the consequent improved immune reconstitution [21]. More research is needed to elucidate whether immune function, rather than some local factors influence the prevalence of H. pylori gastritis among PLHIV.
This is a retrospective case-control study and therefore some potentially relevant information was not available, such as other possible risk factors for HIV/H. pylori co-infection in addition to the ART, e.g. exposure to antibiotics, PPI and H2 blocker therapy, body mass index, etc. Also, we did not explore the H. pylori acquisition in the control, HIV-negative group in detail.
Despite these limitations we believe that the study presents new research findings on the histopathology of H. pylori positive gastritis in HIV/H. pylori co-infection and annual percentage changes in H. pylori infection rates.
Conclusions
In conclusion, according to our data, we believe that in the population of HIV infected individuals the linear trend of the slowly rising prevalence of gastritis associated with H. pylori co-infection could be the consequence of slow and steady immune reconstitution ranging from a rather weak mono or dual ART in the beginning to the more potent modern HAART, resulting in a similar level of H. pylori gastritis development in all our patients.
Our research has shown that H. pylori infection is present only in PLHIV who have preserved CD4 counts, hence, immunity. Although more research is needed in this area, we believe that our conclusions are extremely important for the longer life expectancy of PLHIV as well as the carcinogenicity of H. pylori. We believe that the future outcome and course of HIV infection will be quite different and that diseases not previously studied in the context of HIV will become as common in PLHIV as in HIV-negative patients. No studies conducted after HAART became available have implicated that PLHIV individuals are at a decreased risk of gastric cancer. Therefore, PLHIV with H. pylori co-infection, regardless of their CD4 status, could be at an equal risk for of gastric cancer as HIV negative patients, but less likely to be diagnosed with H. pylori due to reduced gastric inflammation. Testing for and treatment of H. pylori in the HIV positive population should be as aggressive as it is for the HIV negative population.
To definitively determine the risk factors for HIV/H. pylori co-infection, future prospective studies are needed to address the epidemiological characteristics of H. pylori infection in HIV positive population.
Supporting information
S1 Text. Data for Fig 1.
A joinpoint regression analysis of Helicobacter pylori prevalence rate trends in HIV-positive (1) and HIV-negative (2) patients in Serbia in the period of 1993–2014.
https://doi.org/10.1371/journal.pone.0248041.s001
(TXT)
Acknowledgments
This work is dedicated to our teacher and dear friend Professor Goran Trajkovic, who left us too early.
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