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Introduction

Epithelial gastric polyps are pathologies incidentally discovered during endoscopic examinations. The prevalence varies between 2 and 6% in all patients subjected to endoscopy involving the stomach (1). Over the past decades, the occurrence of gastric polyps has exhibited a rising trend and the distribution spectrum of different types of gastric polyps has been changed. Epithelial polyps of the stomach comprise three types, namely fundic gland polyps (FGPs), hyperplastic polyps (HPs) and adenomatous polyps (APs). FGPs exhibit a steep rise in their occurrence and are the most common type (2-5). Older age is associated with an increased risk of gastric polyps, whereas Helicobacter pylori infection is inversely associated with the disease (6).

Gastric HPs develop from hyperproliferation of foveolar cells. Histologically, HPs appear as hyperplastic foveolae, cystic gland dilation and a variable amount of inflammation in the stroma. HPs most frequently occur in the antrum and tend to be larger than other gastric polyps. Larger HPs may cause bleeding from the ulcerated surface or intermittent gastric outlet obstruction. They carry a low malignant potential.

H. pylori is a Gram-negative spiral microorganism that colonizes the mucosa of the human stomach, infecting more than half of the world population. Infection with this bacterium has been indicated to be a cause of peptic ulcer disease and stomach cancer (7). However, recent evidence suggests that chronic infection with H. pylori may be beneficial to the host by conferring protection against gastroesophageal diseases, asthma, other allergic disease manifestations and inflammatory bowel diseases (7). Treatment of H. pylori infection-associated diseases is a complex problem. The most widely recommended regimen is a triple therapy comprising one proton pump inhibitor (PPI) and two antibiotics (8).

The association of HPs with H. pylori infection remains controversial. An inverse association of HPs with current infection of the bacterium has been indicated in the US, an area with low prevalence of H. pylori (2,6). In a retrospective study on a cohort of 741,351 patients in the United States, the prevalence of H. pylori was relatively low, which was determined to be <14%. The infected patients had a lower risk for HPs with an odds ratio of 0.55 (0.51-0.59) (6). The inverse association has been confirmed in another study performed in the US (2). Contrary to this result, it has been indicated that H. pylori eradication may lead to regression of HPs. Successful eradication of H. pylori resulted in a statistically significant increase in the clearance rate of HPs (9-11).

Clarifying the association of HPs with H. pylori infection is particularly relevant to clinical management. At present, the inverse association between HPs and H. pylori has been mainly reported in areas of low prevalence of H. pylori. Therefore, the present study aimed to explore the association in a large cohort in China, an area with a high infection rate of H. pylori (12,13). In order to study the trends of HPs and H. pylori infection over the past decades, the study was limited to patients encountered between 2009 and 2018.

Materials and methods

Study setting

The present study was performed at the Endoscopy Center and the Physical Examination Center of Qingdao Municipal Hospital (Qingdao, China). Biopsies were interpreted by an experienced group of pathologists. Standardized histopathology criteria were used to diagnose the histopathological types of gastric polyps (14). The study was approved by the ethics committee of Qingdao Municipal Hospital (Qingdao, China). As the data were collected entirely by reviewing existing records, no direct contact with either patients or providers was involved and no personal information on the subjects was revealed in any form, and exemption from the requirement for informed consent from participants was granted.

Sources of data

A total of 109,150 consecutive patients undergoing esophagogastroduodenoscopy (EGD) from 1 January 2009 to 31 December 2018 at the Endoscopy Center of Qingdao Municipal Hospital (Qingdao, China) were enrolled. The records of patients who had gastric biopsies were reviewed. Data including inspection time, the patients' birth year, age and sex, information on polyps, intestinal metaplasia (IM) and H. pylori infection were analyzed. The H. pylori status was obtained using histopathological methods. During the same period, the records of 11,077 healthy individuals undergoing health checkups at the Physical Examination Center of Qingdao Municipal Hospital (Qingdao, China) were analyzed. Data including the patients' birth year and H. pylori infection were analyzed. The H. pylori status was obtained with the 13C urea breath test (Shenzhen Zhonghe Headway Bio-Sci & Tech Co., Ltd.).

Statistical analysis

Statistical analyses were performed using SPSS 18.0 (SPSS Inc.) and R 3.5.1. Pearson correlation analysis was used to determine the correlation between the prevalence of gastric polyps and H. pylori infection, the correlation between the prevalence of H. pylori and the examination year, and the correlation between the difference in the prevalence of HPs between H. pylori-negative and -positive patients and age. Logistic regression analysis was used to identify risk factors potentially associated with the presence of gastric polyps. Effects of H. pylori and cofactors on gastric polyps were estimated by determining odds ratios (ORs) and 95% CIs. One-way analysis of variance (ANOVA) and the Student-Newman-Keuls (SNK) test were used to compare the average ages of patients undergoing EGD who obtained H. pylori status between each calendar year. The Cochran-Armitage trend test was performed to estimate the trends in H. pylori infection in different groups of patients according to birth year range using the CATT package in R. P<0.05 (two-tailed) was considered to indicate statistical significance.

Results

Rising trend of HPs

Over a 10-year period, the clinical data of 109,150 patients undergoing EGD was available and histopathology data were obtained for 94,031 participants. A total of 1,497 HPs (1.6%) were detected in the 94,031 participants. The annual detection rate of HPs increased gradually from 2009 to 2018, suggesting a rising trend of the lesions (r=0.95, P<0.001; Fig. 1A). During this period, the prevalence of HPs exhibited a ~4-fold increase. In line with this, the prevalence of FGPs also exhibited a rising trend (Fig. 1A). The increase in the prevalence of HPs appeared to be slower compared with that in FGPs and its proportion among gastric polyps exhibited an obvious drop (Fig. 1B).

Figure 1 Changes in (A) the prevalence and (B) proportion of gastric polyps from 2009 to 2018. HPs, hyperplastic polyps; FGPs, fundic gland polyps; APs, adenomatous polyps.

Identification of risk factors for HPs

To explore the association of potential risk factors with HPs, logistic regression analyses were performed. The results demonstrated that H. pylori infection was inversely associated with HPs. The risk for HPs was significantly decreased in H. pylori-positive patients compared that in H. pylori-negative patients (adjusted OR, 0.66; 95% CI, 0.59-0.75; P<0.001; Table I). Female sex and older age were associated with an increased risk for HPs. However, the OR value of female sex for HPs was lower than that for FGPs. Contrarily, female sex was associated with a lower risk for APs, although the difference was not statistically significant. Older age was associated with a slightly higher, but statistically significant risk for HPs as well as the other types of polyps. IM was also inversely associated with HPs (Table I).

Table I Associations between different types of gastric polyp and age, gender, H. pylori and IM.

Table I

Associations between different types of gastric polyp and age, gender, H. pylori and IM.

A, HPs
			Univariate model		Multivariate model
Variable	Casesa (n=1,497)	Controls (n=90,110)	OR (95% CI)	P-value	OR (95% CI)	P-value
Average age	57.5±11.9	52.6±14.1	1.03 (1.02-1.03)	<0.001	1.03 (1.03-1.04)	<0.001
Female sex	914 (61.1)	43,710 (48.5)	1.66 (1.50-1.85)	<0.001	1.52 (1.36-1.69)	<0.001
H. pylorib	324 (22.7)	28,497 (34.0)	0.57 (0.50-0.65)	<0.001	0.66 (0.59-0.75)	<0.001
IM	314 (21.0)	27,079 (30.1)	0.62 (0.55-0.70)	<0.001	0.51 (0.45-0.58)	<0.001
B, FGPs
			Univariate model		Multivariate model
Variable	Casesa (n=2,209)	Controls (n=90,110)	OR (95%CI)	P-value	OR (95%CI)	P-value
Average age	55.0±11.7	52.6±14.1	1.01 (1.01-1.02)	<0.001	1.02(1.01-1.02)	<0.001
Female sex	1,571 (71.1)	43,710 (48.5)	2.61 (2.38-2.87)	<0.001	2.32 (2.11-2.55)	<0.001
H. pylorib	204 (9.4)	28,497 (34.0)	0.20 (0.18-0.24)	<0.001	0.23 (0.20-0.26)	<0.001
IM	348 (15.8)	27,079 (30.1)	0.44 (0.39-0.49)	<0.001	0.41 (0.36-0.46)	<0.001
C, APs
			Univariate model		Multivariate model
Variable	Casesa (n=35)	Controls (n=90,110)	OR (95%CI)	P-value	OR (95%CI)	P-value
Average age	60.6±12.7	52.6±14.1	1.04 (1.02-1.07)	0.001	1.04 (1.01-1.08)	0.004
Female sex	16 (45.7)	43,710 (48.5)	0.89 (0.46-1.74)	0.741	0.79 (0.37-1.70)	0.550
H. pylorib	3 (11.1)	28,497 (34.0)	0.24 (0.07-0.81)	0.021	0.29 (0.09-0.96)	0.042
IM	9 (25.7)	27,079 (30.1)	0.81 (0.38-1.72)	0.577	0.88 (0.39-1.98)	0.761

[i] ^aExcluded: 13 juvenile polyps, 4 inflammatory fibroid polyps, 104 mixed polyps (including 95 HPs mixed with FGPs, 5 HPs mixed with APs, 2 FGPs mixed with APs, 1 HPs mixed with inflammatory fibroid polyps and 1 FGPs mixed with juvenile polyps), 59 with histological type not described.

[ii] ^bThe H. pylori status of 87,699 patients was available. Values are expressed as the mean ± standard deviation or n (%). OR, odds ratio; HPs, hyperplastic polyps; FGPs, fundic gland polyps; APs, adenomatous polyps; IM, intestinal metaplasia; H. pylori, Helicobacter pylori.

Univariate logistic regression analysis suggested that there was a positive association between H. pylori and IM (OR: 1.31, 95%CI: 1.27-1.35, P<0.001; Table SI).

Declining trend of H. pylori infection

Of the 109,150 participants who underwent EGD examination, 87,699 cases were assigned H. pylori status by histopathological methods. H. pylori was present in 29,059 (33.1%) of the 87,699 participants. The prevalence of H. pylori infection decreased gradually from 35.8% in 2009 to 32.0% in 2018 (r=-0.76, P=0.011; Fig. 2A). This suggested a declining trend of H. pylori infection over the past decade. One-way ANOVA and the SNK test indicated that there was no significant difference in the averages of age between calendar years of the past decade (range from 52.41±14.56 to 53.13±13.49 age; P>0.05; Table SII). Thus, the decline in the infection rate of H. pylori was not associated with age.

Figure 2 Trends in the prevalence of H. pylori with time. (A) Changes of the H. pylori-positive rate in each calendar year. (B) Effect of the birth year range on the H. pylori prevalence in patients undergoing esophagogastroduodenoscopy. (C) Effect of the birth year range on the H. pylori prevalence in individuals undergoing health checkups. H. pylori, Helicobacter pylori.

The potential effect of the birth year range on H. pylori prevalence was explored in the study population. The prevalence was higher in the 1960-1969, 1970-1979 and 1980-1989 birth cohorts, but lower in the cohorts born prior to 1960 and after 1989. Thus, there was no indication that the birth year in the population subjected to EGD examinations affected the prevalence of H. pylori (Fig. 2B). By contrast, a birth cohort effect was detected in the population comprised of 11,007 individuals subjected to routine health checkups. The prevalence of H. pylori exhibited an apparent trend of decline from older to younger birth cohorts (P-value for trend, <0.001; Fig. 2C). The prevalence was 48.6% in the group born prior to 1960 and decreased gradually to 31.1% in the group born after 1989.

Inverse association between the annual prevalence of H. pylori and HPs

Correlation analyses indicated that the annual prevalence of HPs increased with the decrease in the prevalence of H. pylori, suggesting an inverse association between them (r=-0.64, P=0.048; Fig. 3A). An inverse association was also observed between the annual prevalence of H. pylori and gastric polyps or FGPs (Fig. 3B and C). However, the prevalence of H. pylori was not correlated with APs (Fig. 3D).

Figure 3 Correlation between the trend of H. pylori infection and the prevalence of (A) HPs, (B) gastric polyps, (C) FGPs and (D) APs. HPs, hyperplastic polyps; FGPs, fundic gland polyps; APs, adenomatous polyps; H. pylori, Helicobacter pylori.

Impact of age on the effect of H. pylori infection on HPs

The prevalence of HPs exhibited an age-associated increase in H. pylori-negative and -positive groups (Fig. 4A), consistent with the aforementioned result that older age was a risk factor for HPs. However, it appeared that the age-associated increase was different between the two groups. Specifically, the age-associated rise in the prevalence of HPs was slower in H. pylori-infected patients. Correlation analysis revealed that the difference in the prevalence of HPs between the two groups increased with age (r=0.80, P=0.018; Fig. 4B).

Figure 4 (A) Prevalence of hyperplastic polyps in H. pylori-negative and -positive subjects in different age groups (years) and (B) the prevalence difference. The difference increased with age. H. pylori, Helicobacter pylori.

Discussion

In the present study, an increase over time in the prevalence of HPs was identified. The reason may have, in part, been the improvement of detection techniques, but overall, it made less impact. To date, only few studies have explored the trend of the occurrence of HPs over several years. A study on a small population of 3,887 participants examined the prevalence of HPs at five time-points from 1980 to 2016(5). They obtained no significant change in the occurrence of HPs. The present results indicated that the increase in the prevalence of HPs over time was slower compared with that of FGPs. Over the 10-year period, HPs changed from the dominant type of gastric polyps to the second-most common type due to the sharp rise in the prevalence of FGPs. This is in agreement with the results of earlier studies (2-5,15).

The present results revealed that females have an increased risk for HPs. This is in contrast to studies from other geographical regions, according to which gender has no significant influence on the risk of HPs (6,16), although females having a significant increase in the risk of gastric polyps has also been described in Western populations (17). These conflicting results may be attributed to the differences in ethnicity or differences in the prevalence of H. pylori (18,19). In agreement with other studies, older age appeared to be associated with an increased risk for HPs (6,7,20).

HPs carry a low but definite risk for malignant transformation. Thus, determining the association of H. pylori with HPs is a major clinical concern. Studies on large cohorts from areas of low prevalence of H. pylori demonstrated that the pathogen is inversely associated with the occurrence of HPs (2,6). The present study, performed on a population of China, which had a high prevalence of H. pylori, provided similar results. Furthermore, the present data demonstrated that the prevalence of H. pylori exhibited a gradual decrease over the 10-year period assessed. The annual prevalence of H. pylori in the population examined was inversely associated the detection rate of HPs. These results provide further evidence for the inverse association between H. pylori infection and HPs.

The possible reasons for the negative association between the infection and HPs remain controversial. It has been suggested that the increased prevalence of HPs is caused by IM of gastric mucosa, rather than the decreased prevalence of the infection (2). The negative association between the infection and HPs may be an indirect result that merely reflects the loss of current infection of H. pylori in IM. However, this explanation was not supported by other studies (6) and the present result regarding IM being inversely associated with HPs. To further demonstrate the negative association between the infection and HPs, the association between the infection and IM was analyzed. The present results indicated that H. pylori infection was positively associated with IM. This is consistent with results from earlier studies, which examined the prevalence of the infection in IM in large cohorts (21,22). Based on this information, H. pylori infection was indicated to be inversely associated with HPs.

In spite of being a pathogen causing a variety of gastric diseases, H. pylori infection provides protection from diarrhea, Barrett's esophagus, erosive esophagitis and gastroesophageal reflux disease (23-26). To explore whether the inverse association may indicate protection from HPs by H. pylori, the impact of exposure time to the pathogen on the prevalence of HPs was then analyzed. Considering that H. pylori is usually acquired during childhood (27,28), the age of the patients was used to roughly estimate the exposure time of H. pylori. The results indicated that in spite of the age-associated increase in the prevalence of HPs, the rise was much slower in the infected patients. This indicates that the increase in the exposure time to the infection may have a potential protective effect on HPs. In contrast to the present results, a study on 183 patients suggested that the positive rate of H. pylori infection was lower in the group with regression of HPs (29). These contrasting results may be attributed to complexity in the factors involved in the regression of gastric polyps, including the polyp size, which is a key determinant for the disappearance of polyps. Another study indicated that the recurrence of HPs was more frequent in H. pylori-persistent patients after endoscopic removal of polyps (30). However, the present study also indicated that the eradication of H. pylori does not prevent the recurrence of HPs. Therefore, further follow-up studies are required to clarify the association between H. pylori and HPs, taking into account the population size and factors involved in the regression of polyps.

In the present study, the possible causes of the annual decrease of the prevalence of H. pylori in the population subjected to EGD examination were further analyzed. The results suggested that the declining prevalence of H. pylori may not be attributed to the birth cohort effect, that mean the decline was not caused by exposure to environmental factors during early life. However, the presence of the birth cohort effect was demonstrated in the population of patients subjected to health checkups. Therefore, the declining trend in the prevalence of H. pylori over time probably attributes to the eradication interventions for those patients who underwent EGD examination, as the patients undergoing EGD exhibit a variety of symptoms, and the majority of the cases received PPI or H. pylori eradication therapy.

In addition to the potentially protective effect on HPs by H. pylori, the roles of the wide use of PPIs in the development of HPs should be considered. The present results indicated that the decline in the proportion of HPs was accompanied by a relative increase in FGPs. This is what is usually observed in developed countries where the prevalence of H. pylori infection is low and the use of PPI is high (2). Recent studies have indicated that HPs occur after long-term use of PPIs in patients without H. pylori infection (31,32). PPIs may stimulate the secretion of gastrin, leading to hyper-gastrinaemia. This may cause hyper-proliferation of the gastric mucosa and promote the development of HPs (31,32). Despite the lack of information on the history of PPI use in the study population, the present results indicate that it is plausible that the wide use of PPIs accounts for the decline in the HPs. Further study is indicated for clarifying the roles of PPIs in the development of HPs. In addition, it has been reported that the dysbiotic microbiota is associated with the development of nasal and intestinal polyps (33-36). The human stomach harbors a complex microbiota in the luminal cavity and mucosa. Dysbiosis of the gastric microbiota has been linked to the occurrence of gastric cancer (37). Although the microbiota has not been characterized in gastric polyps, it is probable that dysbiosis of the gastric microbiota is causative for HPs. Therefore, antibiotic treatments may restore the dysbiotic microbiota and result in regression of HPs (38). H. pylori infection has a huge impact on the gastric microbiota (39-41). It is possible that the pathogen provides indirect protection against HPs through influencing the microbiota.

The present study examined the prevalence of gastric polyps including HPs in patients who underwent EGD. All of the patients had complaints of upper gastrointestinal symptoms, rather than being asymptomatic. Thus, it should be noted that the prevalence of gastric polyps determined in the present study may not represent the actual incidence of gastric polyps in the general population. Further studies on the general population are indicated to confirm the potential protection of H. pylori on the occurrence of HPs.

In conclusion, the present data demonstrate the rising prevalence of HPs over time. An inverse association between HPs and H. pylori infection was identified. It appears that H. pylori may indirectly protect against HPs, however the risk factors and mechanisms associated with this protection require further study.

Supplementary Material

Association between H. pylori and IM.

The average age of the patients who obtained H. pylori status by histopathological methods in each calendar year.

Acknowledgements

Not applicable.

Funding

No funding was received.

Availability of data and materials

All data generated or analyzed during this study are included in this published article.

Authors' contributions

XY and QD were involved in the conception of the present study. XY and ZW designed the present study. YX and QD supervised the present study. ZW, LW, XM, CZ and YX performed data collection and/or processing. XY, LW, XM, CZ, YX and WS performed the data analysis and/or interpretation. XY and ZW wrote the manuscript. QD critically reviewed the manuscript. All authors have read and approved the final version of the manuscript.

Ethics approval and consent to participate

The present study was approved by the Ethics Committee of Qingdao Municipal Hospital (Qingdao, China).

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References