Introduction
Obstructive sleep apnoea-hypopnea syndrome (OSAHS) is a type of sleep-disordered breathing disease that seriously affects the quality of sleep and life of patients and is typically accompanied by sleep apnoea and daytime sleepiness syndrome. There are many causes of OSASHS, including obesity, excessive drinking, irregular eating habits and laryngeal diseases [
1‐
3]. Recent studies demonstrated that OSAHS can impair the function of target organs in various systems of the body and is significantly associated with systemic diseases such as cerebrovascular disease, metabolic syndrome and tumours [
4,
5]. The literature reports bacteraemia and toxaemia caused by intestinal flora translocation as primary reasons for the malignant development of stress reactions, and sleep deprivation can affect the intestinal flora of rats and promote
Clostridium perfringens proliferation of harmful gases [
6]. A growing body of research has shown gut microbiota disorders to be associated with non-communicable diseases such as cerebrovascular disease, obesity and inflammatory bowel disease; accordingly, the relationship between intestinal microecology and human health and disease is becoming a prominent direction in clinical research [
7,
8]. The development of modern lifestyles and changes in dietary habits has seen OSAHS, with its high incidence rate, low awareness and numerous complications, place enormous mental burdens and economic pressure on people as a result of its health impacts [
9,
10].
At present, chronic intermittent hypoxia (CIH), as a characteristic physiological change occurring in patients with OSAHS, significantly affects the structure and abundance of intestinal flora [
11]. Okubo et al. [
12] established a mouse model of OSAHS by CIH. Their results showed that the diversity of intestinal flora had changed; the structure of intestinal flora had also changed and indicated a decrease in Bacteroidetes and Proteobacteria and an increase in Firmicutes. Ma Jing et al. [
13] of Peking University first reported the characteristics of intestinal flora in patients with OSAHS. The results showed that the number and structure of intestinal flora were increased in patients with OSAHS overall;
Clostridium increased in patients with OSAHS, while the reduction of
Clostridium in patients with hypertension suggests that this decrease may be one of the mechanisms of OSAHS leading to hypertension. However, the characteristics of intestinal flora in patients with OSAHS of different severities have not been further reported, and there are few reports on this direction at home and abroad.
The intestinal flora of patients with OSAHS, healthy adults and patients with moderate or severe OSAHS after surgical treatment were studied to further clarify and compare the intestinal flora composition of patients with OSAHS and healthy adults. Finally, this study aimed to explore the relationship between intestinal flora and sleep structure, hypoxemia and obesity in patients with OSAHS and to further study which intestinal flora may cause changes in the condition of patients with OSAHS to provide a theoretical basis for new intervention methods in clinical treatment in the future.
Discussion
In recent years, the relationship between intestinal microecology and human health and disease has become an important issue in social and clinical research [
14]. To date, many studies at home and abroad have confirmed the close relationship between intestinal microflora disturbance and disease and have explored its influence on disease from the perspective of intestinal microecology, targeting disease-specific interventions as a new therapeutic direction [
15,
16]. However, the bulk of studies on the relationship between OSAHS and intestinal microflora have focused on animals because of the large number of intestinal microflora. The specific CIH pathological state of OSAHS is closely related to intestinal microflora; however, few studies have been conducted on the relationship between OSAHS and intestinal microflora [
17]. On the one hand, many factors affect the intestinal flora, including congenital (e.g. heredity, mode of delivery) and acquired (e.g. diet, living habits, surgery, antibiotics) factors. On the other hand, it is difficult to study the relationship between intestinal flora and patients with OSAHS in clinical research, which requires long periods of time to follow-up. Furthermore, in current research, in the context of whether the intestinal flora is related to the occurrence and development of OSAHS, and if it participates in patients with OSAHS with multi-system injury, the particular mechanism that may be involved is unclear.
In this study, we used high-throughput sequencing technology to analyse the characteristics of patients with OSAHS of different severities, based on what is reflected in a large number of studies. The results showed no significant difference in the diversity and abundance of intestinal flora between patients with OSAHS and healthy cohorts, and there was no significant difference in alpha diversity between patients with OSAHS and healthy individuals. At the same time, the beta diversity of intestinal flora was also analysed to observe changes in intestinal flora composition and structure in patients with OSAHS of different severities. Based on the results, there was no significant difference between patients with OSAHS and the healthy group or between patients with OSAHS and the self-group. However, this conclusion is not consistent with previous animal studies [
18]. Accordingly, a large number of clinical studies are needed to verify these results.
Based on the above findings, the present study carried out species composition relationships at the phyla and genus levels for the intestinal flora of patients with different OSAHS severity levels. The results showed that the intestinal flora that were present represented the phyla level. The dominant flora comprised mainly Firmicutes, Bacteroidetes, Proteobacteria and Fusobacteria, among which Firmicutes and Bacteroidetes accounted for more than 90%. In healthy people, the ratio of Firmicutes to Bacteroidetes is often considered a sign of a healthy gut, whereas an increase in the Firmicutes/Bacteroides (F/B) ratio caused by an increase in Firmicutes or a decrease in Bacteroidetes is considered to be a marker of obesity-and-hypertension-related intestinal dysregulation [
19,
20]. Leyre et al. [
21], in contrast to the analysis of gut microbes in healthy people, showed that the abundance of Firmicutes significantly increased in obese individuals, and Bacteroidetes decreased by approximately 90% in comparison with healthy individuals; with dietary interventions, the F/B ratio gradually returned to the normal level observed in healthy individuals, and weight also decreased significantly. At the same time, it has been shown that Bacteroidetes can significantly inhibit the growth of adipocytes. The results showed that BMI and Firmicutes increased with OSAHS severity, Bacteroidetes decreased and the F/B ratio increased in patients with OSAHS. It is suggested some changes in the composition of intestinal microflora occur between patients with OSAHS and healthy individuals, that is, dysbiosis of intestinal microflora occurs in patients with OSAHS, which can be reduced by intervening with the F/B ratio or controlling the body weight of patients with OSAHS, which has become one of the ways to reduce the risk of disease [
22]. Studies have reported that weight loss through lifestyle changes, anti-obesity drugs and bariatric surgery can improve OSAHS symptoms [
23]. Pihtili et al. found that there were significant differences in OSAHS-related indexes between obese OSAHS patients and normal OSAHS patients, such as apnoea–hypopnea index, oxygen desaturation index, mean SpO(2) and lowest SpO2, indicating a close correlation between obesity and OSAHS [
24]. Therefore, the exact relationship between obesity and OSAHS requires further exploration. The analysis of the species composition of the top 20 dominant bacterial genera and their relative abundance in intestinal flora indicated a decreasing trend for Faecalibacterium with the aggravation of OSAHS.
Polysomnography is considered the gold standard in the diagnosis of OSAHS. To explore whether some species of intestinal flora were related to the indexes of sleep monitoring, we carried out correlation analysis of BMI, AHI, SpO
2min, SpO
2mean and T
max. According to RDA analysis, there was no significant difference between AHI, SpO
2min, SpO
2mean and T
max and the overall abundance of intestinal flora, except that BMI was positively correlated with the overall abundance of intestinal flora. Spearman correlation analysis of bacterial abundance with sleep monitoring indicators was subsequently performed and the results were as follows: (1) there was a negative correlation between Shigella abundance and brute abundance and BMI; (2) the abundance of
Actinomycetospora and
Akkermansia was positively correlated with BMI; (3) the abundance of
Thermus,
Sediminibacterium,
Ralstonia,
Pelomonas,
Blautia,
Anoxybacillus and
Anaerofustis were negatively correlated with AHI and T
max and positively correlated with SpO
2min, respectively. Respiratory
Pelomonas is considered to be a key bacterium contributing to the pathogenesis of allergic asthma, but its mechanism of action in the gut is currently unclear [
25].
Anoxybacillus,
Anaerofustis and
Blautia belong to Firmicutes, and the indexes of clinical sleep monitoring with their presence in the gut. An increase in the proportion of respiratory bacteria and anaerobic bacteria may lead to chronic immune–inflammatory disorder, which indirectly affects sleep quality by affecting the respiratory and digestive symptoms of patients. A continuous inflammatory state is also related to the occurrence and development of OSAHS. However, previous studies have not reported the impact of a pathogen on the occurrence and severity of OSAHS. Further research is needed to clarify whether this correlation is involved in the development of OSAHS and whether it has good clinical significance in predicting its severity.
There is a bidirectional relationship between sleep architecture and gut microbiota composition, and interference with gut microbiota by antibiotics leads to greater fragmentation of non-rapid eye movement (NREM) sleep, which, in turn, reduces sleep quality. Sleep disruption can also lead to changes in the gut microbiota; however, there appears to be a lack of agreement on the relationship between sleep architecture and gut flora. In the microbial–brain–gut axis system, the intestinal flora and changes in sleep structure are closely related. When the circulation in this system is restricted, macrophages can be activated based on the proportion of intestinal flora (probiotics/prebiotics) to enhance non-specific and specific immune responses and natural killer cell activity, thereby enhancing the expression level of cytokines to promote the expression of immunoglobulin, particularly secretory IgA, to improve sleep quality and structure. These findings provide an important scientific basis for conducting intestinal flora intervention in the treatment of related neuropsychiatric disorders. However, further studies are needed to clarify whether the above-noted correlations are involved in the occurrence and development of OSAHS and whether they are of guiding significance in clinical treatment.
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