Effects of IQW and IRW on Inflammation and Gut Microbiota in ETEC-Induced Diarrhea

Liu, Naiyuan; Zhou, Lingsi; Fang, Jun; Jiang, Hongmei; Liu, Gang

doi:https://doi.org/10.1155/2021/2752265

Mediators of Inflammation

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Abstract Introduction Materials and Methods Results Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

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Metabolism of the Host and Microbes to Modulate Immunocytes 2021

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Research Article | Open Access

Volume 2021 | Article ID 2752265 | https://doi.org/10.1155/2021/2752265

Effects of IQW and IRW on Inflammation and Gut Microbiota in ETEC-Induced Diarrhea

Naiyuan Liu,¹Lingsi Zhou,¹Jun Fang,¹Hongmei Jiang,¹and Gang Liu¹

Academic Editor: Mingliang Jin

Received07 Jul 2021

Revised26 Aug 2021

Accepted30 Aug 2021

Published24 Sept 2021

Abstract

Background/Aims. Changing gut microbiota is one of the most common causes of host gut inflammation. The active triple peptides, lle-Gln-Trp (IQW) and lle-Arg-Trp (IRW), cause remarkable changes to gut microbiota. The effects of the triple peptides IQW and IRW in gut-damage treatment were explored in this study via an enterotoxigenic Escherichia coli- (ETEC-) induced mouse model. Methods. The mice were randomly distributed into four groups: (a) control (CTRL) group, (b) ETEC group, (c) IQW-ETEC group, and (d) IRW-ETEC group. Villus length and crypt depth were measured after hematoxylin and eosin staining. The inflammatory reaction was analyzed via inflammatory cytokines (i.e., TNF-α, IL-1β, IL-6, and IL-10) using the enzyme-linked immunosorbent assay (ELISA). The microbiota in the colon was sequenced using 16S ribosomal RNA. Results. The villus length decreased, the crypt depth decreased, and the expression of inflammatory cytokines (i.e., TNF-α, IL-1β, IL-6, and IL-10) increased due to ETEC. In the IRW-ETEC and IQW-ETEC groups, the Shannon index decreased (). IQW and IRW increased the abundance of Firmicutes, Proteobacteria, Clostridiales, Lachnospiraceae, and Alloprevotella; contrastingly, it decreased the abundance of Epsilonproteobacteria, Erysipelotrichales, Prevotellaceae, and Flavobacteriaceae compared to the ETEC group (P <0.05). Conclusion. This study ascertained that the addition of IQW and IRW could alleviate jejunal inflammation and increase microbiota community diversity.

1. Introduction

According to records, diarrhea kills approximately 800,000 children each year [1]. One in ten children worldwide has died due to diarrhea [2]. The cause of diarrhea is complicated; however, pathogenic bacterial infections are one of the major causes. Pathogenic bacteria were detected in 80% of diarrhea patients in Southeast Asia and 72% of diarrhea patients in South America [3].

The traditional treatment of infectious diarrhea involves antibiotics (and sometimes antiviral or antiparasitic medications), which may increase pathogen resistance to drugs. Simultaneously, antibiotics ruin the intestinal microenvironment of the host. Thus, there is much concern about determining alternatives to antibiotics in diarrhea treatment. Natural products, polypeptides, polysaccharides, probiotics, and other substances can be added to the host diet to treat infectious diarrhea; these have received much attention in recent years [4–6]. For example, one study revealed that adding plant polysaccharides to one’s diet can alleviate diarrhea symptoms of mice infected with enterotoxigenic Escherichia coli (ETEC) [7].

Ile-Gln-Trp (IQW) and Ile-Arg-Trp (IRW) are two active tripeptides extracted from egg whites. Some studies have proved that IQW and IRW have several functions, including lowering blood pressure and cholesterol and antioxidant and anti-inflammatory properties [8–11]. Studies have shown that IQW and IRW can reduce the TNF-induced inflammatory and oxidative stress responses in endothelial cells; these anti-inflammatory and antioxidative effects of IRW and IQW are regulated through the NF-κB signal pathway [12, 13]. It has been shown that IRW can display anti-inflammatory effects by inhibiting p65 protein activity in NF-κB [14]. Additionally, research has shown that IRW can upregulate the expression of nicotinamide phosphoribosyltransferase (NAMPT) protein in mouse muscle cells, improving metabolic levels and alleviating obesity [15]. Our team focused on adding this active peptide to the host diet, exploring the prevention and treatment of intestinal damage. We explored the impact of colitis by adding IRW and IQW to the diet of a DSS-induced colitis mouse model; research showed that IQW could adjust the amino acid levels in serum and regulate intestinal immune function to relieve inflammation; IQW and IRW could reduce oxidative stress induced by DSS by increasing antioxidant enzyme activity; IQW and IRW achieved this by increasing the diversity of the host’s intestinal microorganisms and increasing the probiotic biomass [16, 17]. In view of the IQW and IRW effect in the DSS-induced mouse model, we expect IQW and IRW can perform a similar effect in the ETEC-induced mouse model. In this study, we explore the effects of IQW and IRW on jejunal inflammation in an ETEC-induced mouse model.

2. Materials and Methods

2.1. Experiment Design

The Chinese guidelines for animal welfare were observed for the experimental strategy design. Approval from the Animal Care and Use Committee of Hunan Agricultural University was obtained. In total, 24 male mice (8 weeks, average weight: 23 g) were used in the experiment. All mice were raised at Hunan Agricultural University and fed in a comfortable environment (relative humidity: 53%; average temperature: 24 degrees). In order to simulate natural light conditions, the animals were fed under 12 h of light and 12 h without light. In order to alleviate the stress response caused by the environmental change, mice were given a 3-day adaptation period before the experiment. After 3 days, the mice were randomly divided into four groups: (a) control (CTRL) group (), (b) ETEC group (), (c) IQW-ETEC group (), and (d) IRW-ETEC group (). Groups a and b were given basal diet and natural drinking water for the first 7 days. Group a was given 0.1 mL saline in the first 7 days. Group b was given 0.1 mL CFU/mL ETEC for 7 days. Mice in groups c and d were put on a basal diet of IQW (93.04% purity, 0.03% mass concentration) and 0.03% IRW (87.91% purity; 0.03% mass concentration), respectively. Meanwhile, 0.1 mL ETEC was given to groups c and d 7 days after the first day of the feeding experiment; this lasted for 7 days. At the end of the 15th day of the feeding experiment, all mice fasted for 12 h and were subsequently weighed before being sacrificed. The acute blood loss method is used to collect blood in mice. The jejunal tissues and colon contents were collected after autopsy; all samples were frozen using liquid nitrogen and stored in a -80°C freezer for further experimentation.

2.2. Histological Analysis of the Jejunum

Samples contained different alcohol concentrations (50%, 70%, 80%, 90%, and 95%). For dehydration, a dimethyl benzene ethanol and paraffin (1 : 1) solution was used for the sample embedding processing. The jejunal tissue morphology and tissue damage were analyzed, and the height of intestinal villi and crypt depth were microscope measured using hematoxylin-eosin-stained samples.

2.3. Jejunal Tissue Inflammatory Cytokine Detection

Jejunal TNF-α, IL-1β, IL-6, and IL-10 were detected via enzyme-linked immunosorbent assay (ELISA). Antibodies (anti-TNF-α, IL-1β, IL-6, and IL-10) were added into the polystyrene HRP-plate well after dilution with carbonate-coated buffer (1 : 100) and placed at 4°C for 12 h overnight. The solution was poured out, and the plates were washed with PBS solution three times. The blocking solution was added to each plate well, incubated at 37°C for 1.5 h. After washing the samples three times using PBS solution, they were incubated at 37°C for 1.5 h. Diluted biotinylated antibodies (goat against mice) were added for 30 min at 37°C. TMB (3,3,5,5-Tetramethylbenzidine) substrate was added to each reaction well for the color reaction; the reaction lasted 20 min at 37°C. Sulfuric acid was added to each reaction well for the termination reaction. The absorbance of each reaction was measured at 450 nm.

2.4. Microbial Community Analysis

The DNA of colon content samples was extracted, and the purified DNA was used as a template to amplify the variable region of V3+V4 of bacterial 16S rDNA gene by PCR. The PCR products were sent to MicroBio for sequencing analysis. The obtained sequencing results were optimized for OTU-operational taxonomic unit cluster analysis. Alpha diversity analysis (species richness statistics, such as Chao and Ace, and species diversity statistics, such as Shannon and Simpson) was performed using Mothur (version 1.33.3) software. Microbial Ecology (QIIME) was an open-source tool for analyzing the original sequence. PycGootookit6 software was used to deal with the sequence errors and database redundancy in the original data [18]. The optimal overlapping sequence was found by splicing the original sequence [19]. For each sample, the sequence was analyzed using QIIME and the UPARSE application to determine the operational classification unit (OTUs), and the classification data were assigned to each OTUs using the RDP classifier (version 2.2) [20]. The selected sequence of representatives. RDP classifier and Greengenes database were used for classification. Alpha diversity analysis of the jejunal bacterial community was performed using the abundance-based coverage estimator (ACE), bias-corrected Chao richness estimator, Shannon index, and Good’s coverage.

2.5. Data Analysis

The statistical software package (SPSS V16.0) was used for statistical analysis. The one-way ANOVA method was used to analyze significant differences among groups, and the data were represented as . GraphPad Prism 8 was used to make graphs. values < 0.05 were regarded as significantly different.

3. Results

As shown in Figure 1, compared to the CTRL group, the length of intestinal villi in the ETEC group was significantly decreased (), and crypt depth was increased considerably (), which indicated that ETEC could cause severe jejunal damage. However, compared to the ETEC group, in the IQW-ETEC and IRW-ETEC groups, the length of intestinal villi increased while the crypt depth decreased (), which might indicate that IQW and IRW dramatically improve the status of intestinal injury, improving damage recovery.

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As shown in Figure 2, the contents of inflammatory cytokines (TNF-α, IL-1β, IL-6, and IL-10) in the ETEC group were significantly higher than those in the CTRL group. The contents of TNF-α, IL-1β, IL-6, and IL-10 in the IQW-ETEC and IRW-ETEC groups were significantly lower than those in the ETEC group ().

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Sequencing analysis was from the V3-V4 region of 16S rRNA in collected colon content samples. Figure 3 shows the α-diversity analysis of each group. In the ETEC group, the Ace index, Shannon index, Chao index, Sobs index, and Good’s coverage were significantly lower than in the CTRL group. Additionally, compared to the ETEC group, the α-diversity of the IQW-ETEC and IRW-ETEC groups was significantly increased ().

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Microbiota analysis was conducted on colon content samples; Figure 4(a) shows the relative abundance of collected microorganisms at the phylum level. The abundance of Bacteroidetes, Firmicutes, and Proteobacteria showed advantages in the phylum level. In the CTRL group, the relative abundance of microbiota was Bacteroidetes (55.20%), Firmicutes (35.33%), and Proteobacteria (4.08%). In the IQW-ETEC group, the relative abundance of microbiota was Bacteroidetes (58.24%), Firmicutes (29.92%), and Proteobacteria (6.11%). In the IRW-ETEC group, the relative abundance of microbiota was Bacteroidetes (70.21%), Firmicutes (20.66%), and Proteobacteria (4.77%). In Figure 4(b), IQW and IRW significantly increased the abundance of Bacteroidetes compared with the ETEC group (). In Figure 4(c), IQW and IRW significantly reduced the abundance of Firmicutes in mice compared with the ETEC group (). The IRW-ETEC and IQW-ETEC groups were significantly different from the ETEC group (), and the proportion of Firmicutes in the colon of mice in the IRW-ETEC group also increased to a certain extent. In Figure 4(d), the abundance of Proteobacteria in ETEC is significantly higher than in the CTRL group (). The abundance of Proteobacteria in the IRW-ETEC and IQW-ETEC groups is significantly lower than in the ETEC group ().

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Figure 5(a) shows the nine classes with the most abundant abundance in colon contents. In the CTRL group, Bacteroides (54.95%), Clostridia (23.7%), and Bacilli (10.7%) were the most abundant. In the ETEC group, Bacteroidetes (57.5%), Clostridium (12.96%), Bacillus (12.99%), and Erysipelotrichia (3.95%) were the most abundant groups. In the IQW-ETEC group, Bacteroidetes (70.1%), Clostridium (11.6%), and Bacillus (7.1%) were the largest groups. In the IRW-ETEC group, Bacteroides (72.9%), Clostridium (9.1%), Bacillus (5.4%), and Erysipelas (3.0%) were the most abundant groups. The results in Figure 5(b) show that both IQW and IRW treatments increased the abundance of Bacteroidia in the intestine of mice, and both groups showed significant differences compared with the ETEC group (). At the same time, it can be seen from Figure 5(c) that ETEC treatment significantly increased the abundance of Epsilonproteobacteria (). IQW and IRW treatment could significantly reduce the growth of Epsilonproteobacteria (). In Figure 5(d), the relative abundance of Clostridia in the ETEC group is significantly decreased compared to the CTRL group; IQW and IRW significantly increased the abundance of Clostridia compared to the ETEC group.

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Figure 6 shows the highest abundance of colon contents at the order level (Figure 6(a)). And in the CTRL group, Bacteroidales (54.95%), Clostridiales (23.7%), Lactobacillales (5.78%), and Bacillales (4.9%) were the most abundant groups. In the ETEC group, Bacteroidetes (57.53%), Clostridium (12.96%), Lactobacillus (10.3%), and Erysipelotrichales (3.95%) were the most abundant groups. In the IQW-ETEC group, Bacteroidetes (70.1%), Clostridium (11.6%), Lactobacillus (3.1%), and Bacillus (4.0%) were the most abundant groups. In the IRW-ETEC group, Bacteroidetes (72.9%), Clostridium (9.12%), and Lactobacillus (3.99%) were the largest groups. Figure 6(b) shows that ETEC significantly increases the abundance of Bacteroidales (). The effects of IQW-ETEC and IRW-ETEC were not significant according to the ETEC group (). Figure 6(c) shows the levels of Clostridiales in the colon of mice: the group treated with ETEC had significantly decreased amounts compared to the CTRL group (); in contrast, the abundance of Clostridiales in the IQW-ETEC and IRW-ETEC groups was significantly increased compared to the ETEC group (). Thus, the effects of IQW and IRW treatment were effective. Figure 6(d) shows that ETEC can significantly increase the abundance of Erysipelotrichales (). The addition of IQW and IRW had an obvious trend in reducing the Erysipelotrichales content compared with the ETEC group.

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At the family level, nine families had the highest abundance (Figure 7(a)). In the CTRL group, Lachnospiraceae (12.9%), Prevotellaceae (8.1%), and Bacteroidaceae (5.6%) were the most abundant microorganisms. Lactobacillaceae (5.8%) was the most abundant microorganisms in the ETEC group. Lachnospiraceae (6.4%), Prevotellaceae (9.1%), Bacteroidaceae (8.3%), and Lactobacillaceae (7.5%) were the most abundant microorganisms in the IQW-ETEC group. The most abundant microorganisms in the IRW-ETEC group included Lachnospiraceae (9.6%), Prevotellaceae (6.2%), Bacteroidaceae (9.2%), and Staphylococcaceae (3.9%). Lachnospiraceae (7.9%), Prevotellaceae (7.6%), Bacteroidaceae (7.6%), and Ruminococcaceae (4.8%) were the most abundant microorganisms in the IQW-ETEC group. It can be concluded from Figure 7(b) that the Lachnospiraceae in the ETEC group is significantly lower than in the CTRL and IQW-ETEC groups (). However, there was no significant difference between the ETEC and IRW-ETEC groups. There was a clear trend on increasing the abundance of Lachnospiraceae. In Figure 7(c), ETEC significantly increases the abundance of Prevotellaceae (). And the effect of IQW and IRW was effective (). In Figure 7(d), the abundance of Flavobacteriaceae is significantly increased by ETEC () compared to the CTRL group. There is a significant decrease of Flavobacteriaceae in the IQW-ETEC group compared to the ETEC group. However, there is no significant difference between the ETEC group, IRW-ETEC group, and CTRL group, despite the obvious presence of a trend of Flavobacteriaceae decrease in the IRW-ETEC group.

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At the genus level, nine genera have the highest abundance (Figure 8(a)). In the CTRL group, Bacteroides (5.3%), Alloprevotella (5.6%), Lactobacillus (5.4%), and Staphylococcus (4.7%) were the most abundant groups. In the ETEC group, Bacteroides (5.3%), Prevotella (4.8%), Lactobacillus (9.1%), and Helicobacter (2.8%) were the most abundant groups. In the IQW-ETEC group, Bacteroides (9.96%), Prevotella (4.6%), Lactobacillus (2.7%), and Staphylococcus (3.8%) were the most abundant groups. In the IRW-ETEC group, Bacteroides (8.97%), Prevotella (6.4%), and Lactobacillus (3.4%) were the largest groups. As shown in Figure 8(b), the abundance of Bacteroides in intestinal microorganisms was significantly increased by the IQW compared to the ETEC group (), and there was still an obvious trend of Bacteroides increase in the IRW-ETEC group compared to the ETEC group. Figure 8(c) shows that ETEC significantly increased the abundance of Helicobacter compared to the CTRL group (), and the IQW and IRW significantly increased the abundance of Helicobacter compared to the ETEC group (). In Figure 8(d), there is a trend of decreasing abundance of Alloprevotella after ETEC treatment; there was also a recovery effect after IQW and IRW treatment.

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4. Discussion

The intestinal tract is one of the most important digestive organs in mammals. Equally important, the intestinal tract also plays an important role in immune function [21]. The intestinal tract is a dynamic and complex system; the intestinal microenvironment is the coexistent result of host and microbiota [22, 23]. The intestinal cells have a strong regenerative capability, with damaged cells recovering within 3 days [24]. The intestinal cells are composed of two types of cell lineages: an absorptive (enterocyte) cell lineage and a secretory (exocrine) cell lineage, both of which originate from intestinal stem cells (ISCs) [25]. Active ISCs are the major actuator for damaged intestinal cells; crypts are the storage region of ISCs [26]. Intestinal villus length and crypt depths are the two common evaluation indexes of intestinal inflammation. Studies have shown that intestinal damage can decrease villus height while increasing crypt depth [27]. Our research highlights the ability of ETEC to cause jejunal damage. Notably, IRW and IQW polypeptides can promote jejunal cell recovery.

After infection, ETEC can adhere to intestinal cells and initiate damage via toxins in a short period [28]. Additionally, ETEC, through the MAPK and NF-κB pathways, causes further inflammatory damage [29]. A previous study pointed out that ETEC infection increased the expression of IL-1β, IL-6, TNF-α, IL-17, and IL-18 [30]. Our research also determined that ETEC can significantly increase the expression of TNF-α, IL-1β, IL-6, and IL-10. Moreover, IQW and IRW can significantly alleviate the overexpression of inflammatory cytokines (). Accordingly, there is no significant difference between the IQW and IRW groups ().

The intestinal microbiota plays an important role in host immunity, digestion, and metabolism and is unique to a specific host body [31]. The mammalian intestinal tract is homeostatically an orderly symbiotic environment; adverse conditions destroy the balance between intestinal microbiota and host [32, 33]. Intestinal inflammation can lead to a disturbance of host intestinal organisms. A study showed that pathogenic bacterial infections, such as Salmonella enterica infection, can cause host intestinal inflammation, reducing intestinal microbiota diversity [34]. Our research points out that in the -diversity test of the colon intestinal tissue of experimental mice, the microbial community richness in the ETEC group was significantly decreased compared with that in the CTRL group (). Figure 4 shows that the microbial abundance in the ETEC group was significantly lower than the CTRL, IQW-ETEC, and IRW-ETEC groups (). To a certain extent, IQW and IRW can alleviate the decrease in intestinal microbial microorganisms caused by ETEC.

IQW and IRW are two kinds of polypeptides that possess numerous excellent biological activities. A study revealed that IRW functions by regulating and improving the diversity of the intestinal microbiome of the host [35, 36]; our research confirmed this. IRW and IQW can significantly promote intestinal microbiome recovery. In the IQW-ETEC and IRW-ETEC groups, the Shannon index, Sobs index, Chao index, Ace index, and Good’s coverage were significantly higher than in the ETEC group.

ETEC reduced the abundance of Bacteroidetes. Bacteroidetes are the most common intestinal microbes in the human gut, accounting for roughly 50% of the intestinal microbes in a Western person [37]. Some bacteria in the Bacteroides genus, such as Bacteroides fragilis, have been shown to prevent and treat intestinal diseases. One study showed that B. fragilis could alleviate inflammation in the DSS-induced IBD colitis model in mice and alleviate weight loss caused by IBD and inflammation [38]. Some studies have shown that Bacteroides have several probiotic effects, such as promoting the digestion of dietary-fiber polysaccharides and the host immunity [39, 40]. Our experimental results showed that IQW and IRW could facilitate the restoration of the host intestinal microbiome environment, improving the abundance of intestinal probiotics in the host intestinal tract and alleviating the jejunal inflammatory response caused by ETEC. A previous study by our research group revealed that IQW could increase the Bacteroides biomass, and IRW can increase the abundance of Clostridium [41]. And our research showed similar results. Another study pointed out that IRW and IQW intake could increase the abundance of Firmicutes and Actinobacteria and reduce the proportion of Bacteroidetes and Proteobacteria [42]. ETEC increased the abundance of Flavobacteriaceae, e.g., F. aquatile and F. meningosepticum, which can cause many diseases, including aquatic diseases (shark fin rot and equine back disease) and neonatal meningitis, respectively [43]. Flavobacteria infection is also the infectious agent for chronic skin disease and bacterial gill disease in fish [42]. The experimental results demonstrate that the proportion of Flavobacteriaceae in the intestines of IQW-treated mice significantly decreased (); after IRW treatment, the proportion of intestinal Flavobacteriaceae decreased. Studies have pointed out that IQW and IRW can improve the abundance of Firmicutes, Bacteroidetes, and Proteobacteria, increase the Lactobacillus and Bifidobacterium biomass, and decrease the abundance of Helicobacter pylori and Verrucomicrobia[43, 44]. Our research shows similar results, with IRW and IQW improving the abundance of probiotics such as Firmicutes, Proteobacteria, Clostridiales, Lachnospiraceae, and Alloprevotella and decreasing the abundance of pathogenic bacteria such as Epsilonproteobacteria, Erysipelotrichales, Prevotellaceae, and Flavobacteriaceae.

5. Conclusions

ETEC can cause jejunal damage, exacerbating the inflammatory reaction. However, IQW and IRW can decrease the expression of inflammatory cytokines, thereby improving the abundance of probiotics such as Firmicutes, Proteobacteria, Clostridiales, Lachnospiraceae, and Alloprevotella and decreasing the abundance of pathogenic bacteria such as Epsilonproteobacteria, Erysipelotrichales, Prevotellaceae, and Flavobacteriaceae.

Data Availability

The data of this study was available at the corresponding author upon reasonable request.

Conflicts of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

This research was supported by the Hunan Provincial Science and Technology Department (2020NK2004, 2019TP2004, 2018WK4025, 2020ZL2004, 2016NK2101, and 2016TP2005), National Natural Science Foundation of China (Nos. 31772642, 31672457, and 41807135), Local Science and Technology Development Project Guided by The Central Government (YDZX20184300002303 and 2018CT5002), China Postdoctoral Science Foundation (2018M632963 and 2019T120705), Scientific Research Fund of Hunan Provincial Education Department (2020JGYB112 and 18B107), Double First-Class Construction Project of Hunan Agricultural University (SYL201802003, YB2018007, and CX20190497), and Natural Science Foundation of Hunan Province, China (No. 2019JJ50220).

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Copyright © 2021 Naiyuan Liu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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