Treatment Effects of Natural Products on Inflammatory Bowel Disease In Vivo and Their Mechanisms: Based on Animal Experiments

To date, the exact cause of IBD is unknown, but numerous studies have found that the occurrence of IBD is associated with genetics, environment, gut microbes, hygiene, diet, sleep, mental health, smoking, antibiotic use, and post-surgical complications (Figure 1). Of these, genetics, environment, and diet are the three main factors [23].

Due to the complex pathogenesis of IBD, the therapeutic agents and treatments for IBD are complex and varied. Currently, some good therapeutic agents and treatments include amino salicylic acid agents, corticosteroids, immunomodulators, biological agents, stem cell transplantation, fecal microbiota transplantation, helminth therapy, and surgery. Among them, the mainstream methods are pharmacological treatments, such as amino salicylic acid agents, corticosteroids, immunomodulators, and biological agents. Although there is a wide range of therapeutic agents and methods for IBD, the therapeutic effect is not satisfactory and there are problems, such as poor patient compliance with medications, a high disease relapse rate, and therapeutic agents and treatments that are not universally applicable. Figure 2 demonstrates the IBD treatment drugs and methods and their disadvantages. Therefore, there is an urgent need to find low-cost, safer, and effective anti-inflammatory drugs for IBD patients to overcome the problems of existing therapeutic drugs.

Flavonoids are found in almost all green plants and are abundant in vegetables and fruits. Depending on their structures, flavonoids can be broadly classified as flavones, isoflavones, flavanols, flavanones, anthocyanins, etc. [73]. Flavonoids have a wide range of biological activities and are known to promote human health [74]. Numerous studies have shown that flavonoids from plants have therapeutic effects on inflammatory bowel diseases. For example, flavonoids from citrus can exert a modulatory effect on IBD by reducing the inflammatory response and inhibiting intestinal muscle contraction, significantly improving the pathological condition of experimental UC rats [75]. The fruit of Lycium barbarum is rich in flavonoids such as anthocyanins. Using anthocyanins from Lycium barbarum in DSS-induced UC mice, researchers found that anthocyanins from Lycium barbarum improved the symptoms of colitis in mice by affecting three aspects: inflammatory factors, increasing tight junction proteins, and regulating the intestinal microbiota [76]. Similarly, water-soluble isoflavones from soybean alleviated the symptoms of colitis in a mice colitis model by a potential mechanism of inhibiting inflammation by affecting the NF-κB pathway [77]. There is an extensive literature on the preventive and therapeutic effects of flavonoids on IBD. Flavonoids have been systematically described as therapeutic agents for IBD by investigators in recently published reviews [14,78]. Here, we summarized 48 flavonoids with therapeutic effects in experimental IBD models from the recently published literature. Of all the compounds we summarized, flavonoids accounted for 28.2% in terms of number. This higher percentage shows that flavonoids have a more pronounced therapeutic effect on IBD. The sources, types, doses, and mechanisms of action of these compounds are shown in detail in Table 1. Figure 4 shows the structural formulae of flavonoids with IBD therapeutic effects.

Terpenoids are a group of naturally occurring source hydrocarbons widely found in plants and can be found in many plant bodies, especially conifers. Terpenoids can be classified as monoterpenes, sesquiterpenes, diterpenes, dibasic terpenes, triterpenes, tetraterpenes, and polyterpenes based on the number of isoprene structural units in the terpenoid structure. Many terpenoids have important physiological activities, such as being anti-inflammatory, anti-tumor, antibacterial, and antiviral, and are an important source for the study of natural products and the development of new drugs [132]. A recently published review summarized 281 terpenoids with anti-inflammatory activity and found that the powerful anti-inflammatory activity of terpenoids provides additional options for the development of anti-inflammatory drugs [15]. For IBD, some terpenes have also shown good therapeutic effects. Asiatic acid is a naturally occurring triterpenoid. Oral administration of Asiatic acid was found to significantly improve intestinal inflammation in mice with colitis and by inhibiting mitochondria-mediated activation of NLRP3 inflammatory vesicles [133]. Carvacrol, a phenolic monoterpene with anti-inflammatory and antioxidant activity, has been found to treat colitis in experimental mice. It was found to treat acetic acid-induced colitis in C57BL/6 mice by reducing the inflammatory response and oxidative damage [134]. Similarly, plumericin from Himatanthus sucuuba has been used by investigators as a candidate for the treatment of IBD due to its strong anti-inflammatory and antioxidant activities [135]. In Table 2, we summarized 25 natural terpenoids with therapeutic effects on IBD. It can be seen that the terpenoids with therapeutic effects on IBD mainly include monoterpenes, sesquiterpenes, triterpenes, and tetraterpenes. Figure 5 shows the structural formulae of terpenoids with IBD therapeutic effects.

Glycosides are compounds formed by linking the end group carbon atoms of a sugar or sugar derivative to another class of non-sugar substances. Numerous studies have demonstrated that glycosides of natural origin have a wide range of biological activities, such as antiviral, anti-inflammatory, antitumor, and immunomodulatory [159,160]. In our search, we found that some natural glycosides have a better ameliorative effect on IBD; for example, Paeoniflorin [161], Salidroside [162], Wogonoside [163], Hesperidin [164], etc. It was found that glycosides from Paeonia suffruticosa significantly improved the clinical symptoms of IBD mice by reducing the inflammatory response [165]. In addition, total glucoside of Paeonia suffruticosa (TGP) was able to prevent IBD by modulating the IL-23/IL-17 axis and Th17/Treg homeostasis, and high doses of TGP had therapeutic effects on IBD similar to those of the therapeutic drug salicylazosulfapyridine [166]. In Table 3, we summarize 13 glycosides with in vivo therapeutic effects on experimental IBD. Figure 6 shows the structural formulae of the glycosides with therapeutic effects in IBD. It is worth mentioning that ginsenosides, the main active components of ginseng, have strong anti-inflammatory activity and are promising NPs for the treatment of IBD [167]. Ginsenoside Rd is a bioactive component of ginseng that stimulates the proliferation of endogenous stem cells. In a rat model of IBD, ginsenoside Rd stimulated the proliferation and differentiation of endogenous intestinal stem cells in rats, which, in turn, improved intestinal function [168]. In two IBD mouse models (DSS-induced and TNBS-induced), ginsenoside Rb1 could improve colitis by activating the endoplasmic reticulum-resident E3 ubiquitin ligase Hrd1 signaling pathway [16]. Not only that, ginsenoside Rg1 in ginseng can also regulate the intestinal microbiota of IBD mice to alleviate UC through microbial tryptophan metabolism [169]. Besides, ginsenoside Rh2 and ginsenoside Rk3 in ginseng have the same therapeutic and alleviating effects on experimental IBD [170,171]. Ginsenosides have significant therapeutic effects and low side effects and are likely to be used as a potential novel therapeutic agent for IBD [167].

Polyphenols are commonly found in vegetables and fruits, are secondary metabolites of many plants, and are also the most abundant source of natural antioxidants in the human diet. Numerous studies have shown that the intake of foods rich in polyphenols can be used to prevent and treat some common chronic diseases [177]. Polyphenols have a clear therapeutic effect on IBD due to their powerful antioxidant and anti-inflammatory properties [178]. For example, polyphenol extracts from spearmint (Mentha spicata L.) can attenuate inflammatory responses and colonic injury in IBD mice in vivo, and researchers have predicted that they may play an adjunctive role in the treatment of IBD patients [179]. Polyphenol extracts from Ripened Pu-erh tea (RPT, a famous traditional Chinese fermented tea) can ameliorate DSS-induced murine colitis. Researchers found that this may be due to the fact that RPT increased the level of short-chain fatty acids and PPAR-γ expression in the intestine [180]. Some other polyphenolic substances from plants have also been found to have IBD therapeutic activity, such as Black rice [181], Rock tea [182], etc. In Table 4, we summarize 11 polyphenolic compounds with in vivo therapeutic effects on experimental IBD. Figure 7 shows their structural formulae. Among these polyphenolic compounds, resveratrol showed a powerful therapeutic effect on IBD. Numerous studies have found that resveratrol can improve IBD pathology by modulating the intestinal microbiota of experimental IBD mice, reduce the inflammatory response, and alleviate intestinal mucosal barrier dysfunction in UC mice by enhancing autophagy of intestinal epithelial cells. It also inhibited the activation of PI3K/Akt pathway and reduced VEGFA gene expression to improve IBD [183,184,185]. In contrast, in-depth studies revealed that the therapeutic effect of resveratrol on IBD is mainly due to its alteration of the intestinal microbiota. In the presence of resveratrol, gut bacteria are also able to increase the production of short-chain fatty acids, and the gut microbiota has antioxidant and anti-inflammatory properties on the metabolites of resveratrol, which is very beneficial for the treatment of IBD [186]. It is certain that polyphenols of natural origin have potential therapeutic effects on IBD and can alleviate the symptoms of IBD through several pathways. Recently, a growing number of studies on the therapeutic effects of polyphenolic compounds on IBD have demonstrated that it is theoretically possible to develop drugs for the improvement of IBD using polyphenolic substances, and that polyphenols can be used as alternative or complementary therapies to conventional IBD treatments [17]. And some natural polyphenols with high activity may be included in the clinical trial phase, which may lead to the development of natural drugs with therapeutic effects in IBD [187].

Quinones are a class of plant secondary metabolites. Based on the number of benzene rings, quinones can be classified as anthraquinone, naphthoquinone, benzoquinone, and benzoquinone [199]. Several studies have found that quinones have IBD therapeutic activity. Here, we summarize six quinones that have in vivo therapeutic effects on experimental IBD (Table 5). Figure 8 shows their structural formulae. We found that among the four types of quinones, naphthoquinone exhibited more potent therapeutic effects on IBD. The investigators found that juglone, isolated from the green walnut husks of Juglans mandshurica, had in vivo therapeutic effects on DSS-induced UC mice. At a dose intervention of 1 mg/kg, juglone could treat UC in mice by modulating the intestinal microbiota and restoring Th17/Treg homeostasis [18]. Natural shikonin isolated from the root of Lithospermum erythrorhizon has also shown better effects when used to validate its therapeutic effects on UC due to its strong anti-inflammatory activity. After one week of treatment with shikonin at 25 mg/kg per day by gavage in experimental IBD model mice, their pathological symptoms were significantly reduced, probably by reducing inflammation and reversing intestinal mucosal damage [200]. Thymoquinone from Nigella sativa, which has antioxidant and anti-inflammatory properties, was found to reduce colonic inflammation in experimental IBD mice through its ability to modulate the Nrf2/Keap1 system [201]. Among the NPs that have been reported to have therapeutic effects in IBD, quinones are quantitatively modest. However, because they have therapeutic potential for IBD, they could also be a source of potential IBD therapeutic agents.

Alkaloids are a type of nitrogenous organic compound derived from amino acids that can be found in plants, animals, and microorganisms [204]. Alkaloids are usually classified as indoles, isoquinolines, and pyridine alkaloids. Alkaloids of natural origin have been shown to have a variety of pharmacological activities, such as anti-inflammatory, immunomodulatory, and anti-cancer [19]. Recently, numerous studies have reported the therapeutic effects of different sources of natural alkaloids on experimental IBD [205]. In this paper, we summarize 34 natural alkaloids with IBD therapeutic effects (Table 6), and their chemical structural formulae are presented in Figure 9. Quantitatively, the number of alkaloids with IBD therapeutic activity is second only to the flavonoids. This suggests that among the many NPs, the therapeutic potential of alkaloids for IBD is enormous. Berberine, an isoquinoline alkaloid, was found to have a significant therapeutic effect on experimental IBD. Its potential mechanism of action is to improve clinical symptoms in mice with experimental IBD by modulating the intestinal microbiota and protecting the intestinal mucosal barrier [206]. Further studies revealed that berberine may have a therapeutic effect by modulating glial-intestinal epithelial cell-immune cell interactions, thereby improving intestinal neuroinflammation [207]. Piperine from Piper longum Linn. is a natural alkaloid of plant origin with a long history of medicinal use. In a mouse IBD model, piperine exhibited potent IBD therapeutic activity. At a dose of 10 mg/kg/day, piperine significantly reduced DAI scores and reduced the inflammatory response by inhibiting the IκB-α/NF-κB signaling pathway in mice [208,209]. Therefore, piperine may be used as an anti-inflammatory agent for the treatment of IBD. Camptothecin, a quinoline alkaloid extracted from camptotheca acuminata, was also found to have therapeutic effects in mice with experimental IBD. Camptothecin may improve the expression of cellular inflammatory factors in mice with IBD by modulating clinical symptoms in IBD mice by modulating the expression of cellular inflammatory factors [210]. A recent review illustrated the great therapeutic potential of alkaloids of natural origin for UC [19]. This article suggested that the potential mechanisms of natural alkaloids for treating UC are closely related to their regulation of oxidative stress, immune response, intestinal flora, and improvement of intestinal barrier function.

Coumarins are widely present in different parts of the plant and are secondary plant metabolites consisting of a thickened benzene ring and an α-pyrone ring. The mechanism of action of coumarins in experimental IBD models is similar to that of other NPs, such as flavonoids and polyphenols. So far, most of the therapeutic effects of coumarins on IBD have been achieved mainly by reducing inflammatory responses and modulating oxidative stress and immune responses. A few studies have also reported that coumarins act through other signaling pathways, such as NF-κB and PPAR-γ Signaling Pathways, MAPK Signaling Pathway, HIF-1α Signaling Pathway, etc. [20]. In Table 7, we summarize 10 natural coumarins with IBD therapeutic effects, and their chemical structural formulae are presented in Figure 10. Osthole is a natural coumarin-like compound isolated from Cnidium monnieri. Previous studies have shown that osthole has anti-inflammatory activity and a protective effect on the intestinal tract of mice with experimental IBD [247,248]. Further studies revealed that osthole could treat experimental IBD by blocking the activation of NF-κB and MAPK/p38 pathways, as well as reducing the expression of inflammatory mediators [249]. Umbelliferone is a coumarin derivative with anti-inflammatory and antioxidant effects. Umbelliferone was found to have a significant ameliorative effect on acetic acid-induced UC. Umbelliferone not only significantly ameliorated histological damage in rats, but also treated UC by exerting anti-inflammatory and antioxidant effects. Its potential mechanism is to promote the SIRT1/PPARγ signaling pathway to protect UC rats [250].

Natural polysaccharides have powerful bioactivities, especially anti-inflammatory activity [259]. In recent years, natural polysaccharides have received much attention because of their high activity, safety, and easy access [21]. Notably, a large number of studies have reported the therapeutic and ameliorative effects of natural polysaccharides on IBD [260]. For example, a polysaccharide (EP-1) isolated and purified from the monkey head mushroom could alleviate acetic acid-induced UC. It was found that EP-1 ameliorates UC symptoms by modulating the intestinal microbiota and increasing the content of short-chain fatty acids in the intestine [261]. Water-soluble polysaccharides isolated from Auricularia auricular-judae can be used to treat experimental IBD by protecting the intestinal barrier and regulating the intestinal microbiota in mice [262]. An active polysaccharide from Astragalus has also been shown to have an ameliorative effect on experimental IBD. Using a DSS-induced acute UC mouse model to investigate its mechanism of action, it was shown that Astragalus polysaccharide could improve experimental IBD by inhibiting the NRF2/HO-1 pathway and regulating Tfh/Treg cell homeostasis [263,264]. Additionally, polysaccharides from Dictyophora indusiata may also improve the clinical symptoms of experimental IBD by modulating intestinal microbiota and inflammation-related signaling pathways [265]. Natural polysaccharides have a very good effect on the regulation of the intestinal microbiota, according to the extensive literature on the improvement of IBD by natural polysaccharides [266]. On the one hand, natural polysaccharides can restore the imbalance of the intestinal microbiota and protect the intestinal barrier. On the other hand, the metabolism of polysaccharides by the intestinal microbiota produces large amounts of short-chain fatty acids and other metabolites, especially tryptophan, which are also well known to improve experimental IBD [267]. Short-chain fatty acids have been found to play an important role in maintaining intestinal function and intestinal epithelial cell homeostasis [268]. Most of the natural polysaccharides with ameliorative effects on experimental IBD are of plant origin. Studies have shown that natural plant polysaccharides are not only low in toxicity and high in activity, but also have a very positive effect on the relief of IBD. Among them, natural plant polysaccharides rich in galactose and mannose are more effective in the treatment of IBD [269]. A recent study had discussed the ameliorative effects and mechanisms of action of natural polysaccharides on IBD. It was found that natural polysaccharides exerted their ameliorative effects on IBD mainly in terms of improving clinical symptoms of IBD, repairing colonic tissues, reducing oxidative stress, decreasing inflammatory response, immunomodulation, and regulating intestinal flora [21]. In Table 8, we summarized 18 recently published natural polysaccharides with in vivo therapeutic effects on experimental IBD models and their potential mechanisms of action.

Protein peptides have been found to have a variety of active functions, and several peptides have been found to improve intestinal inflammation and have therapeutic effects on experimental inflammatory bowel disease [286,287,288]. Evidence for the use of bioactive peptides in reducing intestinal inflammation has been investigated through the use of in vivo models and clinical trials [22]. In Table 9, we summarized the therapeutic effects of natural proteins and active peptides on experimental IBD. Small peptides obtained from plants have alleviating effects on DSS-induced inflammatory bowel disease, such as the tripeptide VPY from soybean and the dipeptide pyroGlu-Leu from wheat [287,288]. Phycocyanin has been found to possess a variety of physiological activities. It was found that phycocyanin could improve colitis in mice by protecting the intestinal epithelial cell barrier and exerting anti-inflammatory and antioxidant effects [289]. Moreover, recent studies have found that certain protein peptides from animal sources also have the same function of improving colitis; for example, bee venom peptides [290] and yellowtail protein hydrolysates [291]. However, the unstable nature of peptides and their easy inactivation after digestion in the gastrointestinal tract make the treatment of inflammatory bowel disease with peptides more challenging [292]. Today, the development of protein modification and encapsulation techniques has allowed the protection of functional peptide activity. For example, when annexin A1-derived tripeptide MC-12 was grafted onto the disulfide-rich peptide linaclotide, its stability and biological activity were improved [292]. When MC-12 was transplanted into a sunflower trypsin inhibitor ring scaffold, in vivo experiments revealed that it significantly improved acute colitis in mice and exhibited greater stability [293]. Natural proteins have a wide range of biological activities. Oral administration, on the other hand, has a poor pharmacokinetic profile and low bioavailability. Proteins of natural origin may be a promising source of drugs for the treatment of inflammatory bowel disease if their activity is protected by appropriate methods [294].

The main clinical symptoms of IBD are bloody stools, abdominal pain, diarrhea, and weight loss [296]. The pathological conditions in the chemical agent-induced IBD model in mice or rats are generally characterized by colonic inflammation, weight loss, diarrhea, bloody stools, and colon shortening, which are very similar to the clinical symptoms of human IBD [297]. The pathological evaluation of IBD is based on the Disease Activity Index (DAI) score, which is the average of weight loss, fecal status, and blood stool scores, and is used to evaluate the severity of IBD [297]. All 170 NPs that we summarized as having ameliorative and therapeutic effects on experimental IBD improved the pathological symptoms of experimental IBD. For example, alpinetin, a natural flavonoid isolated from Alpinia katsumadai Hayata, significantly improved the symptoms of DSS-induced IBD in mice. This was demonstrated by a reduction in DAI scores and histopathology scores and reversal of colonic shortening [84]. Similarly, the natural polyphenol gallic acid significantly reduced DAI and colonic shortening in UC mice and reduced pathological damage to colonic tissue [189]. Caulerpin, a natural alkaloid, has been shown to have an ameliorative effect on experimental IBD. It was found that caulerpin given to IBD mice at a dose of 4 mg/kg per day significantly promoted the reduction of DAI and attenuated shortening and damage to the colon [241]. In addition, sanguinarine had the same effect of improving pathological symptoms in IBD mice. Compared to acetic acid-induced controls, sanguinarine treatment significantly reduced mortality and improved weight loss, DAI scores, colonic weights, and histological scores in mice [238]. Astragalus polysaccharide was also able to significantly improve clinical signs in IBD mice by increasing survival, DAI scores, body weight, colon length, rate of weight change, and histopathological damage to the colon [264]. Morinda officinalis root polysaccharide treatment not only significantly reduced diarrhea, weight loss, colonic shortening, and histological damage in UC mice, but also inhibited spleen swelling and structural changes in UC mice [298].

The homeostasis of the intestinal microbiota is critical to human intestinal health. In the gut of patients with IBD, an imbalance of the gut microbiota is commonly observed [299]. When the balance of intestinal flora is disrupted, the immune regulation and defense function of the intestine are compromised, causing damage to the intestinal mucosa and exacerbating IBD patients’ clinical symptoms [300]. A recent article summarized the changes in the microbiota of UC patients found in clinical studies. The results showed that in the gut of UC patients, the populations of Firmicutes, Actinobacteria, Bacteroides, Streptococcus, Escherichia coli, and Fusobacterium nucleatum increased and the populations of Bacteroidetes, Bifidobacterium, Blautia, Coprococcus, Lachnospira, Lactobacillus, Roseburia, Ruminnococus, Akkermansia muciniphila, Bacteroides fragilis, Clostridium leptum, Eubacterium rectale, Faecalibacterium prausnitzi, Prevotella stercorea, and Ruminococcus gnavus decreased [301]. Although it is not clear whether gut microbiota imbalance is a causative factor or a pathogenic consequence of IBD, many NPs have demonstrated that modulating the gut microbiota can improve clinical symptoms of experimental IBD [74,185,188,266].

The eight classes of NPs that we counted as having therapeutic effects on IBD all had different degrees of modulating effects on the intestinal microbiota. For example, the polyphenolic compound Salvianolic acid B could reduce the degree of inflammation in colitis by inhibiting the increase of Bacteroides and Akkermansia in the intestine of IBD mice [198]. Ginsenoside Rg1 significantly reversed the DSS-induced imbalance of intestinal microbiota in mice and attenuated acute UC symptoms through microbial tryptophan metabolism [169]. Juglone, a quinone, can increase the ratio of Firmicutes and Bacteroidota, increase the abundance of Actinobacteriota, and decrease the abundance of Verrucomicrobiota to alter the diversity and composition of intestinal microbes in UC mice [18].The coumarin-like compound daphnetin significantly increased the abundance of short-chain fatty acid-producing intestinal microbiota [253]. In addition, there are various natural polysaccharides that have a regulatory effect on the intestinal microbiota. It must be said that natural polysaccharides can provide a good growth environment for beneficial intestinal bacteria after digestion in the gastrointestinal tract, which is very beneficial for intestinal microorganisms [302]. Moreover, the fermentation of natural polysaccharides in the intestine can lower the pH value in the intestine, thereby inhibiting the growth of certain harmful microorganisms. The fermentation products of natural polysaccharides can also produce large amounts of short-chain fatty acids, which, in turn, can improve IBD through a variety of other pathways [303].

The altered permeability of intestinal mucosa is the primary manifestation of intestinal barrier dysfunction. The two main causes of intestinal barrier function damage are apoptosis of intestinal epithelial cells (IEC) and disruption of intercellular tight junctions (TJ) [304]. IEC is the barrier between the inner lumen and the external environment. Studies have shown that IEC apoptosis in the colon contributes to the development of chronic IBD [305]. IEC apoptosis is important in the pathogenesis of IBD. Excessive IEC apoptosis disrupts the intestinal defense system and impairs the function of the intestinal barrier [306]. Numerous studies have proved that NPs can inhibit IEC apoptosis through multiple pathways [188]. The main pathways involved are the death receptor-mediated pathway, mitochondria-dependent pathway, endoplasmic reticulum stress-mediated pathway, MAPK-mediated pathway, NF-κB-mediated pathway, and P13K/Akt-mediated pathway [307]. For example, biodegradation products of chitosan can prevent apoptosis in IEC by inhibiting NF-κB activation and decreasing TNF-α and IL-6 production [270]. TJ is a form of intercellular binding. Selective osmotic closure between adjacent IECs occurs due to the presence of TJ, which, in turn, forms an intestinal barrier to protect intestinal tissues. The cytoplasmic protein ZO (Zonula Occludens Proteins) family, transmembrane proteins (Tricellulin, Nectin, Occludin and Claudins), and cytoskeletal structures together constitute TJ [304]. Disruption of TJ leads to disruption of the intestinal immune system and inflammation, which is closely related to the development of IBD [308]. Alpinetin is a flavonoid isolated from Alpinia katsumadai Hayata. Alpinetin was found to improve intestinal barrier function in IBD mice by upregulating the expression of ocludin and zonula occludens-1 and downregulating the expression of claudin-2 [84]. Piperine is an alkaloid of natural origin. In an experimental IBD rat model, TNBS reduced the expression of claudin-1, ocludin, and zonula occludens-1 in colonic tissues, while Piperine significantly reversed the reduction in TJ expression brought about by TNBS [209]. These studies all confirmed that NPs can protect intestinal barrier function by inhibiting IEC apoptosis and reversing TJ disruption.

Inflammation is a physiological phenomenon that occurs in the organism in response to injury, infection, and stress by the immune system [259]. The primary therapeutic effect of NPs in experimental IBD is improved colonic inflammatory response. Excessive inflammatory responses and pro-inflammatory factor overexpression aggravate colitis symptoms in IBD, and the inflammation is attributed to an over-response of immune cells in the organism, such as Th1 T-cell over-response or Th2 T-cell over-response [309]. The over-response of immune cells causes dramatic changes in cytokines, which include the pro-inflammatory cytokines IL-1, IL-2, IL-6, IL-12, IL-18, IFN-γ, and TNF-α and the anti-inflammatory cytokines IL-4, IL-5, IL-10, and IL-13. Many NPs modulate inflammatory cytokines through multiple pathways to attenuate the IBD inflammatory response. The flavonoid baicalin was reported to significantly reduce TNBS-induced inflammation in UC mice by decreasing the levels of IL-6, TNF-α, and IL-1β and increasing IL-10 [310]. Overexpression of TNF-α is thought to be one of the key factors in the pathogenesis of IBD, while TNF-α knockout mice were shown not to develop significant colitis [21]. In contrast, the natural terpenoid thymol could attenuate the inflammatory response in IBD mice by reducing the acetic acid-induced upregulation of pNF-κB p65 protein and significantly inhibiting the production of MPO and TNF-α in colonic tissues [150]. Zeaxanthin has an ameliorative effect on acetic acid-induced UC in rats. It was found that zeaxanthin ameliorated acetic acid-induced UC in rats by modulating the levels of pro-inflammatory cytokines (TNF-α, IFN-γ, IL-6, IL-1β, NF-κB) [153].

Numerous studies have confirmed that the development of IBD is closely related to the disruption of the antioxidant system. In the intestine of IBD patients, excessive levels of oxidative stress lead to lipid peroxidation, DNA damage, apoptosis, and inflammatory responses [311]. Excessive production of ROS, including superoxide anion radicals, hydrogen peroxide, and hydroxyl radicals, can disrupt the intestinal mucosal barrier by altering the concentration of oxidation-related enzymes and pro-inflammatory cytokines, triggering an inflammatory response and aggravating IBD [312]. In the IBD mouse model, the levels of nitric oxide (NO), myeloperoxidase (MPO), superoxide dismutase (SOD), malondialdehyde (MDA), and catalase (CAT) are altered in mouse colonic tissues, triggering an imbalance in intestinal function [313]. Many NPs have strong antioxidant activities, especially polyphenols and flavonoids. For example, the polyphenolic compound procyanidin B2 was found to have an ameliorative effect on the symptoms of IBD in experimental mice, and its potential mechanism of action is to inhibit oxidative stress in colonic tissues via Nrf2/ARE signaling, which, in turn, promotes the repair of intestinal damage [190]. The polyphenolic compound polydatin also reduced oxidative stress and apoptosis in the colon of IBD mice via the sonic hedgehog signaling pathway, thereby ameliorating DSS-induced acute UC [192]. Intervention with the flavonoid galangin in experimental IBD mice revealed that galangin treatment significantly inhibited the protein expression of p-NF-κB and p-Ikk-βα, COX-2, iNOS, and Nrf2 in the colonic tissues of UC mice and increased HO-1 levels by suppressing inflammation and oxidative stress [79]. In addition to this, some polysaccharides have been found to improve the level of oxidative stress in experimental IBD models. Examples are Lycium barbarum polysaccharides [211], Dendrobium fimbriatum polysaccharides [277], and Dictyophora indusiata polysaccharides [285].

In the development of IBD, changes in the immune system arise from abnormal responses of the innate and adaptive immune systems. In the peripheral blood of IBD patients and in vivo animal models, there is usually an increase in Th17 cells and a decrease in Treg cells [314]. Recent studies have shown that the immunometabolic processes in IBD mainly involve T cells, monocytes, macrophages, dendritic cells, and natural killer cells [315]. Immune cells produce inflammatory cytokines, which play an important role in regulating the inflammatory response process. As a result, targeting immune cell metabolism could be an effective way to treat IBD. Numerous studies have also demonstrated the ability of NPs to improve IBD symptoms by modulating immune metabolic processes in experimental IBD models. For example, nuciferine, an alkaloid, can improve DSS-induced UC in mice by regulating the differentiation of T cells and IgA+ B220+ B cells and restoring the balance of Th17/Treg and CD4+/CD8+ [215]. Similarly, celastrol improves Treg/Th1 and Treg/Th17 homeostasis in UC mice to maintain immune homeostasis in the gut [155]. Ganoderma lucidum polysaccharides have anti-inflammatory and immunomodulatory effects. In a DSS-induced IBD mouse model, Ganoderma lucidum polysaccharides could regulate the intestinal immune barrier function in mice by affecting the number of Th17 cells, B cells, NK cells, and NKT cells in lamina propria lymphocytes [284]. This suggested that targeting the metabolic processes of immune cells could be a novel approach to treating IBD.

Abnormal activation of signaling pathways triggers a dysregulated inflammatory response in patients with IBD [316]. Abundant studies have confirmed that different signaling pathways have important roles in the development and progression of IBD, and NPs can exert ameliorative and therapeutic effects on IBD through multiple signaling pathways.