Modulation in Gut-Brain Axis via Food Supplements and its Effect in Obese Animal Models: A Systematic Review

Jitendra Kumar Patel¹, RS More^1*, Amit Kumar Nayak¹, Alakh Narayan Singh^2
1Department of Anatomy, Institute of Medical Sciences, Banaras Hindu University, Varanasi, India
²Department of Microbiology, Institute of Medical Sciences, Banaras Hindu University, Varanasi, India

*Correspondence author: RS More, Department of Anatomy, Institute of Medical Sciences, Banaras Hindu University, Varanasi, India; Email: [email protected]

Citation: Patel JK, et al. Modulation in Gut-Brain Axis via Food Supplements and its Effect in Obese Animal Models: A Systematic Review. J Clin Immunol Microbiol. 2025;6(3):1-11.

Copyright^© 2025 by Patel JK, et al. All rights reserved. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Table 1: Shows the comprehensive effects of different supplements or drugs on gut microbiota profile (α Diversity, B/F ratio, Bacterial Phylum, Genus and Metabolite produced) after treatment in obese animal models.

Discussion

This systematic review showed the role of intestinal microflora composition in developing obesity via gut-brain axis and provided brief insights of different drugs or supplements on animal models. In present study, we tried to portray the possible underlying mechanisms through which high-fat diet induces obesity and its amelioration by tempering gut microbiota, providing a fibrous diet, prebiotics or probiotics.

Interplay of Gut-Brain Axis in Obesity

Role of Gut microbiota in development of obesity: The studies done by authors show that the animals induced with obesity showed a decrease in gut microbes species richness and increase F/B ratio [32-34,37,39,44,47,49,51,53,55]. Genera belonging to phylum Bacteroidetes like Lactobacillus, Ruminococcus, Allobaculum and Odoribacter produce metabolites SCFAs including isobutyric acid, isovaleric acid and ethyl methyl acetic acid and Firmicutes are the foremost phyla in gut that are associated with energy biotransformation homeostasis [34,38,39,49,54,56]. Studies show Muribaculaceae break down nutritional polysaccharides to build SCFAs, along with succinate, acetate and propionate [36,46,50]. During obesity proportion of Proteobacteria, which mostly contains gram-negative bacteria belonging to the order Lactobacillales, Erysipelotrichales and Mycoplasma that produce LPS (36) and Actinobacteria decreased significantly and Lactobacillus, Bifidobacterium, Oscillospira and Blautia were down-regulated and negatively associated to LPS, fasting blood glucose level, TNF-α and IL-6 [33,46]. The abundance of bacteria genera like Butyricicoccus, Prevotella, Turicibacter, Saccharibacteria, Ruminococcus, Bifidobacterium, Vampirovibrio, Lachnospiracea, Rikenella, Parasutterella, Roseburia, Parvibacter and Clostridium was negatively associated with body weight gain, serum TG, LDL-C levels,  hepatic TG and whereas a positive association was obtained from genera Oscillibacter, Butyricimonas and Acetatifactor [41]. The dysbiosis in gut microbiota causes inflammation compromised epithelial barrier integrity, causing translocation of LPS along with another bacteria from gut to the body fluid circulation and low expression of ZO-1 and occludin linked with hyperglycemia [34,58].  In this way, any disturbance caused in intestinal microflora composition may lead to change in energy metabolism, which is regulated by microorganisms in the intestine, which is a promoting factor for obesity.

Role of Metabolites Produced by Gut Microbes in Obesity

The studies show a change in gut microbiota that causes increased LPS production during obesity [33,36,46,52]. The increased LPS level in the blood causes gut inflammation (36), activates macrophages and thus increases the pro-inflammatory cytokines like TNF-α and IL-6 through TLR4-NFκB pathway that may induce obesity [46]. The SCFAs metabolites like butyric acid, ethyl methyl acetic acid, isobutyric acid and isovaleric acid were found to be reduced in obesity [33]. Guava polysaccharides supplementation shows increased SCFAs, especially butyric acid [41]. SCFAs elucidate ameliorative properties against inflammation and balanced regulation of glycolipid synthesis, distribution and degradation. Thus, they act as metabolic mediator to attach with gut microbiota of host physiology [44]. The different taxa of bacteria responsible for the different types of SCFAs production, like glyceric acid, were positively associated to Parabacteroides and Atopobiaceae, Lactic acid with Oscillibacter, Indole-3-acetic acid with Blautia and Lactococcus and with Blautia and Roseburia [52]. The intestinal microbes draw a prime role in the synthesis of cecal TMA, which is oxidised into TMAO in the liver that affecting the biotransformation of cholesterol and bile acid, inhibiting CYP7A1 expression [37]. This suggests that a change in diet pattern can cause alteration in gut microbiota and their secretory metabolites that will reach to brain along with blood circulation and cause a modulation in the signalling pattern to food intake behaviour and lipid homeostasis that will ultimately lead to obesity. So, gut-brain axis modulation via supplements or drugs will be a promising anti-obesogenic cure.

Therapeutic Effects of Different Supplements or Drugs in Induced Obesity

The data from Table 1 suggests that high-fat diet (HFD 45% or 60% calories obtained from fat)  is one of the most preferred methods to induce obesity in rats or mice animal models, 24% crude fat is used for fish model, another way is High fat High sugar (HFHS) diet [32,37-43,45-60]. Diet induces obese mice to show increased body weight, plasma insulin level, HOMA index, serum Triglycerides, LDL-C, HDL-C and total cholesterol level, which is due to the over-expression of hepatic genes like CYP7A1, HMGCoAS, SCD1, FAS, SCARB1, LDLR and FMO3, as well as intestinal genes, including FGF15 and FXR [40,36,37,47]. STZ and alloxan are commonly used drugs to induce diabetes and hyperglycemia, but they can also be used with HFD or HFHS to induce obesity along with diabetes-like symptoms in animal models [33-35,44,62,63]. MSG-induced obese mouse model shows down regulation of ZO-1 results in low tight junction protein-1, causing disrupted gut barrier, inflamed colon, broken architecture of glandular epithelium, raised lymphocytes infiltration and goblet cell loss [33,48]. DM and ESPs supplementation restores ZO-1 and occludin expression, normalizes tight junction proteins of intestinal barrier and portray neuroprotective effects [33,49]. Berberine treatment elucidates high expression of GLP-1R mRNA in hypothalamic region of brain, resulting in raised insulin sensitivity contributes to glucose metabolism [38]. The prebiotic, probiotic and synbiotics curdlan improved insulin resistance, LDL, cholesterol, fat mass, circulating serum and brain LPS level and also IL-6 mRNA expression in the colon [36,50]. Modulation in gut microbiota through Kimchi supplementation results in increased SCFAs, lowered neuroinflammation caused by broken blood-brain barrier [39]. Guava polysaccharide supplementation regulates glucose homeostasis and insulin sensitivity by suppressing phosphorylated Insulin Receptor Substrate -1 at Ser318 position while promoting the phosphorylation of Protein Kinase B at Ser 473 [41]. 10% 2’-FL supplementation fixed the cholecystokinin-induced inhibition of dietary intake [52]. Prolonged TBPH manifestation causes notable weight gain, adipocyte hypertrophy and subcutaneous fat aggregation by changes in leptin receptors in the brain and leptin B and Adiponectin in the intestine at transcription levels [60]. Review findings draw an idea that diet-induced obesity will be ameliorated by modulating intestinal microflora via the Gut-brain axis pathways. Supplements or drugs change the gene expression patterns that are involved in maintaining the gut barrier or blood-brain barrier integrity or hepatic genes regulate glucose metabolism [64].

Conclusion

Gut-Brain-Axis is a crucial factor in developing and maintaining obesity and this can be modulated by our daily diet intake. The nutritional component decides the abundance of microbes resides in gut and produce particular metabolites like SCFAs or LPS. Upon reaching to the organs like the liver or brain with circulating blood, cause alterations in gene expression, results in modification of energy balance through glucose metabolism, change in hunger and satiety hormones secretion and contributes to development of obesity. The drugs or herbal supplementation elucidate raise in beneficial bacterial genera in intestine that prime role in reducing the global burden of obesity. This systematic review provides extensive analysis on gut microbiota sequencing outputs from various animal model studies regarding the modulation in intestinal microflora composition during obesity, later on treatment with drugs or supplements.

Conflict of Interest

The authors have declared no conflict of interest.

References

1. WHO, Obesity and overweight: Fact Sheet. 2021. [Last accessed on: September 29, 2025]

www.who.int/news-room/fact-sheets/detail/obesity-and-overweight

2. Okunogbe A, Nugent R, Spencer G, Ralston J, Wilding J. Economic impacts of overweight and obesity: Current and future estimates for eight countries. BMJ global health. 2021;6(10):e006351.
3. World Obesity, Newsletter. 2022.
4. Luhar S, Timæus IM, Jones R, Cunningham S, Patel SA, Kinra S, et al. Forecasting the prevalence of overweight and obesity in India to 2040. PloS one. 2020;15(2):e0229438.
5. Piché ME, Tchernof A, Després JP. Obesity phenotypes, diabetes and cardiovascular diseases. Circulation research. 2020;126(11):1477-500.
6. Felber JP, Golay A. Pathways from obesity to diabetes. International journal of obesity. 2002;26(2):S39-45.
7. Alberti KG, Zimmet PZ. Definition, diagnosis and classification of diabetes mellitus and its complications. Part 1: Diagnosis and classification of diabetes mellitus. Provisional report of a WHO consultation. Diabetic medicine. 1998;15(7):539-53.
8. Piché ME, Tchernof A, Després JP. Obesity phenotypes, diabetes and cardiovascular diseases. Circulation research. 2020;126(11):1477-500.
9. Fabbrini E, Magkos F, Mohammed BS, Pietka T, Abumrad NA, Patterson BW, et al. Intrahepatic fat, not visceral fat, is linked with metabolic complications of obesity. Proceedings of the National Academy of Sciences. 2009;106(36):15430-5.
10. Wright SM, Aronne LJ. Causes of obesity. Abdominal Radiology. 2012;37(5):730-2.
11. DiBaise JK, Zhang H, Crowell MD, Krajmalnik-Brown R, Decker GA, Rittmann BE. Gut microbiota and its possible relationship with obesity. InMayo clinic proceedings 2008;83(4):460-9.
12. Ravussin Y, Koren O, Spor A, LeDuc C, Gutman R, Stombaugh J, et al. Responses of gut microbiota to diet composition and weight loss in lean and obese mice. Obesity. 2012;20(4):738-47.
13. Asadi A, Shadab Mehr N, Mohamadi MH, Shokri F, Heidary M, Sadeghifard N, et al. Obesity and gut–microbiota–brain axis: A narrative review. Journal of Clinical Laboratory Analysis. 2022;36(5):e24420.
14. Valdes AM, Walter J, Segal E, Spector TD. Role of the gut microbiota in nutrition and health. BMJ. 2018;361.
15. Shirvani-Rad S, Ejtahed HS, Ettehad Marvasti F, Taghavi M, Sharifi F, Arzaghi SM, et al. The Role of Gut Microbiota-Brain Axis in Pathophysiology of ADHD: A Systematic Review. Journal of Attention Disorders. 2022:10870547211073474.
16. Muscogiuri G, Cantone E, Cassarano S, Tuccinardi D, Barrea L, Savastano S, et al. Gut microbiota: A new path to treat obesity. International Journal of Obesity Supplements. 2019;9(1):10-9.
17. Maukonen J, Saarela M. Human gut microbiota: does diet matter? Proceedings of the Nutrition Society. 2015;74(1):23-36.
18. Liu X, Li X, Xia B, Jin X, Zou Q, Zeng Z, et al. High-fiber diet mitigates maternal obesity-induced cognitive and social dysfunction in the offspring via gut-brain axis. Cell Metabolism. 2021;33(5):923-38.
19. Valdes AM, Walter J, Segal E, Spector TD. Role of the gut microbiota in nutrition and health. BMJ. 2018;361.
20. Rowland I, Gibson G, Heinken A, Scott K, Swann J, Thiele I, et al. Gut microbiota functions: metabolism of nutrients and other food components. European journal of nutrition. 2018;57(1):1-24.
21. Von Martels JZ, Sadaghian Sadabad M, Bourgonje AR, Blokzijl T, Dijkstra G, Faber KN, et al. The role of gut microbiota in health and disease. vitro modeling of host-microbe interactions at the aerobe-anaerobe interphase of the human gut. Anaerobe. 2017;44:3-12.
22. Canfora EE, Meex RC, Venema K, Blaak EE. Gut microbial metabolites in obesity, NAFLD and T2DM. Nature Reviews Endocrinology. 2019;15(5):261-73.
23. Boutagy NE, McMillan RP, Frisard MI, Hulver MW. Metabolic endotoxemia with obesity: Is it real and is it relevant? Biochimie. 2016;124:11-20.
24. Gomes AC, Hoffmann C, Mota JF. The human gut microbiota: Metabolism and perspective in obesity. Gut microbes. 2018;9(4):308-25.
25. Stilling RM, van de Okunogbe A, Nugent R, Spencer G, Ralston J, Wilding J. Economic impacts of overweight and obesity: Current and future estimates for eight countries. BMJ Global Health. 2021;6(10):e006351.
26. Wouw M, Clarke G, Stanton C, Dinan TG, Cryan JF. The neuropharmacology of butyrate: The bread and butter of the microbiota-gut-brain axis? Neurochemistry Iinternational. 2016;99:110-32.
27. Reinshagen M. Neuropods übermitteln Informationen über Nahrungsmittel im Darm über vagale Neuronen in Millisekunden an das Gehirn. Zeitschrift für Gastroenterologie. 2019;57(03):335.
28. Maukonen J, Saarela M. Human gut microbiota: does diet matter? Proceedings of the Nutrition Society. 2015;74(1):23-36.
29. Murphy EF, Cotter PD, Healy S, Marques TM, O’sullivan O, Fouhy F, et al. Composition and energy harvesting capacity of the gut microbiota: relationship to diet, obesity and time in mouse models. Gut. 2010;59(12):1635-42.
30. Sun J, Liao XP, D’Souza AW, Boolchandani M, Li SH, Cheng K, et al. Environmental remodeling of human gut microbiota and antibiotic resistome in livestock farms. Nature Communications. 2020;11(1):1-1.
31. de Noronha SI, de Moraes LA, Hassell Jr JE, Stamper CE, Arnold MR, Heinze JD, et al. High-fat diet, microbiome-gut-brain axis signaling and anxiety-like behavior in male rats. Biological Research. 2024;57(1):23.
32. Page MJ, Moher D, Bossuyt PM, Boutron I, Hoffmann TC, Mulrow CD, et al. PRISMA 2020 explanation and elaboration: updated guidance and exemplars for reporting systematic reviews. BMJ. 2021;372
33. Klingbeil EA, Schade R, Lee SH, Kirkland R, de La Serre CB. Manipulation of feeding patterns in high fat diet fed rats improves microbiota composition dynamics, inflammation and gut-brain signaling. Physiology and Behavior. 2024;285:114643.
34. Zheng Y, Zhou X, Wang C, Zhang J, Chang D, Zhuang S, et al. Effect of dendrobium mixture in alleviating diabetic cognitive impairment associated with regulating gut microbiota. Biomedicine and Pharmacotherapy. 2022;149:112891.
35. Hussein HM, Elyamany MF, Rashed LA, Sallam NA. Vitamin D mitigates diabetes-associated metabolic and cognitive dysfunction by modulating gut microbiota and colonic cannabinoid receptor 1. European Journal of Pharmaceutical Sciences. 2022;170:106105.
36. Wang H, Wang Q, Liang C, Su M, Wang X, Li H, et al.. Acupuncture regulating gut microbiota in abdominal obese rats induced by high-fat diet. Evidence-Based Complementary and Alternative Medicine. 2019;2019.
37. Chunchai T, Thunapong W, Yasom S, Wanchai K, Eaimworawuthikul S, Metzler G, , et al. Decreased microglial activation through gut-brain axis by prebiotics, probiotics or synbiotics effectively restored cognitive function in obese-insulin resistant rats. Journal of Neuroinflammation. 2018;15(1):1-5.
38. Huang F, Zhang F, Xu D, Zhang Z, Xu F, Tao X, et al. Enterococcus faecium WEFA23 from infants lessens high-fat-diet-induced hyperlipidemia via cholesterol 7-alpha-hydroxylase gene by altering the composition of gut microbiota in rats. J Dairy Science. 2018;101(9):7757-67.
39. Sun H, Wang N, Cang Z, Zhu C, Zhao L, Nie X, et al. Modulation of microbiota-gut-brain axis by berberine resulting in improved metabolic status in high-fat diet-fed rats. Obesity Facts. 2016;9(6):365-78.
40. Kim N, Lee J, Song HS, Oh YJ, Kwon MS, Yun M, et al. Kimchi intake alleviates obesity-induced neuroinflammation by modulating the gut-brain axis. Food Research International. 2022;158:111533.
41. Wang TY, Tao SY, Wu YX, An T, Lv BH, Liu JX, et al. Quinoa Reduces High-Fat Diet-Induced Obesity in Mice via Potential Microbiota-Gut-Brain-Liver Interaction Mechanisms. Microbiology Spectrum. 2022:e00329-22.
42. Li Y, Bai D, Lu Y, Chen J, Yang H, Mu Y, et al. The crude guava polysaccharides ameliorate high-fat diet-induced obesity in mice via reshaping gut microbiota. Int J Biological Macromolecules. 2022.
43. Hu M, Zhang P, Wang R, Zhou M, Pang N, Cui X, et al. Three different types of β-glucans enhance cognition: The role of the gut-brain axis. Frontiers in Nutrition. 2022;9.
44. Guo Z, Hu B, Zhu L, Yang Y, Liu C, Liu F, et al. Microbiome-metabolomics insights into the feces of high-fat diet mice to reveal the anti-obesity effects of yak (Bos grunniens) bone collagen hydrolysates. Food Research International. 2022;156:111024.
45. Shao W, Xiao C, Yong T, Zhang Y, Hu H, Xie T, et al. A polysaccharide isolated from Ganoderma lucidum ameliorates hyperglycemia through modulating gut microbiota in type 2 diabetic mice. Int J Biological Macromolecules. 2022;197:23-38.
46. Zhou Y, Qiu W, Wang Y, Wang R, Takano T, Li X, et al. β-Elemene Suppresses Obesity-Induced Imbalance in the Microbiota-Gut-Brain Axis. Biomedicines. 2021;9(7):704.
47. Pan W, Jiang P, Zhao J, Shi H, Zhang P, Yang X, et al. β-Glucan from Lentinula edodes prevents cognitive impairments in high-fat diet-induced obese mice: Involvement of colon-brain axis. Journal of Translational Medicine. 2021;19(1):1-7.
48. Ma X, Xiao W, Li H, Pang P, Xue F, Wan L, , et al. Metformin restores hippocampal neurogenesis and learning and memory via regulating gut microbiota in the obese mouse model. Brain, Behavior and Immunity. 2021;95:68-83.
49. Zhao L, Zhu X, Xia M, Li J, Guo AY, Zhu Y, et al. Quercetin ameliorates gut microbiota dysbiosis that drives hypothalamic damage and hepatic lipogenesis in monosodium glutamate-induced abdominal obesity. Frontiers in Nutrition. 2021;8:671353.
50. Wu J, Zhu Y, Zhou L, Lu Y, Feng T, Dai M, , et al. Parasite-derived excretory-secretory products alleviate gut microbiota dysbiosis and improve cognitive impairment induced by a high-fat diet. Frontiers in Immunology. 2021;12.
51. Yang X, Zheng M, Hao S, Shi H, Lin D, Chen X, et al.. Curdlan prevents the cognitive deficits induced by a high-fat diet in mice via the gut-brain axis. Frontiers in neuroscience. 2020;14:384.
52. Biyong EF, Alfos S, Dumetz F, Helbling JC, Aubert A, Brossaud J, et al. Dietary vitamin A supplementation prevents early obesogenic diet-induced microbiota, neuronal and cognitive alterations. International Journal of Obesity. 2021;45(3):588-98.
53. Lee S, Goodson M, Vang W, Kalanetra K, Barile D, Raybould H. 2′-fucosyllactose supplementation improves gut-brain signaling and diet-induced obese phenotype and changes the gut microbiota in high fat-fed mice. Nutrients. 2020;12(4):1003.
54. Tang T, Song J, Li J, Wang H, Zhang Y, Suo H. A synbiotic consisting of Lactobacillus plantarum S58 and hull-less barley β-glucan ameliorates lipid accumulation in mice fed with a high-fat diet by activating AMPK signaling and modulating the gut microbiota. Carbohydrate Polymers. 2020;243:116398.
55. Liu Z, Li L, Ma S, Ye J, Zhang H, Li Y, et al. S. High-dietary fiber intake alleviates antenatal obesity-induced postpartum depression: Roles of gut microbiota and microbial metabolite short-chain fatty acid involved. Journal of Agricultural and Food Chemistry. 2020;68(47):13697-710.
56. Diling C, Yinrui G, Longkai Q, Xiaocui T, Yadi L, Jiaxin F, et al. Metabolic regulation of Ganoderma lucidum extracts in high sugar and fat diet-induced obese mice by regulating the gut-brain axis. Journal of Functional Foods. 2020;65:103639.
57. Ahmadi S, Nagpal R, Wang S, Gagliano J, Kitzman DW, Soleimanian-Zad S, et al. Prebiotics from acorn and sago prevent high-fat-diet-induced insulin resistance via microbiome–gut–brain axis modulation. The Journal of Nutritional Biochemistry. 2019;67:1-3.
58. Kong C, Gao R, Yan X, Huang L, Qin H. Probiotics improve gut microbiota dysbiosis in obese mice fed a high-fat or high-sucrose diet. Nutrition. 2019;60:175-84.
59. Zhuang P, Shou Q, Lu Y, Wang G, Qiu J, Wang J, et al. Arachidonic acid sex-dependently affects obesity through linking gut microbiota-driven inflammation to hypothalamus-adipose-liver axis. Biochimica et Biophysica Acta (BBA)-Molecular Basis of Disease. 2017;1863(11):2715-26.
60. Ansari A, Bose S, Yadav MK, Wang JH, Song YK, Ko SG, et al. CST: An herbal formula, exerts anti-obesity effects through brain-gut-adipose tissue axis modulation in high-fat diet fed mice. Molecules. 2016;21(11):1522.
61. Zhou Y, Guo W, Lei L, Sun Y, Li R, Guo Y, et al. Bis (2-ethylhexyl)-tetrabromophthalate induces zebrafish obesity by altering the brain-gut axis and intestinal microbial composition. Environmental Pollution. 2021;290:118127.
62. Wen L, Duffy A. Factors influencing the gut microbiota, inflammation and type 2 diabetes. The Journal of Nutrition. 2017;147(7):1468S-75S.
63. Furman BL. Streptozotocin‐induced diabetic models in mice and rats. Current Protocols. 2021;1(4):e78.
64. Rohilla A, Ali S. Alloxan induced diabetes: mechanisms and effects. Int J Res Pharmaceutical and Biomedical Sciences. 2012;3(2):819-23.