PMMB 2022, 5, 1; a0000271. doi: a10.36877/pmmb.0000271 http://journals.hh-publisher.com/index.php/pmmb 

Review Article 

Role of Garlic in Chronic Diseases: Focusing on Gut 

Microbiota Modulation 

Wei Quan Lim1, Jia Ying Cheam1, Jodi Woan-Fei Law1, Vengadesh Letchumanan1, 

Learn-Han Lee1*, Loh Teng-Hern Tan1,2* 

 

Article History 
1Novel Bacteria and Drug Discovery (NBDD) Research Group, Microbiome 

and Bioresource Research Strength (MBRS), Jeffrey Cheah School of 

Medicine and Health Sciences, Monash University Malaysia, 47500, Selangor 

Darul Ehsan, Malaysia. wlim0012@student.monash.edu (W-QL); 

jche0331@student.monash.edu (J-YC); jodi.law1@monash.edu (JW-FL) 

vengadesh.letchumanan1@moansh.edu (VL) 

2Clinical School Johor Bahru, Jeffrey Cheah School of Medicine and Health 

Sciences, Monash University Malaysia, Johor Bahru 80100, Malaysia 

*Corresponding author: Learn-Han Lee, Novel Bacteria and Drug Discovery 

(NBDD) Research Group, Microbiome and Bioresource Research Strength 

(MBRS), Jeffrey Cheah School of Medicine and Health Sciences, Monash 

University Malaysia, 47500, Selangor Darul Ehsan, Malaysia; 

lee.learn.han@monash.edu (L-HL); Loh Teng Hern Tan, Clinical School 

Johor Bahru, Jeffrey Cheah School of Medicine and Health Sciences, Monash 

University Malaysia, Johor Bahru 80100, Malaysia; 

loh.teng.hern@monash.edu (LT-HT) 

Received: 18 July 2022; 

Received in Revised Form: 

13 October 2022; 

Accepted: 25 October 2022;  

Available Online:         

1 November 2022 

Abstract: Garlic is a herb and has been used as a spice with a long history in different types 

of cuisine. Garlic and its components are believed to be able to bring benefits to the health of 

an individual. The gut microbiota is closely related to an individual's health, and garlic is 

shown to have an effect on the gut microbiota as well. Hence, this literature review aims to 

portray the uses of garlic and its bioactive constituents on human health, particularly looking 

at how it modulates the gut microbiota and subsequently affects an individual's health directly 

or indirectly. These studies have shown the ameliorative effects of garlic and its bioactive 

constituents on various chronic diseases, including hypertension, diabetes mellitus, 

hyperlipidaemia and liver diseases.    

Keywords: Garlic; allicin; alliin; gut microbiome; metabolic diseases 

 

1. Introduction 

Chronic diseases, such as hypertension, diabetes mellitus, obesity, hyperlipidaemia, 

and complications, including myocardial infarction and cerebrovascular accidents, are the 

major health concerns surrounding people all the time. It takes time, effort, and money to 

manage the diseases from diagnosis to treatment. They appear as some form of burden to the 

people, and most of the time, uncontrolled diseases will lead to complications that may 



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severely affect the well-being of humans. Awareness regarding the diseases has been raised, 

and people started taking steps to prevent the diseases and their complications. Initiatives can 

be made in the simplest form, including lifestyle modifications (diet modification and 

exercise) and taking medications.  

Regarding preventative methods, garlic has been used traditionally in improving 

health. Garlic as a spice has not only been used to improve the taste of food, but it also has 

the potential to regulate an individual's health. Recently, it has been believed that garlic helps 

to alter the gut microbiota in good ways and further improves health. Various chronic 

illnesses can be prevented by supplementing garlic into our diet. Garlic and its constituent 

allicin, diallyl disulphide, can act as anti-inflammatory and antioxidant agents to help cope 

with diseases. 

Gut microbiota plays a vital role in maintaining human health. The gut microbiome 

consists of different types of bacteria. A balanced gut microbiome system helps maintain 

good health by forming a good immune system and defence against pathogens[1–7]. The 

components in the gut microbiota are largely affected by many factors, including inheritance, 

diet, and drugs[8–11]. As inheritance is a non-modifiable factor, diet and drugs are those we 

can take into account and modify accordingly to help improve our health[12–14]. The gut 

microbiota is in mutualism with the host, and they provide benefits to each other. The gut 

microbes feed on the food we consume, and on the other hand, they help to degrade and 

convert those complex substances to enable the gut to absorb the nutrients. Garlic has been 

part and parcel of our diet, and taking garlic can help to modulate the gut microbiota in a 

good way so that the beneficial microorganisms or the probiotics can be retained while the 

pathogenic species can be eliminated. Consumption of garlic in the long term will help to 

improve health indirectly.  

This review aims to investigate recent studies to determine the benefits of taking 

garlic in daily life and the role of garlic and its constituents in modulating human health via 

gut microbiome modulation. Besides that, this review also provides an overview of how 

garlic prevents chronic diseases and explores the potential use of garlic as a therapeutic agent 

for diseases. 

2. An Overview of Garlic and Its Constituents and Their Effect on Gut Microbiota 

Garlic has been used widely in different cuisines. It can be consumed raw or crushed, 

depending on the consumers’ preferences. Garlic is thought to be bringing a lot of benefits, 

especially towards the health of an individual. A person with a healthy gut microbiota will 

have a healthy immune system. Garlic and its constituents have been shown to modulate the 

gut microbiota composition by selectively stimulating beneficial microorganisms' growth 

and suppressing pathogenic species' growth. Gut microbiota is correlated to an individual's 

health because it affects the absorption and elimination of the food we eat. This is particularly 

more observed with patients with metabolic diseases as those chronic diseases are highly 



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dependent on diet and lifestyles[15]. In the literature review, the aim is to investigate the effect 

of garlic on gut microbiota, in turn, its impact on an individual's health. 

3. Composition of Garlic  

Garlic (Allium sativum L.) is mainly comprised of water, followed by carbohydrates, 

protein, and organosulfur compounds. Fructans are the main component of carbohydrates, 

and they can provoke the growth of probiotic bacteria in the gut and subsequently improve 

the immune system[1]. Organosulfur compounds (OSC) are available in most plants, but 

garlic's amount is higher than the other plants. The primary OSC from garlic are γ-glutamyl-

S-allyl-l-cysteines (G-SAC). G-SAC is a metabolite that will later be converted to alliin and 

is thought to be responsible for antimicrobial activity in the gut[1]. Alliinase will be activated 

during the crushing process of garlic, and it converts alliin into allicin. Allicin has a variety 

of actions on the gut, including antimicrobial, anticancer, antioxidant, and immune-

modulating activities. Allicin will be absorbed in the intestines through the villi, and it can 

bypass the stomach without being affected by the low pH of the gastric acid. Allicin is then 

metabolised into diallyl disulphide in the bloodstream and transported to various organs. 

Allicin and its metabolites can be interconverted by the liver cells. This keeps allicin readily 

available as it can only be transported in the form of diallyl disulphide. The metabolites 

formed from allicin include diallyl disulphide, S-allylmercaptocysteine, S-allyl cysteine, and 

so on, and they are those responsible for bringing benefits to the health[16]. Apart from that, 

garlic also contains a variety of minerals and vitamins, including potassium, zinc, iron, 

sodium, and water-soluble vitamins[17]. 

4. The Effect of Garlic and Its Constituents on Gut Microbiota 

Gut microbiota consists of the bacteria grown in the intestines and have a mutualistic 

relationship with the human host. Bacteroidetes and Firmicutes are the significant part of the 

gut microbiota, and other bacteria reside in the human gut[18]. Numerous studies have 

investigated the relationship between garlic and its effect on gut microbiota and health[1,19–

22]. Through these studies, garlic has been shown to be able to modulate gut microbiota[1,19,21]. 

One of the studies by Chen et al.[23] has demonstrated that garlic supplementation in the diet 

increases Lachnospiraceae and decreases Prevotella[1]. Lachnospiraceae is the normal flora 

found in the gut, and it plays a role in producing short-chain fatty acid (SCFA). SCFAs are 

the primary source of nutrients for colonic epithelial cells, and they exert an anti-

inflammatory effect in the gut[24]. Another study by Filocamo et al.[19] suggested that using 

garlic powder can inhibit the growth of microorganisms in the gut. However, Lactobacilli 

(lactic acid bacteria) have shown resistance towards garlic powder, and these bacterial 

species can grow and replicate despite consuming garlic regularly. Lactobacilli are the 

probiotics that have an essential role in forming the barrier in the gastrointestinal system[25]. 

Apart from that, they act as anti-inflammatory agents and help to prevent cancer and 

inflammation in the intestines[26–30]. Studies also showed that the components present in 

garlic have bactericidal effects on some bacteria species, including Escherichia coli, 

Salmonella typhimurium and Neisseria gonorrhoeae[20,31,32]. Those bacteria are the pathogen 



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that predisposes the host to infections[33,34]. A study by Maeda et al.[35] investigated the effect 

of taking aged garlic extracts on the gut microbiota profile. After seven weeks of consuming 

aged garlic extracts, there is an increase in the Lactobacillus and a decrease in several bacteria 

species, including Clostridium cluster XVIII and Prevotella. The use of garlic has been 

shown to be beneficial to the host. Garlic supplementation in the diet can expand the diversity 

and richness of the gut microbiome and, at the same time, help lower the pathogenic species 

in the gut[36]. 

The ratio of Firmicutes to Bacteroidetes is closely related to obesity, and obese 

patients tend to have a higher Firmicutes/Bacteroidetes ratio compared to a healthy 

individual[21]. The Firmicutes/Bacteroidetes ratio will increase with ageing and implementing 

a high-fat diet[23]. Allicin, the main OSC present in crushed garlic, has an antibacterial effect 

on the gut. Consumption of garlic has been shown to reduce the ratio, and this indirectly deals 

with gut dysbiosis caused by a prolonged high-fat diet[23].  

A study from Zhang et al.[22] demonstrates that alliin (an active component in garlic) 

consumption can modify the gut microbiota, especially Allobaculum sp. The role of 

Allobaculum spp. in the gut is to utilise glucose[37], which helps to weight loss for obese 

individuals[38]. Another study finds that alliin can induce the modulation of components in 

the gut microbiota. The study shows that alliin supplementation results in a decrease in the 

abundance of Lachnospiraceae and an increase in the abundance of Ruminococcaceae[39]. 

Those are the common normal flora found in the gut, and they assist the host in degrading 

the complex materials from plants, such as cellulose and hemicellulose, and further aid in the 

absorption of the substrate to yield energy for the hosts[40]. Those substrates cannot be 

digested and broken down by the host as there is no enzyme specifically targeting those 

substrates, and the host must rely on the gut microorganisms. Besides, the study suggested 

that alliin consumption helps to improve lipid and glucose profiles in the long term[39]. This 

result is consistent with the increase in Ruminococcaceae as it has been proved that 

Ruminococcaceae has a protective function against long-term weight gain in the host[41]. 

Besides alliin, fructan is also the main component found in garlic. Supplementation 

of garlic fructan (GF) can promote the growth of Bifidobacterium in the gut[42]. 

Bifidobacterium is the beneficial normal flora in the gut, and it is linked to many health 

benefits, including preventing colon cancer and reducing the symptoms of inflammatory 

bowel disease[43]. Bifidobacterium probiotic has been used to treat diarrhoea and necrotising 

enterocolitis in preterm neonates[43,44]. Another study by Zhang et al.[45] focuses on the effect 

of inulin-type fructan on the gut microbiota. After treatment with inulin, a rise in the number 

of short-chain fatty acid-producing bacteria and Lactobacillus is evidenced[45]. Apart from 

that, a drop in Desulfovibrio is also present in the study. Desulfovibrio bacteria is considered 

a pathogen in the human host, and it is often associated with ulcerative colitis and intra-

abdominal infections[46,47]. Inulin-type fructan can affect the gut microbiota. It is noted that 

those receiving inulin-type fructan have softer stools, which actually improves the hosts' 

constipation issues[48].  



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Organosulfur compounds in garlic are the hydrogen sulphide (H2S) donors in the 

body[49]. Study shows that H2S can prevent the dysbiosis of gut microbiota caused by non-

steroidal anti-inflammatory drugs (NSAIDs) and alcohol[50]. This helps balance the system 

after the host is exposed to external factors like alcohol and drugs. Besides that, H2S has been 

shown to prevent inflammation and foster the restoration of the damaged tissues in the gut 
[50]. Propyl‐propane thiosulfonate (PTSO) from garlic also exerts anti-inflammatory effects 

and helps restore the epithelial tissues' barrier function in the intestines[51]. This suggests that 

garlic may help with inflammatory bowel diseases in the future. 

5. The Effect of Garlic on Chronic Diseases 

Many studies have shown that garlic can directly or indirectly improve the health of 

an individual, which may link to the modulation of gut microbiota (Figure 1). 

Supplementation of garlic in diet can affect health in a good way. The human gut microbiota 

helps to degrade complex substances, produce short-chain fatty acids, and maintain 

homeostasis in the intestines. When there is microbial dysbiosis, problems start in the host, 

such as metabolic syndromes, allergies, and neurological and gastrointestinal diseases[52–55]. 

 

Figure 1. Summary of garlic's gut microbiome modulation effect in improving overall health and metabolic 

syndromes. 

5.1 Hyperlipidaemia 

Practising a diet high in fat content in the long term affects gut microbiota 

composition. The high-fat diet increases the number of pathogenic bacteria such as 

Proteobacteria, Desulfovibrio, and Actinobacteria in the gut. These pathogenic bacteria tend 

to be pro-inflammatory and affect energy uptake, leading to obesity[56]. In previous studies, 

garlic has been shown beneficial in lowering cholesterol levels and ameliorating the lipid 

profile. One shows that consuming garlic can improve dyslipidaemia caused by a high-fat 

diet[23]. Another study found that intake of aged garlic extract may help decrease fat uptake 



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from the intestines and thus suppressing the deposition of triglycerides in the liver[35]. Black 

garlic melanoidins (MLD) can target obesity issues as they effectively slow down the weight 

gain process caused by the high-fat diet. Besides, MLD can also inhibit lipid accumulation 

in the liver and assist the lipid metabolism process, improving the lipid profile among patients 

with dyslipidaemia[57]. A high-fat diet usually leads to a change in the gut microbiota, and a 

study reveals that implementing low molecular and high molecular melanoidins can reverse 

the changes and eventually relieve the disrupted rhythm of gut microorganisms[58]. Allicin 

from garlic helps the browning of white adipose tissue and further prevents the gaining of 

weight caused by a high-fat diet[59]. Allicin can stimulate lipolysis in the body as well as 

contribute to thermogenesis, and these are ways to burn fat and relieve obesity issues[59]. 

Inulin, as a substrate found in garlic, is also able to promote weight loss in patients with 

obesity. After 3 months of an inulin-rich diet, the participants experienced a drop in their 

BMI and had better blood pressure and sugar profile[60]. 

5.2 Liver diseases 

A high-fat diet causes metabolic syndrome such as obesity, eventually leading to liver 

diseases. Dysbiosis of gut microbiota can lead to liver inflammation and fibrosis. This occurs 

through the change in the yielding of energy from the diet, an increase in intestinal 

permeability that leads to the presence of bacterial products in the bloodstream, the formation 

of ethanol and changes in the metabolism of choline, bile acid, and lipid[61]. Choline 

deficiency predisposes an individual to non-alcoholic fatty liver disease by increasing lipid 

deposition in the liver[62]. Not only does garlic target dyslipidaemia, but garlic also helps with 

liver inflammation. Garlic supplementation in the diet can relieve inflammation in the liver 

by reducing alanine transaminase (ALT) and aspartate transaminase (AST) and normalising 

the lipid profile. This suggests that garlic may potentially treat alcoholic liver fibrosis[63]. 

Diallyl disulphide was used to address the issue of liver inflammation, and it was found that 

diallyl disulphide can suppress inflammation, lipid metabolism, and peroxidation[64]. Non-

alcoholic steatohepatitis (NASH) can be targeted using garlic as a therapeutic agent. Another 

study has used garlic essential oil and diallyl disulphide, and the result shows that they can 

prevent non-alcoholic fatty liver disease (NAFLD) by suppressing inflammation and lipid 

accumulation[65]. A study from Shunming et al.[66] revealed that high amounts of raw garlic 

could help lower the prevalence of NAFLD among men but not women. This can be due to 

allicin's bioactivity, which exhibits anti-inflammatory and antioxidant effects that stop the 

progression of NAFLD [66]. On the other hand, a study by Yang et al.[67] shows that diallyl 

disulphide (DADS) can modulate the gut microbiota by lowering the number of Bacteroides 

and raising the number of Firmicutes. These have been seen in patients with obesity and those 

on a high-fat diet. DADS alters the expression of genes responsible for lipid metabolism, and 

a low dose of DADS, along with a high-fat diet, increases fat deposition in the liver[67]. The 

results from this study are different from the other studies where garlic has consistently 

shown to have the ability to target obesity and liver diseases. More studies need to be done 

to explore garlic's effect on patients' lipid profiles. 

 



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5.3 Hypertension 

Gut microbiota plays a vital role in regulating blood pressure as well. They modulate 

the uses of the energy, metabolism of catecholamines in the gut, and transportation of ions 

through the gastrointestinal system[68]. Production of short-chain fatty acids switches on 

receptors such as G-protein coupled receptors and olfactory receptors, which work to balance 

blood pressure[68]. A rise in Firmicutes to Bacteroidetes ratio puts an individual at a higher 

risk of developing hypertension, and garlic can help to lower the ratio. On the other hand, 

Lactobacilli helps to inhibit angiotensin-converting enzymes and subsequently lowers blood 

pressure[68]. This works similarly to the drugs ACE inhibitors used for hypertensive patients. 

Garlic can lower blood pressure among hypertensive patients. Kyolic aged garlic 

supplementation prevents the stiffening of arteries caused by ageing via lessening the pulse 

wave velocity and thinning the blood to lower the risk of thrombosis[69]. This overall 

improves the cardiovascular health of an individual.  

Allicin found in garlic is able to inhibit the formation of trimethylamine-N-oxide 

(TMAO)[70]. The gut microbiota forms TMAO through the metabolism of carnitine, and it 

acts to promote atherosclerosis[70]. Hence, we can deduce that consumption of garlic in the 

long term will decrease the risk of atherosclerosis.  

Furthermore, garlic-derived organic polysulfides have been shown to exhibit 

vasoactivity. A study showed that several garlic-derived organic polysulfides acted as an H2S 

donors and boosted endogenous H2S production in blood and tissues. H2S can promote 

vasorelaxation of the vessels and indirectly help promote the health of the cardiovascular 

system[71]. A more recent animal study by Hsu et al.[72] revealed that garlic oil 

supplementation protected adult male offspring from hypertension induced by a perinatal 

high-fat diet given to the mother during pregnancy and lactation. Interestingly, garlic oil was 

shown to mediate the hypertension preventive effect with modulations of gut microbiota 

composition, microbiota-derived metabolite SCFAs, H2S-generating pathway, and NO 

bioavailability. Genus Lactobacillus was found to be increased in abundance, while 

Tunricibacter and Staphylococcus were decreased in the garlic oil supplementation group[72].  

5.4 Diabetes mellitus 

Patients with diabetes mellitus tend to show some changes in the gut microbiota to 

some extent. There is an increase in the pathogens and a decrease in the butyrate-producing 

bacteria in the intestines[73]. Diabetic patients have a higher number of Lactobacillus species 

in the gut, and those species have a positive correlation with fasting glucose and HbA1c 

levels[74]. Garlic has a beneficial effect on the blood glucose profile of diabetic patients as 

well. Aged garlic extract used in the study has been demonstrated to improve insulin 

insensitivity[35]. Another study focused on the effect of alliin and found that the use of alliin 

increased the sensitivity to insulin and augmented glucose homeostasis in the body[39]. This 

will prevent fluctuation of glucose levels after meals and help diabetic patients better control 



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their serum glucose levels. A study by Zhang et al.[75] also found that allicin from garlic 

maintained glucose homeostasis, suggesting that it could be used to treat metabolic disorders. 

6. Conclusion 

Consumption of garlic has been demonstrated in many studies that it can modulate 

the gut microbiota by enhancing probiotics' growth and suppressing pathogenic 

microorganisms' growth. Studies showed that garlic has the potential to become a 

complementary alternative medicine to a lot of diseases. Thus, garlic is a great functional 

food containing bioactive constituents with immense potential to be developed as an anti-

inflammatory, lipid-lowering, glucose-lowering, and antihypertensive agent.  

Numerous studies have been conducted, and garlic has been portrayed as a beneficial 

agent for health conditions. It can modulate gene expression in the gut and the gut microbiota. 

Apart from that, garlic can be used to improve blood pressure, blood glucose profile, and 

lipid profile, and most importantly, garlic is a natural organic substance. It can effectively 

reduce the number of medications needed by a patient by substituting them with natural 

substances. However, most studies were done on the animal model. Future studies should be 

conducted on a large scale in humans to understand better the underlying mechanisms of 

garlic in conferring better health outcomes.  

Author Contributions: W-QL performed the literature search, critical data analysis, and manuscript writing. 

J-YC, JW-FL, VL, L-HL, and LT-HT provided critical editing and proofreading. LT-TH and L-HL 

conceptualized this review writing project.  

Acknowledgments: This work was inspired by the Jeffrey Cheah School of Medicine and Health Sciences 

“MED5101 Scholarly Intensive Placement (SIP)”. 

Conflicts of Interest: The authors declare no conflict of interest. 

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