Int J App Pharm, Vol 13, Issue 3, 2021, 30-38Review Article

A COMPREHENSIVE REVIEW ON PHARMACEUTICAL AND NUTRITIONAL APPLICATIONS OF INULIN

C. SAI KISHAN¹, AKHILA A. R.¹, SUBHASHREE SAHOO¹, P. K. KULKARNI^1*

^1*Department of Pharmaceutics, JSS College of Pharmacy, JSS Academy of Higher Education and Research, S. S. Nagara, Mysuru 570015, Karnataka, India
Email: pkkulkarni@jssuni.edu.in

Received: 23 Dec 2020, Revised and Accepted: 13 Mar 2021

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ABSTRACT

Inulin is a versatile, water-soluble polysaccharide that is commonly available in nature. In the pharmaceutical industry, the non-digestible function of inulin has made it attractive. Inulin is granted with GRAS status by the FDA and more than 30,000 plants in nature store inulin as a carbohydrate. The chicory is the key plant source of inulin out of all sources. It can be used as the sugar or fat replacer in the processed foods to influence the desirable characteristics. Good biocompatibility, essential chemical properties, and a wide variety of bioactivities have rendered inulin an outstanding natural nutrient. Regulating blood sugar, antioxidant, anticancer is some of the biological activities of inulin. Inulin can also be a carrier for colon/tumor targeting, as only specific enzymes in the colon zhydrolyze the inulin. It allows the growth of micro-flora, the good bacteria in the gut. Inulin is considered as a prebiotic as it is fermented by bacteria that normalize the colon. This review offers an in-depth insight into its novel Pharmaceutical applications as well as sources, processing, physicochemical properties, and nutritional and physiological activities. The chemically modified inulin is gaining a specific interest in the pharmaceutical field with its outstanding properties which are discussed in this review.

Keywords: Inulin, Pharmaceutical applications, Targeted drug delivery, Prebiotics

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© 2021 The Authors. Published by Innovare Academic Sciences Pvt Ltd. This is an open access article under the CC BY license (https://creativecommons.org/licenses/by/4.0/)
DOI: https://dx.doi.org/10.22159/ijap.2021v13i3.40863. Journal homepage: https://innovareacademics.in/journals/index.php/ijap

INTRODUCTION

More than 30,000 plants in nature store inulin as a carbohydrate. It was first isolated by Valentine Rosein 1804 from the roots of compositae plant-Inula helenium, and named inulin by Thomson in 1817. Inulin being a polysaccharide, belong to the carbohydrate class known as fructans [1]. Fructans are the structures in which the fructose (sugar) molecules are held together in the form of a chain with the aid of β-(2→1)-D-fructose-fructose bond. The current trend of Inulin is towards the food and pharmaceutical industries. It is found in a wide range of herbs, fruits, and vegetables, including onions, bananas, garlic, wheat, asparagus, and artichokes. Certain bacteria and fungi are also capable of producing inulin. Chicory or Jerusalem artichoke tubers are the current sources of raw materials for the industrial use of inulin because of their high inulin content. It can be used as the sugar or fat replacer in the processed foods to influence the desirable characteristics. The sweetness level of inulin is about 10 percent in comparison to sucrose. The good biocompatibility, significant chemical properties, and wide range of bioactivities made inulin an excellent natural nutrient.

Inulin does not only enhance the food flavor but also has different physiological functions, like reducing blood sugar and fat, including cholesterol and triglycerides. It is also used for constipation, diarrhea, diabetes, and as an anticancer [2]. Recent advances of inulin in the pharmaceutical field include colon-targeted drug delivery, as the inulin can only be hydrolyzed by the specific enzymes in the colon. It allows the growth of micro-flora, the good bacteria in the gut. Inulin is considered as a prebiotic as it is fermented by bacteria that normalize the colon.

Besides, inulin is inexpensive and readily available. In European Countries, inulin is recognized as a natural food ingredient [3]. Adding inulin to the diet will enhance the health of the individual as it is considered a functional food. Food, Nutrition, and Health Trends 2020 highlight the main market trends driving industry growth. 'As a natural sugar replacer, inulin became a success, used in several products, and its existence means that businesses can also mark the improved fibre quality on the label.

Chemistry and structure

Inulin is a polydisperse β-(2-1) fructan. It is made up of residues of β-D-fructose bound together by glycosidic bonds [4]. At the end of each fructose chain, a glucose molecule is linked by α-D-glucopyranosyl or α-(1→2) bond, similar to sucrose [5]. Inulin is indigestible in the human small intestine due to β-configuration of anomeric carbon, however, can be fermented by the intestinal microflora in the large intestine. Its β-(2-1) bonds are a special feature of the structure of inulin. These linkages inhibit the digestion of inulin like a standard carbohydrate and are responsible for its decreased caloric value and benefits of dietary fiber. The number of fructose units in chicory inulin ranges from 2 to 60, representing a mixture of oligomers and polymers.

Fig. 1: Chemical structure of inulin [6]

Inulin is expressed as GFn, where G denotes glucose unit, F denotes fructosyl residue, and n is the number of fructose residues. Functionality and industrial applications of the inulin are affected by the degree of polymerization [7]. In functional foods, inulin can be used as dietary fibre and prebiotics with varying degrees of polymerization. The degree of polymerization in bacteria (10,000 to 100,000) is high compared to plants inulin (<200), which is affected by the physical as well as climatic conditions of the plant.

The inulin is also called oligofructose when the degree of polymerization is low (n<10) [8]. Oligofructose resulting from chicory contains fructose chains (Fm) and fructose chains with terminal glucose units (GFn) whereas, Synthesized oligofructose contains only GFnmolecules. However, both express the same nutritional benefits. Short-chain inulin is primarily used to be a sweetener in food, while long-chain inulin is primarily used to be a fat replacer and improves texture.

Fig. 2: Inulin content in various plant sources

Production

Inulin and Oligofructose, which is widely available on the market for industrial food products, is either synthesized from sucrose or derived from chicory roots. Large variety of plants naturally contains inulin [9]. Jerusalem artichoke and dahlia are reported as strong sources of industrial production in temperate regions [10]. Among all the parts, the root parts of various plant sources are rich in inulin and used for extraction. Inulin manufacturing resembles the process of sugar extraction. Initially, the roots are harvested, sliced, and washed. Followed by a hot water diffusion process, then purified and dried. A high-performance (HP) type of inulin is noted as a recent advancement in the production of inulin. By eliminating the shorter-chain molecules, this substance is manufactured. This results in the elimination of both the residual sugars and oligomers. With no sweetness contribution, HP inulin has almost twice the fat mimetic properties of normal inulin.

Industrially most of the inulin is derived from chicory. It is a biannual plant belonging to the Asteraceae family. Extraction and initial purification of raw sugar are carried out in the first step, which is further processed during the second phase of production to obtain a commercial product (above 99.5 percent). In order to eliminate impurities in the purification process, the extracted juice involves several steps such as pre-liming, followed by liming and carbonation at a high temperature (80-90 °C), which may contribute to hydrolysis in the juice and may also inject additional calcium ions, requiring further treatment for purification like microfiltration [11]. In the inulin extraction process, some advanced technologies such as supercritical carbon dioxide, ultrasound, and pulsed electric field (PEF) are involved in achieving higher yields of the purified final product with lower energy consumption. The subsequent inulin contains a degree of polymerization ranging from 3 to 60, mimics the original chicory.

Fig. 3: Extraction of inulin powder from chicory [12]

Physicochemical properties

Chicory-derived inulin is a white powder that has increased clarity for fine particles and is odorless. The long-chain inulin has no sweetness, while standard chicory inulin has a sweetness level of approximately 10 percent relative to sucrose [13]. As a distinctive food ingredient, inulin provides many major dietary advantages along with some industrial properties. Inulin can decrease the freezing point of water and also can raise the boiling point of water. The average molecular weight of inulin varies in the range of 5600-6300 g mol^-1.

Sweetness

The chain length of the inulin decides the sweetness level. Short-chain inulin has a sweet taste, while long-chain inulin remains tasteless. It gives a pleasant feel without leaving any bad flavor in the mouth with its mild and non-irritating taste. Researches proved that Long-term inulin intake would not cause harm to the teeth. Further, inhibits microbial growth [14]. Inulin can act as a substitute for artificial sweeteners like aspartame.

Solubility

Inulin is partially dissolved in water almost 10 percent at 25 °C, allowing it to be applied without any precipitation in an aqueous medium. To produce an inulin solution, the use of hot water at 50-100 °C is suggested [15]. Inulin being hydrophilic, highly soluble in hot water, and sparingly soluble in ethanol or cold water. The solubility of the inulin can be affected by crystallinity. At 23 °C, beta inulin is highly water-soluble. Other polymorphs need higher dissolving temperatures. In strongly acidic conditions, the β-(2-1) bonds present between the fructose units can be partially hydrolyzed.

Hygroscopicity

The high hygroscopicity of inulin is an excellent feature in the food industry. Inulin has the capacity of adsorbing water, thereby reducing water activity. This feature can effectually slow the evaporation of water in food manufacturing to avoid product odor and extend the shelf-life.

Viscosity

The viscosity of the inulin solution is low and it depends on its concentration. At 10 °C, 5% solution shows 1.65 millipascal-second and 30% solution shows 100 millipascal-second. As the IN concentration exceeds 10%, the viscosity starts increasing.

Gel formation

The inulin gel formulation is determined by many factors like polymerization, pH, particle size, and the process of manufacturing. Wheninulin’s concentration reaches 10-30 percent; the gel starts to form [16]. The gel is formed immediately and very smooth when its concentration reaches 40 percent to 50 percent, while the gel created is quite firm above 50 percent. The gel formation rate increases with the concentration. For the formation of gel, a low degree of inulin hydrolysis and a critical concentration of inulin is necessary. Several inulin hydrogels are already designed for use as possible carriers for the release of variable composition drugs into the colon [17].

Stability

Inulin is not readily degraded even when it is heated at 100℃. Hence it exhibits very good thermal stability. Owing to the lack of free water, IN gels are very stable and not readily hydrolyzed. Sigma crystalline inulin possesses higher thermal stability when compared to the other three forms of crystalline inulin. The thermodynamic stability of crystalline inulin falls in the order of beta<alpha<gama<sigma. Inulin is not suggestable for use in acidic beverages as it gets hydrolyzed at pH<4

Fig. 4: Applications of inulin

Nutritional and physiological activities

Low caloric value

The nutritional properties of inulin and oligofructose are fascinating and satisfying. The low caloric value of inulin made it a choice to replace sugar or fat thereby reducing the calories in ice creams, baked products, dairy products, and certain foods. As human intestinal enzymes cannot digest the inulin, it passes the upper GIT without being metabolized and it is because of the β-(2-1) bonds linking fructose molecules. The energy metabolism of the host organism can still be improved by short-chain fatty acids and lactate of inulin. These are produced as inulin is converted through the action of intestinal bacteria into short-chain fatty acids [18]. The caloric value of inulin is around 1-1.5kcal/gram. The other fermentation by-products contain bacterial biomass and gases and they are ultimately excreted. Researches proved that inulin is appropriate for diabetic use higher doses of inulin benefit them [19]. This is because inulin secretion and glucagon secretion do not affect on inulin intake.

Bifidogenic or prebiotic effect

The growth and metabolic activity of certain bacteria in the colon, especially bifidobacteria and lactobacilli, is stimulated by inulin, thus promoting their health and this is known as a bifidogenic or prebiotic effect. Absorption resistance in the upper GIT and fermentation resistance in the intestine by microflora is must be graded as prebiotic. Probiotics are living micro-organisms that have beneficial effects on the host by restoring the gut's microbial composition [20]. Prebiotics, however, are indigestible elements of food that have beneficial effects by increasing the activity and development of one or more colonic bacteria. Food supplementation with Inulin can be allowed to increase bifidobacteria count and thus boost the microbiota of the gut. As a result of higher microbial activity, inulin absorption in various products strengthened their firmness. The researchers concluded that, when carbohydrates which are derived from tubers, sored in cool temperatures for 2 to 4 mo, displayed the effective in vitro prebiotic activity [21], much higher than commercial inulin. The capacity to survive into the distal area of the colon is another desired trait for prebiotics. This is where most chronic diseases, including colon cancer and ulcerative colitis, originate.

Fig. 5: Prebiotic effects of inulin [21]

As a dietary fibre

Their acts as dietary fibres are another most significant feature of inulin. owing to its health-promoting qualities, exposure to dietary fiber-enriched diets has been increased. Inulin and oligofructose affect intestinal function by raising the frequency of stools, especially in the case of constipation [22]. The stool weight off inulin has been increased to 2g for each gram of inulin. Additionally, they reportedly decrease serum triglycerides and blood cholesterol levels in hypercholesterolemic patients. Besides, the inulin intake made serum triglycerides and blood cholesterol levels to decrease in hypercholesterolemic patients. Fermentable by the microflora present in the large intestine without any changes in the small intestine is the fundamental characteristic of the dietary fibre.

Antioxidant effect

The risk of certain diseases may be reduced by a diet rich in antioxidants. Oxidation is a major biological mechanism that supplies the body's energy. Free radicals, when produced in high amounts, will cause severe damage to cells, tissues, and organs which leads to cancer, inflammation, and radiation damage. Antioxidants reduce the free radicals, thereby inhibiting the oxidation [23]. It is known that plant polysaccharides are rich in antioxidant activity and inulin is one among them. Based on the research conducted on the Caco-2 cell model, it is confirmed that intracellular antioxidant enzyme activities are enhanced by inulin [24]. The higher antioxidant activity is seen in the inulin having a lower degree of polymerization. In vivo studies on laying hens confirmed the antioxidant effect of inulin. The action of antioxidant enzymes increased with the increase in the concentration of the inulin. Inulin derivatives that are structurally modified showed improved activity than inulin [25]. The activity of antioxidants was associated with the rate and position of the amino groups.

Minimize the chance of colon cancer and IBD

Inulin has favorable properties to decrease the risk of many intestinal tract diseases, particularly IBD (irritable bowel diseases) and colon cancer. A commonly diagnosed tumor in the colon cells caused by mutations in colon cancer and is also known as rectal cancer or colorectal cancer. Inflammatory bowel disorder is a mixture of ulcerative colitis and Crohn's disease. Both of these are chronic GIT inflammatory diseases that affect up to 250 per 50,000 people in the world today.

Colon cancer is one of the fast-growing malignant tumors which is caused by human lifestyle changes such as dietary changes. Many scientists are still working on the production of safe, low-toxic agents for treating colon cancer from natural origin. There is growing evidence that plant polysaccharides can effectively reduce the risk of colon cancer. Aberrant crypt foci formation is a primary sign of colon cancer. Researches prove that high inulin intake can significantly inhibit the ACF formation thereby not occurring colon cancer [26]. Compared to oligofructose long-chain inulin can prevent the formation of ACF effectively. This is because of the requirement of more fermentation time for the long-chain inulin in the large intestine. Short-chain fatty acid development by fermentation in the intestine is another potential mechanism for inulin’s anti-cancer impact [27].

The prevalence of IBD has risen dramatically over the past few decades. Recent research has shown that a combination of a variety of genetic, environmental, and immunological variables affects IBD. The combination of inulin and probiotic microorganisms has been observed to reduce colitis and enhance the development of intestinal bifidobacteria and lactobacilli. Besides, the combination of inulin and lactulose has been shown to minimize inflammation in colitis caused by dextran sodium sulfate (DSS). In a study, the use of a 15g combination of oligofructose and inulin for 21 d reduced Crohn's disease and increased intestinal bifidobacteria development. The combination of inulin and oligofructose inhibits IBD by enhancing the gut mucosal barrier. Inulin and oligofructose both improve the development of short chain fatty acids and favor the production of Lactobacilli or Bifidobacteria.

Effect of inulin on obesity

Obesity is a general condition with an excess amount of fat in the body. It is a medical condition that raises the risk of other illnesses such as heart disease, diabetes, high blood pressure, and some cancers, as well as other health issues. It is found that by the 21st century, obesity is going to become the greatest killer that threatens human health and life satisfaction. Inulin is a dietary fiber that is not decomposed in the digestive tract, it is sometimes used as a replacement for sucrose which helps in weight loss. Many human trials and animal trials have been conducted to prove the potential of inulin on obesity [28]. A human study demonstrated that intake of inulin in combination with green tea, which is high in catechins, is helpful for bodyweight maintenance and it also lowers blood pressure to avoid more cardiovascular diseases. The inulin-enriched diet substantially increased the feeling of fullness and decreased the intake of energy [29]. In a study conducted by Anastasovska et al., found that the function of hypothalamic neurons can be significantly altered by inulin. It is understood that inulin's mechanism for minimizing the obesity risk may be linked to improvements in the development of intestinal flora and fat oxidation promotion.

Impact on diabetes

Inulin is the most suitable food for diabetic patients. Continuous inulin intake for a couple of weeks will substantially lower HbA1c levels, an important component for blood sugar measurement [30]. The circulating anorexia intestinal hormone can be increased by inulin, which is a piece of key evidence for inulin to reduce blood sugar. Studies on inulin showed the hypoglycemic effect of inulin in animal models [31]. Inulin when given with reishi mushroom also known as Ganoderma lucidum, a plant polysaccharide, improves the metabolism of lipids as well as glucose which is a crucial thing in diabetes. L. plantarum in combination with inulin have been identified to minimize hyperglycemia and hyperlipidemia, also in lowering oxidative stress and to raise insulin as well as leptin levels in the T2DM rat’s hypothalamus.

Impact on constipation and stool frequency

Constipation is surely the most common gastrointestinal issue among older people. Inulin and oligofructose increase the frequency and consistency of stools. Consuming every gram of inulin increase the weight of wet fecal up to 1-2g [32]. In participants with reduced initial stool frequency, the enhancement is greater. Inulin, a soluble fiber that cannot be digested by human enzymes and has an effect on the efficacy of the stomach, thereby reducing the intestine pH, relieve constipation, and increases stool rate. Taking inulin-rich foods and high-water intake will relieve the constipation problem. Taking 25-35 g of inulin a day has been shown to alleviate constipation [33].

Fig. 6: Inhibition of pyruvate carboxylase by inulin [30]

Impact on lipid metabolism

Lipid metabolism, in short, is known as the degradation of lipids in cells. Inulin’s nondigestible feature favours in reducing the risk of high concentrations of triacylglycerol. Inulin-derived oligofructose can significantly decrease triglycerides in both liver and serum, increase the ratios of lipoproteins, and also reduces cholesterol. The daily intake of 10 grams of inulin decreases the risk of atherosclerosis by lowering blood lipogenesis and triacylglycerol plasma concentrations. Various human studies show that inulin is more successful than oligofructose in reducing triglyceridemia. Several studies on rats, rodents proved the effect of inulin in reducing the production of genes that are responsible for the lipogenesis of an enzyme [34]. In addition, it can combat the accumulation of triacylglycerol in the liver and has beneficial effects on hepatic steatosis. The various mechanisms by which inulin influences the metabolism of lipids include: Elevated activity of the muscle LPL enzyme, increased production of satiogenic peptide and polyamine, increased ornithine decarboxylase activity, Increased Bifidobacteria population, and short-chain fatty acid (SCFA) production, etc. SCFAs are used as an energy source and appear to promote the health of the intestinal mucosa [35].

Immune system simulation

The immune system is very essential for the body to conduct immune responses and many functions, consisting of immune organs (IO), immune cells (IC), and immune molecules (IM). The immune system has the role of recognizing and excluding antigenic foreign bodies as the most significant protection system in the human body is to defend against pathogens. Different complex disorders [36]. Such as allergic diseases, AIDS, rheumatoid arthritis, etc., will occur until the immune system is weakened. In order to keep atmospheric equilibrium and physiological harmony, the immune mechanism coordinates with other body systems. The immune system in the human body is probably highly complex. The complexity of the immune system helps it to respond to foreign substances and prevents pathogenic species from intrusion, thereby defend the body by detecting and acting on antigens likely harmful substances. Immune-modulating effect of inulin on gut-associated lymphoid tissue (GALT) was investigated as early as 2002 and indicated that the probable mechanism would include shifts in intestinal flora induced by inulin's fermentation [37]. Several animal studies have shown that T cell functions, Natural killer cells, and phagocytic activities are indirectly activated by inulin and oligo-fructose by altering the intensity of lactic acid bacteria in the GIT, which not only protects mice from infections, as well as from tumours [38]. Besides, combined administration of galactooligosaccharides and inulin can enhance immune responses and improve the role of intestinal shielding in neonatal and postweaning mice. Given in combination, inulin, and oligo-fructose in mice showed the rate of protection against vaccination increased from 74% to 40%. The rate of growth and function of immune-related genes were significantly improved in diets enriched with inulin. A diet enriched with inulin and oligofructose is given for three to four months before immunization against the influenza virus and observed that the NK cell function was increased by the dietary supplements [39]. In addition, fewer illnesses were found to be encountered by volunteers who followed the dietary supplement for a year.

Fig. 7: Health promoting properties of bifidobacterial [30]

Improve mineral absorption

Minerals help your body grow, improve, and stay healthy, just like vitamins. From constructing powerful bones to transmitting nerve impulses, the body uses minerals to perform several different functions. To make hormones or maintain a regular heartbeat, some minerals are also used. Mineral absorption happens mostly in the proximal portion of the small intestine. The recommended minimum dietary intake of magnesium ranges from 340-420 mg/day for males and from 2700-320 mg/day for females. It accounts for 750-800 mg per day in males in the case of calcium, while 800-1000 mg per day in females. Several research studies have reported that inulin can improve the absorption of minerals, particularly minerals like calcium and magnesium[40]. The reduction of intestinal pH may be one way, as colonic inulin fermentation produces SCFA or organic acids resulting in lower pH of the large intestine. During fermentation by intestinal flora, inulin releases SCFA, leading to decreased luminal pH resulting in higher calcium concentration and accelerating passive calcium diffusion. The fermented inulin product can also promote colonic mucosal growth and thus increase the area of intestinal absorption. Animal research studies have shown that inulin fructans have significantly improved mineral absorption, mainly calcium and magnesium [41]. In humans, fructan-type inulin has very little effect on mineral absorption in the small intestine.

Intestinal acceptability

The intestinal suitability of nondigestible constituents has been demonstrated in two ways [42]. One is the osmotic effects of the indigestible components result in increased water content in the colon. Higher osmotic pressure is caused by small chemicals, and excess water flows through the colon. For this cause, sorbitol and lactulose have a much greater purgative effect, unlike inulin. the other way to demonstrate intestinal acceptability is there are some effects, mainly gas output, caused by fermented goods. Components that require more fermentation time are better compared to components that ferment quickly. This is why inulin is easy to survive. Flatulence is a documented and frequently assumed dietary fiber intake after effects. Inulin showed strong tolerance without any after-effects in a study of giving 10g of it per day [43].

Role of Inulin in the pharmaceutical industry

For targeted drug delivery

For Colon-targeting

It is difficult to treat colon diseases since oral administered medications are absorbed at either the level of the stomach and small intestine and do not enter the colon [44]; however, intravenously administered drugs are withdrawn from the body before reaching the colon. For colon disease treatment, the development of colon-targeted therapeutic agents is therefore essential. Inulin is specifically hydrolyzed as a natural polysaccharide by inulinase produced by bifidobacteria and not hydrolyzed by the enzymes present in GIT. Inulin and its derivatives are classified as biodegradable colon-targeted delivery vehicles based on the above information. Different inulin and dextran hydrogels were designed to act as possible carriers for drug delivery into the colon. Since inulin is not consumed by the stomach or SI, and as inulin is destroyed by colonic bacteria, drugs encapsulated in vesicles coated with inulin may be directly released into the colon. Thus, improvements in the treatment of colonic diseases include the use of inulin-coated vesicles. The drug delivery mechanism unique to the colon should be capable of protecting the drug en route to the colon [45]. The reason that inulin in the intestinal tract is not digested or consumed has made this polymer an attractive vehicle for the delivery of colonic drugs. Several types of drug deliveries, such as tablets, microspheres, microparticles, nanoparticles, micelles, nano micelles, hydrogels, have been designed and shown promising results with inulin and its derivatives. Some of the dosage form/drug deliveries for colon targeting with the aid of inulin are shown in table 1.

To optimize drug activity for tumor-targeting

Due to its excellent biocompatibility, biodegradability, and flexibility for simple chemical design, inulin has been broadly used as a linear organic polysaccharide in the preparation of tumor-targeting drug delivery systems. Doxorubicin (DOX) and Paclitaxel (PTX) were found more effective up to 100-200 times when they are loaded in nano-micelles of lauryl carbamate derivatives of the inulin compared to those drugs insoluble form. In further studies, epirubicin in free form exhibit less antitumor activity compared to inulin-ibuprofen polymer-based nanoparticles loaded with epirubicin [46]. The nanoparticles also exhibited lower toxicity. The numerous effective dosage formulations designed to treat tumors with the aid of inulin are shown in table 1.

Table 1: Applications of inulin in drug delivery

	Colon targeting
Inulin or inulin derivatives	Model drug	Dosage forms	References
Inulin	Infliximab	Tablet	[47]
Cinnamoylated inulin	Methotrexate	Microspheres	[44]
Inulin acetate	Indomethacin	Microparticles	[48]
Amphiphilic inulin	Ornidazole	Nanoparticles	[49]
Methacrylated inulin	Prednisolone	Gels	[50]
Methacrylated inulin	Bovine serum	Hydrogels	[51]
Lipoic acid esterified inulin	Tanshinone IIA	Micelles	[51]
PEGylated squalene-grafted-inulin	Doxorubicin	Superparamagnetic iron oxide nano-particle (SPIONs)	[52]
Invite-Bio	--	Long circulated nano micelles	[53]
Tumor targeting
Inulin-Ibuprofen polymer	Epirubicin	Nanoparticles (Neuroblastoma)	[12]
Inulin-2-aminoethyl carbamate	Doxorubicin	Gold nanoparticles (Cervical and lung cancer)	[54]
Carboxymethyl inulin	5-Fluoro uracil	Silver nanoparticles (Pancreatic cancer)	[55]
Inutec® SP1	Paclitaxel	Micelles (Skin cancer)	[56]
Inutec® SP1	Doxorubicin and Paclitaxel	Nano micelles (Breast cancer)	[57]
Inulin-cysteamine-Diethylenetriamine copolymer	siRNA	Superparamagnetic iron oxide nano-particle (SPIONs) (Breast cancer)	[58]

As a stabilizer for different drug deliveries

Protein-based drugs

The discovery of a variety of protein-based therapeutic agents has resulted in rapid developments in microbiology and biopharmaceutical technologies. In aqueous solutions, as these are unstable, so they are available as powders that have been dried through freeze-drying or spray drying, or evaporative drying technique. This may significantly affect either the action or efficacy [59]. Therefore, in these drying processes, a protective agent needs to be applied to prevent the harmful effects. During the drying and subsequent storage period, it is known that sugars can protect proteins. The detailed mechanisms are, however, not well understood. A study on the enzyme stabilizing effects was conducted as early as 1992, revealing that inulin does not have excellent stabilizing effects compared to sugar, sorbitol, and dextran [60]. The poor stabilizing result may be due to the degree of polymerization and less group content.

A significant count of recent studies shown that inulin has a strong stabilizing effect, especially on protein-based drugs. As a model protein, alkaline phosphatase was used to research whether inulin is a competent protein stabilizer. The results showed that the behavior of alkaline phosphatase in drying and storage for 4 w at 20 °C with relative humidity at 0, 45, or 60 can be perfectly maintained by inulin as a stabilizer. Inulin has been reported to be a competent stabilizer of haemagglutinin, an essential component of the influenza vaccine. The strength of haemagglutinin and the immunogenicity of virosomes are preserved by inulin during lyophilization and long-term storage. Inulin demonstrated outstanding protein safety, and it also demonstrated its superiority over trehalose in preserving stability after the tableting process. In a study conducted by Tonniset al. Inulin with 4 kDa showed the best protective effect compared to dextran with 6 kDa, this indicates that the size and molecular flexibility of sugars influence their protein stabilization ability [61]. Therefore, inulin is an effective stabilizer for protein-based drugs.

Fig. 8: Various routes of Inulin delivery [17]

Other systems of drug delivery

Inulin can also be a product stabilizer in other dosage types such as Solid dispersions, PEGylated nanoparticles, solid lipid nanoparticles, etc, in parallel to its function as a protein-based drug stabilizer. Solid dispersions obtained by suspending inulin and tetrahydrocannabinol in THC (tertiary butyl alcohol) and water demonstrated high stability over uncoated THC during storage at 20-25 ℃ and 45% RH for 250 d. In addition, studies have reported that solid dispersions prepared by spray drying containing THC and IN showed better stability than prepared by freeze-drying. Inulin with 1.5 and 4 kDa is proved to be an effective protectant for PEG-modified liposomes. Due to its excellent compatibility with PEG, inulin is a superior stabilizer over dextran for various forms of PEGylated nanoparticles. A variety of structurally modified inulin is often used commonly as stabilizers at present. In the solid lipid nanoparticles, dodecyl inulin and octadecyl inulin were used as a surfactant. These prevented the transfer of lipid crystals and shielded particles from aggregation throughout storage and were superior to the traditional surfactants such as Tweens and Poloxamer.

Enhancement in the action of the drug

Enhancement of drug release

For solid oral formulations, before it can be absorbed, the medication must be dissolved. Thus, the drugs having poor dissolution as well as poor release profiles exhibit poor bioavailability [62]. The dissolution and release profile of these drugs can be enhanced by techniques such as solid dispersion. The use of hydrophilic carriers in the solid dispersion makes it dissolve at a faster rate, thereby increasing bioavailability.

And as inulin exhibits hydrophilic properties, it is used as carriers in the dosage forms which gradually increases the drug dissolution, release, and bioavailability. In a study conducted on the dissolution rate of diazepam, inulin significantly improved the dissolution profiles compared with sucrose or other sugars. Further, a study showed the excellent improvement in the dissolution of diazepam by using solid dispersion tablets containing inulin DP23. Only 10-15 percent of the drug is released from physical mixtures, whereas 80-85 percent of the release was seen from solid dispersion containing inulin. In a comparative study of fenofibrate’s dissolution and stability profile using different carriers like PEG 20k, HP-β-CD, PVP K30, mannitol, and inulin 4kDa, the inulin carrier exhibited excellent dissolution and better stability. Inulin derivatives exhibited controlled release properties in the studies conducted on Irbesartan. Within 60 min, the dissolution rate of Irbesartan reached 90%, while poly (acrylic acid) grafted inulin can achieve approximately 33% controlled-release of Irbesartan.

Moreover, multicomponent solid dispersions prepared by excipients such as mannitol, inulin, and cellulose acetate phthalate not only boost irinotecan (IRN) dissolution and also increase the permeability through the intestine. The various effective dosage forms designed for improved solubility and stability with the aid of inulin are shown in table 2.

Table 2: Various applications of inulin

Inulin or its derivatives	Model drug	Dosage form	Applications	References
Inulin	Fiseten	Inulin nano-particles	Improves solubility and stability	[63]
Inulin-D-α-tocopherol succinate	Curcumin	Self assembling micelles	Improves solubility	[64]
Inulin	Anthocyanins	Microcapsules	Improves stability	[65]
Hydrophobically Modified inulin	Cinnamaldehyde	Nanoemulsions	Improves solubility of nanoparticles	[66]
Aminated inulin	Folic acid complex	Modified release	Controlled	[6]

As a diagnostic tool

In measuring GFR

Inulin can only be cleared by the kidneys in the human body. It is understood that inulin will be filtered from the glomerulus without being reabsorbed by renal tubules. Inulin is thus defined as the most precise substance for clinically measuring glomerular filtration rate (GFR) to evaluate renal function. In this application, inulin is injected intravenously [67]. Although inulin is commonly accepted as the benchmark for GFR clinical determination, this technique has complex procedures and is not sufficient for routine clinical measurement. Researchers have recently upgraded the technique and developed near-IR-dye-labeled inulin as an optical probe to test GFR by transcutaneous pulse dye densitometer, accurately [68].

Vaccine adjuvants

Vaccine adjuvants are the agents that increase certain immune responses for a particular antigen. Aluminum salts are the only vaccine adjuvants currently being approved by the FDA. Others all are considered experimental and need to be subjected to special preclinical examinations [69]. They can be paired with unique vaccines that can offer many benefits, including minimizing the use of antigens, easily stimulating the immune system, strengthening the immune response, and extending the continuous release of antigens. In the early 1980’s itself, there were studies that exhibited γ-Inulin’s adjuvant activity. Researchers have recently verified that δ-inulin, which has comparable solubility to γ-inulin, has excellent adjuvant activity as well [70]. Advax, a microparticle derived from δ-IN, has been developed as an adjuvant for many vaccines, such as influenza, hepatitis B, SARS, anthrax, HIV, etc.

CONCLUSION

Consumers are more mindful of their diet in modern times and demand a low caloric diet, thus improving well-being. Inulin is one such dietary food in the modern era that has garnered attention. This review thoroughly described the biological processes of inulin, including the effect of prebiotics, antioxidants, controlling the metabolism of sugars or lipids, Enhancing the mineral absorption, reducing the risk of IBD, colon cancer, and obesity as a stabilizer for drugs, etc. Inulin has been recognized as having tremendous effects on human growth and state of health. Besides, it can be a good carbohydrate and fat substitute and a strong source of fibre to enrich various foods for product growth. A significant volume of literature indicates that in pharmaceuticals, inulin has great promising applications. For some drugs, especially the protein-based, it can be used as a stabilizer, can greatly enhance dissolution rate and drug release, it can also be used for controlled-release and targeted preparationsFurthermore, studies on chemically modified inulin are increasingly becoming an active field of study. Chemically modified inulin showed great characteristics that made up for the inadequacy of inulin, which further broadened inulin applications. Though the processing technology of inulin is very advanced and can achieve high volume, there are still some challenges for separating and purifying inulin with a single degree of polymerization. Complex systems, weak operability, and low yield are among these obstacles. Research on the separation and purification of inulin is therefore still a field that requires further focus.

FUNDING

Nil

AUTHORS CONTRIBUTIONS

All authors have contributed equally.

CONFLICT OF INTERESTS

The author has no conflict of interest to declare.

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