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Stevioside

Stevioside is a diterpenoid glycoside extracted from the leaves of the Stevia rebaudiana plant, a perennial herb native to South America, and serves as a primary natural non-caloric sweetener with a potency 250–300 times greater than sucrose on a weight basis.
This compound, which constitutes 5–10% of the dry leaf weight, has been utilized traditionally by indigenous Guaraní peoples in Paraguay and Brazil for centuries as a sweetening agent in teas and medicines due to its intense, licorice-like flavor profile.
Chemically, stevioside features the aglycone steviol—a kaurene-type diterpene—glycosylated with three glucose units at the C-13 position and one rhamnose-glucose disaccharide at the C-19 carboxyl group, resulting in the molecular formula C₃₈H₆₀O₁₈ and a molar mass of 804.87 g/mol. First isolated in 1931 by French chemists Marcel Bridel and Robert Lavielle from S. rebaudiana leaves, stevioside gained commercial interest in the mid-20th century as a sugar substitute, particularly in Japan where it has been approved since the 1970s and comprises about 40% of the sweetener market.
It is commonly purified through water extraction, adsorption, and crystallization processes to achieve food-grade purity exceeding 95%, and is often blended with other steviol glycosides like rebaudioside A to mask its slight bitter aftertaste.
In modern applications, stevioside is incorporated into beverages, dairy products, baked goods, and tabletop sweeteners, offering a sucrose alternative for diabetic and weight-management diets due to its lack of impact on blood glucose or insulin levels. Regulatory bodies worldwide, including the Joint FAO/WHO Expert Committee on Food Additives (JECFA) and the U.S. Food and Drug Administration (FDA), have affirmed the safety of stevioside and related steviol glycosides, establishing an acceptable daily intake (ADI) of 4 mg/kg body weight expressed as steviol equivalents, based on extensive toxicological studies showing no genotoxicity, carcinogenicity, or reproductive toxicity at relevant doses.
Metabolized in the gut to steviol, which is absorbed and excreted via urine, stevioside exhibits high stability under heat and acidic conditions, making it suitable for processing, though it may degrade into steviolbioside during prolonged storage.
Emerging research highlights potential therapeutic effects, such as antihypertensive and antihyperglycemic properties in animal models, though human clinical evidence remains limited and its primary role remains as a safe, plant-derived sweetener.

History

Discovery and Isolation

The indigenous Guarani people of Paraguay and surrounding regions have utilized Stevia rebaudiana leaves as a natural sweetener for their beverages and foods since pre-Columbian times, referring to the plant as ka'a he'ê or "sweet herb." This traditional knowledge, passed down through generations, highlighted the plant's intense sweetness without caloric contribution, though scientific documentation of these practices emerged later. In 1887, Italian-Swiss botanist Moisés Santiago Bertoni began exploring the forests of eastern Paraguay, where local guides introduced him to Stevia rebaudiana and its remarkable properties. Bertoni conducted systematic studies on the plant, formally describing it and noting its exceptional sweetness in detail by 1901, which marked the modern scientific recognition of its potential as a sweetening agent. He named the species Stevia rebaudiana in 1905, honoring chemist Ovidio Rebaudi, and emphasized its non-sugar-derived taste in his botanical publications. Significant progress in understanding the plant's chemistry occurred in 1931 when French chemists M. Bridel and R. Lavielle successfully isolated stevioside, the primary sweet glycoside responsible for S. rebaudiana's flavor, from dried leaves. Their method involved initial solvent extraction using hot water or methanol to obtain a crude glycoside-rich filtrate, followed by deproteinization with lead acetate, removal of excess lead via hydrogen sulfide, concentration of the solution, and final purification through recrystallization from methanol to yield pure white crystals of stevioside. This 1930s-era approach relied on classical organic chemistry techniques, including precipitation and solvent-based separation, which were standard for isolating natural products at the time. Bridel and Lavielle determined that stevioside exhibited a sweetness potency of approximately 300 times that of sucrose on a weight basis, establishing its viability as a high-intensity sweetener.

Early Uses and Commercialization

Stevioside, the primary sweet compound extracted from the leaves of Stevia rebaudiana, has been utilized traditionally in South America for centuries, particularly among the Guaraní people in Paraguay and Brazil, where the leaves were brewed into teas as a natural sweetener and incorporated into medicinal preparations. These indigenous communities valued the plant for its intense sweetness, which is 250-300 times that of sucrose, allowing minimal amounts to flavor beverages and remedies. In Asia, stevioside gained prominence in the 1970s, especially in Japan, where regulatory restrictions on artificial sweeteners prompted the development of natural alternatives. Japan initiated stevia cultivation in the early 1970s, leading to the first industrial production of stevioside-based sweeteners in 1971 by Morita Kagaku Kogyo Co., Ltd., marking the global commercialization of purified steviol glycosides. By the late 1970s, stevioside was widely adopted in Japanese food products, including teas and tabletop sweeteners, comprising over 40% of the non-sugar sweetener market by the 1980s. Commercial cultivation expanded to China in the 1970s, with large-scale production beginning in the 1980s, positioning the country as the world's leading stevia producer. In the United States, stevioside faced significant hurdles, with the Food and Drug Administration banning its importation for food use in 1991 due to concerns over potential safety issues raised in early animal studies. This restriction limited stevioside to dietary supplement status until 2008, when the FDA granted Generally Recognized as Safe (GRAS) status to purified forms of steviol glycosides, including stevioside, enabling its use in foods and beverages. Key industry players, such as Coca-Cola, accelerated commercialization through partnerships and patents; for instance, Coca-Cola filed multiple patent applications in 2007 for stevia-derived sweeteners and launched beverages sweetened with Truvia—a stevioside and rebaudioside blend—in late 2008. In Europe, steviol glycosides including stevioside received approval from the European Food Safety Authority in 2011, facilitating entry into the market as a natural sweetener. These milestones fueled rapid market expansion, driven by consumer demand for calorie-free, natural sweeteners amid rising health consciousness. The global stevia market, encompassing stevioside and related glycosides, reached $590 million in value by 2020, with significant growth in beverage and food applications.

Chemical Properties

Structure and Composition

Stevioside is classified as a diterpene glycoside, specifically a tetracyclic ent-kaurene diterpenoid glycoside derived from the aglycone steviol (ent-13-hydroxykaur-16-en-19-oic acid). The steviol backbone features a kaurane skeleton with hydroxyl groups at C-13 and a carboxylic acid at C-19, to which sugar moieties are attached. The molecular formula of stevioside is C₃₈H₆₀O₁₈. Structurally, it comprises the steviol aglycone bound to three β-D-glucose units: a disaccharide sophorose (β-D-glucopyranosyl-(1→2)-β-D-glucopyranose) linked via a β-glycosidic bond at the C-13 hydroxyl group, and a single β-D-glucopyranosyl unit esterified to the C-19 carboxylic acid. This configuration results in the full IUPAC name: 13-[(2-O-β-D-glucopyranosyl-β-D-glucopyranosyl)oxy]kaur-16-en-19-oic acid β-D-glucopyranosyl ester. Compared to related steviol glycosides, stevioside contains three glucose units, whereas rebaudioside A incorporates four through an additional β(1→3)-linked glucose on the sophorose at C-13, contributing to its milder taste with reduced bitterness.

Physical and Chemical Characteristics

Stevioside is a white to off-white crystalline powder. It has a molar mass of 804.87 g/mol and decomposes at a melting point of 198–200 °C. The compound exhibits limited solubility in water, approximately 4 g/L at room temperature, but is more soluble in polar solvents such as ethanol and methanol; it is insoluble in non-polar solvents like diethyl ether and chloroform. Stevioside demonstrates high stability under various conditions, remaining intact when heated up to 200 °C and in solutions with pH ranging from 3 to 10; it is also non-fermentable by yeast, making it suitable for applications requiring preservation of sweetness without microbial degradation. In terms of sensory properties, stevioside is 250–300 times sweeter than sucrose on a weight basis, though it often imparts a bitter aftertaste attributed to its steviol aglycone moiety. This relative sweetness is determined through sensory evaluation panels comparing equivalent sweetness intensities to sucrose solutions, without altering the fundamental taste profile equation in perceptual terms.

Sources and Production

Natural Occurrence in Stevia rebaudiana

Stevioside is naturally occurring primarily in the leaves of Stevia rebaudiana Bertoni, a perennial herbaceous shrub in the Asteraceae family native to the subtropical regions of Paraguay and northeastern Brazil. In these leaves, stevioside constitutes 5–10% of the dry weight and represents the predominant steviol glycoside, typically comprising 40–70% of the total steviol glycosides, which collectively range from 10–20% of the dry leaf biomass depending on genetic and environmental variables. The of stevioside begins in the glandular trichomes of , where geranylgeranyl diphosphate serves as the precursor, undergoing cyclization to form ent-kaurene, followed by oxidation via kaurene oxidase and subsequent and steps to yield the steviol aglycone backbone and attached sugar moieties characteristic of stevioside. Content levels are higher in mature leaves compared to younger ones, with optimal accumulation promoted by environmental factors such as elevated daily light integrals (greater sunlight exposure), well-drained nutrient-rich soils, and suitable temperatures; for instance, increased irradiance has been shown to enhance steviol glycoside production by up to 50% in controlled studies. Varietal differences also influence stevioside concentrations, with certain cultivars exhibiting up to twofold higher levels than others under identical conditions, highlighting the role of genetic selection in natural variation. While S. rebaudiana is the principal source, stevioside occurs in minor amounts in related species such as Stevia phlebophylla, though at concentrations far lower than in S. rebaudiana.

Extraction and Purification Methods

The extraction of stevioside from Stevia rebaudiana leaves typically begins with traditional water-based methods, where dried leaves are infused in hot water at temperatures of 50-120°C under steam pressure for 0.25-4 hours, followed by filtration to separate the aqueous extract containing glycosides. This approach yields approximately 50% total glycosides from the extract, with stevioside comprising a significant portion, though impurities like chlorophyll are co-extracted. Solvent extraction enhances efficiency by using hot water or ethanol at 70-90°C to dissolve the glycosides, often at a leaf-to-solvent ratio of 1:10 to 1:35, followed by concentration through rotary evaporation under reduced pressure. Ethanol-based variants, optimized at 50-70% concentration and 60-80°C, can increase selectivity for stevioside while minimizing solvent use. Advanced techniques address limitations of traditional and solvent methods by improving yield and purity. Supercritical CO₂ extraction, often with an ethanol co-solvent at pressures of 200-300 bar and temperatures of 40-60°C, extracts stevioside with yields exceeding 90% purity and minimal thermal degradation, recovering up to 1.6% steviol glycosides from leaves. Ultrasound-assisted extraction at 225-450 W for 9 minutes further boosts efficiency, reducing extraction time compared to conventional heating. Purification follows extraction to isolate high-purity stevioside, typically involving multiple steps: treatment with calcium hydroxide to adjust pH to 8-10 and precipitate impurities, followed by filtration; adsorption on ion-exchange resins such as strong acid cation and weak base anion types to remove salts and pigments; and final crystallization from methanol or ethanol, with drying to achieve 95% or greater purity. Membrane filtration, using ultrafiltration with 1-10 kDa cut-offs, removes over 96% of pigments like chlorophyll while recovering 45-90% of stevioside, often integrated with chromatography for >98% purity in industrial settings. Yield optimization targets the 5-8% stevioside content in dry leaves, with challenges including co-extraction of chlorophyll and other phenolics that reduce purity to below 70% without refinement. Industrial processes mitigate this through sequential resin adsorption and evaporation, consistently achieving 40-70% stevioside in the final product.

Applications

Use as a Sweetener

Stevioside serves as a primary natural sweetener in the food and beverage industries, particularly as a zero-calorie alternative to sugar. It is commonly added to soft drinks, yogurts, and tabletop sweeteners to reduce caloric content while maintaining sweetness. For instance, stevioside-based blends like Truvia, which incorporate steviol glycosides, are used in consumer products such as certain Coca-Cola formulations, including the now-discontinued Coca-Cola Life. These applications leverage stevioside's high sweetness potency of 250-300 times that of sucrose, allowing minimal quantities to achieve desired flavor profiles. To optimize sensory qualities, stevioside is frequently formulated in blends with erythritol or rebaudioside A, which help mask its inherent bitterness and improve overall taste balance. These formulations provide sweetness equivalent to sucrose without contributing calories or affecting blood glucose levels. This formulation approach enhances its versatility across diverse matrices, from carbonated beverages to dairy items like yogurt. Key advantages of stevioside include its zero-calorie profile, non-cariogenic nature, and glycemic index of zero, rendering it suitable for diabetic-friendly and low-sugar diets. Its sensory characteristics feature a slower onset of sweetness compared to sucrose, accompanied by a lingering aftertaste, though these can be mitigated through blending. Additionally, stevioside demonstrates heat stability up to 120°C, making it viable for baking and other thermal processing applications. In the market, stevioside contributes significantly to the natural sweetener sector, with the global stevia market projected to reach USD 1.4 billion by 2025 and beverages comprising nearly 35% of its applications by value. This growth reflects increasing demand for clean-label, sugar-reduced products in the beverage industry.

Other Industrial and Medicinal Applications

Stevioside serves as an excipient in pharmaceutical formulations, particularly for taste-masking bitter active ingredients in oral dosage forms such as quickly soluble films and tablets. Proven methods include incorporating stevioside extracts to yield palatable products without compromising drug release. Its potential in antidiabetic formulations stems from demonstrated preclinical antidiabetic activity and moderate solubility in aqueous and ethanol-water mixtures, enabling incorporation into gels and jellies for glucose management. In cosmetics, stevioside is utilized in oral care products due to its non-cariogenic properties, inhibiting Streptococcus mutans growth and biofilm formation without promoting dental caries. For skincare, its antioxidant properties, derived from phenolic compounds in Stevia extracts, help protect against oxidative stress and support anti-inflammatory effects in topical applications. Patents describe steviol glycosides, including stevioside, for external cosmetic use to regulate skin cell metabolism. Industrially, stevioside acts as an additive in tobacco products, where stevia extracts containing it are applied to leaves to enhance flavor and reduce bitterness during processing. In animal feed, it functions as a low-calorie sweetener, improving palatability and feed intake in species like goats and broilers without adverse metabolic effects. Emerging applications include stevioside in biopesticides, leveraging insect-repellent effects from Stevia extracts to deter ants and aphids through compounds like phytol and nerolidol. These properties position it as an eco-friendly alternative for pest control in agriculture.

Safety and Regulation

Toxicological Profile

Stevioside exhibits very low acute oral toxicity, with LD50 values exceeding 15 g/kg body weight in rats and mice. Genotoxicity assessments, including the Ames test and in vivo micronucleus assays, have shown no mutagenic or clastogenic effects for stevioside or its metabolite steviol. Long-term toxicity studies in rodents, including 2-year feeding trials in Wistar and F344 rats, demonstrated no evidence of carcinogenicity at dietary concentrations up to 2.5% stevioside, equivalent to approximately 1000 mg/kg body weight per day. These studies identified no treatment-related neoplastic or non-neoplastic lesions, supporting the absence of chronic toxic effects at relevant exposure levels. Upon ingestion, stevioside is hydrolyzed by intestinal gut bacteria to steviol, which is then absorbed, conjugated primarily to steviol glucuronide in the liver, and excreted mainly via urine, with minimal fecal elimination. This metabolic pathway results in no significant tissue accumulation, as confirmed in human pharmacokinetic studies where over 50% of the administered dose is recovered as urinary steviol glucuronide within 72 hours. Reported side effects of stevioside are minimal, consisting of rare instances of mild gastrointestinal discomfort, such as bloating or upset, observed at high intake levels exceeding 1 g per day; these are typically transient and not indicative of toxicity. The compound's bitter aftertaste is a sensory attribute rather than a toxicological concern. Based on comprehensive toxicological evaluations, the Joint FAO/WHO Expert Committee on Food Additives (JECFA) established an acceptable daily intake of 4 mg/kg body weight, expressed as steviol equivalents, in 2008. This determination aligns with the U.S. FDA's recognition of high-purity steviol glycosides, including stevioside, as generally recognized as safe (GRAS).

Regulatory Status Worldwide

In 2008, the Joint FAO/WHO Expert Committee on Food Additives (JECFA) evaluated steviol glycosides, including stevioside, and established an acceptable daily intake (ADI) of 4 mg/kg body weight expressed as steviol equivalents, concluding they are safe for use as sweeteners based on toxicological data from animal studies. This JECFA assessment has been adopted or aligned with by regulatory bodies worldwide, facilitating approvals in more than 100 countries (as of 2024) where high-purity steviol glycosides are permitted as food additives. In the United States, the Food and Drug Administration (FDA) affirmed the generally recognized as safe (GRAS) status for high-purity steviol glycosides (≥95% purity), including stevioside, in December 2008 through the GRAS notification program, allowing their use as sweeteners in foods and beverages under intended conditions. However, whole stevia leaves and crude extracts are not considered GRAS and remain prohibited for use as sweeteners, with imports restricted under FDA Import Alert 45-06 to prevent adulteration of food products. The European Food Safety Authority (EFSA) authorized steviol glycosides, including stevioside, as a food additive under the designation E 960 in November 2011, following a 2010 scientific opinion that confirmed an ADI of 4 mg/kg body weight (steviol equivalents) and required a minimum purity of 95% to ensure safety. This approval aligned with JECFA specifications and permitted use in a wide range of foods, such as beverages and tabletop sweeteners, subject to maximum usage levels. This ADI was reaffirmed by EFSA in May 2025 following a safety assessment. Earlier, in the 1990s, the European Commission's Scientific Committee on Food had restricted stevioside due to concerns over potential mutagenicity and reproductive toxicity raised in preliminary studies on steviol (a metabolite), leading to a de facto ban on its use as a sweetener until comprehensive re-evaluations in 2010 overturned these restrictions based on new genotoxicity and long-term data showing no adverse effects. In Asia, stevioside has long been approved without significant restrictions. Japan granted approval for stevioside as a food additive in 1971, making it one of the first countries to commercialize stevia-derived sweeteners, where it is widely used in products like soft drinks and yogurt. China approved stevioside as a natural sweetener and medicinal adjunct in 1985 via Ministry of Public Health document No. 37, with further confirmation in 1990, allowing its incorporation into foods and pharmaceuticals. South Korea similarly permits steviol glycosides, including stevioside, as approved food additives for use in various categories such as confectionery and non-alcoholic beverages, consistent with international standards.

Health Effects and Research

Potential Health Benefits

Stevioside has demonstrated potential antidiabetic effects in human clinical trials, particularly in managing postprandial glucose levels among individuals with type 2 diabetes. A randomized controlled crossover trial involving type 2 diabetic subjects found that administration of stevioside at a single dose of 1 g with a test meal significantly reduced postprandial blood glucose levels compared to placebo, with an approximate 18% decrease observed. Another short-term study using stevia preloads in healthy adults reported significant reductions in postprandial glucose excursions relative to sucrose equivalents, supporting its role in improving glucose metabolism without caloric contribution. These findings suggest stevioside's zero-calorie nature may aid in glycemic control for diabetic populations, complementing its use as a sweetener. In terms of antihypertensive effects, stevioside consumption has been associated with blood pressure reductions, especially in hypertensive individuals. A 2015 systematic review and meta-analysis of randomized clinical trials indicated that steviol glycosides, including stevioside, led to a non-significant systolic blood pressure reduction of approximately 3 mmHg overall, though greater effects were noted in some individual studies with elevated baseline levels. A two-year randomized placebo-controlled trial in patients with mild essential hypertension further corroborated this, showing sustained decreases in systolic blood pressure of approximately 10 mmHg and diastolic of 6 mmHg with daily oral stevioside at 1.5 g. Stevioside exhibits antioxidant activity as evidenced by in vitro assays, where it demonstrates free radical scavenging capabilities. In DPPH radical scavenging tests, stevioside showed concentration-dependent inhibition of free radicals, attributed in part to its structural features that facilitate hydrogen donation, though its activity is weaker compared to phenolic-rich extracts. This property highlights its potential to mitigate oxidative stress in cellular models. For weight management, short-term randomized controlled trials have indicated modest benefits through appetite regulation. A 2010 crossover trial in healthy adults found that stevia-sweetened preloads did not increase subsequent food intake and were associated with subtle enhancements in satiety ratings compared to caloric sweeteners, leading to lower overall daily energy consumption without long-term data to confirm sustained effects. Anti-inflammatory effects of stevioside have been observed in animal models of colitis, where it reduces pro-inflammatory cytokine production. In dextran sulfate sodium-induced ulcerative colitis in mice, stevioside administration significantly lowered TNF-α levels in colonic tissues, alongside decreases in IL-6 and other mediators, through inhibition of NF-κB and MAPK pathways.

Ongoing Research and Limitations

Ongoing research into stevioside focuses on enhancing its production efficiency and addressing sensory and sustainability challenges associated with its use as a sweetener. Genetic engineering approaches, particularly using CRISPR/Cas9 and related technologies, are being explored to boost steviol glycoside yields in Stevia rebaudiana. For instance, a 2022 study employed a DNA-free CRISPR/dCas9-based transcriptional activation system targeting the UGT76G1 gene in stevia protoplasts, which upregulated expression to facilitate the conversion of stevioside to rebaudioside A, a less bitter glycoside, thereby improving overall desirable compound production. Similarly, overexpression of key biosynthetic genes like SrDXS1 and SrKAH via genetic manipulation has demonstrated up to a 1.88-fold increase in total steviol glycosides, including stevioside, in transgenic stevia plants, highlighting the potential for higher yields through targeted modifications. Clinical investigations continue to evaluate stevioside's health impacts, with emphasis on cardiovascular outcomes amid limitations in long-term human data. As of 2025, randomized controlled trials, such as a placebo-controlled study in patients with early-stage chronic kidney disease, have examined stevia supplementation's effects on inflammatory markers, showing potential reductions in markers like hsCRP and ESR. However, Phase II trials specifically targeting cardiovascular endpoints remain limited, and most evidence derives from shorter-term studies (under one year), underscoring the need for extended-duration research to confirm sustained benefits and safety. A 2024 meta-analysis of randomized trials further supports stevioside's potential to lower fasting glucose, but calls for larger, longitudinal Phase II and III studies to address gaps in diverse populations. Efforts to mitigate stevioside's inherent bitterness, which arises from its aftertaste, are advancing through enzymatic bioconversion techniques. Recent research has optimized recombinant UDP-glucosyltransferase enzymes, such as UGT76G1, to convert stevioside into rebaudioside M, achieving yields of 77.9% in microbial systems like Saccharomyces cerevisiae under controlled conditions. A 2024 study demonstrated this process's scalability for industrial production, reducing bitterness while preserving sweetness intensity, and emphasized its role in developing purer steviol glycoside formulations. These innovations address a key limitation in consumer acceptance, though challenges persist in cost-effective enzyme sourcing and process optimization for large-scale application. Sustainability assessments highlight stevioside's environmental advantages but identify areas for further improvement in farming practices. Studies on water usage in Stevia cultivation report a footprint of approximately 100-200 liters per kilogram of dry leaf, significantly lower than sugar production's 1,800-2,500 liters per kilogram of refined sugar from cane or beet sources. A 2015 life cycle analysis confirmed stevia's overall water efficiency, with 92-95% less consumption compared to beet sugar, attributing this to the plant's drought tolerance and lower irrigation needs in suitable climates. Nonetheless, ongoing research is needed to refine irrigation strategies in water-scarce regions, as variability in soil and climate can elevate usage beyond optimal levels. Key limitations in stevioside research include insufficient pediatric safety data and unexplored potential interactions with medications. While general toxicological profiles indicate safety across populations, specific long-term studies in children are scarce, with current evidence limited to metabolic modeling rather than clinical trials, raising concerns for pediatric use. Regarding drug interactions, in vitro research has identified steviol (stevioside's metabolite) as an inhibitor of renal organic anion transporters (OAT1 and OAT3) and modulator of pregnane X receptor (PXR), suggesting possible effects on drugs like antihypertensives or antidiabetics, but comprehensive human pharmacokinetic studies remain unconducted. These gaps necessitate targeted investigations to ensure safe integration into diverse therapeutic contexts. As of November 2025, no major new Phase III trials or updates on long-term health effects have been reported, emphasizing the need for continued research.