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Isomaltose

Isomaltose is a consisting of two D-glucopyranose units joined by an α-(1→6) glycosidic linkage. It serves as a key intermediate in the of and , where pancreatic α-amylase cleaves α-(1→4) linkages to yield isomaltose from branch points, while lacking activity against the α-(1→6) bonds. In the , isomaltose is hydrolyzed to glucose by the isomaltase, a subunit of the sucrase-isomaltase complex on the membrane, facilitating its absorption and contributing to postprandial glucose levels. Deficiencies in this , as seen in congenital sucrase-isomaltase deficiency, impair isomaltose and can lead to gastrointestinal symptoms upon consumption of starches or related carbohydrates. Naturally, isomaltose occurs in low concentrations in honey, where it arises from enzymatic activity during nectar processing by bees, and in certain fermented foods such as sake and soy sauce. In honey, it has been linked to biological effects, including the induction of granulocyte-colony stimulating factor secretion in intestinal cells. Industrially, isomaltose is produced enzymatically from starch and used in research or as a component in carbohydrate mixtures, though it is fully digestible with a caloric value comparable to other glucose-based disaccharides.

Chemical Identity

Molecular Structure

Isomaltose is a composed of two D-glucopyranose units linked by an α-(1→6) between the anomeric carbon (C1) of the first glucose and the C6 hydroxyl group of the second glucose. The molecular formula is C_{12}H_{22}O_{11}, reflecting the combination of two units with the loss of one during formation. Both glucose moieties adopt the ring configuration in the predominant form, with the first unit serving as the non-reducing end and the second as the reducing end. In a , isomaltose appears as two adjacent six-membered rings, where the anomeric hydroxyl of the left ring (α-oriented) connects via an oxygen bridge to the CH_2OH group extending upward from C6 of the right ring; this α-1,6 linkage contrasts with the linear α-1,4 connection in its . The free anomeric carbon on the second glucose unit enables isomaltose to exhibit reducing properties, as it can equilibrate to an open-chain form.

Nomenclature and Isomers

Isomaltose bears the systematic IUPAC name 6-O-α-D-glucopyranosyl-D-glucopyranose, reflecting its composition as a formed by two D-glucose units linked via an α-(1→6) . This nomenclature adheres to the conventions for naming oligosaccharides, specifying the position and anomeric configuration of the glycosidic linkage. Commonly referred to as isomaltose, it is also known by the synonym brachiose, a term occasionally used in biochemical contexts. The name "isomaltose" originates from the prefix "iso-," denoting its structural isomerism to maltose, and it was first isolated during late 19th-century investigations into starch hydrolysis products. Isomaltose serves as a structural isomer to other glucose-based disaccharides, primarily differing in the site and stereochemistry of the glycosidic linkage connecting the two D-glucopyranose moieties. It contrasts with maltose, which features an α-(1→4) linkage; gentiobiose, characterized by a β-(1→6) linkage; and trehalose, joined by an α-(1→1) linkage. These variations in linkage position and configuration lead to distinct molecular conformations and properties, including differences in rotational freedom around the glycosidic bond, solubility in aqueous media, and thermodynamic parameters of hydrolysis. For example, the α-(1→6) linkage in isomaltose imparts higher conformational flexibility than the α-(1→4) linkage in maltose, resulting in altered solution dynamics and energetic profiles for bond cleavage. Similarly, the β-configuration in gentiobiose versus the α in isomaltose affects the overall polarity and hydrogen-bonding potential, influencing intermolecular interactions.

Physical and Chemical Properties

Physical Characteristics

Isomaltose appears as a to off-white crystalline powder, often in fine granular form, which is characteristic of its solid state at . The of isomaltose is 342.30 g/mol, consistent with its composition of two glucose units. Isomaltose exhibits high solubility in water, with a reported value of approximately 51 g per 100 mL at ambient conditions, making it readily dissolvable for aqueous applications; it is sparingly soluble in . Isomaltose has a reported melting point of 98–160 °C, similar to related disaccharides like . The specific of isomaltose is [α]_D +108° to +118° (c = 0.7 in ), reflecting its chiral and dextrorotatory nature. Isomaltose possesses a mildly sweet taste, approximately 30–50% that of , and is odorless, contributing to its neutral sensory profile in formulations.

Reactivity and Stability

Isomaltose functions as a due to the presence of a free group in its open-chain form, enabling it to react with oxidizing agents such as Benedict's or Fehling's reagents. This property arises from the α-(1→6) glycosidic linkage, which leaves one anomeric carbon available for tautomerization to the . Hydrolysis of isomaltose is catalyzed by α-glucosidases, resulting in the cleavage of the to yield two molecules of glucose. The reaction proceeds as follows: \text{C}_{12}\text{H}_{22}\text{O}_{11} + \text{H}_2\text{O} \rightarrow 2 \text{C}_6\text{H}_{12}\text{O}_6 Thermodynamic studies confirm this favors under standard conditions. Isomaltose exhibits stability in neutral environments but undergoes in acidic conditions, particularly at values below 4, where the rate increases due to of the glycosidic oxygen. This acid sensitivity is less pronounced compared to , owing to the α-(1→6) linkage, which results in a slower rate. Conversely, isomaltose can form during the of glucose at temperatures exceeding 100°C, as thermal polymerization rearranges glucose units into the . As a , isomaltose participates in oxidation reactions and Maillard browning, where its condenses with to produce melanoidins, contributing to color and flavor development in . This reactivity is particularly relevant in heated food systems, enhancing sensory attributes without enzymatic involvement.

Biological Significance

Natural Occurrence

Isomaltose is generated as an during the enzymatic of in the human gastrointestinal tract, primarily through the action of salivary and pancreatic α-amylases on . These enzymes hydrolyze the α-1,4 glycosidic bonds in the linear chains of amylopectin but also release isomaltose at the branch points where α-1,6 linkages predominate, yielding a mixture of products including , , and isomaltose alongside α-limit dextrins. In microbial systems, isomaltose appears during bacterial metabolism of or , where prokaryotic amylases similarly cleave α-1,6 branch points to produce it as a digestible . For instance, oral such as lactobacilli and streptococci, which contribute to formation, utilize or generate isomaltose through the breakdown of dietary starches, supporting their growth in carbohydrate-rich environments like the oral cavity. As a minor natural component, isomaltose is present in and fermented foods such as , , , and , where it forms via partial of by endogenous enzymes during processing or microbial . In these contexts, isomaltose acts as a foundational unit in isomaltooligosaccharides (IMOs), chains of α-1,6-linked glucose residues that occur at low levels in honey-derived and microbial fermentation products, contributing to their prebiotic-like properties.

Metabolic Pathways

In human digestion, isomaltose is hydrolyzed in the by the isomaltase, also known as α-1,6-glucosidase, which forms part of the sucrase-isomaltase complex embedded in the membrane of enterocytes. This enzymatic action cleaves the α-1,6-glycosidic bond, yielding two molecules of glucose that can be readily absorbed. The sucrase-isomaltase complex plays a crucial role in the terminal stages of digestion, ensuring efficient breakdown of dietary oligosaccharides like isomaltose derived from . The liberated glucose molecules are transported across the into the bloodstream via sodium-glucose linked transporter 1 (SGLT1) on the apical membrane and through GLUT2 on the basolateral side. Once in circulation, this glucose serves as a , entering cells where it is phosphorylated to glucose-6-phosphate and metabolized through in the , ultimately generating ATP via subsequent in mitochondria. This pathway underscores isomaltose's contribution to systemic following its complete . In certain bacteria, such as the cariogenic species Streptococcus mutans, isomaltose is metabolized intracellularly by α-glucosidases, including the dexB gene product, an exo-type glucan 1,6-α-glucosidase that hydrolyzes the α-1,6 linkage to release glucose. This utilization supports bacterial growth and acid production from fermented glucose, facilitating biofilm formation on tooth surfaces and contributing to dental caries pathogenesis. As a component of isomaltooligosaccharides (IMOs), longer-chain variants demonstrate prebiotic potential by partially resisting in the human due to the limited capacity of sucrase-isomaltase for chains beyond the , allowing them to reach the colon intact. There, longer-chain IMOs are selectively fermented by , particularly promoting the proliferation of beneficial genera like through production of such as and . This modulation enhances microbial diversity and supports host gut health without significant caloric contribution from upper gut digestion.

Production Methods

Enzymatic Synthesis

Enzymatic synthesis of isomaltose primarily involves the use of transglucosidase enzymes derived from to transfer glucosyl units from , forming α-1,6 glycosidic linkages characteristic of isomaltose. This process, first explored in the 1960s through studies on oligosaccharide formation from using α-glucosidases, laid the groundwork for laboratory-scale production of isomaltose and related isomaltooligosaccharides (IMOs). The reaction catalyzed by A. niger transglucosidase (EC 2.4.1.24) proceeds as follows: serves as both donor and acceptor, where one glucosyl unit is transferred to the non-reducing end of another molecule via an α-1,6 linkage, releasing glucose as a byproduct ( → isomaltose + glucose). This transglucosylation activity predominates under controlled conditions, producing isomaltose alongside higher IMOs like panose, with the exhibiting both hydrolytic and synthetic capabilities depending on concentration. In vitro reactions are typically optimized at 5-6 and temperatures of 50-60°C, using high-maltose syrup (typically 40-50% content) as the substrate to maximize yields. Under these conditions, transglucosidase incubation for 6-24 hours can achieve IMO yields of 40-50%, with isomaltose comprising a significant portion (up to 20-30%) of the product mixture after chromatographic purification. Alternative enzymatic approaches employ pullulanase or isoamylase to cleave α-1,6 branches in , generating linear precursors that enhance substrate availability for subsequent transglucosylation to isomaltose. These debranching enzymes, often sourced from bacterial strains like or , operate under similar and temperature ranges, contributing to overall laboratory yields by minimizing branched impurities.

Industrial Processes

Industrial production of isomaltose occurs primarily as a component within (IMO) mixtures derived from hydrolysates, enabling scalable manufacturing for food-grade applications. The process initiates with liquefaction using thermostable α-amylase, typically from , at temperatures exceeding 100°C to generate dextrins and maltodextrins. This is followed by employing fungal α-amylase and pullulanase at 55–60°C, yielding a high- with maltose concentrations of 60–70%. The high-maltose syrup undergoes transglycosylation catalyzed by transglucosidase (α-glucosidase with transglucosylating activity), commonly sourced from , to form α-1,6-glycosidic linkages, resulting in IMO mixtures containing 25–50% isomaltose alongside higher oligosaccharides like panose and isomaltotriose. In , where industrial production pioneered in the 1970s by firms such as Hayashibara Co., Ltd., immobilized transglucosidase enzymes were integrated into fixed-bed column reactors for continuous operation, enhancing efficiency and enzyme reusability since the introduction of products like Panorup™. Purification to isolate high-purity isomaltose involves applying the crude syrup to tall columns (bed depth ≥7 m) packed with strongly acidic cation exchange resins in sodium, , calcium, or magnesium forms. Hot elution at 45–85°C and space velocities of 0.1–2.0 fractionates the sugars, producing high-isomaltose eluates with ≥40% isomaltose content and recovery yields ≥70%; these fractions are then decolorized, deionized, concentrated via , and crystallized to achieve purities up to 98%. Global production of , of which isomaltose constitutes a significant portion, totals in the hundreds of thousands of tons annually. Quality assurance relies on (HPLC) with detection to quantify isomaltose purity, ensuring levels >98% in isolated products by separating it from glucose, , and other oligosaccharides. IMO mixtures, including isomaltose, have been affirmed as (GRAS) by the U.S. for use as food ingredients at levels comparable to , with similar approvals in and the .

Applications and Uses

Food and Beverage Industry

Isomaltose serves as a building block in isomaltooligosaccharides (IMOs), which are incorporated into functional foods for their prebiotic properties that promote the growth of beneficial gut bacteria such as bifidobacteria. Pure isomaltose itself is fully digestible and does not exhibit prebiotic effects, but IMOs containing isomaltose linkages provide partial resistance to digestion, allowing undigested portions to reach the colon for microbial fermentation. IMOs are commonly added to products like yogurts, cereals, and nutritional formulas at levels typically ranging from 2 to 15 g per serving to enhance digestive health without significantly altering taste or texture. In the sweetener category, exhibits approximately 30-60% of the sweetness of , making it suitable for reducing overall content in formulations while maintaining . Its low cariogenic potential stems from slow fermentation by oral bacteria, such as , which limits acid production and enamel demineralization compared to . This property positions isomaltose as a tooth-friendly alternative in confections, beverages, and oral care-integrated foods. During brewing, isomaltose forms as a minor byproduct of conversion by alpha-amylase enzymes in the process, contributing to beer's residual sweetness and since it is poorly assimilated by standard s. Engineered strains capable of utilizing isomaltose have been developed to produce low-carbohydrate beers with enhanced flavor profiles, reducing calories without compromising body. In , isomaltose serves as a low-calorie bulking agent in reduced-sugar goods, such as cakes and cookies, where it substitutes up to 100% of to lower energy density while preserving volume and texture. Pure isomaltose is primarily used in biochemical research and enzymatic assays, while commercial applications often involve IMO mixtures. Isomaltose-containing IMOs have received regulatory approval as food additives worldwide, including GRAS status in the United States since 2016, novel food authorization in the under Commission Implementing Regulation (EU) 2017/2470, and inclusion in Japan's Foods for Specified Health Uses (FOSHU) list since the 1980s. These approvals affirm their safety for use in food products at specified levels, supporting integration into diverse culinary applications.

Health and Pharmaceutical Uses

Isomaltooligosaccharides (IMOs), which include isomaltose as a component, exhibit prebiotic effects by selectively stimulating the growth of beneficial gut bacteria such as Bifidobacteria, supporting improved and enhanced immune function. Clinical studies have demonstrated that IMO supplementation increases Bifidobacteria abundance and short-chain production, contributing to better balance. Additionally, research in constipated elderly subjects showed that long-term intake of IMOs improved bowel movements and reduced symptoms in a time-dependent manner, with no adverse effects observed. IMOs have a reported glycemic index of approximately 30-40 in some studies, significantly lower than sucrose's , due to partial digestibility leading to slower glucose release. This property makes IMOs valuable for , resulting in reduced postprandial blood glucose spikes and potentially improved insulin sensitivity in models. Pure isomaltose, being fully digestible, has a glycemic response more akin to other disaccharides like . Isomaltose demonstrates weak antimicrobial potential by inhibiting pathogen growth in vitro, including strains like and , due to its bacteriostatic properties. This activity has led to its incorporation in oral care products, where it helps reduce formation by limiting cariogenic adhesion and acid production. Regarding , isomaltose is non-toxic and biodegradable, as it is naturally metabolized without accumulation. Regulatory bodies, including the FDA, have granted GRAS status to IMOs, affirming for daily intakes up to 30 g, with studies showing no adverse gastrointestinal effects even at single doses of 40 g. Unlike other polyols such as , IMOs exhibit minimal effects at these levels, making them suitable for regular consumption in health applications.