Fact-checked by Grok 2 weeks ago

Dextrose equivalent

The dextrose equivalent () is a quantitative measure of the degree of , defined as the of reducing sugars—expressed as dextrose (D-glucose)—in the total dry substance of the product. It serves as a key indicator of the average in -derived carbohydrates, with unhydrolyzed having a DE of 0 and pure dextrose a DE of 100. DE values determine the functional properties of glucose syrups, maltodextrins, and related products, profoundly affecting their performance in formulations. As DE increases, the proportion of short-chain glucose units rises, leading to enhanced , greater , reduced , increased hygroscopicity ( ), and higher fermentability, while anti-crystallization properties and textural stability decrease. For example, low-DE products (below 20) exhibit high and low , making them ideal for bulking without overpowering , whereas high-DE syrups (42–95) offer intense and low at typical solids concentrations (e.g., 71–85% solids). These characteristics enable diverse applications across the food and beverage industries, where DE guides product selection for specific functionalities. Low-DE maltodextrins stabilize foams and provide body in whipped toppings, dry mixes, and nutritional products, while intermediate-DE syrups (e.g., 42 DE) balance sweetness and body in ice creams and baked goods, often contributing to the for color and flavor development. High-DE variants (e.g., 63–95 DE) act as primary sweeteners in soft drinks, jams, and confections, enhancing flavor release and preventing in chocolates, with high-fructose corn syrups (derived from high-DE bases) dominating beverage formulations due to their concentrated .

Definition and Fundamentals

Definition

The dextrose equivalent (DE) is a measure of the percentage of reducing sugars in a starch-derived product, expressed relative to pure dextrose (D-glucose) on a dry basis, which indicates the extent to which the original starch polymers have been broken down into smaller saccharide units. This metric quantifies the reducing power of the hydrolysate, where higher DE values correspond to greater hydrolysis and a higher proportion of low-molecular-weight sugars capable of reducing oxidizing agents. Reducing sugars are carbohydrates that possess a free or group (or a that can equilibrate to form one), enabling them to donate electrons in reactions, such as those used in DE determination. In the context of DE, this reducing capacity arises primarily from the free anomeric carbon at the end of each saccharide chain in the , with the total reducing ends scaled to the equivalent of dextrose molecules. The DE value inversely relates to the average (DP), the mean number of glucose units per chain, following the approximate rule that DE × DP ≈ 120, providing a practical estimate of chain length in hydrolysates. For pure substances, DE values illustrate this scale: intact starch has a DE of approximately 0 due to negligible reducing ends, maltose (a disaccharide) has a DE of approximately 52 reflecting one reducing end per two glucose units, and pure dextrose has a DE of 100 as a monosaccharide with full reducing power per unit weight.

Relation to Starch Hydrolysis

Starch, the primary polysaccharide in plants, is composed of two main components: amylose, a linear polymer of α-D-glucose units linked by α-1,4 glycosidic bonds, and amylopectin, a highly branched structure with α-1,4 linkages in the chains and α-1,6 linkages at branch points. Hydrolysis of starch involves the cleavage of these glycosidic bonds, which generates new reducing ends on the resulting carbohydrate fragments; each reducing end contributes to the reducing sugar content, directly correlating with an increase in dextrose equivalent (DE) as hydrolysis progresses. This process quantifies the degree of breakdown, where the number of reducing ends per unit mass rises with the extent of bond cleavage, reflecting the transition from high-molecular-weight starch to lower-molecular-weight saccharides. The stages of starch hydrolysis correspond to distinct DE ranges, marking the progression from intact to monomeric glucose. Native exhibits a DE of approximately 0 due to its minimal reducing ends, while partial yields consisting of short chains. Further produces maltodextrins (DE 3–20), which retain some polymeric character, and eventually leads to full yielding glucose with a DE of 100, where every glucose unit acts as a . These stages illustrate how DE serves as a proxy for the average chain length reduction during . As DE increases, the resulting hydrolysates exhibit shorter average chain lengths, which enhance in and elevate osmolality due to the greater number of solute particles. This shift in functionality arises from the , making higher-DE products more suitable for applications requiring rapid dissolution or osmotic effects, while lower-DE variants maintain and structural properties closer to native . The DE also enables estimation of the number-average degree of polymerization (DP_n), which represents the average number of glucose units per chain and is empirically related to DE through the formula: \text{DP}_n = \frac{120}{\text{DE}} This approximation derives from the proportional relationship between reducing ends and total carbohydrate mass, assuming one reducing end per chain; for instance, a DE of 10 corresponds to a DP_n of about 12. Such calculations provide insight into the molecular weight distribution without direct structural analysis.

Production Methods

Acid Hydrolysis

Acid hydrolysis has been the traditional method for producing glucose syrups with defined dextrose equivalent (DE) values since the early . The process was pioneered in 1811 by Russian chemist Konstantin Gottlieb Sigismund Kirchhoff, who first demonstrated the conversion of to glucose using under heating, marking a foundational advancement in catalytic saccharification. Commercial production began in 1842, with significant scaling by 1857, establishing acid hydrolysis as the predominant technique for corn syrup manufacturing until the mid-20th century. The process begins with the preparation of a starch slurry, typically from corn, which is gelatinized by heating in water to swell the granules and disrupt their crystalline structure, facilitating subsequent bond cleavage. The gelatinized starch is then acidified to a pH of approximately 2 using dilute hydrochloric or sulfuric acid and subjected to hydrolysis in a pressurized converter at elevated temperatures, generally between 100°C and 150°C, to randomly break the α-1,4 and α-1,6 glycosidic bonds in the starch polymer. This reaction progresses over time, with the degree of hydrolysis controlled by duration, temperature, and acid concentration to achieve target DE values, typically up to 42-45 for standard syrups, beyond which excessive breakdown leads to undesirable side reactions. The simplified chemical reaction for partial hydrolysis can be represented as: (\ce{C6H10O5})_n + m \ce{H2O} \xrightarrow{\ce{H+}} \text{mixture of oligosaccharides and glucose} where m < n, yielding a syrup with a distribution of saccharides including dextrose, maltose, and higher oligosaccharides. Following hydrolysis, the mixture is neutralized, clarified to remove impurities, and concentrated by evaporation to produce the final syrup. Acid hydrolysis offers advantages in cost-effectiveness and simplicity, as it requires no specialized enzymes and can rapidly produce syrups with consistent saccharide profiles due to the random nature of bond cleavage. However, it operates under harsh conditions that promote side reactions, resulting in color formation from and bitterness from byproducts such as and , while providing limited control over the specific saccharide composition compared to alternative methods.

Enzymatic Hydrolysis

Enzymatic hydrolysis of starch to produce glucose syrups with specific (DE) values is a controlled biological process that utilizes specialized enzymes to break down starch polymers into oligosaccharides and monosaccharides. The process typically proceeds in two sequential steps: liquefaction and saccharification. During liquefaction, thermostable α-amylase, an endohydrolase, randomly cleaves the α-1,4-glycosidic bonds within amylose and amylopectin chains, reducing the starch slurry's viscosity and achieving a DE of 8-12. This step occurs under high-temperature conditions, often around 85-105°C and pH 5.5-6.5, to ensure gelatinization and partial hydrolysis without excessive degradation. Following liquefaction, the slurry is cooled to 50-60°C and adjusted to pH 4-5 for saccharification, where (amyloglucosidase) exo-hydrolizes the non-reducing ends of the dextrins to release glucose, potentially reaching DE values of 95-100. For syrups with tailored compositions, such as high-maltose variants at DE 40-50, is employed alongside debranching enzymes like , which specifically hydrolyzes α-1,6-glycosidic branch points in to improve accessibility and yield. operates optimally at 50-60°C and pH 4-5.5, enhancing overall efficiency by preventing steric hindrance during saccharification. These conditions align with the enzymes' stability profiles, minimizing inactivation while maximizing conversion rates over 24-72 hours. This method offers advantages over alternative approaches, including greater specificity for desired saccharide profiles, resulting in clearer, milder-flavored syrups with reduced off-colors and bitterness. It enables precise control for applications requiring particular DE levels, such as high-glucose syrups. However, enzymatic processes incur higher costs due to enzyme pricing and require longer processing times compared to chemical methods. Introduced commercially in the 1960s with the advent of , enzymatic hydrolysis has become the dominant technique for producing high-DE syrups, particularly as precursors for high-fructose corn syrup through subsequent isomerization.

Measurement and Calculation

Traditional Titration Methods

Traditional titration methods for determining dextrose equivalent (DE) rely on the reducing power of sugars, where reducing sugars in starch hydrolyzates reduce copper(II) ions in an alkaline medium to copper(I) oxide, with the amount quantified relative to pure dextrose. These classical assays, developed in the early 20th century, provide a standardized measure of DE as the percentage of reducing sugars expressed as dextrose on a dry basis. The Lane-Eynon method, a volumetric titration procedure, is the most widely adopted traditional approach for DE measurement. In this method, a sample of the hydrolyzate—typically 3 g for refined sugars, adjusted to yield approximately 0.6% reducing sugars—is dissolved in hot water, cooled, and diluted to 500 mL in a volumetric flask. A 25.0 mL aliquot of Fehling's solution (prepared by mixing equal parts of copper sulfate solution and alkaline tartrate solution) is boiled in an Erlenmeyer flask with glass beads to prevent superheating, and the diluted sample is added dropwise from a burette until the endpoint is reached, indicated by the disappearance of the blue color of methylene blue after 2 minutes of boiling. The Fehling's solution is standardized against a 0.6% pure dextrose solution from the National Institute of Standards and Technology (NIST). The DE is calculated as: \text{DE} = \frac{(\text{Sample titer, mL}) \times 0.1200 \times 500}{(\text{Sample weight, g})} \times \frac{100}{\text{Dry substance, \%}} where the factor 0.1200 derives from the standardization equivalent to milligrams of dextrose per milliliter of titer. This method ensures the sample titer falls between 15 and 25 mL, ideally 19 to 21 mL, for optimal precision. The Lane-Eynon method is standardized in ISO 5377:1981 and related AOAC procedures. A variant, the Munson-Walker method, employs a gravimetric endpoint instead of volumetric titration, offering similar copper reduction principles but with direct weighing of the precipitated copper(I) oxide. Here, 50 mL of sample solution is mixed with 25 mL each of copper sulfate and alkaline tartrate solutions, boiled for 2 minutes, filtered through a Gooch crucible with asbestos, washed with hot water, alcohol, and ether, and dried at 100°C before weighing the cuprous oxide. The mass of copper reduced is converted to reducing sugar equivalents using empirical tables or equations specific to dextrose, such as x = \frac{1776.34 y}{3707.48 - y + 0.006585 (440.9 - y)}, where x is milligrams of dextrose, y is milligrams of copper reduced, and constants are calibrated for accuracy with Y_1 = 440.9 mg total copper. Developed in 1906 and refined in 1940 with purer standards, this method unifies earlier copper-based assays for dextrose and invert sugars. Both methods exhibit good repeatability, with differences between duplicate analyses by the same analyst not exceeding 0.75% of the mean DE value, and reproducibility across laboratories limited to 1.5% of the mean. However, they are time-consuming, requiring careful boiling control and multiple steps, and susceptible to interferences from non-sugar reducing substances or high fructose content, which can skew results; accuracy is typically within ±1 DE unit under ideal conditions but degrades with improper sample preparation. These limitations have led to the adoption of faster instrumental techniques in modern laboratories.

Modern Analytical Techniques

Enzymatic assays represent a key modern approach for precise quantification of glucose in starch hydrolysates, directly contributing to DE assessment by measuring the primary reducing sugar component. These assays typically employ glucose oxidase and peroxidase enzymes: glucose oxidase selectively oxidizes β-D-glucose to D-gluconic acid and hydrogen peroxide, while peroxidase couples the peroxide with a chromogenic substrate like o-dianisidine to produce a measurable color change at 510 nm. This GOPOD (glucose oxidase-peroxidase-o-dianisidine) format is highly specific for free glucose, making it ideal for high-DE glucose syrups and partial starch hydrolysates, with a linear range of 4–100 μg glucose per assay and inter-assay precision below 3.6% RSD. Enzymatic assays are primarily suited for free glucose in high-DE products. For low-DE products, total reducing sugars are better assessed via chemical reduction methods or HPLC, as direct enzymatic measurement of oligosaccharide reducing ends is limited. High-performance liquid chromatography (HPLC) offers detailed profiling of saccharide distributions in hydrolysates, facilitating DE calculation through separation and quantification of individual components relative to a dextrose standard. Employing size-exclusion or anion-exchange columns with refractive index detection, HPLC separates oligosaccharides by degree of polymerization (1 to DP>10), where DE is computed as the weighted sum of each saccharide's multiplied by its reducing power factor (1 for glucose, decreasing for higher DP). The AOAC Official Method 979.23 specifies an HPLC protocol for major saccharides (e.g., glucose, , ) in , achieving repeatability with coefficients of variation under 1% and overall DE accuracy of ±0.5 units for industrial samples. This method's specificity surpasses traditional approaches by distinguishing isomeric sugars and minimizing interferences, supporting high-throughput analysis of up to 20 samples per hour. Automated HPLC systems per AOAC 979.23 are increasingly used in industry as of 2025. In production environments, refractive index (RI) detectors and polarimeters enable real-time online monitoring of DE progression during enzymatic or acid . RI instruments measure changes in solution correlated to total soluble solids and hydrolysis extent, providing indirect estimates with sub-minute response times and precision of ±0.1 units, adaptable to starch processing lines. Polarimetry complements this by detecting shifts in ([α]_D) due to varying saccharide compositions—e.g., +52.7° for dextrose versus lower values for maltodextrins—allowing continuous tracking of conversion efficiency. These integrated systems enhance process control, reduce downtime, and align with AOAC and ISO guidelines for , such as ISO 10504 for related analyses. These techniques offer high specificity, such as distinguishing glucose from maltose via HPLC, and support high-throughput analysis, with DE accuracy often ±0.5 units in controlled settings.

Properties and Classification

Physical and Chemical Properties

The physical properties of starch hydrolysates, such as maltodextrins and glucose syrups, are profoundly influenced by their dextrose equivalent (DE) value, which reflects the degree of starch hydrolysis and the resulting molecular weight distribution. Solubility in water generally increases with higher DE values, as greater hydrolysis yields shorter glucose chains that dissolve more readily; for instance, low-DE maltodextrins (DE < 20) exhibit limited solubility at room temperature, for example approximately 15% for DE 10, whereas high-DE syrups (DE > 60) are fully miscible even at elevated concentrations. Similarly, viscosity decreases as DE rises due to the reduced chain length and lower molecular entanglement; solutions of low-DE products (e.g., DE 10) display significantly higher viscosity than those of moderate-DE variants (e.g., DE 40), impacting their flow behavior in processing. Hygroscopicity, or the tendency to absorb , also escalates with increasing , attributable to a higher proportion of free hydroxyl groups on the shorter chains that facilitate . High-DE corn syrups thus serve as effective humectants in formulations requiring retention, while low-DE maltodextrins are comparatively less prone to clumping in dry states. Chemically, the reducing power of these hydrolysates is intrinsically linked to their value, as it quantifies the concentration of end groups capable of reducing agents like (II) ions in standard assays; each hydrolyzed chain contributes one reducing end, making higher-DE products richer in reactive functionalities relative to dextrose. This elevated reducing capacity in high-DE variants enhances their participation in the , promoting faster browning and flavor development when heated with proteins or , in contrast to low-DE products with fewer such sites per unit mass. Regarding thermal stability, low-DE hydrolysates (DE < 20) exhibit a greater propensity for retrogradation upon heating and cooling, where linear fractions reassociate into crystalline structures, potentially forming gels or in solutions; this behavior stems from their longer chains, which facilitate intermolecular hydrogen bonding during temperature fluctuations. High-DE products, conversely, resist such gelation due to their oligomeric nature, maintaining clarity and fluidity under similar conditions.

Classification by DE Value

Starch hydrolysates are categorized by their value into low, medium, and high ranges, each defining specific product types with characteristic saccharide compositions that reflect the extent of starch breakdown. Low DE products, with values from 0 to 20, encompass and . typically exhibit DE values of 1 to 13 and consist predominantly of higher molecular weight with minimal reducing sugars. , defined under U.S. regulations as having DE values of 3 to 20, are composed of more than 90% saccharides with a greater than 5, resulting in low sweetness and high content; for example, a 10 DE contains approximately 1% DP1, 3% DP2, and 90% DP5+. Medium DE products, ranging from 20 to 45, are classified as glucose syrups and feature a balanced profile of approximately 20-40% glucose alongside oligosaccharides such as and . For instance, a DE glucose syrup typically includes about 19% glucose, 14% , and higher saccharides making up the remainder. High DE products, with values from 45 to 100, include high-conversion syrups and dextrose. High-conversion syrups, such as those with DE 60, contain roughly 60% glucose with reduced levels of longer oligosaccharides; a representative 63 DE syrup has 36% glucose, 31% , and 20% DP4+. Dextrose monohydrate achieves a DE of 99 or higher, comprising nearly 100% glucose. In industry nomenclature, spray-dried forms of low DE hydrolysates (DE < 20) are often referred to as solids, distinguishing them from liquid syrups while maintaining similar compositions. These DE-based categories correspond to progressive shifts in properties like increasing and with higher DE values.

Applications and Uses

In Food and Beverage

Dextrose equivalent (DE) products, such as glucose syrups and maltodextrins derived from starch hydrolysis, play a crucial role in food and beverage manufacturing by modulating sweetness levels. High-DE syrups (DE 40 and above) serve as effective sucrose replacers due to their increasing proportion of reducing sugars, with DE 42 syrups offering approximately 45-50% the sweetness of sucrose and DE 62 syrups providing 60-70% relative sweetness, making them suitable for beverages and candies where balanced flavor is desired. For instance, high-fructose corn syrups (HFCS) with DE values around 42 exhibit sweetness comparable to sucrose (100% relative), while HFCS-55 reaches 100-110%, enabling their widespread use in soft drinks to achieve desired taste profiles without excessive caloric density. These syrups contribute fermentable sugars that enhance flavor development during processing. In terms of texture and , low-DE products like maltodextrins (DE 5-10) function as fat mimetics and stabilizers, imparting body and in reduced-fat formulations such as low-calorie dressings and products. Their high molecular weight provide and prevent , while also inhibiting to maintain smooth textures in frozen desserts like , where they reduce ice crystal formation for improved creaminess. DE 28-36 syrups further enhance by offering high humectancy, which resists and extends in moisture-sensitive foods. For baking and confectionery applications, intermediate-DE syrups (DE 20-30) are valued for their properties, retaining moisture in products like and cakes to prevent staleness and maintain softness over time. In , DE 42-62 syrups promote the for desirable browning and flavor, while in , DE 28-42 variants control texture by interfering with in hard candies and jams, ensuring a glossy finish and pliability. These properties allow for consistent quality in humid environments. High-DE syrups (DE 60+) are particularly important in fermentation processes, acting as readily available yeast substrates in baking and brewing due to their high content of monosaccharides like dextrose, which are 95% fermentable and accelerate dough rising or alcohol production. For example, DE 62 syrups yield about 70% fermentable extract, supporting efficient yeast metabolism in breadmaking and beer production without residual sweetness interference. This fermentability enhances product volume and flavor complexity in fermented foods and beverages.

In Pharmaceuticals and Other Industries

In pharmaceuticals, high-DE dextrose, particularly in the form of 5% intravenous solutions, serves as a critical component in to treat by rapidly elevating blood glucose levels. These solutions are administered parenterally to provide immediate energy and prevent complications in patients with low blood sugar, such as those with or undergoing . Additionally, dextrose monohydrate functions as a and filler in tablet formulations, enhancing compressibility and disintegration while contributing mild sweetness to chewable or effervescent products. Low-DE maltodextrins, typically with DE values below 20, are employed in controlled-release matrices due to their film-forming properties and ability to modulate , providing sustained release profiles in oral . In , with DE values of 10-15 act as effective carriers for flavors and essential oils in formulations, enabling through spray-drying to improve stability and controlled release of volatile compounds. These low-to-medium DE variants form protective matrices that prevent oxidation and evaporation of essential oils, such as those derived from lavender or , while maintaining product texture in powder-based . Their and facilitate even distribution in emulsions, enhancing sensory attributes without altering the final product's aesthetic. Beyond pharmaceuticals and cosmetics, low-DE dextrins find utility in industrial adhesives for paper products, where they provide strong bonding to cellulosic materials like and envelopes due to their high wet tack and clean machining properties. In the textile sector, these dextrins serve as binders and agents, improving fabric cohesion and during processes. High-DE dextrose syrups, often with DE values approaching 95, are integral to media for production, such as penicillin, acting as a primary carbon source that supports microbial growth and yield in submerged cultures. In medical devices, low-DE starch hydrolysates (DE 13-17) are incorporated into wound gel dressings combined with glycerine to provide a biocompatible matrix that maintains a moist environment, promotes tissue repair, and aids in managing exudate in chronic wounds like pressure ulcers.

Regulations and Health Aspects

Regulatory Standards

In the United States, the Food and Drug Administration (FDA) regulates glucose syrups, which are defined under 21 CFR 168.120 as purified, concentrated aqueous solutions of nutritive saccharides from edible starch with a dextrose equivalent (DE) of not less than 20%, expressed as D-glucose on a dry basis, and a total solids content of not less than 70% mass/mass (m/m). For dried glucose syrups under 21 CFR 168.121, the total solids must be at least 93% m/m when the DE is less than 88%, or at least 90% m/m when the DE is 88% or higher. Purity requirements include sulfated ash not exceeding 1.0% m/m (dry basis) and sulfur dioxide not more than 40 mg/kg. The Commission establishes international standards for sugars, including under CXS 212-1999, requiring a of not less than 20% m/m (as D-glucose, dry basis) and total solids of at least 70% m/m for liquid forms, with dried variants at 93% m/m solids. Contaminant limits align with general guidelines, such as (e.g., lead not exceeding 0.1 mg/kg in syrups) and microbial criteria for food-grade materials, including absence of pathogens like and limits on total plate count to ensure hygiene. In the , s generally follow Codex standards for composition ( ≥20% and solids ≥70%), supplemented by (EC) No /2006 setting maximum levels for contaminants like lead (≤0.1 mg/kg in sugars) and cadmium, alongside microbial limits under (EC) No 2073/2005 for . Labeling is governed by (EU) No 1169/2011. Standardized testing methods ensure compliance for , with the Association of Official Analytical Chemists (AOAC) recommending the Lane-Eynon for DE determination based on content, as detailed in historical methods like AOAC 945.66, though modern adaptations follow Corn Refiners Association Method E-26 for corn syrups. The (ISO) provides ISO 10504:2013 for DE measurement via copper , facilitating consistent quality assessment. Labeling requirements do not mandate declaration of the exact DE value in most cases, but U.S. regulations under 21 CFR 168.120 require indication of the nominal and source material if not corn-derived. In the EU, per Regulation (EU) No 1169/2011, products are labeled as "" if fructose is below 5% (), with "" implying typical DE ranges of 20-45 without explicit numerical disclosure, focusing instead on ingredient listing and information.

Nutritional and Health Implications

Dextrose equivalent (DE) products, such as glucose syrups and maltodextrins, provide approximately 4 kcal per gram as digestible carbohydrates, similar to other sugars, since they are hydrolyzed to glucose in the body. However, their digestion rate varies by value; low-DE maltodextrins (DE <20) are broken down more slowly than high-DE variants, resulting in a (GI) typically ranging from 85 to 105, with even lower values for DE below 10 due to their longer chain lengths that delay absorption and moderate blood sugar spikes. Resistant low-DE maltodextrins (e.g., DE 5-15), particularly those with DE 5-10, exhibit prebiotic properties by resisting complete digestion and reaching the colon, where they promote beneficial such as and through selective . This modulation supports gut health by enhancing microbial diversity and short-chain fatty acid production. Additionally, maltodextrins demonstrate reduced cariogenicity compared to , as they produce less acid during bacterial in the oral cavity, lowering the risk of enamel demineralization. A 2023 study on resistant maltodextrin (a low-DE fraction) found it suppresses excessive calorie intake and boosts appetite-regulating gut hormones like GLP-1, further aiding metabolic balance through microbiota alterations. High-DE products, akin to glucose or high-fructose syrups, contribute to risks when consumed excessively, mirroring the effects of other added sugars by promoting rapid insulin responses, , and , which elevate and risk. Their prevalence in ultra-processed foods often leads to hidden intake, exacerbating these issues through overconsumption. The recommends limiting free sugars—including high-DE syrups—to less than 10% of total daily energy intake to mitigate such metabolic disorders.

References

  1. [1]
    [PDF] Dextrose Equivalent (Lane and Eynon) - Corn Refiners Association
    Dextrose equivalent is defined as "reducing sugars expressed as dextrose and calculated as a percentage of the dry substance."
  2. [2]
    Dextrose Equivalent - an overview | ScienceDirect Topics
    Dextrose equivalent (DE) refers to a measure of the reducing power of glucose syrups derived from starch, indicating the length of the chain of glucose residues ...
  3. [3]
    Dextrose Equivalent (DE) Explained | callebaut.com
    How DE Affects the Properties of Glucose Syrups ; Increases, Viscosity, Decreases ; Increases, Influence on textural stability, Decreases ; Increases, Water ...Missing: applications uses<|control11|><|separator|>
  4. [4]
    [PDF] Sweeteners from Starch: Production, Properties and Uses
    Dextrose equivalent. 35.4. 42.9. 53.7. 75.4. 85. 60. 457 000. 80. 7 080 000. 1 410 000 ... trial applications. The ability of yeast to ferment starch-derived ...
  5. [5]
    Sweetness Explained | Sweeteners - Cargill
    Dextrose Equivalent (DE). This is a measure of the degree of starch break down (hydrolysis), and is used as a general way of identifying different glucose ...
  6. [6]
    Monosaccharide Diversity - Essentials of Glycobiology - NCBI - NIH
    Aldoses and ketoses were historically referred to as “reducing sugars” because they responded positively in a chemical test that effected oxidation of their ...
  7. [7]
    [PDF] Starch Dictionary - Agro by Nature
    ... average degree of polymerization (DP) of the starch hydrolysate. The product. DE x DP (average) is about 120. ... Dextrose Equivalent (DE) between 5 and. 20 ...
  8. [8]
    Characterization of Destrins with Different Dextrose Equivalents - NIH
    The extent of hydrolysis is normally expressed in terms of the ''dextrose equivalent''(DE), a quantity usually determined by titration and a measure of the ...Missing: definition | Show results with:definition
  9. [9]
    Dextrose equivalent values (DE) of the most common sugars
    Sep 2, 2021 · Dextrose equivalent (DE) is a measure of the amount of reducing sugars present in a sugar product, expressed as a percentage on a dry basis ...
  10. [10]
    [PDF] Properties and applications of starch-converting enzymes of the
    Oct 25, 2017 · This group is known as the reducing end. Two types of glucose polymers are present in starch: (i) amylose and (ii) amylopectin. Amylose is a ...
  11. [11]
    Exploring the Equilibrium State Diagram of Maltodextrins ... - NIH
    Their structure and properties are determined by the degree of polymerization (DP) and the extent of hydrolysis, reflected in the dextrose equivalent (DE).
  12. [12]
    Physicochemical characterization of dextrins prepared with ...
    Nov 15, 2013 · Dextrins are starch hydrolysis products obtained by acid or enzymatic hydrolysis 1. They are defined by a dextrose equivalent (DE), which is a ...
  13. [13]
    Starch Hydrolysate - an overview | ScienceDirect Topics
    maltodextrins are defined as nonsweet, nutritive starch hydrolysates (consisting of glucose units linked primarily by α1-4 bonds) with DE values less than 20.
  14. [14]
    [PDF] STARCH PRODUCTION OF DEXTRINS AND MALTODEXTRINS
    Maltodextrins are classified by DE (dextrose equivalent) and have a DE between 3 to 20. The higher the DE value, the shorter the glucose chains, the higher ...
  15. [15]
    Lignocellulose saccharification: historical insights and recent ...
    Jan 27, 2025 · In 1811, the Russian chemist Gottlieb Kirchhoff hydrolyzed starch for the first time, by the action of sulfuric acid under heating, and the ...
  16. [16]
    [PDF] Nutritive Sweeteners From Corn - Corn Refiners Association
    While potatoes served as the early source for starch and syrup, dextrose ... Dextrose Equivalent. 55. 60. 65. 70. 40. 45. 50. 10. 20. 30. 40. 50. Dextrose. Higher ...Missing: origin | Show results with:origin
  17. [17]
    Commercial preparation of Liquid Glucose: The Process - HL Agro
    Sep 19, 2016 · The corn syrup can be obtained through two processes: enzyme hydrolysis or acid hydrolysis. It can also be obtained by using the two processes ...
  18. [18]
    US3663369A - Hydrolysis of starch - Google Patents
    Accordingly, acid hydrolysis is not well suited for making a low D.E. product, i.e., one having a D.E. value below about 30. Although the degree of hydrolysis ...
  19. [19]
    [PDF] One Hundred Years of Commercial Food Carbohydrates in the ...
    Before 1938, corn syrups were produced exclusively by acid- catalyzed hydrolysis of corn starch and, as a result, suffered from off-flavors and color. A ...
  20. [20]
    Enzymatic hydrolysis of wheat starch for glucose syrup production
    The enzymatic hydrolysis consists of three main stages: gelatinization, liquefaction, and saccharification [6] . This stage is of great importance because, ...
  21. [21]
    Optimization of a Simultaneous Enzymatic Hydrolysis to Obtain a ...
    Jun 17, 2022 · For alcohol production, a first phase of starch hydrolysis is necessary to obtain a glucose syrup. This hydrolysis usually consists of two ...<|control11|><|separator|>
  22. [22]
    Pullulanase with high temperature and low pH optima improved ...
    Dec 19, 2022 · In order to meet the criteria necessary for starch saccharification, pulllulanase that has a temperature optimum of 60 °C or higher and pH ...
  23. [23]
    Glucose syrup production through enzymatic methods and acid ...
    Oct 21, 2024 · The enzymatic method was proven to be more effective in producing high returns compared to acid hydrolysis. Moreover, the key factors to be ...
  24. [24]
    High-fructose corn syrup production and its new applications for 5 ...
    High fructose corn syrup has been industrially produced by converting glucose to fructose by glucose isomerases, tetrameric metalloenzymes widely used in ...
  25. [25]
    [PDF] Redetermination of the Munson-Walker reducing-sugar values
    In 1906, Munson and Walker [7] surveyed the various methods and proposed one to unify all the others for the determination of dextrose, invert sugar, and two ...Missing: AOAC | Show results with:AOAC
  26. [26]
    [PDF] ISO-5377-1981.pdf - iTeh Standards
    The results of two determinations carried out in rapid succes- sion by the same analyst shall not differ by more than 0,75 % of their arithmetic mean. 8.3 ...
  27. [27]
    D-Glucose Assay Kit (GOPOD Format)
    ### Summary of D-Glucose Assay Kit (GOPOD Format)
  28. [28]
    Validation of Enzytec™ Liquid D-Glucose for Enzymatic ... - NIH
    Conclusions. The method is robust and accurate for manual and automated applications. The method was approved as AOAC Official Method of Analysis℠.
  29. [29]
    AOAC INTERNATIONAL - In Food & Agriculture, We Set the Standard
    AOAC INTERNATIONAL provides the platform, processes, and scientific rigor that enable industry and regulators to keep our food and environment safe.About AOAC · Official Methods of Analysis · AOAC Programs · Join AOACMissing: dextrose equivalent<|control11|><|separator|>
  30. [30]
    [PDF] Analysis of Saccharides in Low-Dextrose Equivalent Starch ...
    HPLC separates saccharides by chain length, using a Waters 6000A pump, HPX-42A column, and a RI detector. Quantitation uses sugar standards.
  31. [31]
    An Inline Refractive Index Analyzer for Measuring Sugar Content in ...
    The Electron Machine MPR E-Scan™ provides inline refractive index measurement of cane sugar, HFCS (High-Fructose Corn Syrup), or beet sugar concentration in ...
  32. [32]
    Establishment of a Refractive Index Approach for Assessing Starch ...
    Nov 3, 2025 · In this study, starch characteristics and in vitro enzymatic hydrolysis in three rice (Oryza sativa L.) mutants (RSML 184, RSML 278 and RSML ...
  33. [33]
    Determination of Dextrose Equivalent Value and Number Average ...
    Jan 21, 2009 · ABSTRACT: Dextrose equivalent (DE) value is the most common parameter used to characterize the molecular weight of maltodextrins.Abstract · Introduction · Materials and Methods · Results and Discussion
  34. [34]
    [PDF] Sweeteners from Starch: Production, Properties and Uses
    bed, the fructose portion is selectively absorbed relative to dextrose, resulting in sep- ... Dextrose equivalent. 35.4. 42.9. 53.7. 75.4. 85. 60. 457 000. 80. 7 ...
  35. [35]
    Effect of Dextrose Equivalent on Maltodextrin/Whey Protein Spray ...
    Dec 17, 2020 · This study aimed to investigate the effects of maltodextrin (MD) with different dextrose equivalent (DE) values on retention of flavor substances during ...
  36. [36]
    [PDF] Corn Syrups: Clearing up the Confusion
    Hygroscopicity—The ability of corn sweeteners to absorb moisture increases with increasing DE. This property makes corn syrups useful as moisture conditioners, ...
  37. [37]
    Dextrin characterization by high-performance anion-exchange ...
    The hydrolysis products are typically characterized by the "dextrose equivalent" (DE), which refers to the total reducing power of all sugars present relative ...
  38. [38]
    Dextrin - an overview | ScienceDirect Topics
    Maltodextrins are those products having DE values of less than 20, generally DE 5–19. Syrup solids are those products of starch hydrolysis with DE values of ...
  39. [39]
    https://www.grainprocessing.com/news-insights/spray-drying-solutions-from-gpc
  40. [40]
    [PDF] 3 Production and Description - Cereals & Grains Association
    The lower the extent of hydrol- ysis, the lower the DE. Dextrose syrups, which have a high DE (95 and greater), are often referred to as liquid dextrose.
  41. [41]
    Spray Drying Solutions from GPC - Grain Processing Corporation
    Mar 1, 2021 · Maltodextrin or corn syrup solids function as an easy-to-dry, glassy solids builder. Generally, low DE MALTRIN® maltodextrins are favored as ...
  42. [42]
    [PDF] Sweet Options
    The term DE (dextrose equivalent) is commonly used to convey relative ... “Solubility is about 30% at room temperature, increasing to the same level as ...
  43. [43]
    Dextrose: Side Effects, Dosage & Uses - Drugs.com
    Nov 18, 2024 · Dextrose is used to treat very low blood sugar (hypoglycemia), most often in people with diabetes mellitus.<|control11|><|separator|>
  44. [44]
    Determination That Dextrose, 20 Grams/100 Milliliters, and Dextrose ...
    Aug 20, 2019 · This determination will allow FDA to approve abbreviated new drug applications (ANDAs) for Dextrose, 20 g/100 mL, and Dextrose, 50 g/100 mL ...
  45. [45]
    Dextrose Monohydrate: What is it and where is it used? - Drugs.com
    May 16, 2025 · Dextrose (C6H12O6), also known as corn sugar, is a common binder used in the pharmaceutical industry. Binders are added to tablet formulations ...
  46. [46]
    Dextrose Monohydrate as a filler or filler/binder - Roquette
    Dextrose monohydrate provides key excipient and nutrient benefits as a filler/binder and as a carbohydrate source.
  47. [47]
    The characteristic and application of maltodextrin - ChemicalBook
    Brief overview of uses of Maltodextrin. The main aim of novel drug delivery is to achieve targeted and controlled drug release. The encapsulation of drug in a ...
  48. [48]
    [PDF] A REVIEW ON APPLICATIONS OF MALTODEXTRIN IN ...
    Controlled release of core drug material. 4. Improved processing and texture ... Maltodextrin with low DE value has shown to impart flexibility and.
  49. [49]
    Essential oil encapsulation by electrospinning and electrospraying ...
    This review addresses the main proteins used in electrospinning/electrospraying techniques, production methods, their interactions with EOs, bioactive ...
  50. [50]
    Formulation and Evaluation of Spray-Dried Reconstituted Flaxseed ...
    Maltodextrin: starch: flaxseed oil emulsions with FOCE or distilled water as liquid phases, and 10% and 20% of oil were spray-dried at 180 °C. The solubility, ...<|separator|>
  51. [51]
    https://www.echemi.com/cms/1676003.html
  52. [52]
    Adhesive Glue – Dextrin Glue | USAdhesive.com
    Dextrin adhesives provide clean machining and excellent bonding properties to cellulosic materials, such as paper and paperboard. They exhibit high wet tack ...Missing: DE textiles
  53. [53]
    Our Products - GAEL - Gujarat Ambuja Exports Limited
    Rating 4.9 (10) In the paper and textile industries, dextrins serve as effective binders, adhesives, and coatings due to their excellent adhesive properties. Moreover, their ...
  54. [54]
    How do dextrose anhydrous manufacturers put their products to ...
    Feb 7, 2024 · Penicillin fermentation uses dextrose anhydrous liquid with a high DE value as the substrate, and crystallized dextrose anhydrous mother ...
  55. [55]
    Fermentation processes and the use of glucose syrup DE 95 in ...
    Fermentation uses glucose as a carbon source, often with DE95 glucose syrup. It produces antibiotics, enzymes, amino acids, citric acid, and vitamin C.
  56. [56]
    Prolotherapy: Potential for the Treatment of Chronic Wounds? - PMC
    Topical application of 50% glucose solution, in combination with negative pressure therapy is reported to hasten wound bed granulation tissue formation in ...
  57. [57]
    Role of Prolotherapy in Pressure Ulcer - Clinical Surgery Journal
    In vitro studies have shown that even concentrations as low as 5% dextrose have resulted in the production of several growth factors critical for tissue repair.
  58. [58]
    Method and compound for treating wounds with starch hydrolysate ...
    A gel composition for treating a wound in a patient, the gel composition having a continuous phase of starch hydrolysate, sterile water, and a dispersed phase ...
  59. [59]
    21 CFR 168.120 -- Glucose sirup. - eCFR
    (1) The total solids content is not less than 70.0 percent mass/mass (m/m), and the reducing sugar content (dextrose equivalent), expressed as D-glucose, ...
  60. [60]
    21 CFR § 168.121 - Dried glucose sirup.
    (2) The total solids content is not less than 93.0 percent m/m when the reducing sugar content, (dextrose equivalent) expressed as D-glucose, is less than 88.0 ...Missing: FDA | Show results with:FDA
  61. [61]
    [PDF] CODEX STANDARD FOR SUGARS
    Glucose syrup has a dextrose equivalent content of not less than. 20.0% m/m (expressed as D-glucose on a dry basis), and a total solids content of not less than ...Missing: DE | Show results with:DE
  62. [62]
    [PDF] STANDARD FOR SUGARS1 CXS 212-1999 Adopted in 1999 ...
    SCOPE AND DESCRIPTION. This Standard applies to the following sugars intended for human consumption without further processing.Missing: DE | Show results with:DE
  63. [63]
    [PDF] Corn Syrup Analysis E-26-1
    The Lane and Eynon method is described here, whereby a reducing sugar solution is used to titrate a fixed volume of standard copper sulfate in alkaline ...
  64. [64]
    EU Labeling and Legislation for Cereal Sweeteners - Cargill
    Glucose syrups and glucose-fructose syrups are regulated under the EC Directive 2001/111/EC relating to certain sugars intended for human consumption.<|separator|>
  65. [65]
    [PDF] Maltodextrins
    Derived from conventional (non GMO) crops such as wheat, potatoes and maize, maltodextrins are obtained through the partial hydrolysis of starch. Especially ...Missing: 90% DP<|control11|><|separator|>
  66. [66]
    Feeding with resistant maltodextrin suppresses excessive calorie ...
    Consuming resistant maltodextrin (RMD) decreases food intake and increase appetite-related gut hormones, but the underlying mechanisms have remained unknown.
  67. [67]
    Resistant Maltodextrin Intake Reduces Virulent Metabolites in the ...
    May 3, 2022 · This study aimed to quantify the effects of RMD on the intestine, especially the intestinal microbiome and metabolome profiles.
  68. [68]
    Maltodextrin and dental caries: a literature review - SciELO
    Maltodextrin's role in dental caries is unclear, but it has a lower acidogenic potential than sucrose. Studies on its association with other sugars are scarce.
  69. [69]
    The role of dietary sugars, overweight, and obesity in type 2 ... - Nature
    Mar 21, 2022 · Current scientific evidence clearly points toward excess energy intake followed by excess body fat gain being most relevant in the development of T2DM.
  70. [70]
    Guideline: sugars intake for adults and children
    Mar 4, 2015 · This guideline provides updated global, evidence-informed recommendations on the intake of free sugars to reduce the risk of NCDs in adults and children.