585-88-6 Usage
Description
Maltitol is a low-caloric artificial sweetener, consisting of a sugar alcohol (polyol), and is a disaccharide sugar alcohol derived from maltose by hydrogenation. It is a white, odorless, sweet, anhydrous crystalline powder with a solubility in water of approximately 1,750 g/L at room temperature. Maltitol is stable under common food processing conditions and is approximately 90% as sweet as sucrose. It is noncariogenic and has good stability.
Uses
Used in Chewing Gum:
Maltitol is used as a sweetener for chewing gum due to its sweetness and stability.
Used in Dry Nut Bakery Products:
Maltitol is used as a sweetener in dry nut bakery products because of its nonhygroscopic nature and sweetness.
Used in Chocolate:
Maltitol is used as a sweetener in chocolate, providing a similar level of sweetness as sucrose without the negative effects on dental health.
Used as a Flavor Enhancer:
Maltitol is used as a flavor enhancer in various food and beverage products, such as fruit, vanilla, and chocolate flavors. It modifies the inherent flavors without contributing its own distinct flavor. It is used in beverages and desserts with a typical usage range of 10–200 ppm.
Used in the European Union:
In the European Union, maltitol is approved as E 965 for a large number of food applications.
Used in the United States:
Maltitol is Generally Recognized As Safe (GRAS) in the United States and is also approved in many other countries.
Used in Commercial Production:
Maltitol is produced on a commercial scale by hydrogenation of corn syrup with high maltose content, which is prepared by enzymatic hydrolysis of starch. The resulting crystalline product has a maltitol content of between 90 and 99%, along with small amounts of sorbitol and hydrogenated trisaccharides.
Used in Dental Health:
Maltitol is noncariogenic, meaning it does not promote tooth decay. It is less susceptible to fermentation by certain oral bacteria, such as Streptococcus mutans and Actinomyces viscosus, compared to sucrose. Additionally, a 10% maltitol solution does not lower plaque pH below 5.7 in humans, which helps prevent dental cavities.
Production Methods
Maltitol is produced by chemical hydrogenation of maltose, which can be obtained by enzymatic degradation of starch under conditions similar to those used for other starch hydrolysates such as glucose. The Starting material can be the different commercially available starches including corn, potato, and others. A partially degraded starch, which can be obtained by treatment with diluted hydrochloric or sulphuric acid and subsequent neutralization or with heat-stable a-amylase, is then subjected to enzyme treatment for further degradation to maltose-rich products.Enzymes used for maltose production are b-amylases, fungal a-amylases, a-1.6- glucosidases, maltogenic amylases, and debranching enzymes, preferably with high temperature optimum.
Production Methods
Maltitol is obtained from hydrogenated maltose syrup. Starch is
hydrolyzed to yield a high-concentration maltose syrup, which is
hydrogenated with a catalyst. After purification and concentration,
the syrup is crystallized.
Biotechnological Production
Maltitol is produced by chemical hydrogenation of maltose, which can be obtained
by enzymatic degradation of starch under conditions similar to those used for other
starch hydrolysates such as glucose. The Starting material can be the different
commercially available starches including corn, potato, and others. A partially
degraded starch, which can be obtained by treatment with diluted hydrochloric or
sulphuric acid and subsequent neutralization or with heat-stable a-amylase, is then
subjected to enzyme treatment for further degradation to maltose-rich products.
Enzymes used for maltose production are b-amylases, fungal a-amylases, a-1.6-
glucosidases, maltogenic amylases, and debranching enzymes, preferably with
high temperature optimum.
Examples can be found in patent applications for processes for production of
maltose and maltitol.
Flammability and Explosibility
Notclassified
Pharmaceutical Applications
Maltitol is widely used in the pharmaceutical industry in the
formulation of oral dosage forms. It is a noncariogenic bulk
sweetener, approximately as sweet as sucrose, well adapted as a
diluent for different oral dosage forms, wet granulation, and sugarfree
hard coating.
Biochem/physiol Actions
Sugar substitute with a weak genotoxic effect.
Safety
Maltitol is used in oral pharmaceutical formulations, confectionery,
and food products, and is considered to be noncariogenic. It is
generally regarded as a nontoxic, nonallergenic, and nonirritant
material.
Digestion of maltitol follows two different metabolic pathways:
absorption in the small intestine and fermentation in the large
intestine (colon). These two metabolic pathways must thus be
considered when evaluating the energy value.
The hydrolysis of maltitol in the small intestine releases sorbitol
and glucose. Glucose is actively transported and rapidly absorbed,
whereas sorbitol absorption is passive. The nonabsorbed sorbitol and nonhydrolyzed maltitol are fermented by the microflora in the
colon. The relative importance of the two absorption pathways
depends on numerous individual factors and is related to the
quantity of maltitol ingested. Excessive oral consumption (>50 g
daily) may cause flatulence and diarrhea.
Maltitol exhibits a low glycemic index and can therefore, under
medical supervision, have a place in the diet of diabetic patients. The
intake of maltitol must be taken into account for the calculation of
the daily glucidic allowance.
The WHO, in considering the safety of maltitol, did not set a
value for the acceptable daily intake since the levels used in food to
achieve a desired effect were not considered a hazard to health.
storage
Maltitol has good thermal and chemical stability. When it is heated
at temperatures above 200°C, decomposition begins (depending on
time, temperature, and other prevailing conditions). Maltitol does
not undergo browning reactions with amino acids, and absorbs
atmospheric moisture only at relative humidities of 89% and above,
at 20°C.
Regulatory Status
GRAS listed. Accepted for use as a food additive in Europe.
Included in oral pharmaceutical formulations. Included in the
Canadian List of Acceptable Non-medicinal Ingredients.
Check Digit Verification of cas no
The CAS Registry Mumber 585-88-6 includes 6 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 3 digits, 5,8 and 5 respectively; the second part has 2 digits, 8 and 8 respectively.
Calculate Digit Verification of CAS Registry Number 585-88:
(5*5)+(4*8)+(3*5)+(2*8)+(1*8)=96
96 % 10 = 6
So 585-88-6 is a valid CAS Registry Number.
InChI:InChI=1/C12H24O11/c13-1-4(16)7(18)11(5(17)2-14)23-12-10(21)9(20)8(19)6(3-15)22-12/h4-21H,1-3H2/t4-,5+,6-,7-,8+,9+,10-,11+,12+/m1/s1
585-88-6Relevant articles and documents
Hollow ni-p amorphous alloy nanospheres: An efficient catalyst for sugars hydrogenation to polyols
Yong, Yang,Huajun, Gu,Qingxiao, Zhang,Fang, Zhang,Hui, Li
, p. 282 - 290 (2020/04/27)
In this paper, hollow Ni ? P nanospheres (NSs) are prepared through Ni electroless plating on the Au-activated silica NSs externally covered by aminopropyl moieties, followed by removing the silica template with sodium hydroxide. With various characterizations, the resulting hollow Ni ? P NSs are identified to be amorphous alloy. During liquid-phase hydrogenation of sugars to sugar alcohols, the hollow Ni ? P amorphous alloy NSs delivered much superior catalytic performances to the commercial Raney Ni catalyst, showing a good potential in practical applications. Of particular interest is the unique hollow chamber structure of the hollow Ni ? P amorphous alloy NSs, which allows for improving catalytic activity and durability relative to those associated with the dense Ni ? P amorphous alloy NSs. This work demonstrated that such hollow Ni materials with nanoporous chamber structure displayed advantages such as easy experimental handling and high accessibility for the reactants in liquid-phase reaction, more Ni active sites, as well as the existence of more electron-enriched inner surface, which is essential to provide highly efficient catalysts for some reactions.
RECTANGULAR PARALLELEPIPEDAL MALTITOL
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Page/Page column 7, (2009/07/25)
The invention concerns maltitol crystals, characterized in that they have a rectangular parallelepipedal shape and have a length to width dimensional ratio in the range 1.8 to 5.3, preferably 3±0.7, and a process for producing them.
Method of preparing lacitol monohydrate and dihydrate
-
, (2008/06/13)
The invention relates to the new product lactitol monohydrate and to a method for the production of crystalline lactitol. The crystalline lactitol monohydrate can be obtained bij seeding an aqueous lactitol solution of a special concentration under special conditions causing the lactitol monohydrate to crystallize and recovering the product. From the mother liquor a further amount of lactitol dihydrate can be recovered. Crystalline lactitol dihydrate can be obtained using different special conditions. Lactitolmonohydrate can further be obtained by mixing one part bij weight of an aqueous lactitol solution of a suited concentration with 1 tot 3 parts bij weight of methanol or ethanol and cooling the mixture to 15° tot 25° C.