EP3259279A1

EP3259279A1 - Fibre-rich malto-oligosaccharides with low glucose bioavailability, method of production thereof and uses of same in human and animal nutrition

Info

Publication number: EP3259279A1
Application number: EP16707928.4A
Authority: EP
Inventors: Pierrick Duflot; Jean-Michel Roturier; Baptiste Boit; Pierre Lanos; Heike JEROSCH
Original assignee: Roquette Freres SA
Current assignee: Roquette Freres SA
Priority date: 2015-02-16
Filing date: 2016-02-16
Publication date: 2017-12-27
Also published as: WO2016132064A1; JP2020203903A; CN107250143A; US20180037599A1; ES2848319T3; FR3032709A1; CA2976734A1; CN107250143B; JP2018507856A; CN112079880A; FR3032709B1; KR20240006709A; EP3056506B1; EP3056506A1; KR20170117080A; MX2017010576A; BR112017017538A2; BR112017017538B1; CA2976734C; JP6811180B2

Abstract

The invention relates to malto-oligosaccharides having an α-1,4 osidic bond content of between 70 % and 80 % of the total number of 1,4-type osidic bonds. The invention also relates to the method for producing said malto-oligosaccharides. Said malto-oligosaccharides offer all the advantages of fibre-based food, with an extremely low nutritional value. Such a compromise is not only particularly interesting in healthy and balanced diets, but also in the treatment and/or prevention of the pathology of diabetes. The invention further relates to the use of said malto-oligosaccharides in the fields of human and animal nutrition.

Description

MALTO-OLIGO-SACCHARIDES RICH IN FIBERS AND HAVING LOW GLUCOSE BIOSISISIBILITY, PROCESS FOR THEIR PRODUCTION AND THEIR

USES IN HUMAN AND ANIMAL NUTRITION

FIELD OF THE INVENTION The present invention relates, in a first embodiment, to maltoligo-saccharides having a content of 1-4 -osidic linkages of between 70% and 80% of the total number of type I-4 osidic bonds. . According to a second embodiment, the malto-oligo-saccharides having in particular a content of 1-4 bonds between 65% and 83% of the total number of 1 -4 bonds and / or a ratio of the total number of bonds 1 - 4 on the total number of bonds 1 -6 greater than 1 and / or a content of bonds at 1 -6 between 35 and 58% of the total number of bonds 1 -6 osidic. The term "malto-oligo-saccharides" refers here to saccharides comprising at least 2 saccharide units, that is to say for example to saccharides having a degree of polymerization DP of between 2 and 30, said saccharides comprising at least less a carbohydrate that is maltose. The term "polysaccharides", also used in the present Application, refers more broadly to saccharides comprising at least 2 saccharide units, that is to say for example to saccharides having a degree of polymerization DP of between 2 and 30.

Particularly advantageously, it is the fine tuning of the content of 1,4-dide bonds which leads to unique products and in accordance with the present invention, attesting to an ideal compromise between a relatively high fiber content and a very high low bioavailability of glucose vis-à-vis the body. In this way we have mixed products that have not yet been identified, offering all the benefits of fiber-based foods with extremely low nutritional value. Such a compromise is particularly interesting to implement in healthy and balanced diets, but also in the treatment and / or prevention of the pathology of diabetes.

The invention also relates to an original and very simple method of implementation for the manufacture of these malto-oligo-saccharides, where a mixture between an aqueous solution of carbohydrates rich in maltose, at least one polyol and at least one acid undergoes a heat treatment at high temperature (between 130 ° C and 300 ° C) and under reduced pressure. The choice of starting raw materials and in particular the aqueous solution of maltose-rich carbohydrates, but also the duration of the treatment are part of the levers for regulating the content of bonds to 1 -4 in the range mentioned above.

A final object of the present invention is the use of malto-oligo-saccharides according to the invention, in human and animal nutrition. TECHNICAL PROBLEM AND PRIOR ART

For several years, there has been a certain interest among the general public for new diets based on fiber. By dietary fiber is meant parts of plant origin which are not hydrolysed by enzymes during the digestion process. These are residual substances from the cell wall or plant cytoplasm, consisting of complex mixtures of carbohydrates, which have been identified as non-starch polysaccharides. Among the dietary fibers, insoluble fibers are distinguished from water-soluble fibers. Oats, barley, fruits, fresh vegetables and pulses (beans, lentils, chickpeas) are good sources of soluble fiber, while whole grain cereals and wholemeal bread are high in insoluble fiber. Insoluble fibers, such as cellulose, resistant starches, corn (duff) or soybean fiber, have an essentially mechanical role in the gastrointestinal tract. They are only very slightly fermented by the colonic flora and contribute to the reduction of the intestinal transit time by the effect of ballast. Insoluble fiber helps prevent constipation by increasing stool weight and reducing intestinal transit time.

Soluble fibers, such as pectin and inulin, which are not digestible by the intestinal enzymes of humans or animals, are fermented by the colonic flora. This fermentation releases short-chain fatty acids into the colon, which in turn reduces the pH of the colon and consequently limits the development of pathogenic bacteria and stimulates the development of beneficial bacteria. In addition to these compounds, which are predominantly extracted from plants, there are molecules derived from starch or from its partial or total hydrolysis products. Polydextrose is for example synthesized by random polymerization of glucose in the presence of sorbitol and a suitable acid catalyst (such as citric acid) and at high temperature. The said polydextrose is widely used in food as a filler and as a low-calorie ingredient.

More generally, glucose polymers are conventionally manufactured industrially by hydrolysis of natural or hybrid starches and their derivatives. These starch hydrolysates (dextrins, pyrodextrins, etc.) are thus produced by acid or enzymatic hydrolysis of starch from cereals or tubers. They are in fact made of a mixture of glucose and glucose polymers of very varied molecular weights. Said hydrolysates have a wide distribution of saccharides containing both linear structures (1-4 -sidic linkages) and branched (1-6 -sidic linkages).

By way of example, patent applications EP 0 368 451 and US Pat. No. 5,264,568 describe a process for the preparation of pyrodextrins, the characteristics of which are reinforced by the action of dietary fiber. an α-amylase or several α-amylases successively on a dextrin or on a pyrodextrin in solution and at high temperature.

In the patent application EP 0 530 11 1, indigestible dextrins obtained by extrusion of an acidified corn starch dehydrated under particular conditions are described. This treatment can be completed by the action of a heat-resistant α-amylase.

The Applicant Company itself has also described in its patent application EP 1 006 128 branched maltodextrins having between 22% and 35% of osidic bonds 1 -6 (of both type a and β), a reducing sugar content. less than 20%, a polymolecularity index of less than 5 and a number-average molecular weight Mn of not more than 4500 g / mol. These branched maltodextrins have, above all, an indigestibility character which has the consequence of reducing their caloric power, by preventing their assimilation at the level of the small intestine; they are therefore essentially a source of indigestible fiber.

The Applicant Company has also described and protected in its patent application WO 2013/128121 hyperbranched maltodextrins of low molecular weight, ie having an equivalent dextrose (DE) of between 8 and 15 and a molecular weight Mw of between 1700 and 3000 Daltons, characterized by a content of α-and β osidic linkages of between 30% and 45%, a soluble indigestible fiber content of between 75% and 100% (according to the AOAC method N ° 2001 - 03) and remarkable hypoglycemic properties, which they translate in vitro as in situ, by a limiting effect vis-à-vis the digestion of standard maltodextrins.

Patent application WO 2014/158777 is also known, which describes a carbohydrate that can be used as a food ingredient (especially as a calorie-reducing agent) containing both linear and branched oligomers, whose sugar content is between 5%. and 25% by weight of its dry weight, with a fiber content of between 10% and 70% of its dry weight. Another of its characteristics is to have a polysaccharide content with high molecular weights, such that its viscosity is less than 16,000 cPs, 100 ° F and a solids content of 75%.

Also known are patent applications US 7,608,436 and WO 2008/085529 describing a food product based on oligosaccharides, poorly digestible. Said oligosaccharides here have a content of branched oligomers greater than the content of linear oligomers, and a concentration of nonlinear oligomers with a degree of polymerization greater than or equal to 3 greater than 20% by dry weight.

Finally, the patent application WO 2014/145276, which describes carbohydrate-based compositions having a low calorific value, is known. Different families of carbohydrates are described and claimed, in particular through their contents of molecules of degree of polymerization 1 and 2, in 1 -6 bonds, in sum of the 1-4 and 1-6 bonds, through the ratio between the levels of 1 -4 and 1 -6 bonds, and finally through their molecular weight.

Furthermore, the products marketed under the names PROM ITOR (Tate & Lyle), FIBERSOL (MATSUTAN I), LITESE (DUPONT DAN ISCO) and N UTRIOSE (ROQUETTE), all of which are products based on polysaccharides, are known. or less rich in fiber.

From the foregoing, it follows that continual innovations have been made in at least the last 10 years in the field of high-fiber products which may offer human advantages in the context of new, healthier and better diets. balanced. In particular, it may be quite advantageous to have a product which is both rich in fiber and which can release only very little glucose when it is digested by the body or alternatively have a kinetics of glucose release. very long vis-à-vis the body. In doing so, this last property appears potentially very interesting in diabetic regimens and / or in order to limit the risks of exposure to this pathology.

SUMMARY OF THE INVENTION In this regard, the applicant company has continued many works and laborious research, which allowed him to develop products that meet this expectation. According to one embodiment, the products in question may be defined as malto-oligo-saccharides, having in particular a content of 1 -4 bonds between 70% and 80% of the total number of 1 -4 bonds. According to a second embodiment, the products in question can be defined as maltoligosaccharides, having in particular a content of 1 -4 bonds between 65% and 83% of the total number of 1 -4 bonds and / or a ratio of the total number of 1 -4 bonds to the total number of 1 -6 bonds greater than 1 and / or a content of 1 -6 bonds of between 35 and 58% of the total number of 1 -6 osidic bonds. Compared to prior art products known to the Applicant, certain maltoligo-saccharides of the present Invention have very particular levels of 1 -4 bonds never described or hitherto achieved. At the same time and according to the knowledge of the Applicant, there are no prior art products of the malto-oligo-saccharide type having a linkage content of 1 -4 between 70% and 80% of the total number of 1-4 bonds or malto-oligosaccharides having in particular a content of 1-4 bonds between 65% and 83% of the total number of 1 -4 bonds and / or a ratio of the total number of bonds 1 -4 on the total number of 1 -6 bonds greater than 1 and / or a linkage content of 1-6 between 35 and 58% of the total number of 1 -6 osidic bonds. In addition, it is thanks to an original approach combining proton nuclear magnetic resonance (1 H NMR) and gas chromatography techniques that the Applicant has managed to identify the influence of the parameter retained (ie the content of bonds a 1 -4 relative to all the links 1 -4) on the fiber content of the final product and the bioavailability of glucose vis-à-vis the body.

NMR gives access to the proportions in total osidic bonds at 1-4 and 1 -6 on the one hand, and the other saccharide bonds on the other hand. As for mass spectrometry, it gives access to proportions in total 1,4-dide bonds, 1 -6, 1-2 and 1-3, without indicating the nature of anomeric. This last technique is implemented within the framework of the method well known to those skilled in the art known as HAKOMORI, and which makes it possible precisely to quantify the total osidic binding content in 1 -4, 1 -6, 1 -2 and 1 -3. This method, described for the first time more than 50 years ago (HAKOMORI, S., 1964, J. Biol Chem., 55, 205) is today widely used in the scientific world (see in particular the patent application EP 1 006 128 already cited in the present Application).

It is on the basis of this work and of such an approach that the Applicant has demonstrated the criticality of the content of 1 -4 bonds relative to all type 1 -4 osidic bonds, in order to obtain: a sufficient fiber intake in order to maintain the aforementioned beneficial effects associated with a diet rich in fiber,

an extremely low bioavailability of glucose, and in particular much lower than that displayed by the majority of commercial products available to date.

This bioavailability in glucose refers to the glucose level released after digestion by the intestinal enzymes.

Most advantageously, the very precise regulation of the content of 1 -4 bonds relative to all of the 1,4-type osidic bonds in the abovementioned range is the main lever to achieve the ideal compromise between this sufficient intake. in fiber and this extremely low bioavailability in glucose.

In addition, it is by means of a very simple process that the Applicant has succeeded in synthesizing the malto-oligo-saccharides which are the subject of the present invention. Very schematically, this process initially consists in providing an aqueous solution of carbohydrates rich in maltose, in adding at least one polyol and at least one acid, and then in carrying out a high temperature heat treatment (between 130 ° and 300 ° C.) under reduced pressure. Finally, it should be pointed out that throughout the present application, the fiber content, the glucose level released or accessible after enzymatic digestion as well as the content of the osidic bonds are determined according to strict protocols which are the subject of a very detailed description in the experimental part relating to the said Application.

DETAILED DESCRIPTION OF THE INVENTION

A first object of the present invention is based on a process for producing malto-oligosaccharides comprising the steps of: a) providing an aqueous solution of at least 2 carbohydrates, characterized in that 40% to 95% of the dry weight of said solution is maltose,

b) bringing the aqueous solution resulting from step a) in the presence of at least one polyol, and at least one mineral or organic acid,

c) optionally increasing the solids content of the aqueous solution resulting from step b) to at least 75% by weight of its total weight,

d) carrying out a heat treatment on the aqueous solution resulting from step b) or possibly from step c), at a temperature of between 130Ό and 300Ό and under a depression of between 50 and 500 mbar.

The first step of the process according to the invention consists in providing an aqueous solution of carbohydrates, of which 40% to 95% of its dry weight consists of maltose.

Preferably, the other carbohydrates are saccharide glucose compounds. These carbohydrates can thus be provided in the form of one or more glucose syrups.

According to a variant of the invention which is very particularly preferred, the said aqueous solution resulting from step a) additionally contains glucose.

In this step, maltose and other carbohydrates can be provided in the form of dry products (powders) or alternatively in liquid form. If it is dry products, it is appropriate to add water to them so as to achieve the aqueous solution object of step a). The liquid form is called "syrup" and consists of an aqueous solution of at least one carbohydrate. A preferred variant of the invention consists in mixing a syrup containing at least one carbohydrate and at least one carbohydrate in the form of a dry product. According to this variant, the mixture is facilitated if the temperature is raised to at least 50 ° C. and at most 90 ° C. The aqueous solution resulting from step a) has a dry matter content of at least 50%, preferably at least 70%, very preferably at least 80% by weight of its total weight, and in all not more than 95% by weight of its total weight. A syrup of at least one particularly preferred carbohydrate is a syrup whose distribution of the degrees of polymerization (DP) is as follows: from 1% to 5% of compounds having a degree of polymerization of 1

from 40% to 75% of compounds having a degree of polymerization of 2

from 10% to 25% of compounds having a degree of polymerization of 3

from 5% to 10% of compounds having a degree of polymerization of between 4 inclusive and 8 inclusive of 1% to 15% of compounds having a degree of polymerization between 9 inclusive and 20 inclusive of 1% to 15% of compounds having a degree of polymerization strictly greater than each of these% being expressed in% of the total weight of the carbohydrates contained in said syrup, and the sum of these% being equal to 100%.

Among the most preferred syrups, mention may be made of the syrup marketed by the Applicant Company under the name Sirop de glucose 5774, the distribution of the degrees of polymerization of which is consistent with the ranges listed above.

Another syrup of at least one particularly preferred carbohydrate is a syrup whose distribution of degrees of polymerization (DP) is as follows:

from 8% to 30% of compounds having a degree of polymerization of 1

from 40% to 75% of compounds having a degree of polymerization of 2

from 7% to 17% of compounds having a degree of polymerization of 3

from 3% to 10% of compounds having a degree of polymerization of between 4 inclusive and 8 inclusive of 0.1% to 5% of compounds having a degree of polymerization between 9 inclusive and 20 inclusive of 0.1% to 5% of compounds having a degree of polymerization greater than or equal to each of these% being expressed in% of the total weight of the carbohydrates contained in said syrup, and the sum of these% being equal to 100%.

This other syrup can in particular be obtained by mixing glucose syrup 5774 with dextrose in powder form.

The second step of the process according to the invention consists in putting the aqueous solution of carbohydrates described above in the presence of at least one polyol, and at least one mineral or organic acid. The mixture is facilitated if the temperature of the medium is raised to at least 50 ° and at most 90 ° C. The polyol used in the process according to the invention may in particular be chosen, without this choice being exhaustive, among glycerol, erythritol, xylitol, arabitol, ribitol, sorbitol, dulcitol, mannitol, maltitol, isomaltitol, lactitol and mixtures thereof, more preferably from sorbitol, mannitol and maltitol, the most preferred polyol being maltitol. The polyol represents 5% to 30%, preferably 5% to 25%, very preferably 5% to 10% by weight of the sum of the dry weight of carbohydrates, of said polyol and of the acid.

The polyol is introduced in the form of an aqueous solution, with a solids content of between 20% and 90%, preferably between 25% and 85%, and very preferably between 30% and 80% by weight of its total weight. Alternatively, the polyol may initially be in anhydrous form; in this case, it can be dissolved directly by introduction into the syrup containing at least one carbohydrate, or it can be previously put in aqueous solution by dissolving in water. The process according to the present invention also involves a mineral or organic acid, preferably an organic acid, as a catalyst for the polymerization reaction. This organic acid may be chosen in a non-exhaustive manner from citric acid, sulfuric acid, fumaric acid, succinic acid, gluconic acid, hydrochloric acid, hydrochloric acid and mixtures of these acids, citric acid being the most preferred.

In any case, the selected acid should not have too much volatility, and should not present incompatibility or points of vigilance with regard to future use in the fields of human and animal nutrition. The amount of acid used is here between 0.5% and 2%, preferably between 0.5% and 1.5%, and is very preferably approximately 1% by weight of said acid relative to the dry weight. carbohydrate, polyol and said acid. In all cases, those skilled in the art will be able to adapt the quantity of acid used, taking into account in particular the issues of subsequent neutralization, related to the use of a possible excess of said acid. The acid in question may be used in the form of an aqueous solution with a solids content of between 20% and 90%, preferably between 25% and 85%, and very preferably between 30% and 80% by weight of its total weight. Alternatively, said acid may initially be in anhydrous form; in this case, it can be dissolved directly by introduction into the carbohydrate syrup, or it can be previously put in aqueous solution by dissolution in water.

Preferably, one skilled in the art implementing the method according to the present invention will seek to obtain a solids content for the reaction medium including the mixture of carbohydrates, polyol and acid, between 20% and 98% preferably between 25% and 95%, and very preferably between 30% and 95% by weight of its total weight. It will be able to adapt this dry matter content, in particular according to the desired richness of the reaction mixture, but also among other things taking into account the viscosity of the medium (with regard to possible problems of pumpability and / or transfer of the resulting medium). It will also be able to adapt it in order to limit or even avoid, if it wishes, the optional step c) of increasing the dry matter content by at least 75% by dry weight of the solution. aqueous solution containing the carbohydrates, the polyol and the acid.

The third step of the process according to the invention is optional since it consists, where appropriate, in increasing the dry matter content of the aqueous solution resulting from step b) to at least 75% by weight of its weight. total. This is carried out in the form of a heat treatment, in particular at a temperature of between 60 ° C. and 150 ° C., preferably between 80 ° C. and 120 ° C. Preferably, a depression of between 50 mbar and 500 mbar, preferably between 100 mbar and 400 mbar, will be applied. The duration of this stage is between 4 and 20 hours. Those skilled in the art will be able to adapt the parameters of time, temperature and pressure, in particular according to its initial dry matter content and the dry matter content it ultimately wishes to obtain. For the skilled person, the terms "applying a vacuum" means that the indicated pressure is less than 1 bar absolute pressure, contrary to the terms "apply pressure" which means that the pressure is greater than atmospheric pressure. In other words, when applying a depression between X mbar and Y mbar, this means that the absolute pressure is between X mbar and Y mbar.

The fourth step of the process according to the invention consists in carrying out a heat treatment on the aqueous solution resulting from step b) or possibly from step c), at a temperature of between 130 ° and 300 ° C. and under a depression comprised between between 50 and 500 mbar. It is under these conditions that the polymerization reaction is carried out.

This step is performed in a polymerization reactor, equipped with heating devices and to work under reduced pressure. Such a reactor may in particular consist of a polymerization oven, or a vacuum oven. Alternatively, the adjustment operation of the dry matter and polymerization is carried out in the same reactor, which advantageously has the aforementioned means and devices.

The polymerization reaction is carried out at a temperature of between 130 ° C. and 300 ° C., preferably between 150 ° C. and 200 ° C. The water generated by the reaction is evacuated continuously by evaporation. This operation is carried out under reduced pressure, in particular at a vacuum of between 50 mbar and 500 mbar. In parallel, said reaction is conducted for a time of between 5 minutes and 4 hours, preferably between 5 minutes and 2 hours.

Temperature and reaction time are interdependent variables. Care must be taken not to raise the temperature too much so as to avoid any phenomenon of pyrolysis and / or thermal degradation of the products (such degradation may alter the sensory properties final food product). However, the reaction time decreases as the temperature increases, for a complete polymerization. From this point of view, the products according to the present invention can quite well be manufactured at a temperature of the order of 250 ° and with a residence time of 10 minutes, at a temperature of about 180 ° C. and a residence time of about 90 minutes. Using the method of the invention, one of skill in the art can vary the 1-4 linkage content of the total number of 1-4 -osidic linkages in the following manner; the further the polymerization reaction proceeds, the lower the content.

A second subject of the present invention consists of malto-oligo-saccharides that can be obtained according to the process defined above.

These malto-oligo saccharides have, according to a first mode, a content of bonds at 1-4 of between 70% and 80% of the total number of 1-osidic bonds. These malto-oligo saccharides have, according to a second mode, a content of 1 -4 bonds comprised between 65% and 83% of the total number of 1,4-dide bonds and / or a ratio of the total number of 1,4-dideic bonds on the total number of osidic bonds 1 -6 greater than 1 and / or a content of bonds at 1-6 between 35 and 58% of the total number of osidic bonds 1 -6.

Another subject of the present invention consists of malto-oligo-saccharides having, in a first embodiment, a content of 1-4 bonds of between 70% and 80% of the total number of 1,4-dide bonds. These malto-oligo saccharides have, according to a second mode, a content of 1 -4 bonds comprised between 65% and 83% of the total number of 1,4-dide bonds and / or a ratio of the total number of 1,4-dideic bonds on the total number of osidic bonds 1 -6 greater than 1 and / or a content of bonds at 1-6 between 35 and 58% of the total number of osidic bonds 1 -6. These malto-oligo-saccharides, objects of the present invention may also be characterized in that they have a content of bonds at 1-6 between 35 and 58% of the total number of osidic bonds 1 -6, advantageously between 38 and 52% of the total number of saccharide bonds 1 -6, preferably between 40% and 50% of the total number of 1 -6 osidic bonds. These malto-oligo-saccharides may also be characterized in that they have a fiber content of between 50% and 70%.

These malto-oligo-saccharides are also characterized in that they have a glucose level released or accessible after enzymatic digestion of between 1% and 12%, more preferably between 3 and 9%.

According to this second embodiment, the malto-oligo saccharides may have a content of 1-4 bonds of between 65% and 80% of the total number of 1,4-dide bonds, in particular between 65% and 70% of the total number of bonds. osidic 1 -4. The malto-oligo saccharides of the first mode can, like that of the second mode, a ratio of the total number of 1 -6 osidic bonds to the total number of osidic bonds 1 -6 greater than 1. Preferably, the malto-oligo saccharides of the invention have a ratio of the total number of 1 -4 bonds on the total number of bonds 1 -6 ranging from 1.03 to 2.50, for example from 1.05 to 2 .

A final subject of the present invention relates to the use of malto-oligo-saccharides according to the invention or capable of being obtained according to the method defined above in human and animal nutrition. By way of non-limiting limitation, the malto-oligo-saccharides according to the invention or obtainable by the process defined above can be incorporated into compositions or products intended for ingestion and oral administration, such as various foodstuffs such as confectionery, pastries, ice cream, chewing gum, chewing gum, beverages, jams, soups, milk-based preparations, yogurt, cakes, prepared animal feed, supplements pharmaceutical, veterinary, dietary or hygienic products such as elixirs, cough syrups, tablets or tablets, lozenges, oral hygiene solutions, toothpastes and toothpastes.

Malto-oligosaccharides of the second mode and variants of these malto-oligosaccharides:

Embodiment A: Malto-oligo saccharides having a 1-4 linkage content comprised between 65% and 83% of the total number of 1 -4 -sidic linkages, a ratio of the total number of 1 -4 -sidic bonds of the total number of osidic bonds 1 -6 greater than 1 and a content of bonds at 1-6 between 35 and 58% of the total number of osidic bonds 1-6.

Embodiment B: Malto-oligo saccharides according to Embodiment A further having a ratio of the total number of 1-4 -osidic linkages to the total number of 1-6 -sidic bonds ranging from 1.03 to 2.50, by Example 1, 05 to 2. Embodiment C: Malto-oligo saccharides according to Embodiment A or B further having a 1-6 linkage content between 38 and 52% of the total number of 1 -6 osidic linkages preferably between 40% and 50% of the total number of 1 -6 osidic bonds.

Embodiment D: Malto-oligo saccharides according to one of the embodiments A to C further having a 1-4 linkage content of between 65% and 80% of the total number of 1-to 4-dide linkages.

Embodiment E: Malto-oligo saccharides having a 1-4 linkage content of between 65% and 80% of the total number of 1,4-dide linkages and a ratio of the total number of 1,4-dide linkages of the total number of osidic bonds 1 -6 greater than 1. Embodiment F: Malto-oligo saccharides according to Embodiment E further having a 1-6 linkage content of between 35 and 58% of the total number of 1 -6 osidic linkages, advantageously between 38 and 52% of the number total of 1 -6 osidic bonds, preferably between 40% and 50% of the total number of 1 -6 osidic bonds.

Embodiment G: Malto-oligo saccharides according to one of embodiments E or F further having a ratio of the total number of 1-osidic bonds to the total number of osidic bonds 1-6 ranging from 1.03 to 2.50, for example from 1.05 to 2.

Embodiment H: Malto-oligo saccharides having a 1-4 linkage content of between 65% and 83% of the total number of 1,4-dide linkages and a 1-6 linkage content of between 35 and 52% of the total number of saccharide bonds 1-6. Embodiment I: Malto-oligo saccharides according to Embodiment H further having a ratio of the total number of 1-4 -osidic bonds to the total number of 1 -6 osidic bonds greater than 1, advantageously ranging from 1.03 to 2.50, for example from 1.05 to 2.

Embodiment J: Malto-oligo saccharides according to embodiment H or I further having a content of 1-6 bonds between 38 and 52% of the total number of saccharide bonds 1 -6, preferably between 40% and 50% of the total number of saccharide bonds 1-6.

Embodiment K: Malto-oligo saccharides according to one of Embodiments H to J further having a 1-4 linkage content of from 65% to 80% of the total number of 1-4 -osidic linkages.

Embodiment L: Malto-oligo saccharides according to one of embodiments A to K further having a fiber content of between 50% and 70%. Embodiment M: Malto-oligo saccharides according to one of Embodiments A to L further having a 1-4 linkage content of from 65% to 70% of the total number of 1-4 -osidic linkages.

Embodiment N: Malto-oligo saccharides according to one of embodiments A to M further having a glucose level released or accessible after enzymatic digestion of between 1% and 12%, more preferably between 3 and 9%.

The following examples will make it easier to understand the present invention without limiting its scope. EXAMPLES

EXPERIMENTAL METHODS

Throughout the present Application, the content of the osidic bonds are determined by NMR, and by the method of HAKOMORI.

NMR gives access to the proportions in alpha bonds 1, 4 and alpha 1 -6 on the one hand, and the other bonds osidic on the other hand.

The method of HAKOMORI gives access to the contents of total osidic bonds in 1 -4, 1 -6, 1 -2 and 1 -3.

For NMR, an Avance I II (Bruker Spectrospin) Fourier Transform Spectrometer, operating at 400 MHz, was used and using 5 mm NMR tubes at 60 ° C. More generally, it is possible to use any other Fourier transform spectrometer, provided that said spectrometer is equipped with all the accessories making it possible to produce and exploit a proton spectrum, as well as an accessory enabling it to work. at temperatures above room temperature. Deuterated water, or D ₂ 0 (min 99%), Euryso Top (CEA group, Gif-sur-Yvette, France) and sodium salt of 3-trimethylsilyl-1-propanesulfonic acid, are used. or TSPSA (Aldrich, ref 178837).

The procedure of the experiments is as follows:

Introduce 10 mg of sample and 0.75 m L of D ₂ 0 into an NMR tube.

Close the tube, mix and place in a bain-marie.

- After dissolution, remove the tube from the water bath and allow to cool to room temperature.

Add 50 μί of a solution of TSPSA at 10 mg / g in D ₂ 0.

Fit the spinner on the tube and place it all in the magnet.

Perform the acquisition, without solvent removal, with a relaxation time of at least 10 s and without rotation, after the appropriate settings of the instrument (field, lock phase and shims). Use a spectral window between at least - 0.1 ppm and 9 ppm, with reference to the methyl signal of TSPSA calibrated at 0 ppm.

The spectrum is used after Fourier transform, phase correction and subtraction of the baseline in manual mode (without exponential multiplication, LB = GB = 0). The results are exploited as follows:

Integrate signals we can particularly refer to Figure 1/2 for the integration terminals. Normalize to 600 the signal S5 corresponding to the non exchangeable protons of anhydroglucose unit (H ₂ , H ₃ , H ₄ , H ₅ and 2H ₆ ); the rest of the signal corresponding to the set of protons (reductive connections and terminations).

- Record the S1 values (h ^ alpha (1, 4), S2 (h ^ alpha reducer) and S3 (h ^ alpha (1, 6)) - Determine the S4 beta-reductants by performing the operation S2 ^* 0.6 / 0.4.

- Calculate S6 by performing the operation S6 = 100 - (S1 + S2 + S3 + S4)

Determine the proportions of alpha- (1, 4), alpha- (1, 6) and other bonds by summing the 3 respective surfaces (S1, S3 and S6) and normalizing them to 1 00 to express them. % (ie% i = Si ^* 100 / (S1 + S3 + S6)).

Table 1

The method of HAKOMORI is that described in the 1964 publication J. Biol. Chem., 55, 205.

Throughout the present Application, the glucose level released or accessible after enzymatic digestion is determined according to the following method.

Weigh 0.3 g of product to be tested.

Add 75 ml of maleate buffer of Na pH 7.00 to 0.1 mol / l (Fluka, reference 631 80).

Shake until the product dissolves.

Place the flasks in a water bath for 15 minutes, so that the temperature of the solution is 37O.

Take 0.75 ml of the initial solution and add 0.075 g of porcine pancreatin after taking the initial solution (Sigma, reference P7545); this operation corresponds to the origin of the times

Incubate at 37 ° C. in a thermostatically controlled bath with stirring for 30 minutes.

Make a sample of 0.75 ml.

Add 0.40 g of rat intestinal mucosa (Sigma, reference 11630).

Incubate for 3h30 at 37 ° C. in a thermostated bath with stirring. Achieve during these 3:30 samplings of 0.75 ml at 60, 120, 180 and 240 minutes.

Stop the enzymatic reaction by placing the specimens in a dry bath at 100 ° C for 10 minutes.

- Perform the determination of the glucose of the samples (standard enzymatic method GOD).

Calculate the level of glucose released during the digestion of the product at the end of 3h30 (expressed in%): concentration of glucose in g / L of the sample ^* (100 / dry matter of the product) ^* (volume of the digestate in ml / 1000) ^* (100 / weight of the wet product in g). Throughout the present Application, the fiber content is measured according to AOAC Method No. 2001 -03.

PRODUCTS ACCORDING TO THE INVENTION

In tests Nos. 1 to 5, 5 products were produced according to the process according to the present invention.

There is a glucose syrup 5774 ("Flolys D57") marketed by the company ROQUETTE at 85% dry matter.

This syrup is diluted to 50 ° Bx.

1 kg of material is prepared with the% by weight mentioned in the table below, in a glass beaker. Said beaker is placed on a heating plate, with stirring with a magnet bar set at 500 rpm, the temperature being set at 60 ° C.

Once this temperature is reached, it is introduced, in powder form, into the beaker glucose sold under the name Dextrose Anhydrous C, by Roquette.

The following products are then added to this aqueous solution in powder form:

maltitol marketed under the name SWEETPEARL P200 by the company ROQUETTE

The citric acid marketed by SIGMA, of purity greater than or equal to 99.5%

The mass% of the constituents are given in Table 2, for tests Nos. 1, 2, 3, 4 and 5 which represent the invention.

Test No. 1 2 3 4 5

Flolys D57 81 68 68 72 71

(85% of MS)

Glucose 9 22.2 22.2 18 18

Maltitol 9 8.9 8.9 9 9

Citric acid 1 0.9 0.9 1 2

Table 2 After complete dissolution of the powders, ie a few minutes, the mixture is clear.

120 grams of the mixture are then taken and transferred into an aluminum tray marketed by PRO'JET under the reference KPL1001.

The trays are placed in a vacuum oven for 20 hours at 80 ° C. and then 6 hours at 120 ° C. A depression of 125 mbar is applied in the oven. This gives a dry matter of 95.0%.

The trays with the dry product are then placed in a second oven previously heated to 200 ° C, all being put under a vacuum of 125 mbar. The trays are removed 90 minutes later.

The product is then diluted with water at 30% dry matter.

For each of the 5 previous tests, the Applicant has determined: the% in α -1 -4 -sidic bonds of the total number of 1-osidic bonds

- the% in osidic bonds alpha 1 -6 of the total number of osidic bonds 1 -6

the ratio of the total number of 1,4-dide bonds to the total number of sugar bonds 1 -6 the fiber content in%

the glucose level released in%

NON-INVENTION PRODUCTS

The Applicant has also determined these same parameters for the following products: NUTRIOSE FB06 marketed by the Applicant Company (Test No. 4)

NUTRIOSE FB10 marketed by the applicant company (test n ° 5)

ULTRA LITESE marketed by the company DUPONT DAN ISCO (test n ° 6)

PROM ITOR 70 marketed by the company TATE & LYLE (test n ° 7)

PROM ITOR 85 marketed by the company TATE & LYLE (test n ° 8)

FIBERSOL 2 marketed by the company MATSUTAN I (test n ° 9)

IMO 500 marketed by the company (test n ° 10)

The overall results were reported in Table 3, as well as in Figure 2/2, with the exception of MOS products 4 and 5.

Table 3 It can be seen in a remarkable manner that all the commercial products belonging to the state of the art and rich in fibers have an alpha 1 -4 osidic bond content of greater than 80%, this being within a very short range. restricted, between 80% and 90%.

Furthermore, all of these products have a fiber content of at least 60%, in most cases at least 75% and a systematically available glucose content of greater than 10%, in most cases superior at 15%, and sometimes even above 20%.

On the other hand, the products according to the invention have a content of 1,4-dide bonds of between 66% and 81%. It is found that, particularly advantageously, these products have a high fiber content, since it is around 60%. Finally, 3 products according to the invention have a very low level of available glucose, levels never reached in the past. This is particularly surprising because these new products, although high in fiber, have a lower fiber content than other products tested. Also, only these products present the ideal compromise between a product relatively rich in fiber, and therefore perfectly adapted in healthy and balanced diets, and a product with a very low bioavailability of glucose vis-à-vis the body, so perfectly adapted to diabetic patients or in regimes aiming at decreasing the sensitivity to this pathology.

Claims

1 - Process for producing malto-oligo-saccharides comprising the steps of: a) providing an aqueous solution of at least 2 carbohydrates, characterized in that 40% to 95% of the dry weight of said solution consists of maltose,

d) carrying out a heat treatment on the aqueous solution resulting from step b) or possibly from step c), at a temperature of between 140Ό and 300Ό and under a depression of between 50 and 500 mbar.

2 - Process according to claim 1, characterized in that the aqueous solution resulting from step a) contains glucose.

3 - Process according to claim 1 or 2, characterized in that the aqueous solution resulting from step a) has a solids content of at least 50%, preferably at least 70%, very preferably from less than 80% by weight of its total weight, and in all cases not more than 95% by weight of its total weight.

4 - Process according to any one of claims 1 to 3, characterized in that the polyol is selected from glycerol, erythritol, xylitol, arabitol, ribitol, sorbitol, dulcitol, mannitol, maltitol, isomaltitol, lactitol and mixtures thereof, more preferably among sorbitol, mannitol and maltitol, the most preferred polyol being maltitol.

5 - Process according to any one of claims 1 to 4, characterized in that the acid when it is organic is selected from citric acid, sulfuric, fumaric, succinic, gluconic, hydrochloric, hydrochloric and mixtures thereof. acids, citric acid being the most preferred.

6 - Process according to any one of claims 1 to 5, characterized in that step c) is carried out in the form of a heat treatment, at a temperature between 60 ° C and 150 ° C, preferably between 80 ° C and 120 ° C.

7 - Process according to claim 6, characterized in that step c) is carried out under a depression of between 50 mbar and 500 mbar, preferably between 100 mbar and 400 mbar. 8 - Process according to any one of claims 1 to 7, characterized in that step d) is carried out between 150 ° C and 200 ° C.

9 - Process according to claim 8, characterized in that step d) is carried out at a pressure of between 50 mbar and 500 mbar.

Malto-oligo-saccharides obtainable by the process as claimed in any one of claims 1 to 9 having a 1-4 linkage content of between 70% and 80% of the total number of saccharide bonds. 1 -4.

1 1 - Malto-oligo-saccharides according to claim 1 0, characterized in that they have a content of 1-6 bonds between 35 and 58% of the total number of osidic bonds 1 -6, preferably between 38 and 52 % of the total number of osidic bonds 1-6, preferably a content of bonds at 1-6 between 40% and 50% of the total number of osidic bonds 1-6.

12 - malto-oligo-saccharides according to any one of claims 10 or 1 1, characterized in that they have a fiber content of between 50% and 70%.

13 - Malto-oligo-saccharides according to any one of claims 10 to 12, characterized in that they have a glucose level released or accessible after enzymatic digestion between 1

% and 12%, more preferably between 3 and 9%.

14 - Malto-oligo-saccharides having a content of 1-4 bonds between 70% and 80 of the total number of 1-osidic bonds.

15 - Malto-oligo-saccharides according to claim 14, characterized in that they have a content of bonds at 1-6 between 35 and 58% of the total number of osidic bonds 1 -6, advantageously between 38 and 52% of the total number of osidic bonds 1 -6, preferably a content of bonds at 1-6 between 40% and 50% of the total number of 1 -6 osidic bonds.

16 - Malto-oligo-saccharides according to any one of claims 14 or 15, characterized in that they have a fiber content of between 50% and 70%.

17 - Malto-oligo-saccharides according to any one of claims 14 to 16, characterized in that they have a glucose level released or accessible after enzymatic digestion between 1

% and 12%, more preferably between 3 and 9%.

18 - Use of malto-oligo-saccharides according to any one of claims 10 to 17 in human and animal nutrition.