EP4090307A1 - Edible toothpaste composition to be sucked or chewed, method for preparing said toothpaste composition - Google Patents

Abstract

One aspect of the invention relates to a method for preparing a toothpaste composition, which is in the form of an edible lozenge to be sucked or chewed and which comprises: - an enzymatic complex comprising the following compounds: o invertase, o glucose oxidase, o amyloglucosidase, o lactoperoxidase, o lactoferrin, - at least one gelling agent, which method is characterized in that it comprises: - a step of heating said at least one gelling agent to a temperature of between 82 and 88°C, - a step of encapsulating the enzymatic complex by incorporation or by ionization of said enzymatic complex in said at least one gelling agent when the temperature of said at least one gelling agent is between 55 and 65°C.

Description

DESCRIPTION

TITLE: COMPOSITION TOOTHPASTE EDIBLE TO SUCK OR TO CHEW, PROCESS FOR PREPARING THE SAID COMPOSITION

TOOTHPASTE

TECHNICAL FIELD OF THE INVENTION

[001] The technical field of the invention is that of oral hygiene.

The present invention relates to a process for preparing an edible toothpaste composition, to suck or chew, which can be used anywhere and at any time of the day to promote the removal of food residues on the teeth and ensure the protection of the oral microbiotic environment

TECHNOLOGICAL BACKGROUND OF THE INVENTION

Today, toothpaste compositions are most often in the form of a gel, a dental paste or even a powder which requires the use of a toothbrush in order to spread the composition on the teeth and remove food residues. However, this presupposes having access to an adequate space (room, water, mirror) which is not always possible, especially during the day and / or when traveling.

In order to overcome the aforementioned drawbacks, there are toothpaste compositions in the form of tablets which can be used anywhere and any time, without brushing or rinsing, as described in patent applications FR2648346A1 and W09638122A1. To be used, these tablets must be placed in the oral cavity so that they can dissolve in saliva and disperse into multiple fragments which are then spread over the teeth using the tongue. However, such an operation can prove to be difficult and inefficient. Indeed, use has shown that such tablets break and dissolve rapidly in saliva so that the active ingredients, in small quantities, do not remain in contact with the user's teeth long enough to ensure brushing. effective. In addition, these tablets can be abrasive to tooth enamel, especially in the presence of recent food acids on the teeth. Thus, patent application FR2822700A1 describes a toothpaste composition which is in the form of a tablet which gels on contact with water, in particular saliva, or of a semi-solid gel pre-gelled in a single dose to be applied. directly on the teeth. If this The composition has the advantage of having a prolonged action by adhesive action on the teeth, it is less effective than “conventional” brushing because it does not make it possible to effectively ensure the removal of oral food residues adhering to the teeth.

[005] Chewing gums have the advantage of including non-cariogenic sugars which, with prolonged chewing facilitating hyper salivation, results in the elimination of part of the oral food residues adhering to the teeth. For example, patent application FR 2487668A1 describes a chewing device for cleaning teeth and gums. This device comprises a base member from which several fibers protrude outwardly and the free end of these fibers has hooks which rub against the surface of the teeth and gums after a toothpaste compound or a breath-freshening substance. dissolves enough to reveal the fibers that it initially coats. However, the use of such chewing gums does not completely remove food residues from the oral cavity. In addition, chewing gum has disadvantages for the health of the user, in particular because they can lead to the loss of amalgams, gastric acidity or even aerophagia. In addition, chewing gum must be discarded after use and therefore constitute waste that pollutes the environment.

Finally, there are toothpaste compositions contained in vaporizers, also called "spray". However, this type of toothpaste composition does not provide effective oral hygiene.

SUMMARY OF THE INVENTION

The invention offers a solution to the problems mentioned above, by providing a toothpaste composition which can be used anywhere and at any time of the day while effectively ensuring the elimination of food residues, strengthening the salivary defenses and maintaining the balance of the oral flora.

The invention relates to a process for preparing a dentifrice composition in the form of an edible lozenge to suck or chew and comprising: an enzymatic complex comprising: invertase, gluco-oxidase, amino-glucosidase lactoperoxidase, lactoferrin, at least one gelling agent. the process is characterized in that it comprises:

A step of heating said at least one gelling agent to a temperature between 82 and 88 ° C,

A step of encapsulating the enzyme complex by incorporation or by ionization of said enzyme complex in said at least one gelling agent when the temperature of said at least one gelling agent is between 55 and 65 ° C.

[0009] The gelling agent is heated to a temperature between 82 and 88 ° C corresponding to a pasteurization phase so as to obtain a base microbiologically close to zero and constant with each manufacture. The gelling agent is lowered to a temperature of between 55 and 65 ° C to reach a supercooling level thus making it possible to mold the complex enzymatic mixture - gelling agent. The supercooling stage is a state where the gelling agent remains molten and is ready to be molded.

Thanks to the enzymatic complex, the toothpaste composition acts globally and autonomously on the bactericidal activation of salivary enzymes and against cariogenic bacteria of the oral cavity which is more at the opportune moment because it is active immediately in the presence of cariogenic sugars .

[0011] In addition, the gelling agent is a binder and a gelling agent giving the adequate texture, ie malleability and firmness, to the toothpaste composition so that it can be sucked or chewed so that it can be used at any time. during the day without having to have access to a dedicated space. In addition, the action of the active principle, here the enzyme complex, takes place slowly while the pellet is sucked or chewed, which makes its action more effective than the tablets of the prior art which dissolve rapidly in saliva. In addition, its use is easier than chewable tablets as it is no longer necessary to spread the toothpaste composition on the teeth.

Finally, unlike chewing gum, the toothpaste composition in the form of a lozenge is edible so that it does not pollute the environment and does not present a risk to the health of the user.

[0013] According to one particular characteristic, the preparation process comprises, before the encapsulation step:

A step of heating at least one polyol compound to a temperature between 82 and 88 ° C,

A step of mixing said at least one polyol compound with said at least one gelling agent when the temperature of said at least one polyol compound and the temperature of said at least one gelling agent are between 82 and 88 ° C,

A step of cooling the mixture comprising said at least one polyol compound and said at least one gelling agent to reach a temperature of between 55 and 65 ° C.

The polyol compound is heated to a temperature between 82 and 88 ° C corresponding to a pasteurization phase. Pasteurization is used to control the microbiological load of the mixture. Indeed, the microbiological load must follow the ISO 17516 Standard, the number of bacteria must be less than 1000 CFU (Colony forming unit) / gram or less than 1000 CFU / ml. Pasteurization ensures a homogeneous mixture between the polyol compound and the gelling agent.

[0015] According to one particular characteristic, the preparation process comprises, after the encapsulation step:

A step of molding the encapsulated enzyme complex in molds at a temperature between 55 and 65 ° C.

[0016] The temperature range of between 55 and 65 ° C corresponds to a level of supercooling of the mixture, thus making it possible to mold the entire mixture.

According to one particular characteristic, the preparation process comprises, after the molding step: A step of demolding the encapsulated enzyme complex to obtain a plurality of pellets.

[0018] According to one particular characteristic, the preparation process comprises, after the demolding step:

A step of coating the plurality of pellets with a coating agent.

[0019] According to one particular characteristic, the preparation process comprises, after the coating step:

A step of bagging each pellet in a moisture-proof and air-tight bag.

[0020] According to a particular characteristic, after the step of heating the compound of the gelling agent, the preparation process comprises a step in which the gelling agent is maintained at a temperature between 82 and 88 ° C for 40 minutes.

The step of maintaining a temperature after heating the gelling agent makes it possible to pasteurize the latter and therefore to obtain a base microbiologically close to zero.

[0022] According to a particular characteristic, after the step of heating the polyol compound, the preparation process comprises a step in which the polyol compound is maintained at a temperature between 82 and 88 ° C for 40 minutes.

The step of maintaining a temperature after heating the polyol compound makes it possible to pasteurize the latter and therefore to obtain a base microbiologically close to zero.

[0024] According to one particular characteristic, after the step of molding the enzyme complex, the preparation process comprises a step in which the temperature of the mold is lowered in order to solidify the encapsulated enzyme complex and thus form a plurality of pellets.

[0025] According to a first embodiment, the encapsulation step is carried out by incorporating the enzyme complex into said at least one gelling agent

According to a second embodiment, the encapsulation step is carried out by ionization by electro nebulizer. According to the second embodiment, two solutions of distilled water are passed through a dual channel and ionized by means of an electro spray device.

According to the second embodiment, the encapsulated enzyme complex is dispersed in the gelling agent in the form of a gelled matrix.

According to the second embodiment, the enzyme complex is encapsulated in capsules whose diameter is between 1 and 50 microns.

According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises between 0.5 and 1% by weight of enzymatic complex relative to the total weight of the toothpaste composition.

According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises between 20 and 25% by weight of gelling agent (s) relative to the total weight of the toothpaste composition.

[0032] According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises at least one polyol compound.

The polyol compound makes it possible to replace the sweet taste provided by the sugar. Such a polyol compound provides volume and a sweet taste close to sugar. This is then referred to as a filler sweetener. These polyols are low in calories and also have the advantage of being non-cariogenic. In addition, the polyol compound has an antiseptic and bacteriostatic effect. It allows better salivation, including better diffusion of the enzyme complex in the salivary medium. In addition, its bacteriostatic action strengthens the antiseptic action of the enzymatic complex

According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises between 45 and 65% by weight of polyol compound (s) relative to the total weight of the toothpaste composition.

According to one particular characteristic, said at least one polyol compound is chosen from the following list:

Sorbitol,

Xylitol,

Glycerol. According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises at least one vegetable oil.

[0037] According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises 1 and 2% by weight of vegetable oil (s) relative to the total weight of the toothpaste composition.

[0038] According to one particular characteristic, the dentifrice composition obtained by the preparation process comprises at least one protein agent.

[0039] According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises between 1, 6 and 2% by weight of protein agent (s) relative to the total weight of the toothpaste composition.

[0040] According to one particular characteristic, said at least one protein agent is a beef protein or a milk protein.

According to one particular characteristic, the toothpaste composition obtained by the preparation process contains fluorine.

[0042] According to one particular characteristic, the toothpaste composition obtained by the preparation process is devoid of fluorine.

[0043] According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises at least one non-abrasive friction agent.

According to one particular characteristic, the toothpaste composition obtained by the preparation process comprises between 0.75 and 1.25% by weight of non-abrasive friction agent (s) relative to the total weight of the composition toothpaste.

According to one particular characteristic, the toothpaste composition obtained by the preparation process is for human or animal use.

BRIEF DESCRIPTION OF THE FIGURE

[0046] Figure 1 is presented only as an indication and in no way limiting the invention.

[0047] Figure 1 is an illustration of ionization encapsulation.

DETAILED DESCRIPTION

The invention relates to a chewable toothpaste composition which effectively eliminates food residues in the teeth of an adult person, from a child or an animal, etc. and to stimulate the natural antibacterial defenses of saliva by enriching the microbiota and the oral enzymatic system.

[0049] The toothpaste composition is in the form of an edible chewable or suckable lozenge. Advantageously, the pellet is spherical and has a diameter of between 5 and 3 cm. Of course, the pellet can have another shape, for example elliptical, rectangular etc. Advantageously, the pellet is bagged in an individual bag sealed against water and air.

The dentifrice composition comprises an enzymatic complex including the following compounds: invertase, gluco-oxidase, amino-glucosidase, lactoperoxidase, lactoferrin.

Such an enzymatic complex has antibacterial, anti-cariogenic, anti-dental plaque, antiseptic and whitening properties. Indeed, this enzymatic complex ensures the activation of the bactericidal power of saliva allowing the prevention of dental plaque and caries, the balance of the oral environment and a reduction in inflammation of the gingival and digestive mucous membranes (Cf publication Dr Brisker, faculty of Medicine of Nancy / 2000 and Professor Daniel Faculté Dentaire de Nantes / 2004). In particular, it is a combination of a glucose donor enzyme, an oxidoreductase enzyme, a peroxidase enzyme and a glycoprotein, lactoferrin. The combination of these enzymes leads to the formation of non-cariogenic glucose derivatives as well as strongly bactericidal hypothiocyanate ions. In addition, this combination leads to chelation of the iron necessary for the development of bacteria as well as lysis of the cell membrane of acidogenic streptococci. In addition, the proposed composition makes it possible to indirectly provide a bleaching and bactericidal agent: hydrogen peroxide.

In fact, the enzymatic complex acts upon ingestion of sucrose obtained from food sugars by degrading said sucrose which is the main substrate for cariogenic bacteria. In fact, invertase, also called sucrase, an enzyme that hydrolyzes the Beta -2.6 and / or Beta -2.1 bonds between fructofuranosyls, transforms sucrose into a molecule of glucose and a molecule of fructose in interaction with cariogenic bacteria. . The invertase of the enzyme complex acts directly on the food sucrose ingested by the subject, which makes it possible to supply the glucose necessary for the reaction in a direct, sufficient and timely manner. Then, the gluco oxidase, oxidoreductase ensuring the transformation of glucose, transforms the glucose produced into glucuronic acid and hydrogen peroxide but without producing lactic acid which is a strong acid at the origin of enamel demineralization. and thus to the appearance of cavities.

The bactericidal activity of the enzyme complex is provided by the hypothiocyanate formed by oxidation of thiocyanate (natural component of saliva) by hydrogen peroxide. Hydrogen peroxide produced by oxidation of glucose from the degradation of sucrose by invertase and then catalyzed by salivary lactoperoxidase during the reaction to form hypothiocyanate. In addition, the anti-bacterial action of the complex is increased by the synergistic contribution of Lactoferrin, a glycoprotein, present in small quantities in the saliva, which chelates iron preventing the development of bacteria and which binds the lipopolysaccharides necessary for the survival of cariogenic streptococci.

Lactoferrin is an enzyme which lyses by chelation of ferrous ions the bacterial membrane of many pathogenic organisms including acidogenic streptococci and greatly increases the body's immune defenses. This enzyme also alters the outer membrane of bacteria and thus leads to their destruction. Lactoferrin works by regulating the cellular immune response at different levels. In healthy individuals, lactoferrin is believed to be at the forefront of the immune defense system and protects the openings and orifices of the body from infectious invasions, thanks to its unique ability to bind to iron used by a wide range of organisms. pathogens and tumors to grow and reproduce.

The bactericidal activity of the enzyme complex allows the elimination of cariogenic streptococci and thus the neutralization of the acidity (lactic acid) resulting from the transformation of food sugars by the bacteria. The present invention thus provides a complete and immediately active enzymatic complex which, in the presence of cariogenic sugars, is able to inhibit the effect of proliferation and production of toxins by oral bacteria in the presence of sucrose (food sugar). In addition, a soft anti-dental plaque activity making it possible to destabilize recent plaque can be ensured by the addition of a beta-glucanase on the levans, ie polymers of fructose and mutans, ie polymers of glucose and d. 'an alpha glucanase on dextrans, ie polymers of glucose with formation of maltose, the latter then being transformed into glucose by the action of an amyloglucosidase with oxidation of the NAD + cofactor.

[0057] Thus, the enzyme complex is a complex which strengthens the salivary defenses against oral infections but also against the acidity of dental plaque resulting from the use of dietary sugars by bacteria, in particular by cariogenic streptococci. The sugars of food origin theoretically used by bacteria to grow are used in the invention as substrates (after hydrolysis by invertase) for the enhancement of the bactericidal activity of saliva. This is the opportune time to inhibit the bacterial growth induced by the supply of sucrose, definitely strengthening the salivary anti-cariogenic defenses of the physiological Lactoperoxidase system and the immune system. In addition, there is a decrease in inflammation of the mucous membranes and the preservation of the microbiotic balance of the oral cavity.

The enzymatic complex allows the implementation of different constituents acting in a complementary manner both in the bactericidal effect against streptococci of the oral cavity and in the neutralization of acids from food sugars. The enzymatic complex generates the following steps: a separation of the food sugar, (ie sucrose) by a sucrase (sucrase) and an amyloglucosidase into a glucose molecule and a fructose molecule, a transformation of the glucose molecule by a glucose oxidase into hydrogen peroxide and glucuronic acid, ie weak acid, a transformation of fructose and glucose into inert substances, ie D Lactones by an Amyloglucosidase and a Glucose oxidase, a transformation of salivary thiocyanate into hypothiocyanate, strongly bactericidal by the action a lactoperoxidase using the active dioxygen of the hydrogen peroxide formed, iron chelation and binding of microbial envelope polysaccharides by lactoferrin.

Thus, in the invention, the enzyme complex makes it possible to supply glucose from cariogenic sugars, i. e. Sucrose, Lactoperoxidase and Lactoferrin to initiate and strengthen the physiological bactericidal system of saliva. Advantageously, the dentifrice composition according to the invention comprises between 0.5 and 1% by weight of enzymatic complex relative to the total weight of the dentifrice composition.

In addition, the dentifrice composition comprises at least one gelling agent. The term “gelling agent” is understood to mean a substance making it possible to give the toothpaste composition a rubbery texture, cohesion, length in the mouth and an elastic chewy sensation, a bit like that of chewing paste, commonly called “ chewing gum ”, but to a lesser extent. We can also speak of a texturizing agent. According to the invention, the term “gelling agent” is understood very particularly to mean a gelling and / or thickening hydrocolloid of plant (pectin, etc.) or animal (bovine gelatin, etc.) origin. The gelling agent according to the invention is more particularly chosen from gelatin, pectin, agar agar, preferably gelatin. Advantageously, the toothpaste composition according to the invention comprises between 20 and 25% by weight of gelling agent (s) relative to the total weight of the toothpaste composition.

Advantageously, the dentifrice composition comprises at least one polyol compound, for example sorbitol, xylitol and / or glycerol. The presence of said at least one glycerol compound makes it possible to protect the enzyme complex and participates in the protection of the enamel through its content of film-forming agent. More preferably, the dentifrice composition according to the invention comprises between 45 and 65% by weight of polyol compound (s) relative to the total weight of the dentifrice composition.

Advantageously, the toothpaste composition comprises at least one vegetable oil. Advantageously, the vegetable oil is for example a mint oil because it has antiseptic properties. More preferably, the dentifrice composition according to the invention comprises 1 and 2% by weight of vegetable oil (s) relative to the total weight of the dentifrice composition. Preferably, the dentifrice composition comprises at least one protein agent, for example milk proteins and / or beef proteins. The protein agent makes it possible to give the consistency and the texture to be given to the lozenge. More preferably, the dentifrice composition according to the invention comprises between 1, 6 and 2% by weight of protein agent (s) relative to the total weight of the dentifrice composition.

[0064] In addition, the toothpaste composition can comprise at least one non-abrasive friction agent. More preferably, the toothpaste composition according to the invention comprises between 0.75 and 1.25% by weight of non-abrasive friction agent (s) relative to the total weight of the toothpaste composition.

[0065] Furthermore, the toothpaste composition can comprise one or more flavors, for example of mint, of red fruits, and the like. and / or one or more natural dyes.

[0066] Advantageously, the toothpaste composition comprises an edible coating agent for conditioning the components of the toothpaste composition. The coating agent is for example wax, preferably beeswax.

According to an exemplary embodiment, the dentifrice composition comprises: between 0.5 and 1% of enzymatic complex, preferably 0.6%, between 40 and 60% of powdered sorbitol, preferably 50%, between 4 and 6% powdered xylitol, preferably 5%, between 18 and 24% bovine gelatin, preferably 21%, between 5 and 15% water, preferably 15%, between 0.8 and 1.2% d 'essential oil of peppermint, preferably 1%, between 0.5 and 2% of milk proteins, preferably 1% between 0.8 and 1, 2% of menthol, preferably 1%, between 0.0015 and 0 , 0025% blue dye, preferably 0.002%, between 1 and 2% beeswax, preferably 1.5%. The percentages indicated below are mass percentages calculated relative to the total weight of the toothpaste composition.

The invention also relates to a process for preparing the toothpaste composition according to one embodiment of the invention. In an optional step, the natural dye is dissolved in water and then the protein agents are hydrated in colored water obtained at room temperature. Subsequently, at least one polyol compound is incorporated into the mixture obtained. Indeed, if the dye is incorporated a posteriori of the addition of a polyol compound, lumps that cannot be removed are formed. Protein agents should be incorporated before adding a polyol compound as these need to sequester all of the water.

In a heating step, said at least one gelling agent and said at least non-abrasive friction agent are heated and mixed in a first tank. Advantageously, the heating step is carried out at a temperature between 82 and 88 ° C, preferably at 85 ° C.

In a heating step, said at least one polyol compound is heated in a second tank. Advantageously, the heating step is carried out at a temperature between 82 and 88 ° C, preferably at 85 ° C. The temperature between 82 and 88 ° C corresponds to the pasteurization level. Said at least one polyol compound is maintained at the pasteurization stage for 40 minutes. Pasteurization makes it possible to control the microbiological load of the mixture and therefore to ensure a homogeneous mixture.

In a mixing step, the gelling agent and the non-abrasive friction agent previously heated in the first tank are mixed with said at least one polyol compound previously heated in the second tank. Advantageously, the mixing step is carried out when the temperature of the gelling agent and of the non-abrasive friction agent is between 82 and 88 ° C, preferably 85 ° C and when the temperature of said complex containing at least a polyol compound, is between 82 and 88 ° C, preferably 85 ° C. In a cooling step, the temperature of the mixture obtained at the end of the mixing step is lowered in order to reach a temperature between 55 and 65 ° C, preferably 63 ° C. In an encapsulation step, the enzyme complex is incorporated into the mixture obtained at the end of the cooling step so as to protect the enzyme complex from heat and water. Advantageously, the encapsulation step is carried out when the temperature of said mixture is between 55 and 65 ° C, preferably 63 ° C.

In a second embodiment of the encapsulation step illustrated in Figure 1, the enzyme complex is included in a first solution of distilled water A containing 1 to 60% of the enzyme complex. The first solution of distilled water A is passed in dual channel with a second solution of distilled water B containing 1 to 80% of high molecular weight polysaccharides and soluble in water but not digestible (soluble fiber) with a pH included between 3 and 7.5. The polysaccharide can be modified starch. The first solution of distilled water A and the second solution of distilled water B are passed through a dual channel and ionized by electro nebulizer under a pressure between 0.5 and 10 bars and under a voltage between 500 and 4000 Volts and preferably between 2000 and 3000 volts by means of an electro spray device 10. The term “electro nebulizer ionization” (in English electrospray ionization) is understood to mean the dispersion of a liquid in the form of electrically charged droplets. During this step, the two solutions A and B pass through an emitter 2 and are then projected. The projection of solutions A and B form at the end of the emitter 2 a cone shape with convex sides and a rounded end also called a Taylor cone 3. The ionized capsules are added and dispersed in a receiving tank 5 containing a gelled matrix 4 added with the polyol (s) beforehand.

This step makes it possible to encapsulate small capsules of enzyme complex whose diameter is between 1 and 50 microns.

This encapsulation allows the active enzymatic agents to remain active for 45 minutes so as to protect the oral environment until a new ingestion of sugars.

In a molding step, the encapsulated enzyme complex is placed in molds. Advantageously, the molding step is carried out at a temperature between 55 and 65 ° C, preferably 63 ° C. The temperature of the encapsulated enzyme complex corresponds to the supercooling stage. This level allows the entire mixture to be molded, which may last several tens of minutes.

In a cooling step, the temperature of the mold is lowered in order to solidify the encapsulated enzyme complex and thus form a plurality of pellets.

In a demolding step, the pellets obtained at the end of the molding step are demolded.

In a coating step, the removed pellets are coated with a coating agent. [0083] In a bagging step, each pellet is packaged in an individual bag sealed against moisture and air.

Naturally, the invention is not limited to the various embodiments which have been described, and variant embodiments are possible.

Claims

[Claim 1] Process for preparing a toothpaste composition, in the form of an edible lozenge to suck or chew and comprising: - An enzymatic complex comprising the following compounds: o invertase, o gluco oxidase, oamyloglucosidase, o lactoperoxidase, o lactoferrin, - at least one gelling agent, characterized in that it comprises: - a step of heating said at least one gelling agent to a temperature between 82 and 88 ° C, - a step of encapsulating the enzyme complex by incorporation or by ionization of said enzyme complex in said at least one gelling agent when the temperature of said at least one gelling agent is between 55 and 65 ° C. [Claim 2] Preparation process according to claim 1, characterized in that it comprises, before the encapsulation step: - a step of heating at least one polyol compound to a temperature between 82 and 88 ° C, a step of mixing said at least one polyol compound with said at least one gelling agent when the temperature of said at least one polyol compound and the temperature of said at least one gelling agent are between 82 and 88 ° C, a step of cooling the mixture comprising said at least one polyol compound and said at least one gelling agent to reach a temperature of between 55 and 65 ° C. [Claim 3] Preparation process according to claim 1 or 2, characterized in that it comprises, after the encapsulation step: - a step of molding the encapsulated enzyme complex in molds at a temperature between 55 and 65 ° C. [Claim 4] Preparation process according to claims 1 or 2 characterized in that after the step of heating the gelling agent, the process comprises a step where the gelling agent is maintained at a temperature between 82 and 88 ° C for 40 minutes. [Claim 5] Preparation process according to claims 1, 2 or 4 characterized in that after the step of heating the polyol compound, the polyol compound is maintained at a temperature between 82 and 88 ° C for 40 minutes. [Claim 6] Preparation process according to claim 3 characterized in that after the step of molding the enzyme complex, the method comprises a step where the temperature of the mold is lowered in order to solidify the encapsulated enzyme complex and thus form a plurality. of lozenges. [Claim 7] Preparation process according to claim 1 characterized in that the encapsulation step is carried out by electro nebulizer ionization. [Claim 8] Preparation process according to claim 7, characterized in that two solutions of distilled water are passed through a dual channel and ionized by means of an electro spray device 10. [Claim 9] Preparation process according to claims 7 or 8 characterized in that the encapsulated enzyme complex is dispersed in the gelling agent in the form of a gelled matrix (4). [Claim 10] Preparation process according to claims 7 to 9 characterized in that the enzyme complex is encapsulated in capsules whose diameter is between 1 and 50 microns.