FR3095739A1 - HIGH DENSITY RECONSTRUCTED PLANT LEAF - Google Patents

Abstract

Provided is a reconstituted plant leaf suitable for heating devices without burning tobacco, said reconstituted plant leaf having a high density.

Description

*HIGH DENSITY RECONSTITUTED PLANT SHEET*

The present disclosure relates to the field of devices for heating tobacco without burning it and relates to a reconstituted plant leaf obtained by a high density papermaking process.

Background of the invention

A large number of devices for heating tobacco without burning it have been developed to avoid the formation of harmful constituents during the combustion of tobacco. Mention may be made, by way of example, of the applications published under the numbers WO 2016/026810 and WO 2016/207407 which describe such devices. In these devices, the tobacco is heated to a temperature below the combustion temperature without being burned, which leads to the formation of an aerosol. The aerosol generated during tobacco heating replaces cigarette smoke, has interesting organoleptic properties when inhaled by the user. This allows the user to inhale nicotine and tobacco flavors while significantly reducing their exposure to harmful constituents.

For the user to adopt these heating devices, it is important that the experience provided by said devices be as close as possible to the experience provided by a conventional cigarette, namely a quantity of nicotine equivalent to a conventional cigarette and organoleptic properties satisfying for every puff.

Conventional tobacco is not suitable for such devices because it does not provide a satisfactory experience for the user, in particular it does not easily generate a sufficient quantity of aerosol with interesting organoleptic properties.

Reconstituted tobacco is more suitable for these heating devices, because it makes it possible to generate a large quantity of aerosol having interesting organoleptic properties.

Nevertheless, it is necessary to further increase the nicotine transfer rate and to improve the organoleptic properties of the aerosols formed with each puff so that the experience provided by the heating devices is even closer to the experience provided by a conventional cigarette. .

Summary

It is thus to the merit of the inventors to have found that it was possible to meet these needs using a reconstituted plant leaf comprising:
- a fibrous support comprising refined plant fibres,
- an aerosol generating agent, and
- a plant extract,
characterized in that the density of the reconstituted plant leaf is greater than or equal to 0.6 g/cm ³ .

Advantageously, the reconstituted plant leaf according to the invention has a higher nicotine transfer rate than a reconstituted plant leaf of lower density.

In addition, with each puff, the reconstituted plant leaf according to the invention advantageously forms an aerosol whose organoleptic properties are improved compared to an aerosol formed by a reconstituted plant leaf of lower density.

A second object of the invention is a process for manufacturing a reconstituted plant leaf according to the invention comprising the following steps:
a) passing the plant fibers through a paper machine to form a fibrous support,
b) bringing an aerosol-generating agent and a plant extract into contact with the fibrous support to obtain a moist reconstituted plant leaf, and
c) drying the wet reconstituted plant sheet.

A third object of the invention is a use of a reconstituted plant leaf according to the invention in a heating device, in particular a device for heating tobacco without burning it.

According to a first object, the invention relates to a reconstituted plant leaf comprising:
- a fibrous support comprising refined plant fibres,
- an aerosol generating agent, and
- a plant extract,
characterized in that the density of the reconstituted plant leaf is greater than or equal to 0.6 g/cm ³ .

Typically the density of the reconstituted plant leaf may be between 0.62 g/cm ³ and 1.50 g/cm ³ , in particular between 0.65 g/cm ³ and 1 g/cm ³ .

Typically the density of the reconstituted plant leaf is calculated by dividing its basis weight by its thickness.

To determine the weight of the plant leaf, the following method can be used:
A sample of 0.25 m² is cut with a template (dimensions: 57.5 x 43.5 cm) approximately 15 cm from the edge of the reconstituted plant leaf to be analyzed. The sample is then folded in four and placed on a hot plate to be dried in order to eliminate the water without eliminating the aerosol-generating agent.
The dried sample is then weighed to determine the basis weight of the plant leaf.

To determine the thickness of the plant leaf, the method described in standard NF EN ISO 534 (December 2011) adapted to reconstituted plant leaves can be used:
- measurement of the average thickness of the control parchment paper used to measure the thickness of the reconstituted plant leaf (6 measurements minimum on one layer, on places marked on the paper),
- the reconstituted plant leaf sample is placed between 2 layers of parchment paper,
- as soon as the micrometer probe is in place, wait 30 seconds before taking the measurement (stabilization of the sample during the thickness measurement),
- 6 measurements minimum at the places marked on the sheet of parchment paper,
- the thickness of the calculated reconstituted plant sheet is the average of the overall thickness measured (reconstituted plant sheet + 2 layers of parchment paper) from which is subtracted 2 times the average thickness of the parchment paper.

Typically the reconstituted plant sheet may have a weight of between 60 g/m² and 300 g/m², in particular between 80 g/m² and 250 g/m², very particularly between 90 g/m² and 200 g/m², more particularly still between 140gsm and 190gsm.

Typically, the reconstituted plant leaf may have a thickness of between 100 μm and 450 μm, in particular between 120 μm and 375 μm, most particularly between 140 μm and 325 μm.

According to a particular embodiment, the reconstituted plant leaf may have a density of between 0.65 g/cm ³ and 1 g/cm ³ , a basis weight between 90 g/m ² and 200 g/m ² and a thickness between 140µm and 325µm.

Those skilled in the art will know how to adapt the basis weight and the thickness of the reconstituted plant sheet to achieve the desired high density.

Within the meaning of the present application, “fibrous support” denotes a base sheet (“web base” in English) comprising refined fibers of the plant, the base sheet being typically obtained by a papermaking process.

Within the meaning of the present application, “refined plant fibers” designates plant fibers having undergone a refining step allowing the fibrillation and/or cutting of the plant fibers. The refining step is conventionally implemented in a papermaking process, such as the papermaking process for manufacturing papermaking reconstituted tobacco. On the other hand, the refining step is not implemented in a process for manufacturing cast leaf reconstituted tobacco.

Typically the fibrous support can comprise refined fibers from the same plant or from several plants.

Within the meaning of the present application, "aerosol-generating agent" designates a compound which allows the formation of an aerosol when it is heated, for example in contact with hot air.

Let S _AG be the total content by weight of dry matter of the aerosol-generating agent included in the reconstituted plant leaf of the present invention. Typically S _AG can be between 10% and 29%, in particular between 14% and 27%, more particularly between 16% and 25%.

The aerosol generated by a reconstituted plant leaf having an S _AG greater than the ranges mentioned above causes unwanted burning of the mouth and/or throat (a phenomenon known as "hot puff").

Typically the aerosol generating agent can be a polyol, a non-polyol or a mixture thereof. Typically a polyol generating agent can be sorbitol, glycerin, propylene glycol, triethylene glycol or a mixture thereof. Typically a non-polyol generating agent can be lactic acid, glyceryl diacetate, glyceryl triacetate, triethyl citrate, isopropyl myristate or a mixture thereof.

According to one embodiment, the aerosol-generating agent is glycerin, propylene glycol, or a mixture of glycerin and propylene glycol, glycerin being preferred.

An aerosol is generated during heating of the reconstituted plant leaf of the invention. Advantageously, the plant extract which comprises aromatic compounds gives this aerosol aromas of the plant. By simply changing the reconstituted plant leaf, the user can easily vary the aromas of the aerosol generated by the heating of said reconstituted plant leaf.

Within the meaning of the present application, "plant extract" designates all the water-soluble products of the plant. Advantageously, the plant extract comprises nicotine, the compounds conferring organoleptic properties and/or therapeutic properties on the aerosol.

The organoleptic properties and the therapeutic properties of the aerosol formed by heating said reconstituted plant leaf may depend on the dry matter weight content of the plant extract comprised in the reconstituted plant leaf of the present invention.

The total content by weight of dry matter of the plant extract depends on the plant used and, more particularly, on the content of aromatic compounds or compounds with therapeutic properties of the plant used.

Let S _P be the total content by weight of dry matter of the plant extract included in the reconstituted plant leaf of the present invention. Typically S _p can be between 20% and 45%, in particular between 25% and 40%, more particularly between 27% and 36%.

To determine S _P , the following method can be used:
The reconstituted plant leaf to be analyzed is ground in order to reach a particle size less than or equal to 1 mm. The reconstituted plant leaf is then mixed with boiling water for 45 minutes to extract all of the plant extract. S _P is calculated by the difference between the dry weight of the reconstituted plant leaf sample to be analyzed and the dry weight of the fibrous residue after extraction.

According to one embodiment, the sum of the total content by weight of dry matter of plant extract and the total content by weight of dry matter of aerosol-generating agent, S _P + S _AG , can be between 40% and 70%, in particular between 45% and 65%, more particularly between 50% and 60%.

According to one embodiment, the ratio between the total content by weight of dry matter of plant extract and the total content by weight of dry matter of aerosol-generating agent, S _P /S _AG , is between 1, 0 and 2.0, in particular between 1.10 and 1.80, more particularly between 1.15 and 1.70.

Advantageously, the nicotine transfer rate is improved and the organoleptic properties of the aerosols formed are even more satisfactory when the reconstituted plant leaf according to the invention has an S _P /S _AG ratio in the ranges mentioned above.

According to a particular embodiment, the reconstituted plant leaf may have an S _AG between 16% and 25%, an S _P between 27% and 35%, an S _P + S _AG between 50% and 60%.

According to a particular embodiment, the reconstituted plant leaf may have a density of between 0.65 g/cm ³ and 1 g/cm ³ , a basis weight between 90 g/m ² and 200 g/m ² and a thickness between 140 µm and 325 µm, an S _AG between 16% and 25%, an S _P between 27% and 35%, and an S _P + S _AG between 50% and 60%.

The plant fibers and the plant extract may be independently obtained from a plant selected from spore plants, seed plants or a mixture thereof. In particular, the plant can be a plant chosen from the tobacco plant, food plants, aromatic plants, perfume plants, medicinal plants, plants of the Cannabaceae family , or a mixture of these.

According to a particular embodiment, the plant is the tobacco plant.

If the plant is a medicinal plant, the aerosol generated by heating the reconstituted plant leaf may also exhibit therapeutic properties such that the reconstituted plant leaf may be used for therapeutic treatment.

Advantageously, a plant extract obtained from a mixture of plants makes it possible to offer a wide range of organoleptic properties and/or therapeutic properties. A mixture of plants also makes it possible to counterbalance the unpleasant organoleptic properties of a plant of the mixture, for example a medicinal plant, by the pleasant organoleptic properties of another plant of the mixture, for example the tobacco plant, an aromatic plant or a perfume plant.

Typically the plant fibers can be obtained from a first plant and the plant extract can be obtained from a second plant. In fact, the fibers of a plant may not have mechanical properties allowing the formation of a fibrous support, but the extract of this plant may give the aerosol organoleptic properties and/or desired therapeutic properties. Conversely, the fibers of a plant may have mechanical properties allowing the formation of a fibrous support, but the extract of this plant may not give the aerosol the organoleptic properties and/or the desired therapeutic properties.

Advantageously, mixing plants to obtain the plant fibers makes it possible to adapt the mechanical properties of the reconstituted plant leaf and/or the organoleptic or chemical properties of the aerosol.

When the plant is the tobacco plant, then the tobacco fibers and tobacco extract may be obtained from any tobacco plant or type of tobacco, for example Virginia tobacco, Burley tobacco, air-cured tobacco, dark air-cured tobacco, oriental tobacco, sun-cured tobacco, fire-cured tobacco or a mixture thereof.

Typical food plants are garlic, coffee, ginger, liquorice, rooibos, stevia rebaudiana, tea, cocoa, chamomile, maté, star anise, fennel, lemongrass.

Typical aromatic plants are basil, turmeric, clove, bay leaf, oregano, mint, rosemary, sage, thyme.

Typical perfume plants are lavender, rose, eucalyptus.

Typically the medicinal plants are those indicated in the document, list A of medicinal plants traditionally used (French Pharmacopoeia January 2016, published by the National Agency for the Safety of Medicines (ANSM) or plants known to include compounds with therapeutic properties. Typical medicinal plants listed are ginkgo, ginseng, sour cherry, peppermint, willow and red vine.

Typically among the medicinal plants known to include compounds with therapeutic properties are eucalyptus.

Typically the plant fibers and plant extract of the reconstituted plant leaf of the present invention may result from different parts of the plant, the parts of the plant being parts of the plant itself or the result of processing of different parts of the plant. Typically the plant parts may be whole plant parts or debris from threshing or mixing and chopping the plant parts.

Typically, the parts of the plant can be selected from among the parts of the plant that are richest in aromatic compounds giving the aerosol its organoleptic properties. Typically these parts can be the whole plant, the aerial parts of the plant such as the flower bud, the branch bark, the stem bark, the leaves, the flower, the fruit and its peduncle, the seed, the petal , the flowering top, or the underground parts, for example, the bulb, the roots, the root bark, rhizome or a mixture of these. The part of the plant can also be the result of the mechanical, chemical or mechano-chemical transformation of one or more parts of the plant, such as for example the shell protecting the cocoa bean resulting from the process of shelling the beans.

Typically the parts of the tobacco plant can be the parts richest in aromatic compounds which give the aerosol its organoleptic properties. Typically the parts of the tobacco plant may be the parenchyma (lamina) optionally supplemented with ribs (stems) of the tobacco plant. Typically the parts of the tobacco plant may be the leaves of the tobacco plant or the debris from the threshing or mixing and chopping into scaferlati of the leaves and veins of the tobacco plant.

Among the food plants, one can select as parts, for example, the bulb of garlic, the fruit of coffee or star anise, the rhizome of ginger, the root of licorice and the leaves of rooibos, stevia rebaudiana, or tea.

Among the aromatic plants, one can select as parts, for example, the flower buds of the clove tree (cloves), the leaves of basil, laurel and sage, the leaves and flowering tops of mint, oregano, rosemary and thyme, or the turmeric rhizome.

Typically among perfume plants, one can select the flower and the flowering top of lavender, or the flower bud and the petals of the rose.

Among the medicinal plants listed in the French pharmacopoeia, one can select, for example, the leaf of ginkgo, the underground part of ginseng, the peduncle of the fruit (tail of cherry) of the cherry tree, the leaves and the flowering top of peppermint , the stem bark and leaves of the willow, or the leaves of the red vine.

According to a particular embodiment, the reconstituted plant leaf may have a density of between 0.65 g/cm ³ and 1 g/cm ³ , a basis weight between 90 g/m ² and 200 g/m ² and a thickness between 140 µm and 325 µm, an S _AG between 16% and 25%, an S _P between 27% and 35%, and an S _P + S _AG between 50% and 60% and the plant is the tobacco plant.

Typically the content by weight of dry matter of the refined plant fibers included in the reconstituted plant leaf can be between 15% and 70%, in particular between 30% and 61%, more particularly between 40% and 57%.

Typically, the fibrous support of the reconstituted plant sheet may further comprise plant cellulosic fibers.

Vegetable cellulosic fibers are fibers obtained by a chemical or mechanical or thermo-mechanical cooking process such as wood pulp, hemp, or annual plants such as flax for example. A mixture of these vegetable cellulosic fibers can also be used.

Advantageously, these plant cellulosic fibers can improve the mechanical strength properties of the reconstituted plant leaf.

Typically, the plant cellulosic fibers can represent between 0.5% and 20%, in particular between 3% and 17.5%, more particularly between 5% and 15% by weight in dry matter of the reconstituted plant sheet.

According to a second object, the invention relates to a method for manufacturing a reconstituted plant leaf as defined above comprising the following steps:
a) passing the refined plant fibers through a paper machine to form a fibrous support,
b) bringing an aerosol-generating agent and a plant extract into contact with the fibrous support to obtain a moist reconstituted plant leaf, and
c) drying the wet reconstituted plant sheet.

According to the invention, the fibrous support is manufactured using a papermaking process. According to a preferred mode of the invention, a reconstituted plant leaf according to the invention is a reconstituted plant leaf capable of being obtained by a papermaking process.

Typically, the fibrous support formed during step a) can have a weight of between 25 g/m² and 150 g/m², in particular the minimum value of the weight can be 55 g/m², 60 g/m², 65 g /m², 70 gsm, 75 gsm.

Advantageously, a fibrous support whose basis weight is included in the above ranges makes it possible to obtain the desired high density.

Typically, the fibrous support formed during step a) may have a thickness of between 70 μm and 430 μm, in particular between 100 μm and 350 μm, most particularly between 120 μm and 300 μm.

The basis weight and thickness of the fibrous support are typically measured by the same methods as the basis weight and thickness of the reconstituted plant sheet described above.

According to one embodiment, the plant fibers of the fibrous support and the plant extract are obtained according to the following steps:
d) mixing one or more parts of the plant with a solvent in order to extract the plant extract from the plant fibres,
e) separating the plant extract from the plant fibres.

Plant extract and plant fibers are therefore typically obtained by a dissociation process. During step d), one or more parts of the plant are mixed with a solvent, for example in a digester, in order to extract the plant extract from the plant fibres. During step e), the plant extract is separated from the plant fibers, for example by passage through a screw press, to isolate and obtain, on the one hand, the plant fibers and, on the other hand , plant extract.

Typically the solvent can be an apolar solvent, an aprotic polar solvent, a protic polar solvent or a mixture of these, in particular the solvent can be methanol, dichloromethane, ethanol, acetone, butanol, water or a mixture thereof, more particularly the solvent is ethanol, acetone, water or a mixture thereof.

According to a particular embodiment, the solvent is an aqueous solvent, most particularly the solvent is water.

A person skilled in the art will know how to adapt the temperature of the solvent during step d) to the plant, to the part of the plant and to the parts of the plant to be treated. Typically the solvent temperature when treating a root or bark will be higher than the solvent temperature when treating a leaf or petal.

Typically the temperature of the solvent during step d) can be between 10°C and 100°C, in particular between 30°C and 90°C, more particularly between 50°C and 80°C.

Depending on the embodiment in which the solvent is water and the plant is tobacco, the water temperature can typically be between 30°C and 80°C. Typically for treating the ribs of a tobacco plant, the water temperature can be between 50°C and 80°C. Typically for the treatment of the parenchyma of a tobacco plant, the water temperature can be between 30°C and 70°C.

Typically the plant fibers can be refined in a refiner and then passed through the paper machine to form the fibrous support.

Typically refined plant fibers can come from different plants.

The fibers of each plant can be obtained separately according to the dissociation process described above. They can then be mixed so that this mixture of fibers from different plants goes through the paper machine to form the fibrous support. It is also possible to obtain fibers from different plants together by bringing together one or more parts of the different plants and then subjecting them to the dissociation process described above. The water temperature will then be adapted to the plants to be treated and, in particular, to the plant requiring the highest water temperature to extract the extract from this plant. This alternative embodiment is very advantageous because it makes it possible to obtain the fibers of the different plants without implementing several dissociation processes in parallel.

Typically the plant extract can be an extract from different plants.

The extract of different plants can be obtained by mixing different plant extracts obtained separately according to the dissociation method described above. It is also possible to obtain the extract of different plants by bringing together one or more parts of the different plants and then subjecting them to the dissociation process described above. The water temperature will then be adapted to the plants to be treated and, in particular, to the plant requiring the highest water temperature to extract the extract from this water-soluble plant. This alternative embodiment is very advantageous because it makes it possible to obtain the extract from different plants without implementing several processes in parallel. In these two cases, the extract from different plants is brought into contact with the fibrous support during step b).

Typically different plant extracts, obtained according to the dissociation process described above, can also be brought into contact with the fibrous support separately during step b).

Typically the plant extract can be concentrated before being brought into contact with the fibrous support during step b). A device such as a vacuum evaporator can be used to concentrate the herbal extract.

Typically during step b), the plant extract and the aerosol-generating agent can be brought into contact with the fibrous support one after the other, or can be mixed to be brought into contact with the fibrous support together.

Typically step b) of bringing the plant extract into contact can be carried out by impregnation or by spraying, in particular by impregnation. Typically the impregnation can be carried out using a size press.

For example, to obtain the desired high density, it is possible to reduce the linear pressure applied by the size press during step b). Typically, this linear pressure during step b) is significantly lower than the linear pressure applied by a size press implemented in conventional papermaking processes for the production of reconstituted plant leaves, such as those described in applications FR 15 59081 and FR 17 57991.

To obtain the desired high density, it is also appropriate to adapt the total amount of plant extract and of aerosol-generating agent used in step b) to the basis weight of the fibrous support.

Contrary to conventional papermaking processes for the production of reconstituted plant leaves, which produce reconstituted plant leaves having a density of less than 0.6 g/cm ³ , and without wishing to be bound by any theory, the inventors are of the opinion that the step b) of the process of the invention makes it possible to obtain the desired high density by allowing impregnation of the plant extract and of the aerosol-generating agent in the fibrous support. This specific impregnation makes it possible to obtain a homogeneous distribution of the plant extract and of the aerosol-generating agent in the fibrous support and to increase the nicotine transfer rate.

Typically, a person skilled in the art will know how to adapt the operating conditions to carry out step c) of drying.

Typically, step c) of drying can be carried out by Infrared ramp, roller dryers in an American battery, drying with hot air in a tunnel dryer, a vertical dryer, a fluidized bed dryer, a pneumatic dryer, in particular in a tunnel dryer.

The reconstituted plant leaf of the invention can then be cut into sheets, sheets similar to tobacco strips or rolled into a roll. Multiple sheets can be put together to form a sheet mix.

The reconstituted plant leaf of the invention can be used in a tobacco heating device without burning it.

Thus, according to a third object, the invention relates to a use of a reconstituted plant leaf as defined above in a heating device, in particular a device for heating tobacco without burning it.

Within the meaning of the present invention, the term "device for heating tobacco without burning it" designates any device allowing the formation of an aerosol intended to be inhaled by a consumer. The aerosol replaces smoke, allowing the user to inhale plant aromas while significantly reducing their exposure to harmful constituents.

Typically a heating device comprises, in the direction of the air flow, an air inlet, a heating body, a location intended for the establishment and maintenance of the reconstituted plant leaf of the invention comprising the generating agent, and an air outlet intended to be introduced into the mouth of the user. The air inlet, the heating body, the location, and the air outlet are typically interconnected at least fluidly.

Typically when using the heater, air is drawn into the heater by the user through the air inlet; the sucked air then passes through the heated part to obtain heated air; in contact with the reconstituted plant leaf of the invention comprising the generating agent held in the location, an aerosol is formed by the heated air and is then inhaled by the user. If the plant is a medicinal plant, then the aerosol formed has therapeutic properties.

In addition, thanks to the heating device, there is no burning of the sheet. The user can therefore take advantage of the organoleptic properties of the plant, and possibly of tobacco, while very significantly reducing his exposure to harmful constituents.

Examples

Sheet 1 reconstituted tobacco according to the invention

A mixture of Virginia-type tobacco scraps and ribs is brought into contact with water at 65° C. with stirring for 45 minutes. The tobacco extract is separated from the fibrous part by mechanical pressing. The tobacco extract is concentrated under vacuum to a dry matter concentration of 54%. Glycerin, as an aerosol generating agent, is added in the concentrated tobacco extract.
The tobacco fibers are refined then passed through a laboratory paper machine to form a fibrous support with a basis weight of approximately 77 g/m².
The concentrated tobacco extract comprising the glycerin is brought into contact with the fibrous support by impregnation in a size press to produce the reconstituted tobacco sheet in order to obtain an _SP of 27.3%, an S _AG of 23.7 % and a sum S _AG + S _P of 51% in the reconstituted tobacco leaf produced.

This sheet has a density of 0.68 g/cm ³ , a basis weight of 145 g/m² and a thickness of 212 μm.

F hey 2 of reconstituted tobacco in accordance with the invention

Another sheet of reconstituted tobacco is produced according to the method described above, the differences being that: it is a mixture of strips and stems of Virginia type tobacco which is used, the grammage of the fibrous support is approximately 78 g/m², S _AG is 20.7%, S _P is 30.8% and the sum S _AG + S _P is equal to 51.5%.

This sheet has a density of 0.69 g/cm ³ , a basis weight of 156 g/m² and a thickness of 226 μm.

F hey 3 of reconstituted tobacco in accordance with the invention

Another sheet of reconstituted tobacco is produced according to the method described above, the differences being that: it is a mixture of strips and stems of Virginia type tobacco which is used, the grammage of the fibrous support is approximately 63 g/m², S _AG is 21.1%, S _P is 35.4% and the sum S _AG + S _P is equal to 56.5%.

This sheet has a density of 0.84 g/cm ³ , a basis weight of 129 g/m² and a thickness of 153 μm.

Reconstituted tobacco leaf not in accordance with the invention

A sheet of reconstituted tobacco not in accordance with the invention is produced according to a procedure similar to that described above, the differences being that the basis weight of the fibrous support is 57 g/m², that S _P is 34.1% , S _AG is 14.9% and the sum S _AG + S _P is 43%.

This sheet of reconstituted tobacco has a density of less than 0.6 g/cm ³ , a basis weight of 95 g/m² and a thickness of 166 μm.

Rate nicotine transfer

The nicotine transfer rate of Sheet 1 of reconstituted tobacco in accordance with the invention and of the sheet of reconstituted tobacco not in accordance with the invention is determined with a heating system of the glo ^TM type and according to the following protocol.

The rate of nicotine transfer into a reconstituted tobacco leaf is calculated by dividing the nicotine content in the aerosol generated by the heating of said reconstituted tobacco leaf by the nicotine content in said reconstituted tobacco leaf.

The nicotine content in the aerosol generated by heating the reconstituted tobacco leaf is determined as follows:
commercial sleeves of Kent sticks for glo ^TM are emptied of their tobacco then filled with scaferlati of the leaf tested, with a mass of tobacco of 260 mg/stick and a draw resistance of 70 +/- 3 mm of column of water,
an aerosol is generated via a Borgwaldt RM04 smoking machine on which the filled Kent sticks have been installed (by applying the operating procedure supplied with the glo ^TM type heating system),
the aerosol material is collected on a Cambridge 40 mm filter. It is then dissolved in methanol,
the nicotine content in the aerosol is assayed after separation by gas chromatography and assay by FID with respect to n-heptadecane (used as standard). The nicotine content of the aerosol is measured according to the ISO10315:2013 standard, using methanol instead of the isopropanol mentioned in the standard. The chromatography equipment used is the same as that used for the nicotine analysis of the leaf tested. 6 replicates are carried out for the determination of the nicotine content in the aerosol.

The nicotine content in reconstituted tobacco leaf is determined as follows:
the nicotine content in the sheet tested is determined by gas chromatography analysis - FID detection, with an Innowax gas chromatography column (dimensions of the column: length 30 m; internal diameter: 0.53 mm; film thickness 1 μm).

The results for the sheets tested are shown in [Table 1] below.

These results demonstrate that the nicotine transfer rate of Sheet 1 of reconstituted tobacco in accordance with the invention is significantly higher than the nicotine transfer rate of tobacco leaves having a density of less than 0.6 g/cm ³ .

Sheet 1 of reconstituted tobacco in accordance with the invention 38% Reconstituted tobacco leaf not in accordance with the invention <30%

P organoleptic properties

The tobacco leaf in accordance with the invention and a tobacco leaf not in accordance with the invention are cut into scaferlati and then smoked, one after the other, by an independent expert in a glo ^TM type heating system.

According to the independent expert, all the aerosols formed during the smoking of the tobacco leaf in accordance with the invention have very satisfactory organoleptic properties, in particular the aerosol is not very bitter, not very irritating, not very aggressive and has a good round taste. and balanced greater than the aerosols formed during the smoking of the tobacco leaf not in accordance with the invention.

Claims (11)

Reconstituted plant sheet comprising:
- a fibrous support comprising refined plant fibres,
- an aerosol generating agent, and
- a plant extract,
characterized in that the density of the reconstituted plant leaf is greater than or equal to 0.6 g/cm ³ . Reconstituted plant leaf according to Claim 1, the density of which is between 0.62 g/cm ³ and 1.50 g/cm ³ . A reconstituted plant leaf according to claim 1 or claim 2 wherein the plant is the tobacco plant. A reconstituted plant leaf according to any one of Claims 1 to 3, in which the total content by weight of dry matter of aerosol-generating agent is between 10% and 29%. Reconstituted plant leaf according to any one of claims 1 to 4, in which the total content by weight of dry matter of the plant extract is between 20% and 45%. A reconstituted plant leaf according to any one of claims 1 to 5, wherein the sum of the total content by weight of dry matter of plant extract and the total content by weight of dry matter of aerosol is between 40% and 70%. Reconstituted plant leaf according to any one of Claims 1 to 6, the thickness of which is between 100 µm and 450 µm. Reconstituted plant sheet according to any one of Claims 1 to 7, the basis weight of which is between 60 g/m² and 300 g/m². A reconstituted plant leaf according to any one of claims 1 to 8, wherein the aerosol generating agent is sorbitol, glycerin, propylene glycol, triethylene glycol, lactic acid, glyceryl diacetate, glyceryl triacetate, triethyl citrate, isopropyl myristate or a mixture thereof. A method of manufacturing a reconstituted plant leaf as defined in claims 1 to 9 comprising the following steps:
a) passing the refined plant fibers through a paper machine to form a fibrous support,
b) bringing an aerosol-generating agent and a plant extract into contact with the fibrous support to obtain a moist reconstituted plant leaf, and
c) drying the wet reconstituted plant sheet. Use of a reconstituted plant leaf as defined in claims 1 to 9 in a heating device.