1 PROCESS The present application is a divisional application from Australian patent application number 2013336577, filed 25 October 2013, which claims priority from European patent application number 12290369.3, filed 25 October 2012, the entire disclosures of which are incorporated 5 herein by reference. This disclosure relates to the encapsulation of actives, and particularly fragrances. Core-shell microcapsules, that is, microcapsules in which a core of a desired active is completely 0 surrounded by a polymeric shell, have been known and used for some time. Typical actives for encapsulation include pharmaceutical and medicinal substances, fragrances and flavours, encapsulation being used for their preservation and later release. Typical examples of uses include, in the fragrance area, fine fragrances, consumer products such as laundry applications including softeners, liquid detergents, and powder detergents; personal care and hair care 5 applications including shampoo, conditioners, combing creams, leave-on conditioners, styling cream, soaps, body creams; deodorants and anti-perspirants; oral care applications, household applications such as cleaning compositions, and in the flavours area, all kinds of consumable compositions (including foodstuffs, beverages and medicinal compositions). 0 Encapsulation has typically been achieved by emulsifying the active in a solution of shell forming material and causing the polymer shell to form around the emulsified active particles or droplets. A wide variety of shell materials are known and have been used, for example, gelatine, aminoplast (urea- and melamine-formaldehyde) resins, polyuria polyurethane and acrylic. These typically involve chemical reaction in the formation of the shell, or in its 25 subsequent consolidation, for example, by crosslinking. It has now been found that an alternative technique may be used successfully to provide encapsulated actives. There is therefore provided a method of encapsulation of active comprising (a) dispersing an active in an aqueous medium having a pH of less than 6; 30 (b) causing the formation on this dispersed active of a polymer shell, the formation comprising the sequential deposition of a series of polymeric layers, each layer being capable of hydrogen bonding with the preceding layer; to form an aqueous slurry of active-containing capsules; characterised in that one of the first two layers is a polycarboxylic acid and that the first two 35 to four layers taken together exhibit an interfacial compression dilation modulus of greater than 10 mN/m.
WO 2014/064252 PCT/EP2013/072397 2 There is additionally provided encapsulated active, comprising a core of active completely surrounded by a polymeric shell, the shell comprising at least two layers of polymer, each polymer layer being hydrogen-bonded to the adjacent layer(s), and one of the first two layers being a polycarboxylic acid, the first two to four layers taken together exhibiting an 5 interfacial compression dilation modulus of greater than 10 mN/n. The technique used here is so-called layer-by-layer (LbL) encapsulation. Previously, it has involved the alternate application of two polyelectrolytes to a sacrificial template core (typically silica) to build up a series of layers held together by electrostatic attraction and/or 10 hydrogen bonding. When the desired layers have been attained, the core is then dissolved to give a hollow capsule, which may then be loaded with the desired active. The technique offers the possibility of unprecedented control over release properties, and has been of great interest to the pharmaceutical industry (see, for example, Kozlovskaya et al, Chen. Mater. 2006, 18, 328-336). 15 In this particular application, it has been found possible to make active-containing LbL capsules without any kind of template. To do this, the first two to four layers must comply with a particular physical parameter. This shall be further discussed hereinunder. 20 The method offers numerous advantages: 1. It does not use any chemical reaction which could leave a residue. Residues can be a problem in some potential uses, for example, in cosmetic and personal care applications. In addition, the polymers used can be selected from polymers that are 25 stable and do not depolymerise to give undesirable species. 2. It allows the precise tailoring of the nature of the capsule shell, and therefore of their robustness and friability, so that breakage at the right time can be assured. 3. It allows robust capsules to be made with shells that are considerably thinner than those made by other techniques. A typical capsule shell made by conventional 30 methods has a thickness of the order of 100-150nm. Robust shells of thicknesses as low as 5nm can be made. 'Typical size ranges are from 5-100, particularly from 5 70, more particularly from 5-50nm 4. In the specific case of fragrance encapsulation, it allows the preparation of capsules that have a minimal effect on perfumes. It is well known that certain fragrance WO 2014/064252 PCT/EP201 3/072397 components, notably aldehydes, have a tendency to react with some encapsulation materials. This can result in the fragrance created by the perfumer not being realised to its full hedonic capacity. 5 Of the initial two layers of the shell, one must be a polycarboxylic acid. By "polycarboxylic acid" is meant any polymeric material that has a plurality of pendant carboxylic acid groups (which term includes acid anhydrides that become acids under the conditions of the process). 10 The two layers combine by hydrogen bonding, The phenomenon of hydrogen bonding and the criteria to be fulfilled, so that one material is hydrogen-bonded to another, are well known to the art. In this particular case, there must additionally be adherence to a further parameter, as described hereinunder. Typical combinations include poly(methacrylic acid)/poly(vinyl pyrrolidone), poly(acrylic acid)/poly(vinyl pyrrolidone), poly(vinyl 15 acetate)/ ethylene-malei c anhydride copolymer and poly(vinyl alcohol),/ethylene-maleic anhydride copolymer. Once the initial two layers have been applied, the succeeding layers need not be selected from the same materials as these initial two layers. The only requirement is that each layer 20 hydrogen-bonds with the previous layer. This allows considerable versatility in tailoring the nature of the shell for desired properties The shell must be such that the first two to four layers exhibit an interfacial compression dilation modulus of greater than 10 mN/rm, preferably greater than 15mN/m more 25 preferably greater than 20mN/m. The achievement of this for any given polymer selection is by routine non-inventive experimentation. The interfacial compression dilation modulus E is given by the equation: 30 F- dv dy 30 ~~~E = A0 -'y- = -- y-- "dA din A in which AO is the initial area of the droplet, A is the arca of the droplet and y is the interfacial tension.
WO 2014/064252 PCT/EP201 3/072397 4 The equipment used to measure the interfacial compression dilation modulus is well known to the art. A typical example of a suitable apparatus is a rising/pendant drop tensiometer of the type described in Cao et al in Journal of Colloid and Interjace Science (2004) 270:295 298. 5 Examples of an appropriate equipment and method of measurement are further described in detail in the examples hereinunder. The method of making the capsules consists of applying successive polymer solutions to 10 the active dispersed in aqueous solution. In each layering stage, an excess of polymer is used and the remainder washed away prior to the application of the next layer. 'This has the advantage that no particular proportions of polymer need be used, so no precise compositional limitations need be observed. 15 A further advantage of the process is that the high interfacial modulus generated by the polymer association allows the formation of microcapsules with a wide variety of methods such as emulsification, microfluidic or prilling. The process is simple and robust that allows the achievement of active-bearing capsules 20 having non cross-linked walls of hitherto unobtainable thinness. A typical wall thickness of a melamine-formaldehyde capsule is 150 nm; the thickness here can be as low as 5 nm. Moreover, the process allows the precise tailoring of capsule characteristics, to give an optimum compromise between porosity, robustness (to withstand the rigours of manufacture, compounding, transport and storage) and friability (to allow the capsule to 25 break at the appropriate time and release its active). Moreover, these thin-walled, non cross-linked nicrocapsules do riot leave any toxic nor sensitive residuals if applied on skin. The polymer shell may optionally be crosslinked or immobilised. This may be achieved by any convenient means. For example, polymers having amino or hydroxyl groups may be 30 crosslinked by the addition of materials such as amines, glutaraldehyde, isocyanates, epoxides or silicate coupling agents having such a reactive function. Alternatively, there may be provided a final layer of silicate. This is provided by the hydrolysis of
(R)
1 -Si(ROH) 4 - in which R is CI-C3 alkyl and n=1-4, and the addition of the hydrolysis product to the slurry of LbL capsules.
WO 2014/064252 PCT/EP201 3/072397 The polymer shell may optionally be used as a basis for further chemistry in order to obtain aminoplast, polyurea, polyurethane, polyacrylic or inorganic microcapsules, by depositing such materials on the shell. 5 The capsules prepared as hereinabove described may be used in many different applications. Typical examples of commercial compositions (i.e., compositions sold for particular consumer or industrial end-uses) include (i) in the fragrance industry, fine fragrances, consumer products such as laundry 10 applications including softeners, liquid detergents, and powder detergents; personal care and hair care applications including shampoo, conditioners, combing creams, leave-on conditioners, styling cream, soaps, body creams; deodorants and anti-perspirants; oral care applications, such as toothpastes and mouthwashes, household applications such as cleaning compositions, 15 medicinal products; (ii) in the flavours industry, all kinds of consumable compositions, such as canned and instant soups., pre-packaged meals, frozen foods, frozen desserts, baked goods, beverages, dairy products; (iii) in the medicinal area, all manner of pharmaceutical and medicinal substances. 20 It is naturally possible to include more than one active. There is therefore also provided a commercial composition comprising a commercial composition base and an encapsulated active, the active being contained in capsules 25 prepared as hereinabove described. By "commercial product base" is meant all the art recognised ingredients nornally used in the particular composition. The natures and proportions of these will vary according to the nature of the composition, but all such formulation is within the ordinary skill of the art. 30 The quantity of capsules added will depend entirely on the end-use and the nature of the composition. Given the wide variety of such end-uses and compositions, the possible proportions involved are equally wide, but a suitable proportion can always be ascertained by non-inventive, routine experimentation.
WO 2014/064252 PCT/EP201 3/072397 6 The disclosure is further described with reference to the following non-limiting examples, which depict particular embodiments. Example 1: 5 Method of measurement of interfacial compression dilation modulus. The interfacial compression dilation modulus is measured using a rising/pendant drop tensionieter of the type described in Cao et al in Journal of Colloid and Interface Science (2004) 270:295-298. 10 1. Preparation of polymer solution at lwt% in water a. The polymer is dissolved in Milli-Q Water at 2wt%. Millipore (Milli-Q system) filtered water with an 18.2 MQ resistivity is used b. The solution is stirred for at least 12h 15 c. The pI of the polymer solution is adjusted to 3 with 1M NaOH or IM HCl d. Water is added until a lwt% polymer solution is obtained. 2. Preparation of the rinsing solution: Millipore water is adjusted to pH 3 with IM HCI 20 3. Layer construction at the oil/water interface a. 5 mL of a solution of a first polymer (Polymer A) is introduced into the cell b. A drop of fragrance is formed in the cell at the end of a needle (drop volume depending on the system) c. A waiting time of ih to I 2h enables the polymer adsorption at the oil-water 25 interface d. The aqueous phase in the cell is rinsed with the rinsing solution to remove excess polymer. The rinsing is done with a bulk phase exchange. There is a flow of 1OmL/min for 15 min. e. 15 min. wait 30 f. The aqueous phase in the cell is then rinsed with a second polymer solution (Polymer B). The rinsing is done with a bulk phase exchange. There is a flow of I OmL/min for 5 min. g. A waiting time of 25 min to lh enables the second polymer adsorption at the oil-water interface WO 2014/064252 PCT/EP201 3/072397 h. The method is repeated until the desired number of layers at the oil-water interface is achieved. 4. Measurement of the interfacial dilation-compression modulus 5 a. Once the layers are adsorbed, the measurement is carried out b. Area oscillations are run for frequency of 0. 1 Hz for area deformation from 0.1 to 10% c. Values of interracial compression dilation modulus are calculated according to the equation given above, 10 Example 2 Preparation of fragrance-containing capsules The polymers used in this are poly(methacrylie acid) and poly(vinyl pyrrolidone). 2 layers, when measured by the method outlined hereinabove, exhibit a interfacial compression 15 dilation modulus of 150mN/m. A 5niL of a 1% (wt) PMAA aqueous solution is adjusted to p'- 1 3. To this solution is added 5mL of a proprietary fragrance. The two solutions are kept in contact for 24 hours, then emulsified using an Ultra-turrax m blender at 24000rpm for 2 minutes. The emulsion is 20 added to a separating funnel and washed with water at pH 3 (10-3 M HCl) to give a 10% fragrance solution. This solution is slowly mixed and then allowed to settle for 24 hours. The lower aqueous phase is removed and washed four times to extract excess polymer. This 25 washed phase is added to 1(wt)% aqueous PVP solution at pH3 under gently stirring. This phase is allowed to settle for 24h and it is then washed with water at pH 3 as described in the previous step. The settling, lower layer removal and washing steps are repeated. The previous step is repeated with PMAA solution, and then again with PVP solution. This 30 alternation is continued until 5 layers have been deposited. After 2 layers, microcapsules can be observed under the microscope, and they are sufficiently strong to retain their integrity.
WO 2014/064252 PCT/EP201 3/072397 8 The final fragrance-containing capsules have an average diameter of 31 Um and a wall thickness of 14nm. Example 3 5 Preparation of fragrance-containing capsules The polymers used in this example are 50PAA1C12 and poly(vinyl pyrrolidone). 50PAAiC12 is a polyacrylic acid with some hydrophobic constituents: the backbone is about 50 000 g/mol. The grafted part has 12 carbons and it is grafted at I (mol) % (1 10 hydrophobic part for 100 units). When deposited as 4 layers, the interfacial compression dilation modulus is 4OnN/m 15 A 5mL of a 1% (wt) 50PAA1C12 aqueous solution is adjusted to pH 3. To this solution is added 5mL of a proprietary fragrance. The two solutions are kept in contact for 24 hours, then emulsified using an Ultra-turraxrm blender at 24000rpm for 2 minutes. The emulsion is added to a separating funnel and washed with water at pH 3 (10- M HCI) to give a 10% fragrance solution. 2)0 This solution is slowly mixed and then allowed to settle for 24 hours. The lower aqueous phase is removed and washed four times to extract excess polymer. This washed phase is added to 1(wt)% aqueous PVP solution at pHl 3 under gently stirring. This 25 phase is allowed to settle for 24h and it is then washed with water at pH 3 as described in the previous step. The settling, lower layer removal and washing steps are repeated. The previous step is repeated with PAA solution, and then again with PVP solution. This alternation is continued until a desired number of layers is attained, in this case until 5 WO 2014/064252 PCT/EP201 3/072397 9 layers are attained. After 2 layers, microcapsules can be observed under the microscope and manipulated. The final fragrance-containing capsules have an average diameter of 31 pm and a wall 5 thickness of 18nm. Example 4 Testing of microcapsules 10 PMAA/PVP microcapsules of the type described in Example 2, but with 10 layers, are deposited on a blotter. To another blotter is added proprietary fragrance of the type in the capsules, such that the quantity of fragrance added is the same. The blotters are left to stand for 24 hours at 25'C and normal atmospheric pressure, and 15 they are evaluated by a team of 8 trained fragrance panellists. The panelists found that the odour in both cases is weak and the same intensity. However, rubbing the blotter with the capsules produced a noticeable boost in fragrance. 20 Example 5: Preparation of a body cream comprising I 0-layer PMAA/PVP microcapsules of the type described in Example 2. A body cream formulation is prepared by admixing the ingredients listed in the table. 25 Ingredient Amount I%] w/w Petrolatum oil 5 Cetyl Alcohol 0.5 Cetearyl Octonoate 1 Stearic acid 0.5 Isopropyl paliitate 3 Isopropyl myristate 2 Steareth 2 (surfactant) 2.9 Steareth 21 (surfactant) WO 2014/064252 PCT/EP201 3/072397 10 Methyl Paraben (Preservative) 0? Propyl Paraben (Preservative) 0.1 Carbomer 980 (Thickener) 0.2 Sodium hydroxide (10%,,) to p1-I = :5.7 Deionised water 82.5 Body cream is prepared by mixing the microcapsules at 2% by weight, relative to the total weight of the body cream into the body cream formulation shown in the table. To the identical body cream is added a proprietary fragrance of the type in the capsules, such that 5 the quantity of fragrance added is the same. Body creams are applied to human skin on the forearm, in an amount of 0.5g with a micropipette, and the forearm is gently massaged during 10sec by rubbing a finger on the whole surface. 10 The perfume intensity is evaluated on a blind basis after 4 hours by an expert panel consisting of 8 trained panellists. The panellists find that the odour in both cases is weak and have the same intensity. However, rubbing the forearm with the capsules produces a noticeable boost in fragrance. 15 Example 6: Preparation of a flavour-shifting ice cream comprising 10-layer PMAA/PVP microcapsules of Example 2. 20 An ice cream is prepared by mixing the microcapsules containing a cherry flavour into an ice cream formulation at pH 5 containing a vanilla flavour. The initial taste sensation is vanilla, quickly followed by cherry flavour after dissolution of capsules at pH 7 in the mouth. 25 Example 7: Preparation of a leave-on hair cream formulation comprising 10-layer PMAA/PVP microcapsules of Example 2 WO 2014/064252 PCT/EP201 3/072397 11 A leave-on formulation is prepared by admixing the ingredients listed in the table. Ingredient Amount 1% 1 w/w Dirnethicone- 42 Cyclomethicone 30 Cycliopentasiloxane & Dirnethicono 13 25 Ph~enyl trimethicone' - - - - Quatermumn 80 1 5 1 DC 200 fluid (ex Univar) 2 DC 345 fluid (ex Univar) 3 ABILm OSW 5 (ex Goldschnridt) 4 DC 556 Fluid (ex Univar) 10 The leave-on formulation is prepared by mixing the microcapsules at 2% by weight, relative to the total weight of the hair cream, into the formulation prepared above. To another sample of the body wash is added a proprietary fragrance of the type in the capsules, such that the quantity of fragrance added is the same. 15 The two formulations are applied to hair swatches in an amount of 0.5g with a micropipette and hair is massaged using a finger on the whole surface for 10 sec. The perfume intensity is evaluated on a blind basis after 4 hours by an expert panel consisting of 8 trained panellists. The panellists find that the odour in both cases is weak 20 and of the same intensity. However, rubbing the hair swatch with the capsules produces a noticeable boost in fragrance. Example 8 Preparation of a rim block comprising the 10-layer PMAA/PVP microcapsules of Example 25 2. A toilet rim block gel formulation is prepared by admixing the ingredients listed below.
WO 2014/064252 PCT/EP201 3/072397 Ingredient AMOUnt IIw/w Natrosol M 250 MR 1 1,2 - Propylene glycol 4 Ka C7G 0.05 Fragrance 1 3 5 Water 74. 75 A rim block gel is prepared by mixing microcapsules containing a proprietary fragrance 2 (different from the fragrance I in the formulation above) at 2% by weight relative to the total weight of the rim block into the rim block formulation prepared above. To another rim 5 block with the same formulation (also containing Fragrance 1) is added proprietary fragrance 2 (which is different from the free fragrance) of the type in the capsules, such that the quantity of fragrance added is the sarne. The rim blocks gels are applied to separate toilets. 10 The perfume is evaluated by an expert panel consisting of 8 trained panellists on a blind basis before and after putting the rim block in contact with water (pHI 7). In the case of the rim block without capsules, the panellists found that the perfume is the 15 same before and after putting the rim block in contact with water for in the absence of microcapsules. In the case of the rim block with microcapsules, perfume is significantly different before and after putting the rim block in contact with water due to breakage of capsules by pH 20 increase, caused by the toilet water (pH7).