Title:  Discoloration-resistant vitamin composition

United States Patent:  6,403,119

Assignee:  R. P. Scherer Technologies, Inc. (Paradise Valley, NV)

Filed:  May 4, 2000

Foreign Application Priority Data: Nov 06, 1997[AU] (PP0222)

The invention disclosed herein includes a vitamin composition encapsulated in a soft or hard shell capsule, said vitamin composition comprising water soluble vitamin particles suspended in a fill liquid, wherein said water soluble vitamin particles are coated with a material that is substantially insoluble in the fill liquid and the shell of the capsule, but soluble in the gastrointestinal tract of a mammal, and the coated water soluble vitamin particles are of a size that are suitable for encapsulating as a suspension in said capsule. The invention also includes a process for manufacturing the same. Vitamin containing capsules according to this invention are discoloration-resistant.

DETAILED DESCRIPTION OF THE INVENTION

Most preferably the capsule is a soft gelatin capsule comprising gelatin, a suitable polyol and water. The suitable polyol is preferably glycerol. Although soft gelatin capsules are preferred, the advantages of the invention are applicable to other soft shell capsules and hard shell capsules, and compositions encapsulated in hard shell capsules also form part of the invention.

Water soluble vitamins that have found to be suitable for use in this invention are the B group vitamins namely Thiamine, Riboflavin, Folic Acid, Biotin, Nicotinic Acid, Pantothenic Acid, Pyridoxine, Cyanocobalamine and Lipoic Acid and Vitamin C, namely Ascorbic Acid. The invention has been found to be particularly applicable for use with Ascorbic Acid.

The fill liquids of the invention may be any liquid based system that is encapsulatable in a soft or hard shell capsule. The coating material may be either hydrophobic or hydrophilic in nature. The selection of the fill liquid for encapsulation will depend upon the nature of the coating material used. For example, if the coating material is hydrophobic, a hydrophilic fill liquid, such as Macrogol 400 will preferably be used. If the coating material is hydrophilic, a hydrophobic fill liquid will preferably be used, such as Soya Bean Oil. This will ensure that the coating material will be insoluble in the fill liquid.

Preferred hydrophobic fill liquids include vegetable oil, vegetable oil derivatives or medium chain triglycerides or mixtures thereof. Suitable vegetable oils include Almond Oil; Arachis Oil; Borage Oil; Canola Oil; Evening Primrose Oil; Fractionated Coconut Oil; Lecithin; Linseed Oil; Maize Oil; Olive Oil; Rapeseed Oil; Rice Bran Oil; Safflower Oil; Soya Bean Oil; Spearmint Oil; Sunflower Oil or Wheatgerm Oil.

Preferred hydrophilic fill liquids include polyethylene glycols having a molecular weight of from 300 to 8,000 or mixtures of polyethylene glycol with other polyols. Most preferred hydrophilic fill liquids include Macrogol 400 and mixtures of Macrogol 400 and propylene glycol and/or glycerol.

The coating material may comprise any material having the requisite properties of insolubility in the fill liquid and the shell of the capsule, whilst being able to disassociate from the particle in the gastrointestinal tract.

The selection of the fill liquid is determined by the solubility of coating material in the fill liquid. Whereas this is largely determined by the hydrophobic/hydrophilic nature of the fill liquid, it has been found that some hydrophobic coating materials remain insoluble in hydrophobic fill liquids. For example, some hydrogenated vegetable oils remain insoluble in a hydrophobic fill liquid such as Soya Bean Oil. Similarly some hydrophilic coating materials will remain insoluble in polyethylene glycol fill liquids.

Whereas it is preferred to select the fill liquid by its hydrophobic/hydrophilic nature, the selection of the fill liquid is determined by the solubility of the coating material in the fill liquid.

Suitable hydrophilic coating materials include glycols and polyglycols having a molecular weight of from 1000-8000. Preferred hydrophilic coating materials include lower alkoxy glycols and lower alkoxy polyglycols, for example, a most preferred material is polyethoxy glycol.

Suitable hydrophobic coating materials include vegetable oil derivatives, fatty acids, fatty acid derivatives including polyoxy ethylene derivatives or fatty oils. Most preferred are hydrogenated vegetable oils, for example derivatives based on Arachis, Coconut or Soya Bean Oils.

The selection of an appropriate fill liquid is essential to ensure that the coating material will remain insoluble within the fill liquid and the shell of the capsule. For this reason it is preferred that if the coating material is essentially hydrophilic in nature, the fill liquid will be hydrophobic. If the coating material is essentially hydrophobic in nature, the fill liquid will preferably be hydrophilic.

In some circumstances, the coating material may contain a mixture of materials, including a mix of hydrophilic and hydrophobic materials. In such circumstances the selection of fill liquid is determined by the overall nature of the coating material and whether that coating material will remain insoluble in the fill liquid. It is however anticipated that the coating material will be essentially either hydrophilic or hydrophobic in nature.

The shell of some soft and hard shell capsules may be considered to be slightly hydrophilic in nature. It has been found that the preferred hydrophilic and hydrophobic coating materials of the invention remain substantially insoluble against the shell of the soft or hard shell capsule. It is only appropriate to use coating materials that are substantially insoluble against the shell of the capsule.

The coating material should be continuous surrounding the vitamin particle to avoid leaching of the vitamin. Preferably, the coating material comprises at least 10% w/w of the coated vitamin particle. More preferably the coating material comprises between 10% w/w and up to 50% w/w of the coated particle and most preferably about 30% w/w.

The coated vitamin particle size may be of any size that is suitable for encapsulation as a suspension in a soft or hard shell capsule. Preferably the particle size is 300 .mu.m or less however larger particle sizes are also contemplated. Most preferably, the particle size is 180 .mu.m or less. As the vitamin composition is presented as a suspension, the particle size of the coated vitamin particle should be appropriate for encapsulation as a suspension in a soft or hard shell capsule.

The coated vitamin particle may be produced by first coating the particles and then obtaining the correct particle size upper limit by sieving out the bigger particles. The coating may also be achieved by admixing the coating material and the vitamin, however an inferior result is generally achieved unless a continuous coating of the particle is achieved and aggregates of the particles are removed.

The fill liquid may also include other suspending/dispersing agents such as fatty acids, lecithins and wax mixtures if the fill liquid is hydrophobic, or higher molecular weight dispersing agents such as Macrogol 8000 if a hydrophilic fill liquid excipient is used.

The soft or hard shell capsule may include any suitable amount of vitamin particles in suspension, but generally will include from 10 mg to 1000 mg of vitamin as an active ingredient. The vitamin composition may include a mixture of coated vitamin particles or a combination of coated particles and other coated or uncoated active ingredients.

During the manufacturing process, it is most preferred that the coated vitamin particle is not milled by a high shear process prior to encapsulation in the soft or hard shell capsule. Milling the coated particles by high shear processes may cause the coating material to crack, which can lead to migration of the vitamin material to the shell. Generally a continuous coating is maintained if the coated particle is not milled by high shear processes prior to encapsulation.

The present invention also resides in a process for manufacturing a soft or hard shell capsule containing a coated vitamin composition including the steps of:

(i) providing water soluble vitamin particles which have been coated with a material that is insoluble in a fill liquid and the shell of a soft or hard shell capsule, but soluble in the gastrointestinal tract of a mammal, wherein the coated water soluble vitamin particles are of a size that are suitable for encapsulating as a suspension in the capsule;

(ii) suspending the coated vitamin particles in a compatible fill liquid; and

(iii) encapsulating the vitamin composition in a soft or hard shell capsule to produce the vitamin composition as hereinbefore described.

It is a particular advantage of the present invention that any darkening of the shell by the vitamin is avoided. Therefore this avoids the need to utilise dark shell colours when encapsulating the vitamin. Although conventional shell colours may be used, the shell of the soft or hard shell capsule of the invention may also be coloured to reflect citrus fruits, for example colours such as yellow, orange and lime may be used. Other light colours may also be used. The shell may also be clear or clear coloured. Fruit flavours, odours, perfumes and other additives may also be used as an additive to the shell material. This is particularly advantageous when encapsulating Ascorbic Acid.

Claim 1 of 30 Claims

What is claimed is:

1. A vitamin composition encapsulated in a soft or hard shell capsule, said vitamin composition comprising water soluble vitamin particles suspended in a fill liquid, wherein;

said water soluble vitamin particles are coated with a material that is substantially insoluble in said fill liquid and the shell of said capsule, but soluble in the gastrointestinal tract of a mammal, whereby the discoloration of the shell by the vitamin particles is reduced; and

the coated water soluble vitamin particles are of a size that are suitable for encapsulating as a suspension in said capsule; and

wherein when the coating material is hydrophilic the fill liquid is hydrophobic, and when the coating material is hydrophobic the fill liquid is hydrophilic.

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