The present invention relates to a dry solid oral dosage form of biologically active substance in an oil phase of an oil in water emulsion and more particularly, the present invention provides regulated release of the active substance achievable on contact with water of body fluids.
Low bioavailability of hydrophobic drugs with extremely low water solubility can be a serious problem. Different approaches have been taken to achieve a desired level of drug solubility and dissolution rate. These approaches have been based on preparations with increased surface area (micronised powders), molecular inclusion complexes (cyclodextrines and derivatives), co-precipitates with water-soluble polymers (PEG, polozamers, PVP, HPMC) and non-electrolytes (urea, mannitol, sugars etc.), micellar solutions in surfactant systems (Cremophor™, Tween™, Gellucires™), multilayer vesicles (liposomes and niosomes). Dispersed colloidal vehicles, such as oil-in-water, water-in-oil and multiple (O/W/o or W/O/W) emulsions, microemulsions and self-emulsifying compositions also have been used to improve bioavailability of poorly soluble molecules.
None of these approaches has provided the efficiency for selected cases for bioavailability improvement of immediate drug release formulations. Moreover, a significant increase in bioavailability for such low soluble drugs as nifedipine can lead to dangerous side effects due to “dose dumping” when the water miscible vehicle (PEG-400) has been used.
Self-emulsifying drug delivery systems usually comprise a mixture of the liquid or semi-solid lipid phase (usually fatty acid glycerides or esters) with a surfactant (e.g., oxyethylated glycerides or oxyethylated fatty acids), and an additional cosurfactant or cosolvent (e.g., lecithin, monoglycerides, aliphatic alcohols, PEO-PPG copolymers). A hydrophobic drug can be efficiently dissolved in the mixture. After the addition of water, the mixture rapidly converts into an oil-in-water emulsion with the drug remaining in the oil droplets. Absorption of the drug in the gastro-intestinal system from the emulsion is increased.
Microemulsion systems are to some extent similar to self-emulsifying systems and often are composed of analogous- components (oil, surfactant, short or medium chain alcohol as the cosurfactant, and water) with the difference being in the ratio of the components. When diluted with water, an oil-in-water or water-in-oil emulsion may be produced, accordingly to composition and water amount. Drug entrapment and distribution in the stomach and intestine is also good.
All of the delivery systems discussed are liquid preparations and as such, the formulation must be administered as a fluid mixture or as a soft gelatin capsule (SGC).
Although useful, liquid and SGC present complications in turn of taste masking, compatibility with SGC walls, dosage from stability and manufacturing restraints.
Tableted forms of abovementioned delivery systems are limited to matrix type tablets, which do not provide any significant improvement of bioavailability. In addition, tablets with a high concentration of oil phase or low melting point lipids and waxes are very soft, demonstrate poor friability and are difficult to manufacture due to sticking, chipping, capping problems and oil leakage during tableting. The described formulations for oil containing tablets correspond to low loaded compositions, with oil levels usually measuring below 20%. (Gupta et al., U.S. Pat. No. 5,591,451; Okada et al, U.S. Pat. No. 5,164,193). Formulations highly loaded with omega—acid oil preparations (Desai et al., U.S. Pat. No. 4,867,986) need to be fabricated using a pre-emulsification process, followed by spray-drying and result in a product with poor tablet cohesion.
Use of microcrystalline cellulose, inorganic silicates, silicon dioxide or calcium phosphate as oil sorbents have been described in, for example, U.S. Pat. No. 4,327,076 (Puglia et al) and U.S. Pat. No. 6,562,372 (Yokoi et al.). However, to obtain a free-flowing oil-containing composition for tableting, Yokoi used emulsification, followed by spray-drying, without which, tablet formulations could not be prepared.
In U.S. Pat. No. 5,897,876, issued Apr. 27, 1999 to Rudnic et al., there is disclosed an emulsified drug delivery system which specifically relates to a water-in-oil emulsion which contains a discontinuous water phase in an amount of between 5.1 and 9.9%. The examples are all directed to liquid compositions. Since the compositions are all liquid there is inherently a hydrophilic phase. In terms of tablet or solid discussion, Rudnic et al. only teach that the water emulsion could be absorbed on tablet excipients. This is significantly different from providing a tablet which is a homogenous composition emulsifiable in the presence of body fluid. In this respect, the Rudnic et al. disclosure is simply directed to a coating on a preformed tablet. The only area where the composition would be marginally homogeneous would be the exterior layer of the preformed tablet. In the text, it is mentioned that formation of the emulsion requires the application of shear force, i.e. the patented formulation cannot be described as “self-emulsified”. The text provides description of the homogenizers which can be used for emulsification and describes the process as “prilling” or “congealing”. Silicon dioxide or silica gel along with magnesium or calcium stearates are provided as flow aids, and for this purpose they are usually added in only small amounts, far from being effective absorbent amounts.
In terms of other advancements in this field, U.S. Pat. No. 6,174,547, issued Jan. 16, 2001, to Dong et al. teaches a liquid composition comprising a hydrophilic phase retained in a osmotic hydrogel matrix. This reference is primarily focused on a two phase emulsion. This is a significant departure from an emulsifiable composition. The composition set forth in the reference is not emulsifiable, since the composition is already emulsified in its liquid form. In this manner, Dong et al. do not address the complications associated with providing a homogeneous distribution within a tablet, which composition can be emulsified under certain conditions.
In Friedman et al., U.S. Pat. No. 6,004,566, issued December 1999, there is disclosed a topical emulsion cream. The emulsion is designed for transdermal delivery. Friedman et al. is only relevant to emulsions; there is nothing in the reference which would provide one skilled in the art with instruction to form a tableted emulsifiable composition.
There are numerous further references directed to sustained release formulations, water dispersible vitamin E compositions, etc. These reference include the following: U.S. Pat. Nos. 5,965,160; 5,858,401; 4,369,172; 4,259,314; 5,603,951; 5,583,105; 5,433,951; and 5,234,695.
It would be desirable to have a dry tablet formulation with a significant increase in bioavailability. The present invention addresses this requirement.
One object of the present invention is to provide an improved solid tablet and method of forming this tablet to enhance the bioavailability of an active ingredient over a prolonged period of time.
It has been found that the composition based on proper mixture of hydrophobic active compound with oil phase and surfactant (or combination of surfactants) and physiologically acceptable excipients, explicitly specific sorbents, can be successfully fabricated as dry solid standard equipment—mixers, granulators, tablet presses. Being placed into the water-containing media, the abovementioned tablet generates “in situ” formulation of oil-in-water emulsion with the active components dissolved in the oil droplets of the formed emulsion.
One object of one embodiment of the present invention is to provide a solid composition for improved bioavailability of orally delivered biologically active hydrophobic compounds, said composition being self-emulsifying for forming an oil-in-water containing media with prolonged dissolution.
Advantageously, the pharmacokinetics of a biologically active compound can be influenced by the formulation of the tablet. It has been found that by providing a homogeneous dispersion of known compounds which are subsequently granulated and compressed into a hard solid body tablet that prolonged release is achievable.
The type and composition of the used excipients is important to obtain a tablet with the appropriate mechanical properties. The dissolution rate can be regulated by existing techniques, for example with the use of a water-swellable eroding polymer. This assists in sustaining the release of the hydrophobic drug for the desired time interval. Immediate release tablets can also be prepared through the use of appropriate disintegrants.
As generally discussed herein previously, where prolonged release is attainable, blood “dumping” or rapid delivery of the biologically active material into the blood plasma can be avoided.
Where prolonged release is achievable, it follows that the bioavailability will demonstrate concomitant efficacy. It will be evident where this union of desirable results is realized, the patient to which the drug is administered does not have to be continuously interrupted for administration of, for example, a drug in order for the drug content in blood plasma levels to be sustained. This inherently leads to fewer doses over a predetermined time frame. Where the bioavailability of the drug can be sustained in a substantially constant concentration the efficacy is not perceived to fluctuate by the patient. This provides the patient with comfort and regular metabolism of the drug over a time period.
In the tests conducted for the present invention, it was determined that the self-emulsifying tablet consistently maintained a higher active ingredient concentration in blood plasma for the same time frame for a non emulsifiable tablet.
Dissolution rate can be regulated by ways known to those skilled. As a possibility, use of water swellable eroding polymers is a suitable technique and sustained release of hydrophobic drug can be effectively suspended for a desired time interval.
A further object of one embodiment of the present invention is to provide a solid composition comprising a compressed tablet.
With respect to the composition, successful results have been obtained with the composition when the same is a homogeneous mixture of the compounds in the composition. In one embodiment, the ingredients may be granulated and subsequently compressed into a tablet having a substantially uniform solid cross-section. This effectively provides uniformity which is important for effecting the bioavailability of the composition and particularly, the biologically active compound.
In the prior art, this was not recognized; the prior art taught the formation of a tablet, however, the emulsion composition has been only deposited as a coating on the tablet. At best, such an arrangement provides for localized homogeneity of the emulsion in a thin layer. This is vastly different from a composition which is entirely emulsifiable. When the tablet is entirely emulsifiable, prolonged release is achievable with relatively constant bioavailability. In the prior art formulations, localized homogeneity effectively provides active material “dumping” upon immediate dissolution with a rapid tapering of bioavailability.
The formulation of an emulsifiable composition is not without its complications. One of the more difficult challenges in preparation relates to the compression of the granulation. As is known, compression of materials into a tablet form requires enormous forces. In the instant composition, it was observed that the hydrophobic phase was not disrupted nor where the submicron particles containing the active ingredient when exposed to the compression for tableting.
Having thus described the invention, reference will now be made to the accompanying drawings illustrating preferred embodiments.
Coenzyme Q-10 will be referred herein as CoQ10.
The lipid phase can be prepared from any physiologically acceptable oily or fatty component(s). It is desirable that the lipid phase is liquid or semisolid at body temperature to form an oil-in-water emulsion. As example, the lipid phase may comprise: triglycerides (food grade oils—live, corn, canola, soy; palm oil, cocoa oil, fractionated palm oil, medium chain triglycerides (MCT, capric/caprylic glycerides, etc.; animal fats, fish oil, tallow oil, modified glycerices—acetylated monoglycerides, mono- and digylcerides; lipid soluble vitamins—alpha-, beta- and gamma-tocopherol and correspondent tocopherol esters (vitamin E), tocotrienols and related compounds, retinol and retinol esters (vitamin A), etc.; aliphatic and aromatic esters: tributylcitrate, diethyladipate, dibutylphtalate, etc.
Miscellaneous lipid substances include Squalan, squalen, mineral oil, liquid silicon polymers, synthetic and natural waxes with a suitable melting point.
To form a tablet with suitable physico-chemical properties, an appropriate sorbent for the lipid phase must be used. The sorbent function is to hold the lipid phase during the granulation process to provide free flowing granulation and prevent the lipid phase from leaking during the tableting process. The sorbent should be physiologically inert, safe and suitable for granulation and tableting processes. The sorbent should possess high surface area/porosity, high mechanical strength and be relatively inert to prevent chemical interaction with formulation components. As example, the following compounds are typically suitable:
Silicon dioxide—colloidal (dried silicagel—Syloid™ 244, GRACE; Sipernats®, DEGUSSA) or fumed (prepared by hydrolysis of silicone alides -Cab-O-Sil® M5, CABOT, or Aerosil® 200/300, DEGUSSA), inorganic sorbents such as synthetic Magnesium Aluminum Silicate (Neusilin®, FUJI), di- and tribasic calcium phosphates, calcium carbonate, calcium silicate, zeolites, talcite, kaolin, benthonite, etc., cross-linked polymers with high surface area, such as cross-linked povidone (Povidone® XL, BASF) may also be used.
Biocompatible surfactants may selected from polyethoxylated derivatives of tocopherol acid succinate (TPGS™, Eastman-Kodak), glycerides (Gellucire™, Gatefosse, Tagat™, Henkel; etc), polyol esters (Sorbitan esters, Tween™), sucrose stearates (Sucrose ester™, Gattefosse), PEG derivatives of long chain acids (PEG stearate, Lipo-PEG™, Mirj® 52) or block-copolymers (Poloxamer™, Pluronic™) with suitable HLB value.
In respect of suitable excipients, sorbents, tablet forming materials, glidants, lubricants, hydration regulators can be selected according to desired tablet properties and loading level. Since many of the proposed components are liquid or semisolid materials at room temperature, preparation of the tablets becomes a challenging task. Highly absorptive compounds facilitate for preparation of free flowing powders, however, most of the absorbed material is squeezed out of the matrix during tablet compression (applied force is typically 1-10 tons per tablet), thus compromising the properties of the tablet.
Unexpectedly it was found that the combination of microcrystalline cellulose (polysaccharide type sorbent) with a mixture of two inorganic sorbents, one of which is a silicate-type material, resulted in a preparation with good flowability, without water granulation, avoiding oil leakage during tableting, and yielded tablets with high hardness and excellent friability. The selection of the ratio between the microcrystalline cellulose, lipid phase and inorganic sorbents results in tablets with desired properties.
Biocompatible surfactants suitable in the formulation include those selected from polyethoxylated derivatives of tocopherol acid succinate (TPGS™, Eastman-Kodak), glycerides (Gellucire™, Gatefosse, Tagat™, Henkel; etc), polyol esters (Sorbitan esters, Tween™), sucrose stearates (Sucrose ester™, Gattefosse), PEG derivatives of long chain acids (PEG stearate, Lipo-PEG™, Mirj® 52) or block-copolymers (Poloxamer™, Pluronic™) with a suitable HLB value. The current invention describes the preparation of tablets with a high lipid and surfactant content. The tablets possess acceptable physical characteristics such as hardness, friability, dissolution behaviour and can be manufactured using standard equipment such as granulators, ovens, dryers, mixers, tablet presses. On contact with water media, the tablets release “in-situ” forming oil-in-water emulsions comprising active components dissolved in the oil phase.
Such properties facilitate high bioavailability for hydrophobic substances included into the tablet.
Polymers for release rate control work as main dissolution rate regulators. After contact with water they form a hydrated gel in parallel with emulsification process. Release of the formed emulsion follows the gel dissolution and partial diffusion of the tiny lipid droplets from gelled matrix to surrounded media. Preferred gel forming polymers are water swellable or water soluble cellulose derivatives, for example, Hydroxypropylmethylcellulose (Methocel™, types A, E, K, F, Dow Chemical), Hydroxyethylcellulose (Natrosol™, Hercules), Hydroxypropylcellulose (Klucel™, Aqualon), Carboxymethylcellulose (cellulose gum). Another types of synthetic polymers include polyacrylic acid (Carbopol™, BFGoodrich), Polyethylene oxide (Polyox™, Union Carbide), Polyvinylpyrrolidone (Kollidon™, PVP and PVP-VA, BASF), natural gums and polysaccharides—Xantan gum (Keltrol™, Kelco), carrageenan, locust bean gum, acacia gum, chitosan, alginic acid, hyaluronic acid, pectin, etc.
Having thus generally described the invention, reference will now be made to the examples.
CoQ10 Self-Emulsifying Controlled Release Tablet; 30 mg strength, dissolution time greater than 6 hours.
As a first example of the first formulation, the slowly dissolving composition contains CoQ10 (Ubiquinone) in amount of 30 mg per tablet. The oil phase comprises of alpha-tocopherol acetate (vitamin E acetate), PEG-40 stearate (Lipo-PEG 39S) used as the surfactant with optimal HLB value for effective emulsification of the oil phase. A weight ratio of 1:1 between CoQ10 and the oil phase was used. In respect of the surfactant to oil phase, the w/w ratio used was 1.6 to 1.
The composition of the 30 mg CoQ10 self-emulsifying extended release tablet is displayed in table 1.
CoQ10, surfactant (PEG stearate) and oil phase (alpha-tocopherol acetate) were heated together between 50° C. and 55° C. and mixed until the coenzyme completely dissolved. This solution was diluted with ethyl alcohol and then mixed with colloidal silicon dioxide, dibasic calcium phosphate and part of microcrystalline cellulose as sorbents. The paste was carefully mixed to obtain homogenous dispersion. This is important to maintain a relatively uniform composition in the final tablet and also contributes to prolonged release and bioavailability. This dispersion was transferred to a planetary granulator and carefully mixed with gel-forming polymers Methocel K4M, Methocel E15 and part of lactose (hydration rate regulator). The mixture was granulated with separately prepared 5% binder solution of polyvinylpyrrolidone (Kollidon PVP K-25) in ethyl alcohol until a suitable granulate was obtained. This granulate was dried at 45° C. until the solvent evaporated. The dry granulate was passed through a (16 mesh) sieve, mixed with microcrystalline cellulose, lactose and sieved magnesium stearate (lubricant).
Tablets were prepared using conventional equipment (such as 16-station rotary tablet press). The tablets had a hardness greater than 8 kg and friability of less than 1%.
Dissolution tests were carried according to USP requirements, using USP apparatus #2 at 37° C., with paddle rotation at 100 rpm. 900 ml of simulated gastric fluid (SGF) without enzymes or simulated intestinal fluid (SIF) served as the dissolution media.
Dissolution was insensitive to media type. The tablet was almost completely dissolved between 6 and 8 hours. Upon dissolution, a colloidal emulsion of the CoQ10 dissolved in the oil phase was formed and gradually released into dissolution media, forming a hazy bluish dispersion. The dissolution pattern is displayed in
CoQ10 Self-Emulsifying Controlled Release Tablet (50 mg strength).
Preparation followed the protocol as described in Example 1. The tablet was found to be between 6 kg and 10 kg with a friability of less than 1%. The dissolution pattern is presented in
The drug release from self-emulsifying matrix can be absolutely independent to media type.
Alpha-lipoic acid in Self-Emulsifying Controlled Release Tablet (50 mg strength).
The slowly dissolving composition contained alpha-lipoic (octathioic) acid in amount of 50 mg per tablet. The oil phase comprised alpha-tocopherol acetate (vitamin E acetate). Another tocopherol derivative, tocopherol acid succinate PEG1000 ester (TPGS™) was used as the surfactant. The weight ratio between the lipoic acid and the oil phase used was 1:1. A 1:1 ratio was observed for the surfactant and oil phase.
The composition of the 50 mg extended release tablet is displayed in table 3.
Alpha-lipoic acid, alpha-tocopherol acetate and surfactant, alpha-tocopherol acid succinate-PEG1000 (TPGS™) were mixed together and stirred in dry ethanol until complete dissolution of the components was observed. The solution was then mixed with sorbents including colloidal silicon dioxide, dibasic calcium phosphate and part of microcrystalline cellulose. The paste formed was carefully mixed to achieve homogenous dispersion and transferred to a granulator and subsequently mixed with gel-forming polymers: Methocel K4M, Methocel E15 and part of lactose (hydration rate regulator). The formed blend was granulated with separately prepared 5% binder solution of polyvinylpyrrolidone (Kollidon PVP K-25) in ethyl alcohol until a proper granulate was obtained. This granulate was dried at 45° C. until the solvent was evaporated. The dry granulate was passed through a 16 mesh sieve, mixed with microcrystalline cellulose, lactose and sieved magnesium stearate (lubricant).
The tablets were prepared using the equipment as discussed in Example 1. The obtained tablet provided a hardness of between 5 kg and 8 kg with a friability of less than 1%.
Dissolution tests were carried according to USP requirements, using USP apparatus #2 at 37° C., with paddle rotation at 100 rpm. The tablet was completely dissolved in 6 hours. Upon dissolution a colloidal emulsion of oil droplets was formed and gradually released into the dissolution media, forming a hazy bluish dispersion. The active ingredient, alpha-lipoic acid, was distributed between the oil droplets and the water phase in accordance with the partition coefficient and pH-of dissolution media.
The observed dissolution pattern was similar to that in the tablets of Examples 1 and 2.
Indomethacin in self-emulsifying controlled release tablet (75 mg strength).
Indomethacin, a well known non-steroid anti-inflammatory drug (NSAID), is very popular due to high potency of analgesic and antiflogistic action. A draw back of the compound is the side effect of a strong irritation of the gastric mucose. This is characterized of NSAIDS. By inclusion of the indomethacin (as other NSAID, e.g., diclofenac, piroxicam, naproxen, ketoprofen, etc.) into a self-emulsifying may decrease irritation due to contact of undissolved crystalline drug substance with sensitive stomach and intestine mucosal surfaces. The limited solubility of indomethacin in common oil phases required a suitable review of the composition of the oil phase components for better solubilization of the drug. As result of experimental probes, a mixture of MCT with polar oils, glycerol monolaurate and Labrafil™ 1944, was used. Tyloxapol™, a copolymer of alkylphenol and formaldehyde, was used as a pharmaceutical grade surfactant. A hydration rate controlling polymer, polyethylene oxide (Polyox™ WSR N-12K, Union Carbide) illustrated suitability of polyethylene oxide homopolymer for self-emulsifying controlled release matrices.
Compositional details of the 75 mg indomethacin self-emulsifying extended release tablet are displayed in table 4.
Indomethacin, MCT oil, Labrafil 1944 and glycerol monolaurate (GML) and surfactant Tyloxapol™ were mixed together and heated to between 55° C. and 60° C. until a clear solution was obtained. The solution was then mixed with the sorbents colloidal silicon dioxide, sodium aluminum silicate and part of microcrystalline cellulose. The formed paste was carefully mixed to homogeneity. This dispersion was granulated and mixed with the gel-forming polymer Polyox WSR N-12K and part of lactose (hydration rate regulator). The formed blend was granulated with a separately prepared 5% binder solution of polyvinylpyrrolidone (Kollidon PVP K-90) in ethyl alcohol until a proper granulate was obtained. This granulate was dried at 45° C. until the solvent was totally evaporated.
The granulate was sieved (16 mesh), mixed with rest part of microcrystalline cellulose, lactose and sieved magnesium stearate (lubricant). Capsule shaped tablets were prepared to yield tablets having a hardness greater than 3.5 kg.
The dissolution tests were carried according to USP requirements, using USP apparatus #2 at 37° C., with paddle rotation at 100 rpm. Complete dissolution of the tablet was achieved in 6 hours. Upon dissolution a colloidal emulsion of the oil droplets was formed and gradually released into dissolution media, forming hazy bluish dispersion. The active component, indomethacin, was distributed between the oil droplets and water phase in accordance with the partition coefficient and pH of the dissolution media.
A controlled release self-emulsifying tablet comprising 25 mg of indomethacin was prepared in a similar manner as Example 4, but with another composition. (See Table 5). The dissolution data is illustrated in
This tablet has satisfactory physical properties (hardness, friability, tableting behaviour) and dissolution profile.
The developed delivery system can be successfully applied for controlled release of natural active substances, both plant and animal origin. The best results were observed with extracts.
Self-emulsifying controlled release tablet with 50 mg of Red Reishi Mushrooms extract.
The Red Reishi Mushroom demonstrates high activity as immunomodulator and use as a nutritional additive. Recently, extract of the mushrooms was presented to replace multiple bulky doses (600 mg capsules 3-4 times a day) for 20-50 mg of dry material concentrate of active ingredients. The main active components in the extract are different triterpenoids, aromatic compounds and polysaccharides.
The tablet allowed a significantly improved drug release pattern and consumer convenience. It was found that one tablet a day provided constant and smooth delivery of the active ingredients. The Red Reishi Mushroom extract, formed in a process of dissolution oil droplets, has high concentrations of triterpenoids surrounded by polysaccharides and efficiently penetrates the gastrointestinal lining, providing a significant quantity of the biologically active ingredients to the body.
Granulation was prepared as described in accordance with Example 2, but the granulate was dried at between 32° C. and 35° C.
The extract of Red Reishi Mushrooms (Garuda Inc., USA), alpha-tocopherol acetate and surfactant, alpha-tocopherol acid succinate-PEG1000 (TPGS™, Eastman) were mixed together and stirred in dry ethanol at 35° C. until a homogenous suspension was obtained. The suspension was mixed with sorbents as in the previous examples. The formed paste was carefully mixed, transferred to the granulator and mixed with Methocel K4M, Methocel E15 and PVP. The formed blend was then granulated with ethyl alcohol until a proper granulate was obtained. The granulate was dried at temperature no more than 35° C. (to prevent evaporation of volatile aromatic compounds of extract) until the solvent was totally evaporated.
The dried granulate was sieved and mixed with microcrystalline cellulose, inter alia as discussed previously. The tablets were found to have a hardness of between 10 kg and 12 kg and a friability of less than 1%.
The tablet determined in accordance with USP 23 (37° C., 100 rpm, 900 ml water) dissolved in about 6 hours in apparatus 2 (more than 80% dissolved).
Multivitamin composition in self-emulsifying controlled release tablet.
The formulation included water soluble and a lipid soluble vitamin components and was prepared consistent with the method described in Example 3. The composition is presented in table 7.
The main advantage of sustained release delivery of self-emulsifying compositions is realized by the highly increased bioavailability of the included active components. This is of great importance for poorly soluble compounds and controlled delivery of such compounds can significantly decrease potentially dangerous drug dumping and provide constant and uniform delivery profiles.
Entrapping the drug into the small (usually less than 1 micron diameter) oil droplets leads to significantly decreased local irritation (it is extremely important for such drugs as NSAID) and visibly increases penetration efficacy through the gastro-intestinal mucosal membranes. Absence of undissolved NSAID crystals adhered on the stomach wall eliminates possible bleeding due to drug erosive action.
In view of the fact that the pattern of the size distribution for these oil droplets shown in
The described pharmaceutical composition has, sufficient loading of the poor water-soluble drug, and provides prolonged release of the included drug. The drug loaded oil-in-water emulsion is gradually released from the composition.
Different types of active compounds were successfully incorporated into the composition, this demonstrating that the composition has wide suitability and potential for different types of biologically active materials.
Conveniently, sustained release of the active material permits a change from multiple dosing (2-6 tablets a day) to a single dose delivery per day. This feature decreases the chances for missing doses or significant variations of the drug in the blood.
The CoQ10 pharmacokinetics for self-emulsifying tablet as set forth in Example 2 was investigated relative to the only available 50 mg CoQ10 tablet (Enzymatic Therapy®, CoQ10 50 mg, lot L9300). This tablet contains micronized CoQ10.
Twenty healthy male volunteers (aged 19˜23 years) participated in the study. Each subject of one group received multiple oral doses of CoQ10 as sustained release tablets for fifteen days and each day took one time 50 mg. The subjects of the other group did the same, but with regular tablets.
The blood samples were taken prior to the oral administration and at specified times. After blood plasma was precipitated by methanol for protein removal it was extracted with hexane. Aqueous and organic solvents were separated by low speed centrifugation and the organic phase was collected, dried under a nitrogen gas stream and dissolved into 100 μl of ethanol. The solution was injected into HPLC-UV system with a 10 μm, 250μ×4.6 mm reverse phase column and heated to 30° C. The mobile phase was constituted by methanol-ethanol 9:1 v/v with a flow rate of 1.5 ml.min-1 and UV detection at 275nm. Coenzyme Q9 was used as an internal standard material for analysis.
Total CoQ10 concentrations in plasma following oral administration of self-emulsified tablets were higher (p<0.05), compared to those in plasma following oral administration of regular tablets. According to obtained pharmacokinetic data, blood concentration of CoQ10 at day 14 increased from initial level ˜50% for commercial immediate release tablet and ˜80% for self-emulsifying tablet. AUC values are 146% and 188%, respectively (100%-initial CoQ10 level, 0.81 and 0.96 mcg/ml, resp.).
As further evidence of the efficiency of the composition of the present invention, by way of comparison, our investigations showed that the tablet obtained in accordance with U.S. Pat. No. 5,897,876 (column 7, lines 10-28 and column 6, lines 51-63) had extremely poor mechanical properties (hardness was found to be less than 2 kp, visible squeezing of the lipid phase from the tablet with a weak and soft surface and pronounced sticking during tableting).
Further, the mentioned excipients (column 7, lines 4-28) do not result in a tablet with suitable hardness high enough to manufacture such tablets on any reasonable scale using common pharmaceutical equipment. Tablets prepared by this method had hardness measurements of 1 kg and 3 kg for a 10 mm round biconvex tablet, while a normal value for such tablets must be at least 6. The friability parameter is higher than 5% (maximum allowed 1%, normal 0.1-0.2%) and most importantly, the tablets did not release emulsion when placed in contact with a water phase. Table 8 establishes the data and demonstrates the effectiveness of the present invention.
The test conditions included a 0.05M phosphate buffer, pH of 6.8, 500 ml with USP dissolution apparatus #2. The paddles were rotated at 100 rpm. The left beaker included a tablet prepared by the technology of the present invention and the right beaker in accordance with the prior art.
The prolonged release of emulsion from the self emulsifying tablet according to the present invention is evident and the absence of drug release and dissolution from the prior art tablet is also evident form the Figures.
Although embodiments of the invention have been described above, it is not limited thereto and it will be apparent to those skilled in the art that numerous modifications form part of the present invention insofar as they do not depart from the spirit, nature and scope of the claimed and described invention.
This is a continuation-in-part of U.S. Ser. No. 10/252,158, filed Sep. 23, 2002, which is in turn a continuation application of Ser. No. 09/482,109 filed Jan. 13, 2000.
Number | Date | Country | |
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Parent | 10252158 | Sep 2002 | US |
Child | 10947222 | Sep 2004 | US |
Parent | 09482109 | Jan 2000 | US |
Child | 10252158 | Sep 2002 | US |