Process for producing spherical base granule comprising easily water-soluble drug

Abstract

Provided is a process for producing spherical base granules comprising a easily water-soluble drug and suited for film coating by spraying a layering liquid over pharmaceutically inert spherical core particles, thereby coating the particles with a layer comprising the easily water-soluble drug, wherein (1) the spherical core particles have a microcrystalline cellulose content of 30 mass % or greater and a water absorbing capacity of 0.5 cm³/g or greater; and (2) the layering liquid is an aqueous solution comprising at least the easily water-soluble drug and a low water-soluble saccharide.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This

H: volume [cm³/g] of water which spherical core particles can retain therein.

W: mass [g] of the spherical core particles.

Described specifically, it can be determined by adding 30 mL of purified water to 10 g of a sample (in terms of a dried sample), leaving the resulting mixture as is at room temperature for one hour, natural filtering out the solid through a filter paper, lightly wiping off water attached to the surface of the solid mass with another filter paper, measuring the mass of the solid, and dividing a difference calculated by subtracting 10 from the mass (water content) by 10.

When the water absorbing capacity is smaller than 0.5 cm³/g, severe agglomeration of particles occurs during layering. The water absorbing capacity of 0.7 cm³/g or greater is preferred because it suppresses agglomeration effectively. The water absorbing capacity of 0.9 cm³/g or greater is more preferred.

No limitation is imposed on the water absorbing capacity from the viewpoint of agglomeration. However the particles which have swelled with water absorbed therein shrink during drying step after they are coated with a drug-containing layer, leading to deterioration in the strength of the resulting spherical base granules. The preferred maximum water absorbing capacity of particles, which do not swell even after water absorption, is about 1.8 cm³/g.

The spherical core particles have an average particle size of preferably from about 50 to 1000 μm. The particle size distribution is preferably sharp. The spherical core particles have a (tapped) bulk density of preferably from about 0.5 to 2.0g/cm³, though it depends on the balance of strength and water absorbing capacity. The spherical core particles composed only of microcrystalline cellulose have a bulk density of preferably from about 0.5 to 1.0 g/cm³.

The mechanical strength of the spherical core particles is preferably higher.

The layering liquid to be used in the present invention will hereinafter be described.

The layering liquid comprises at least an easily water-soluble drug and a low water-soluble saccharide.

The term “easily water-soluble drug” as used herein means a drug having a solubility of 1 g or greater in 1 cm³ of water at 20° C.

Conventionally, it was considerably difficult to adopt the layering process for producing spherical base granules with a high production yield when the easily water-soluble drug contained had a solubility of 1.5 g or greater. The present invention enables adoption of the layering process for the production of granules comprising such a easily water-soluble drug.

Examples of the easily water-soluble drug to be used in the present invention include chlorpheniramine d-maleate, ethyl L-cysteine hydrochloride, chloperastine hydrochloride, fasudil hydrochloride, procainamide hydrochloride, ceftizoxime sodium, tradipine, migrenin, and loxoprofen sodium.

The term “low water-soluble saccharide” as used herein means a saccharide having a solubility of 0.8 g or less in 1 cm³ of water at 20° C. Examples of it include monosaccharides, disaccharides, oligosaccharides, and sugar alcohols. Preferred are D-mannitol, maltose, and lactose. They may be used either singly or in combination. Of these, D-mannitol is especially preferred.

The layering liquid has a content of the easily water-soluble drug of preferably from 5 to 30 mass % based on the total mass of the layering liquid. The layering liquid has a content of the low water-soluble saccharide of preferably from 1 to 30 mass %, more preferably from 3 to 20 mass %, still more preferably from 4 to 10 mass %. Since the solubility of D-mannitol in 1 cm³ of water at 20° C. is 0.18 g, when it is used as the low water-soluble saccharide, its content is preferably from 1 to 15 mass %, more preferably from 3 to 12 mass %, especially preferably from 4 to 10 mass %.

If necessary, the layering liquid may comprise another pharmaceutical additive. Addition of a binder is especially preferred because it contributes to improvement in the strength of a layer comprising the easily water-soluble drug. Examples of such a binder include hydroxypropyl cellulose, povidone, and hydroxypropylmethyl cellulose.

The coating amount with the layer comprising the easily water-soluble drug can adequately be determined depending on the formulation design such as single dosage or size of the preparation. For example, the coating amount of the drug is generally from about 0.5 to 200 mass % based on the spherical core particles.

The production process of the spherical base granules according to the present invention will hereinafter be described.

A fluidized-bed coating apparatus can be used for coating the spherical core particles with the easily water-soluble drug containing layer. Examples of the fluidized bed coating apparatus include not only an ordinarily fluidized bed type but also, for example, a spouted bed type having, inside thereof, a guide tube (Wurster column) and a tumbling fluidized bed type equipped, on the bottom thereof, a rotation mechanism.

Specific examples of such apparatuses include “Flow Coater” and “Spiral Flow”, products of Freund Corporation, “WST/WSG Series” and “GPCC Series”, products of Glatt GmbH, “New Marumerizer”, product of Fuji Paudal Co., Ltd., and “Multiplex”, product of Powrex Corporation.

The layering liquid can be sprayed by a method suited for each of apparatuses such as top spray, bottom spray, side spray, and tangential spray. It may be sprayed to the spherical core particles continuously or intermittently.

After completion of spraying, the spherical base granules are dried. Drying of the spherical base granules may be performed as are or after controlling the air flow or temperature as needed while not taking out the granules from the apparatus.

The coating rate (spray rate of layering liquid) of the easily water-soluble drug layer is preferably 0.8 g/min or greater, in terms of an amount of a solid content of the layering liquid, per kg of the spherical core particles. Such a spray rate enables densification of the easily water-soluble drug containing layer and smoothing of the surface and as a result, spherical base granules suited for film coating can be obtained. In addition, such a spray rate enables a decrease in the layering time and improvement in the production efficiency.

The coating rate is more preferably 1.0 g/min or greater, more preferably 1.3 g/min or greater.

Next, one example of a production method of the spherical base granules will be described.

(a) Preparation of layering liquid: A layering liquid is prepared by adding a low water-soluble saccharide to water, thoroughly stirring the resulting mixture to dissolve the low water-soluble saccharide, adding an easily water-soluble drug and, if necessary, a pharmaceutical additive to the aqueous solution, and stir and dissolve (suspend) the resulting mixture sufficiently.

(b) Heating of spherical core particles and fluidized-bed coating apparatus: After spherical core particles are charged in a fluidized-bed coating apparatus, the core particles are caused to flow (when a fluidized-bed type coating apparatus with rotating equipment is employed, the rotating portion of it is turned simultaneously) by supplying hot air from the bottom portion of the apparatus until the outlet-air temperature reaches a predetermined temperature.

(c) Coating with drug containing layer: The layering liquid is sprayed at a predetermined spray rate continuously or intermittently or at a rate raised in a stepwise fashion. The supply of the layering liquid is terminated when the coating amount reaches a predetermined amount.

(d) Drying of spherical base granules: The spherical base granules are dried while adjusting the amount of hot air and temperature (rotation speed of the rotating portion when a tumbling fluidized bed type is employed) if necessary.

(e) Taking-out of spherical base granules: In the end, the resulting spherical base granules are taken out.

The spherical base granules obtained by the present invention can be used as granules, capsules, tablets or the like after subjected to particle size regulation and sustained release film coating, enteric film coating, or bitter-taste masking film coating if necessary.

Example 1

The present invention will next be described based on some examples. First, measuring methods of physical properties are described collectively.

<Sphericity [-] of Spherical Core Particles and Spherical Base Granules>

The shape of a sample is photographed using a digital microscope (“VH-7000”, product of KEYENCE CORPORATION) (with a 50× or 100× lens) and a short diameter (D) and a long diameter (L) of 50 particles are measured using an image analyzer (“Image Hyper”, product of Inter Quest). The terms “short diameter” and “long diameter” as used herein mean a short side and a long side of a minimum (in area) circumscribed rectangle of boundary pixels of a particle, respectively. The sphericity is an average of a short diameter/long diameter (D/L) ratio

<Average Particle Size [μm] of Spherical Core Particles>

The average particle size is defined as a value at 50% in the cumulative distribution of the small diameter (D) determined in the same manner as the measuring method of a sphericity.

<Water Absorbing Capacity [cm³/G] of Spherical Core Particles>

It can be determined in the following manner 30 mL of purified water is added to 10 g (in terms of a dried sample) of a sample. After the resulting mixture is left as is at room temperature for one hour, the resulting mixture is naturally filtered through a filter paper to separate a solid and water attached to the surface of the solid mass is wiped off lightly with another filter paper. Then, the sample is weighed and the amount of contained water is divided by 10. The above-described operation is repeated five times and an average is adopted as the water absorbing capacity.

<Tapped Bulk Density [g/Cm³] of Spherical Core Particles>

A 100 cm³ graduated cylinder is filled with 30 g of a sample and a tapped volume [cm³] after tapping about 30 times is measured. The tapped bulk density is calculated in accordance with the following equation. This operation is repeated three times and an average is adopted as a tapped bulk density.
Apparent tapped bulk density [g/cm³]=30 [g]/tapped volume [cm³].
<Recovery Ratio [Mass %] of Spherical Base Granules>

The recovery ratio is determined in accordance with the following equation based on the recovery amount [g] of spherical base granules after layering and total amount [g] of raw materials employed.
Recovery ratio [mass %]=(recovery amount [g]/total amount [g] of raw materials)×100
<Agglomeration Ratio [%] of Spherical Base Granules>

After dispersion of spherical base granules on paper, the number [a] of particles constituting agglomerated granules and the number [b] of single isolated particles are counted visually. The agglomeration ratio is calculated in accordance with the following equation. The number of particles observed is 1000 (=a+b).
Agglomeration ratio [%]={a/(a+b)}×100
<Tackiness [-]>

A layering liquid (3 g) is poured in a polypropylene Petri dish having a diameter of 8 cm and dried at 40° C. in an air-circulation-free dryer (“FC610”, product of Advantec Co., Ltd.). Within three seconds after taking out the dried product from the dryer, tackiness of the dried film when an index finger is pressed against the film for two seconds and then released therefrom is evaluated by a panel of three experts. The tackiness is rated as “1” when no tackiness is observed, “2” when a little tackiness is observed, “3” when tackiness is observed, “4” when strong tackiness is observed, and “5” when very strong tackiness is observed. The tackiness of the dried film is evaluated by the average of them.

It is known empirically that agglomeration occurs during layering when the tackiness is “3” or higher so that the layering rate must be set low to prevent it. Layering cannot be performed in practice when the tackiness is “5”.

Example 1

(Preparation of Layering Liquid)

6.0 g of D-mannitol (product of Towa Kasei Kogyo Co., Ltd.) of a low water-soluble saccharide was added to 99.6 g of water while stirring with propeller. The resulting mixture was stirred until completely dissolved. Then, 2.4 g of povidone (“K-30”, product of ISP Tec. Inc.) and 12.0 g of chlorpheniramine d-maleate (product of Kongo Chemical Co., Ltd.) were added as a binder and an easily water-soluble drug, respectively, then the resulting mixture was stirred until completely dissolved to yield a layering liquid.

(Production of Spherical Base Granules)

Spherical base granules having a sphericity of 0.94 were obtained by charging 0.6 kg of spherical core particles consisting of 100% microcrystalline cellulose (“CELPHERE” CP-203, product of Asahi Kasei Chemicals Corporation, water absorbing capacity: 1.0 cm³/g, average particle size: 237 μm, sphericity: 0.90, tapped bulk density: 0.96 g/cm³) in a tumbling fluidized-bed coating apparatus (“Multiplex” MP-01, product of Powrex Corporation) and layering the spherical core particles with the layering liquid by using a tangential bottom spray until the coating amount reached 3.4 mass % (2.0 mass % in terms of the drug) under the conditions of a spray air pressure of 0.16 MPa, a spray air flow rate of 40 L/min, a inlet-air temperature of 80° C., an outlet-air temperature of from 45 to 46° C., an air flow of from 37 to 50 m³/h, and a spray rate of layering liquid of 5.0 g/min (corresponding to the coating rate of 1.4 g/min in terms of a solid content per kg of spherical core particles). During production, the rotation speed of the rotor was adjusted to 400 rpm until the layering amount reached 1.7 mass % and then adjusted 450 rpm until the layering amount reached 3.4 mass %. After that, the rotation speed of the rotor was reduced to 200 rpm and drying was performed until the outlet-air temperature increased to 48° C. A heater for charge air was then turned off and cooling was performed until the outlet-air temperature decreased to 40° C.

The spherical base granules thus obtained scarcely attached to the inside wall of the coating apparatus and a substantially whole amount of them was collected.

Example 2

(Preparation of Layering Liquid)

The same layering liquid used in Example 1 was used.

(Production of Spherical Base Granules)

Spherical base granules having a sphericity of 0.94 were obtained by charging a Wurster coating apparatus (“Multiplex” MP-01 using a Wurster column, product of Powrex Corporation) with 0.3 kg of the same spherical core particles as employed in Example 1 and layering the spherical core particles with the layering liquid until the layering amount reached 3.4 mass % (2.0 mass % in terms of the drug) under the conditions of spray air pressure of 0.16 MPa, spray air flow rate of 40 L/min, inlet-air temperature of 75° C., outlet-air temperature of from 42 to 49° C., air flow of from 31 to 43 m³/h, and spray rate of layering liquid of 2.5 g/min (corresponding to the coating rate of 1.4 g/min in terms of a solid content per kg of spherical core particles).

Example 3

(Preparation of Layering Liquid)

1.5 g of D-mannitol was added to 51.3 g of water while stirring with propeller. The resulting mixture was stirred until completely dissolved. Then 1.2 g of povidone and 6.0 g of chlorpheniramine d-maleate were added therein, and the resulting mixture was stirred until completely dissolved to obtain a layering liquid.

(Production of Spherical Base Granules)

In the same manner as Example 2 except that layering of the spherical core particles was performed at a spray rate of the layering liquid of 2.5 g/min (corresponding to a coating rate of 1.2 g/min in terms of a solid content per kg of spherical core particles) until the coating amount reached 2.9 mass % (2.0 mass % in terms of the drug), spherical base granules having a sphericity of 0.93 were obtained.

Example 4

(Preparation of layering liquid)

0.3 g of D-mannitol was added to 52.5 g of water while stirring with propeller, and stirring was continued until completely dissolved. Then 1.2 g of povidone and 6.0 g of chlorpheniramine d-maleate were added therein, and the resulting mixture was stirred until completely dissolved to obtain a layering liquid.

(Production of Spherical Base Granules)

In the same manner as Example 2 except that layering of the spherical core particles was performed at a spray rate of the layering liquid of 2.5 g/min (corresponding to a coating speed of 1.0 g/min per kg of spherical core particles) until the layering amount reached 2.5 mass % (2.0 mass % in terms of the drug), spherical base granules having a sphericity of 0.92 were obtained.

Example 5

(Preparation of Layering Liquid)

13.0 g of D-mannitol was added to 81.0 g of water while stirring with propeller, and stirring was continued until completely dissolved. Then 1.0 g of povidone and 5.0 g of chlorpheniramine d-maleate therein were added, and the resulting mixture was stirred until completely dissolved to obtain a layering liquid.

(Production of Spherical Base Granules)

In the same manner as Example 2 except that layering of the spherical core particles was performed at a spray rate of the layering liquid of 2.0 g/min (corresponding to a coating rate of 1.3 g/min in terms of a solid content per kg of spherical core particles) until the layering amount reached 7.6 mass % (2.0 mass % in terms of the drug), spherical base granules having a sphericity of 0.96 were obtained.

Example 6

(Preparation of Layering Liquid)

1.5 g of lactose (“Pharmatose 200M”, product of DMV) was added to 51.3 g of water while stirring with propeller, and stirring was continued until completely dissolved. Then, 1.2 g of povidone and 6.0 g of phenylchloramine d-maleate were added therein, and the resulting mixture was stirred until completely dissolved to obtain a layering liquid.

(Production of Spherical Base Granules)

In the same manner as Example 2 except that layering of the spherical core particles was performed at a spray rate of the layering liquid of 2.5 g/min (corresponding to a coating rate of 1.2 g/min in terms of a solid content per kg of spherical core particles) until the layering amount reached 2.9 mass % (2.0 mass % in terms of the drug), spherical base granules having a sphericity of 0.91 were obtained.

Comparative Example 1

(Preparation of Layering Liquid)

In the same manner as Example 1 except that D-mannitol was not added, a layering liquid was prepared. Described specifically, 2.4 g of povidone as a binder and 12.0 g of chlorpheniramine d-maleate were added to 105.6 g of water while stirring with propeller and the resulting mixture was stirred until completely dissolved to obtain a layering liquid.

(Production of Spherical Base Granules)

In the same manner as Example 1 except that layering of the spherical core particles was performed until the layering amount reached 2.4 mass % (2.0 mass % in terms of the drug) under the conditions of an outlet-air temperature of from 42 to 46° C., an air flow of from 40 to 55 m³/h, and a spray rate of the layering liquid of 5.0 g/min (corresponding to a coating rate of 1.0 g/min in terms of a solid content per kg of spherical core particles), spherical base granules having a sphericity of 0.92 were obtained. The rotation speed of a rotor was adjusted to 400 rpm until the layering amount reached 1.2 mass % and then adjusted to 450 rpm until the layering amount reached 2.4 mass %.

Since the spherical base granules had high tackiness and attached to the inside of the coating apparatus, their recovery ratio was low.

Comparative Example 2

In the same manner as Comparative Example 1 except that the spray rate of the layering liquid was adjusted to 2.5 g/min (corresponding to a coating rate of 0.5 g/min in terms of a solid content per kg of spherical core particles), spherical base granules having a sphericity of 0.92 were obtained.

Comparative Example 3

(Preparation of Layering Liquid)

The same layering liquid as employed in Comparative Example 1 was used.

(Production of Spherical Base Granules)

It was tried to carry out layering of spherical core particles until the layering amount reached 2.4 mass % (2.0 mass % in terms of the drug) in the same manner to Example 4, but operation was terminated because the spherical base formed a mass on the bottom of the column when the layering amount reached 0.84 mass %, thus stopped flowing.

Comparative Example 4

(Preparation of Layering Liquid)

A layering liquid was prepared in the same manner as Example 1.

(Production of Spherical Base Granules)

It was tried to carry out layering of spherical core particles until the layering amount reached 3.4 mass % (2.0 mass % in terms of the drug) in the same manner to Example 2 except that spherical granules (“Nonpareil” NP-101, grain size: 32-42 type, product of Freund Corporation, average particle size: 423 μm, sphericity: 0.91) composed of purified sucrose and corn starch was used as the spherical core particles. The spherical base granules formed a mass on the bottom of the column when the layering amount reached 1.7 mass %, thus stopped flowing so that operation was terminated.

The results of Examples 1 to 6, and Comparative Examples 1 to 4 are shown in Table 1.

The layering liquids obtained in Examples 1 to 6 according to the present invention each showed low tackiness, and the recovery ratio was high and low agglomeration of the spherical base granules was observed.

In contrast, the layering liquids obtained in Comparative Examples 1 to 3 which comprised no low water-soluble saccharide showed high tackiness. As a result, the spherical base granules thus obtained had high tackiness and attached to the inside wall of the apparatus, leading to a low recovery ratio. Moreover, the agglomeration ratio was high, thus the spherical base granules were not suited for film coating.

In Comparative Example 3 in which a Wurster column (guide tube) was used, the spherical base granules formed a mass on the bottom of the column, which prevented completion of layering.

In Comparative Example 4 in which the spherical core particles comprising no microcrystalline cellulose were used, the spherical base granules obtained had high tackiness in spite of low tackiness of the layering liquid so that layering was not completed.

TABLE 1
	Composition	Composition of layering
	of spherical	liquid
	core particles		Low water-
	Microcrystalline	Easily water-	soluble	Coating	Tackiness*	Agglomeration	Recovery ratio
	cellulose	soluble drug	saccharide	rate**	of layering	of base	of base
	[mass %]	[mass %]	[mass %]	[g/min]	liquid	granule [%]	granule [%]
Example 1	100	10	5	1.4	1(1, 1, 1)	9.8	97.6
Example 2	100	10	5	1.4	1(1, 1, 1)	6.1	95.5
Example 3	100	10	2.5	1.2	1(1, 1, 1)	8.9	93.7
Example 4	100	10	0.5	1.0	2(2, 1, 2)	9.9	90.4
Example 5	100	5	13	1.3	1(1, 1, 1)	9.2	90.2
Example 6	100	10	2.5	1.2	1(1, 1, 1)	11.3	89.6
Comp. Ex. 1	100	10	0	1.0	4(4, 4, 4)	34.4	73.7
Comp. Ex. 2	100	10	0	0.5	4(4, 4, 4)	25.2	95.5
Comp. Ex. 3	100	10	0	1.0	4(4, 4, 4)	Interruption of layering
Comp. Ex. 4	0	10	5	1.4	1(1, 1, 1)	Interruption of layering
*Numerals in the parenthesis under tackiness are evaluation by a panel of experts.
**Solid content per kg of spherical core particles.

SEM photographs of the spherical base granules obtained in Example 1 and an example of unagglomerated spherical base granules obtained in Comparative Examples 1 and 2 are shown in FIGS. 1 to 3.

The spherical base granules obtained in Example 1 and Comparative Example 1, both of which had a high spray rate of the layering liquid, had a smooth surface, while the spherical base granules obtained in Comparative Example 2, which had a low spray rate, had a surface inferior in smoothness.

Referential Example 1

5.0 g of lactose (“Pharmatose” 200M, product of DMV) as a low water-soluble saccharide was added to 83.0 g of water while stirring with propeller, and the resulting mixture was stirred until completely dissolved. Then, 2.0 g of polyvinylpyrrolidone and 10.0 g of chlorpheniramine d-maleate as an easily water-soluble drug were added, and the resulting mixture was stirred until completely dissolved. The tackiness of the layering liquid was measured.

Referential Example 2

In the same manner as Referential Example 1 except that maltose (product of Wako Pure Chemical Industries) was used as the low water-soluble saccharide instead of lactose, a layering liquid was prepared and tackiness thereof was measured.

Referential Example 1

5.0 g of lactose (“Pharmatose” 200M, product of DMV) as a low water-soluble saccharide was added to 83.0 g of water while stirring with propeller, and the resulting mixture was stirred until completely dissolved. Then, 2.0 g of polyvinylpyrrolidone and 10.0 g of chlorpheniramine d-maleate as an easily water-soluble drug were added, and the resulting mixture was stirred until completely dissolved. The tackiness of the layering liquid was measured.

Referential Comparative Example 2

In the same manner as Referential Example 1 except that fructose (product of Wako Pure Chemical Industries) (solubility in 1 cm³ of water: 0.6 g) which was not a low water-soluble saccharide was used instead of lactose, a layering liquid was prepared and tackiness thereof was measured.

Referential Example 3

5.0 g of lactose was added to 88.0 g of water while stirring with propeller and the resulting mixture was stirred until completely dissolved. Then, 2.0 g of polyvinylpyrrolidone and 10.0 g of loxoprofen sodium (product of OHARA Pharmaceutical Co., Ltd.) which was an easily water-soluble drug were added and the resulting mixture was stirred until completely dissolved. The tackiness of the resulting solution was measured.

Referential Comparative Example 3

2.0 g of polyvinylpyrrolidone and 10.0 g of loxoprofen sodium were added to 88.0 g of water while stirring with propeller. The resulting mixture was stirred until completely dissolved and the tackiness of the solution was measured.

Referential Comparative Example 4

In the same manner as Referential Example 3 except that sorbitol was used instead of lactose, a layering liquid was prepared and tackiness thereof was measured.

Referential Comparative Example 5

In the same manner as Referential Example 3 except that fructose was used instead of lactose, a layering liquid was prepared and tackiness was measured.

The composition and tackiness of each of the layering liquids obtained in Referential Examples 1 to 3 and Referential Comparative Examples 1 to 5 are shown in Table 2.

The layering liquids of Referential Examples 1 to 3 comprising a low water-soluble saccharide had low tackiness irrespective of the kind of the easily water-soluble drug employed.

In contrast, the layering liquids of Referential Comparative Examples comprising no low water-soluble saccharide each had high tackiness. In particular, results of Referential Comparative Examples 1, 2, 4, and 5 have revealed that sorbitol and fructose which are high water-soluble do not show a tackiness reducing effect although they are saccharides.

TABLE 2
	Composition of layering liquid
		Saccharide [mass %]
	Easily water-soluble	Low water solubility	High water solubility
	drug [mass %]	Lactose	Maltose	Sorbitol	Fructose	Tackiness*
	Chlorpheniramine	Loxoprofen	(solubility**	(solubility**	(solubility**	(solubility**	of layering
	maleate	sodium	0.19 g)	0.78 g)	0.9 g)	6 g)	liquid
Ref. Ex. 1	10		5				1(1, 1, 1)
Ref. Ex. 2	10			5			1(1, 2, 1)
Ref. Comp. Ex. 1	10				5		5(5, 4, 5)
Ref. Comp. Ex. 2	10					5	5(4, 5, 5)
Ref. Ex. 3		10	5				1(2, 1, 1)
Ref. Comp. Ex. 3		10					4(4, 4, 4)
Ref. Comp. Ex. 4		10			5		4(4, 4, 4)
Ref. Comp. Ex. 5		10				5	4(5, 4, 4)
*Numerals in the parenthesis under tackiness are evaluation by a panel of experts
**Solubility in 1 cm3 of water of 20° C.

INDUSTRIAL APPLICABILITY

The production process of the present invention is preferably employed in the field of production of pharmaceutical granules subjected to film coating.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 Surface condition of spherical base granules obtained in Example 1.

FIG. 2 Surface condition of spherical base granules obtained in Comparative Example 1.

FIG. 3 Surface condition of spherical base granules obtained in Comparative Example 2.

LEGEND

None

Claims

1. A process for producing spherical base granules comprising an easily water-soluble drug, which comprises spraying a layering liquid over pharmaceutically inert spherical core particles to thereby coat the particles with a drug-containing layer, wherein:

(1) the spherical core particles have a microcrystalline cellulose content of 30 mass % or greater, a water absorbing capacity of 0.5 cm³/g or greater and a bulk density of about 0.5 to about 2.0 g/cm³;

(2) the layering liquid is an aqueous solution comprising at least from 5 to 30 mass % of the easily water-soluble drug and from 1 to 30 mass % of D-mannitol;

(3) the easily water-soluble drug has a solubility of 1.5 g or greater in 1 cm³ of water at 20° C.; and

(4) (3) the easily water-soluble drug is at least one selected from the group consisting of ethyl L-cysteine hydrochloride, cloperastine hydrochloride, procainamide hydrochloride, ceftizoxime sodium, migrenin, and loxoprofen sodium.

2. The process for producing spherical base granules comprising an easily water-soluble drug according to claim 1, wherein the coating rate of the drug-containing layer is 0.8 g/min or greater per kg of the spherical core particles.

3. The process for producing spherical base granules comprising an easily water-soluble drug according to any one of claims 1 or 2, wherein the spherical core particles comprise microcrystalline cellulose in an amount of 70 mass % or greater.

4. The process for producing spherical base granules comprising an easily water-soluble drug according to claim 1 or 2, wherein the water absorbing capacity of the spherical core particles is 0.7 cm³/g or greater.

5. The process for producing spherical base granules comprising an easily water-soluble drug according to claim 1 or 2, wherein the layering liquid comprises from 5 to 20 mass % of the easily water-soluble drug and from 3 to 20 mass % of D-mannitol.

6. The process for producing spherical base granules comprising an easily water-soluble drug according to claim 1 or 2, wherein the layering liquid comprises from 1 to 15 mass % of D-mannitol.