COMPOSITION AND MEDICAMENT OF PALBOCICLIB ISETHIONATE

Abstract

The present invention discloses a composition of palbociclib isethionate and a medicament, and belongs to the technical field of pharmaceutical preparations. The composition includes palbociclib isethionate, a diluent, a disintegrant and a lubricant, as well as optionally a glidant. The palbociclib isethionate in the composition has a release rate of greater than or equal to 60% at a pH of 6.8 at 60 min. According to technical solutions of the present invention, influence of the pH environment in the human body on the release of a palbociclib isethionate medicament is reduced, the restriction that a medicament needs to be taken after a meal is overcome, and the medicament prepared from the composition of palbociclib isethionate can be taken before or after a meal without the restriction of achieving different effects when the medicament is taken before or after a meal.

Claims

1. A composition of palbociclib isethionate, comprising the following components in parts by mass: TABLE-US-00016 palbociclib isethionate 25-50 parts diluent 40-70 parts disintegrant 1-15 parts glidant 0-10 parts lubricant 0.1-10 parts .

2. The composition of palbociclib isethionate according to claim 1, wherein when the composition is tested in 900 mL of a phosphate buffer medium with a pH of 6.8 at 50 rpm and a dissolution temperature of 37±0.5° C. by a paddle method, the palbociclib isethionate has a release rate of greater than or equal to 60% at 60 min.

3. The composition of palbociclib isethionate according to claim 1, wherein when the composition is tested in 900 mL of a hydrochloric acid medium with a pH of 1.2 at 50 rpm and a dissolution temperature of 37±0.5° C. by a paddle method, the palbociclib isethionate has a release rate of greater than or equal to 85% at 15 min.

4. The composition of palbociclib isethionate according to claim 1, wherein a raw material of the palbociclib isethionate has a particle size D90 of 3-60 .Math.m.

5. The composition of palbociclib isethionate according to claim 4, wherein a raw material of the palbociclib isethionate has a particle size D90 of 3-20 .Math.m.

6. The composition of palbociclib isethionate according to claim 4, wherein the particle size of the palbociclib isethionate is controlled in a synthesis process of the raw material of the palbociclib isethionate, or the particle size of the palbociclib isethionate is controlled by conducting a pulverization, grinding or micropulverization process on the raw material of the palbociclib isethionate prepared.

7. The composition of palbociclib isethionate according to claim 4, wherein the particle size of the palbociclib isethionate is controlled in a synthesis process of the raw material of the palbociclib isethionate.

8. The composition of palbociclib isethionate according to claim 1, wherein the composition comprises 30-45 parts by mass of the palbociclib isethionate.

9. The composition of palbociclib isethionate according to claim 1, wherein the diluent is selected from one or more of lactose, microcrystalline cellulose, pregelatinized starch, mannitol or calcium hydrogen phosphate.

10. The composition of palbociclib isethionate according to claim 9, wherein the composition comprises 50-60 parts by mass of the diluent.

11. The composition of palbociclib isethionate according to claim 9, wherein the disintegrant is selected from one or more of crospovidone, sodium carboxymethyl starch, crosslinked sodium carboxymethyl cellulose, crosslinked calcium carboxymethyl cellulose or low-substituted hydroxypropyl cellulose for combined use.

12. The composition of palbociclib isethionate according to claim 11, wherein the composition comprises 3-10 parts by mass of the disintegrant.

13. The composition of palbociclib isethionate according to claim 11, wherein the glidant is optionally selected from one or more of silicon dioxide, talc powder or polyethylene glycol.

14. The composition of palbociclib isethionate according to claim 13, wherein the glidant is silicon dioxide.

15. The composition of palbociclib isethionate according to claim 13, wherein the composition comprises 0.5-5 parts by mass of the glidant.

16. The composition of palbociclib isethionate according to claim 13, wherein the lubricant is selected from one or more of magnesium stearate, sodium stearyl fumarate, calcium stearate or stearic acid.

17. The composition of palbociclib isethionate according to claim 16, wherein the lubricant is magnesium stearate.

18. The composition of palbociclib isethionate according to claim 16, wherein the composition comprises 0.5-4 parts by mass of the lubricant.

19. A medicament, comprising the composition of palbociclib isethionate according to claim 1, wherein granules obtained after granulation of the composition have a tap density of 0.55-0.72 g/mL and an angle of repose of less than or equal to 44°.

20. The medicament according to claim 19, wherein the tap density is 0.62-0.69 g/mL.

21. A medicament, comprising the composition of palbociclib isethionate according to claim 2, wherein granules obtained after granulation of the composition have a tap density of 0.55-0.72 g/mL and an angle of repose of less than or equal to 44°.

22. The composition of palbociclib isethionate according to claim 2, wherein when the composition is tested in 900 mL of a hydrochloric acid medium with a pH of 1.2 at 50 rpm and a dissolution temperature of 37±0.5° C. by a paddle method, the palbociclib isethionate has a release rate of greater than or equal to 85% at 15 min.

23. The composition of palbociclib isethionate according to claim 2, wherein a raw material of the palbociclib isethionate has a particle size D90 of 3-60 .Math.m.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0038] FIG. 1 shows release curves of palbociclib isethionate capsules prepared from raw materials different in particle size of palbociclib isethionate in Example 1 and palbociclib capsules in a free alkali form in a medium with a pH of 1.2;

[0039] FIG. 2 shows release curves of palbociclib isethionate capsules prepared from raw materials different in particle size of palbociclib isethionate in Example 1 and palbociclib capsules in a free alkali form in a medium with a pH of 6.8;

[0040] FIG. 3 shows release curves of palbociclib isethionate capsules prepared from raw materials different in particle size of palbociclib isethionate in Example 2 and palbociclib capsules in a free alkali form in a medium with a pH of 1.2;

[0041] FIG. 4 shows release curves of palbociclib isethionate capsules prepared from raw materials different in particle size of palbociclib isethionate in Example 2 and palbociclib capsules in a free alkali form in a medium with a pH of 6.8;

[0042] FIG. 5 shows release curves of 5 batches of samples of palbociclib isethionate capsules in Example 9 in a medium with a pH of 1.2; and

[0043] FIG. 6 shows release curves of 5 batches of samples of palbociclib isethionate capsules in Example 9 in a medium with a pH of 6.8.

DETAILED DESCRIPTION

[0044] Unless otherwise defined, meanings of all technical and scientific terms used herein are the same as those usually understood by a person skilled in the art to which the present invention belongs. The term “and/or” used herein includes any or all combinations of one or more of related listed items.

[0045] When specific conditions are not specified in embodiments, processes shall be carried out in accordance with conventional conditions or conditions suggested by manufactures. All reagents or instruments used without specific manufacturers are commercially available conventional products.

[0046] As used herein, the term “about” is used for providing flexibility and imprecision associated with a given term, measure, or value. The degree of flexibility of specific variables can be easily determined by a person skilled in the art.

[0047] Parts, concentrations, quantities, and other numerical data can be presented in the form of a range herein. It should be understood that the form of a range is used only for convenience and brevity, and should be interpreted flexibly to include not only values that are explicitly stated as limits of the range, but also all individual values or subranges that are covered within the range, as if each value and subrange are explicitly stated. For example, the numerical range from about 1 to about 4.5 should be interpreted to include not only explicitly stated limits from 1 to about 4.5, but also individual numbers (such as 2, 3, and 4) and subranges (such as 1 to 3 and 2 to 4). The same principle is applicable to ranges that state only one value, such as “less than about 4.5,” which should be interpreted to include all of the above values and ranges. In addition, the interpretation should apply regardless of the scope or breadth of features described.

[0048] Any steps described in any method or process claims may be carried out in any order, and are not limited to the order set forth in the claims. Limitations of a method and a function or a step and a function are adopted only when all of the following conditions are satisfied in a specificclaim limitation: a) a “method for......” or a “step for......” is explicitly stated; and b) corresponding functions are explicitly stated. Therefore, the scope of the present invention shall be determined only by the attached claims and legal equivalents thereof and not by the description and embodiments provided herein.

[0049] The present invention is further described below in conjunction with specific embodiments.

[0050] First, the applicant has studied the solubility of palbociclib isethionate in water, a hydrochloric acid solution with a pH of 1.0, a phosphate buffer with a pH of 6.8 and an acetate buffer with a pH of 4.5 (as shown in Table 3). It has been found that the palbociclib isethionate is a pH-dependent medicament, has a good degree of dissociation in acidic gastric juice, and can be effectively absorbed. However, the palbociclib isethionate enters the intestinal tract rapidly on an empty stomach, and the pH environment becomes neutral and weakly alkaline. As the solubility of the palbociclib isethionate is extremely low at a pH of 6.8, absorption of the palbociclib isethionate will be affected by the solubility, which is extremely unfavorable to the absorption and utilization of the palbociclib isethionate.

TABLE-US-00004 Solubility data of palbociclib isethionate at different pH values Serial number pH Solubility (mg/mL) 1 1.0 90.7 2 4.5 84.7 3 6.8 0.04 4 Water 84.8

Example 1

[0051] A prescription includes the following components:

TABLE-US-00005 Palbociclib isethionate 160.23 g Lactose 82.7 g Microcrystalline cellulose 165.4 g Crospovidone 27 g Colloidal silicon dioxide 5.7 g Magnesium stearate 9 g Prepared into 1,000 granules

Preparation Process:

[0052] In this example, in order to investigate differences of in vitro release behaviors of products caused by the particle size, raw materials of palbociclib isethionate with the following particle size D90 were separately used: 3 .Math.m, 20 .Math.m, 30 .Math.m, 60 .Math.m, 80 .Math.m, and 120 .Math.m (the particle size of the raw materials was tested by a laser particle size analyzer of Sympatec and a particle size tester with a model of HELOS/BR-RODOS/T4&CUVETTE; and test parameters were as follows: a dispersion system of RODOD/T4 was selected, an R5 (0.5-875 .Math.m) lens was selected, an injector was set to VIBRI, the injection rate was 20%-90%, the dispersion pressure was 3.5-4.5 bar, and the parameters were the same below). The palbociclib isethionate different in particle size was obtained by synthesis. Capsules were prepared by the following method according to the components in the above prescription.

1. Preparation of Raw and Auxiliary Materials

[0053] The raw materials of palbociclib isethionate (with the particle size D90 of 3 .Math.m, 20 .Math.m, 30 .Math.m, 60 .Math.m, 80 .Math.m, and 120 .Math.m separately), the microcrystalline cellulose and the crospovidone were separately sifted with a 40-mesh sieve, and the lactose, the colloidal silicon dioxide and the magnesium stearate were separately sifted with an 80-mesh sieve for later use.

2. Premixing

[0054] The palbociclib isethionate and the microcrystalline cellulose were weighed according to the amounts in the prescription respectively, premixed, and then sifted with a 40-mesh sieve. A premix, the lactose, the crospovidone and the colloidal silicon dioxide were added to a three-dimensional motion mixer and mixed for 15 min.

3. Dry Granulation

[0055] After parameters of a dry granulation machine were set, a mixture obtained in step 2 was subjected to dry granulation.

4. Blending

[0056] The magnesium stearate and granules obtained after the dry granulation were added to the three-dimensional motion mixer and blended for uniform mixing for 10 min.

5. Filling of Capsules

[0057] Capsules were filled with blended granules by using a capsule filling machine, where 0# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsule Capsugel® LTD. were used in the example) were used, and the filling capacity was 450 mg.

[0058] Obtained samples were recorded as a sample 1-1 (the particle size D90 of the raw material of palbociclib isethionate was 3 .Math.m), a sample 1-2 (the particle size D90 of the raw material of palbociclib isethionate was 20 .Math.m), a sample 1-3 (the particle size D90 of the raw material of palbociclib isethionate was 30 .Math.m), a sample 1-4 (the particle size D90 of the raw material of palbociclib isethionate was 60 .Math.m), a sample 1-5 (the particle size D90 of the raw material of palbociclib isethionate was 80 .Math.m), and a sample 1-6 (the particle size D90 of the raw material of palbociclib isethionate was 120 .Math.m).

Example 2

[0059] A prescription includes the following components:

TABLE-US-00006 Palbociclib isethionate 128.18 g Lactose 66.16 g Microcrystalline cellulose 132.32 g Crospovidone 21.6 g Colloidal silicon dioxide 4.56 g Magnesium stearate 7.2 g Prepared into 1,000 granules

Preparation Process:

[0060] In this example, in order to investigate differences of in vitro release behaviors of products caused by the particle size, raw materials of palbociclib isethionate with the following particle size D90 were separately used: 3 .Math.m, 20 .Math.m, and 60 .Math.m. The raw material with the particle size D90 of 3 .Math.m was obtained by air flow pulverization, and the raw materials with the particle size D90 of 20 .Math.m and 60 .Math.m were separately obtained by synthesis. Capsules were prepared by the following method according to the components in the above prescription under three conditions.

1. Preparation of Raw and Auxiliary Materials

[0061] The raw materials of palbociclib isethionate, the microcrystalline cellulose and the crospovidone were separately sifted with a 40-mesh sieve, and the lactose, the colloidal silicon dioxide and the magnesium stearate were separately sifted with an 80-mesh sieve for later use.

2. Premixing

[0062] The palbociclib isethionate and the microcrystalline cellulose were weighed according to the amounts in the prescription respectively, premixed, and then sifted with a 40-mesh sieve. A premix, the lactose, the crospovidone and the colloidal silicon dioxide were added to a three-dimensional motion mixer and mixed for 15 min.

3. Dry Granulation

[0063] After parameters of a dry granulation machine were set, a mixture obtained in step 2 was subjected to dry granulation.

4. Blending

[0064] The magnesium stearate and granules obtained after the dry granulation were added to the three-dimensional motion mixer and blended for uniform mixing for 10 min.

5. Filling of Capsules

[0065] Capsules were filled with blended granules by using a capsule filling machine, where 1# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsule Capsugel (R) LTD. were used in the example) were used, and the filling capacity was 360 mg.

[0066] Obtained samples were recorded as a sample 2-1 (the particle size D90 of the raw material of palbociclib isethionate was 3 .Math.m), a sample 2-2 (the particle size D90 of the raw material of palbociclib isethionate was 20 .Math.m), and a sample 2-3 (the particle size D90 of the raw material of palbociclib isethionate was 60 .Math.m).

[0067] The samples prepared from raw materials different in particle size in Example 1 and Example 2 were separately sampled at different time points to investigate the release rate in 900 mL of a hydrochloric acid medium with a pH of 1.2 at 50 rpm and 900 mL of a phosphate buffer medium with a pH of 6.8 at 50 rpm by a paddle method, so as to study in vitro release behaviors.

[0068] Test results of the release rate of products prepared from raw materials different in particle size show the following conclusions.

[0069] The capsule samples prepared from raw materials different in particle size in Example 1 of the present invention and palbociclib isethionate capsules in a free alkali form (commercially available product, Ibrance® with a specification of 125 mg) produced by Pfizer were taken to study in vitro release behaviors, and have release curves as shown in FIG. 1 at a pH of 1.2 (as capsule shells of the same type were used, influence of the capsule shells on the release rate can be excluded). Results show that the samples prepared from raw materials different in particle size have release behaviors basically consistent with that of the palbociclib isethionate capsules in a free alkali form in the medium with a pH of 1.2, and the dissolution rate is greater than 85% at 15 min. However, as shown in FIG. 2, the release rate of the palbociclib isethionate capsules in a free alkali form (commercially available product, Ibrance® with a specification of 125 mg) produced by Pfizer is still less than 20% at 360 min in the medium with a pH of 6.8, which is the same as that in previous studies. The palbociclib isethionate capsules in a free alkali form are suitable for taking after a meal, and have poor bioavailability when taking before a meal. On the contrary, the release rate of the capsules of the compositions prepared from the raw materials of palbociclib isethionate with the D90 of 3-120 .Math.m is greater than that of the palbociclib isethionate capsules in a free alkali form in the medium with a pH of 6.8. When the raw materials of palbociclib isethionate different in particle size are used, the release behaviors are different. With the increase of the particle size, the release is slowed down. The capsules of the compositions prepared from the raw materials of palbociclib isethionate with the D90 of 3-60 .Math.m have a basically consistent release rate at 60 min, and the release rate is greater than 60%.

[0070] The capsule samples prepared from raw materials different in particle size in Example 2 of the present invention were taken to study in vitro release behaviors, and have release curves as shown in FIG. 3 at a pH of 1.2. Results show that the capsule samples prepared from raw materials different in particle size have release behaviors basically consistent with that of the palbociclib isethionate capsules in a free alkali form in the medium with a pH of 1.2, and the release rate is greater than 85% at 15 min. However, as shown in FIG. 4, the release rate of the palbociclib isethionate capsules in a free alkali form (commercially available product, Ibrance® with a specification of 125 mg) produced by Pfizer is still less than 20% at 360 min in the medium with a pH of 6.8. On the contrary, the release rate of the capsules of the compositions prepared from the raw materials of palbociclib isethionate with the D90 of 3-60 .Math.m is greater than that of the palbociclib isethionate capsules in a free alkali form in the medium with a pH of 6.8. When the raw materials of palbociclib isethionate different in particle size are used, the release behaviors are basically consistent, and the release rate is greater than 60% at 60 min. Therefore, when the particle size of the raw materials of palbociclib isethionate is controlled to 3-60 .Math.m, the effect of good bioavailability can also be achieved when the palbociclib isethionate is taken before a meal. When the particle size D90 of the raw materials of palbociclib isethionate is 3-20 .Math.m, the release rate is high, and thus this range is a more preferred particle size range.

[0071] Through comparison between Example 1 (palbociclib isethionate with a specification of 160.23 mg) and Example 2 (palbociclib isethionate with a specification of 128.18 mg), different specifications of the palbociclib isethionate have basically the same release rate at a pH of 1.2 and a pH of 6.8.

Example 3

[0072] A prescription includes the following components:

TABLE-US-00007 Palbociclib isethionate 96.14 g Lactose 42.7 g Microcrystalline cellulose 105.4 g Crospovidone 15 g Colloidal silicon dioxide 6.76 g Magnesium stearate 4 g Prepared into 1,000 granules

1. Preparation of Raw and Auxiliary Materials

[0073] A raw material of the palbociclib isethionate (D90 was 31 .Math.m), the microcrystalline cellulose and the crospovidone were separately sifted with a 40-mesh sieve, and the lactose, the colloidal silicon dioxide and the magnesium stearate were separately sifted with an 80-mesh sieve for later use.

2. Premixing

[0074] The palbociclib isethionate and the microcrystalline cellulose were weighed according to the amounts in the prescription respectively, premixed, and then sifted with a 40-mesh sieve. A premix, the lactose, the crospovidone and the colloidal silicon dioxide were added to a three-dimensional motion mixer and mixed for 15 min.

3. Dry Granulation

[0075] After parameters of a dry granulation machine were set, a mixture obtained in step 2 was subjected to dry granulation.

4. Blending

[0076] The magnesium stearate and granules obtained after the dry granulation were added to the three-dimensional motion mixer and blended for uniform mixing for 10 min.

5. Filling of Capsules

[0077] Capsules were filled with blended granules by using a capsule filling machine, where 2# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsule Capsugel® LTD. were used in the example) were used, and the filling capacity was 270 mg.

[0078] The release rate of the capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

Example 4

[0079] A prescription includes the following components:

TABLE-US-00008 Palbociclib isethionate (D90 was 45 .Math.m) 160.23 g Lactose 52.7 g Microcrystalline cellulose 225.4 g Sodium carboxymethyl starch 26.67 g Colloidal silicon dioxide 10 g Magnesium stearate 9 g Prepared into 1,000 granules

[0080] A specific preparation process and a capsule specification were the same as those in Example 1.

[0081] The release rate of the capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

Example 5

[0082] A prescription includes the following components:

TABLE-US-00009 Palbociclib isethionate (D90 was 15 .Math.m) 128.18 g Calcium hydrogen phosphate 25.16 g Microcrystalline cellulose 162.32 g Crospovidone 31.6 g Sodium stearyl fumarate 6.2 g Prepared into 1,000 granules

[0083] A specific preparation process and a capsule specification were the same as those in Example 2.

[0084] The release rate of the capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

Example 6

[0085] A prescription includes the following components:

TABLE-US-00010 Palbociclib isethionate (D90 was 50 .Math.m) 96.14 g Lactose 32 g Microcrystalline cellulose 103 g Crospovidone 27 g Colloidal silicon dioxide 13 g Magnesium stearate 2 g Prepared into 1,000 granules

[0086] A specific preparation process and a capsule specification were the same as those in Example 3.

[0087] The release rate of the capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

Example 7

[0088] A prescription includes the following components:

TABLE-US-00011 Palbociclib isethionate (D90 was 25 .Math.m) 96.14 g Lactose 82.7 g Microcrystalline cellulose 165.4 g Crospovidone 27 g Colloidal silicon dioxide 5.7 g Magnesium stearate 9 g Prepared into 1,000 granules

[0089] A specific preparation process was the same as that in Example 1. 1# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsugel ® LTD. were used in the example) were used, and the filling capacity was 386 mg.

[0090] The release rate of capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

Example 8

[0091] A prescription includes the following components:

TABLE-US-00012 Palbociclib isethionate (D90 was 32 .Math.m) 128.18 g Lactose 30.1 g Microcrystalline cellulose 75.28 g Crospovidone 16 g Colloidal silicon dioxide 3.8 g Magnesium stearate 3 g Prepared into 1,000 granules

[0092] A specific preparation process was the same as that in Example 1. 2# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsugel ® LTD. were used in the example) were used, and the filling capacity was 256 mg.

[0093] The release rate of capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

Example 9

[0094] A prescription includes the following components:

TABLE-US-00013 Palbociclib isethionate (D90 was 20 .Math.m) 128.18 g Calcium hydrogen phosphate 96.16 g Microcrystalline cellulose 102.32 g Calcium carboxymethyl cellulose 21.6 g Colloidal silicon dioxide 4.56 g Magnesium stearate 7.2 g Prepared into 1,000 granules

Preparation Process:

1. Preparation of Raw and Auxiliary Materials

[0095] The palbociclib isethionate, the microcrystalline cellulose and the crospovidone were sifted with a 40-mesh sieve, and the calcium hydrogen phosphate, the colloidal silicon dioxide and the magnesium stearate were sifted with an 80-mesh sieve for later use.

2. Premixing

[0096] The palbociclib isethionate and the microcrystalline cellulose were weighed according to the amounts in the prescription respectively, premixed, and then sifted with a 40-mesh sieve.

3. Mixing

[0097] A premix, the calcium hydrogen phosphate and the calcium carboxymethyl cellulose were added to a three-dimensional motion mixer and mixed for 15 min.

4. Dry Granulation

[0098] After parameters of a dry granulation machine were set, a mixture obtained in step 3 was subjected to dry granulation. The press roll pressure was set to 25-35 kg/cm.sup.3, 35-45 kg/cm.sup.3, 45-55 kg/cm.sup.3, 55-65 kg/cm.sup.3, and 65-70 kg/cm.sup.3 separately to obtain five batches of dry granulated samples.

5. Blending

[0099] The colloidal silicon dioxide, the magnesium stearate and three batches of granules obtained after the dry granulation were separately added to the three-dimensional motion mixer and blended for uniform mixing for 10 min.

6. Filling of Capsules

[0100] Capsules were filled with blended granules by using a capsule filling machine, where 1# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsule Capsugel® LTD. were used in the example) were used, and the filling capacity was 360 mg.

[0101] 5 batches of samples 9-1, 9-2, 9-3, 9-4, and 9-5 were prepared by a capsule filling process after granules were prepared by dry granulation at different press roll pressures, and properties of the granules (including angle of repose, bulk density, and tap density), content uniformity of finished products, and other indexes were investigated separately. Results show that the five samples prepared by the dry granulation at different press roll pressures can be better filled. According to requirements of pharmacopoeia, the release rate of the samples is greater than or equal to 80% (Q) of the labelled amount in a medium with a pH of 1.2 within 30 minutes. Thus, the release rate of the various batches of samples (9-1, 9-2, 9-3, 9-4, and 9-5) was investigated in a medium with a pH of 1.2. Results show that the release of all the samples is qualified. Results are as shown in Table 4 and FIG. 5 below.

TABLE-US-00014 Sample Sample 9-1 Sample 9-2 Sample 9-3 Sample 9-4 Sample 9-5 Press roll pressure (kg/cm.sup.3) 25-35 35-45 45-55 55-65 65-70 Powder mix angle of repose (°) 38 36 37 37 38 Bulk density (g/cm.sup.3) 0.530 0.578 0.621 0.640 0.650 Tap density (g/cm.sup.3) 0.620 0.650 0.690 0.720 0.741 Compression index 14.5 11.1 10.0 Filling property Capsules have good filling conditions Capsules have good filling conditions Capsules have good filling conditions Capsules have good filling conditions Capsules have good filling conditions Loading difference (limit requirement ± 7.5%) -2.3% to 4.7% -3.0% to 2.1% -1.3% to 2.9% -1.0% to 1.2% -1.2% to 1.1% Content uniformity (limit requirement A+2.2S≤15) 6.1 5.7 2.7 2.4 2.5 Disintegration time (min) 2 min 50 s 3 min 30 s 5 min 46 s 10 min 16 min

[0102] The above study data indicate that the prescription powder mix of the present invention has good compressibility in dry granulation at a press roll pressure of 25-65 kg/cm.sup.3, a powder mix angle of repose of 36-38° and a tap density of 0.62-0.72 g/cm.sup.3, the granular powder mix prepared has good fluidity and can be easily filled into capsules, a filling process is stable, filled capsules have small differences, the content uniformity of the samples meets requirements of a content uniformity test method of General Rule 0941 of Pharmacopoeia (2015 edition), and the disintegration time is shorter than 15 min. With further increase of the pressure, the disintegration time is prolonged, resulting in decrease of the dissolution rate.

[0103] FIG. 5 shows that capsules are filled with granules prepared from the prescription powder mix of the present invention by dry granulation at a press roll pressure of 25-65 kg/cm.sup.3, and the prepared samples have in vitro release behaviors basically consistent with that of capsules in a free alkali form in a medium with a pH of 1.2. As shown in FIG. 6, release curves of the five samples from 9-1 to 9-5 at a pH of 6.8 indicate that the samples from 9-1 to 9-5 have a release rate of greater than 60% at 60 min at a pH of 6.8, and have a higher release rate than the capsules in a free alkali form.

[0104] Therefore, when the press roll pressure is controlled in the range of 25-65 kg/cm.sup.3 in the dry granulation process with the same dry granulation machine as that in the example, samples which have good fluidity, are easily filled into capsules, and have a release rate of greater than 60% at 60 min at a pH of 6.8 can be obtained.

Example 10

[0105] A prescription includes the following components:

TABLE-US-00015 Palbociclib isethionate (D90 was 30 .Math.m) 160.23 g Lactose 82.7 g Microcrystalline cellulose 165.4 g Crospovidone 27 g Colloidal silicon dioxide 5.7 g Magnesium stearate 9 g Prepared into 1,000 granules

Preparation Process:

1. Preparation of Raw and Auxiliary Materials

[0106] The palbociclib isethionate, the microcrystalline cellulose and the crospovidone were sifted with a 40-mesh sieve, and the lactose, the colloidal silicon dioxide and the magnesium stearate were sifted with an 80-mesh sieve for later use.

2. Mixing

[0107] The palbociclib isethionate, the microcrystalline cellulose, the lactose, the crospovidone and the colloidal silicon dioxide were weighed according to the amounts in the prescription respectively, added to a three-dimensional motion mixer and mixed for 15 min.

3. Dry Granulation

[0108] After parameters of a dry granulation machine were set, a mixture obtained in step 2 was subjected to dry granulation.

4. Blending

[0109] The magnesium stearate and granules obtained after the dry granulation were added to the three-dimensional motion mixer and blended for uniform mixing for 10 min.

5. Filling of Capsules

[0110] Capsules were filled with blended granules by using a capsule filling machine, where 0# capsules (hollow gelatin capsules produced by the manufacturer Suzhou Capsule Capsugel® LTD. were used in the example) were used, and the filling capacity was 450 mg.

[0111] The granules prepared by using the method in this example have a powder mix angle of repose of 44°, a bulk density of 0.509 g/cm.sup.3, a tap density of 0.567 g/cm.sup.3, a loading difference (limit requirement ± 7.5%) of -5.5% to 5.9%, a content uniformity (limit requirement A+2.2S≤15) of 14.3, and good fluidity. The capsules can be better filled.

[0112] The release rate of the capsules in this example was separately tested by the same release rate measurement method as above at a pH of 1.2 and a pH of 6.8. Results show that the capsules prepared in this example have release behaviors basically consistent with that of capsules in a free alkali form at a pH of 1.2, but the release rate is greater than that of the capsules in a free alkali form at a pH of 6.8, and the release rate is greater than 60% at 60 min.

[0113] The above content is a schematic description of the present invention and embodiments thereof, and the description is not restrictive. The content as shown in the examples is only one of the embodiments of the present invention, and the embodiments are actually not limited thereto. Therefore, when those of ordinary skill in the art are inspired by the present invention, structural modes and examples made similar to the technical solutions without creative design on the premise of not departing from the creative purpose of the present invention shall fall within the protection scope of the present invention.