CN102258786A - Porous microspheres for medicine carriers, preparation method and medicine loading method - Google Patents

Porous microspheres for medicine carriers, preparation method and medicine loading method Download PDF

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CN102258786A
CN102258786A CN201110164346A CN201110164346A CN102258786A CN 102258786 A CN102258786 A CN 102258786A CN 201110164346 A CN201110164346 A CN 201110164346A CN 201110164346 A CN201110164346 A CN 201110164346A CN 102258786 A CN102258786 A CN 102258786A
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microsphere
organic solvent
medicine
porous
preparation
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CN102258786B (en
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马光辉
韦祎
王玉霞
苏志国
周炜清
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Institute of Process Engineering of CAS
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Abstract

The invention relates to the field of preparation of porous microspheres, in particular to porous microspheres for medicine carriers, a preparation method and a medicine loading method. The method comprises the following steps of: 1) dissolving a degradable di-block amphiphilic polymer material in an organic solvent to form an oil phase O; 2) adding the oil phase O into a water phase W which contains a stabilizing agent to form O/W pre-emulsion; 3) allowing the O/W pre-emulsion obtained in the step 2 to pass through a microporous membrane to obtain O/W emulsion; and 4) removing the organic solvent from the emulsion obtained in the step 3, and curing, performing centrifugal washing and freeze drying to obtain porous medicine carrying microspheres. The organic solvent in the step 1) at least comprises a solvent of which the solubility in water is less than 2 percent; and the volume ratio of the oil phase O to the water phase W is 1:5-20. The porous microspheres overcome the problem that the conventional sustained release microspheres cannot be completely released at a later stage, and can effectively keep the medicine activity in the processes of carrying, storing and releasing the medicines.

Description

A kind of porous microsphere, preparation method and drug loading method that is used for pharmaceutical carrier
Technical field
The present invention relates to the preparation field of porous microsphere, particularly, the present invention relates to a kind of porous microsphere, preparation method and drug loading method that is used for pharmaceutical carrier.
Background technology
Along with the development of emerging biometric technology and genetic engineering, the biochemical medicine of protein and polypeptide class macromole (as growth hormone, insulin, heparin, interferon, interleukin etc.) because show in dwarfism, diabetes, liver cirrhosis and cancer etc. are difficult to the therapeutic process of cure diseases that pharmacological action is strong, few side effects and the characteristics that seldom cause allergic reaction and extremely pay attention to.Because polypeptide and protein drug poor stability easily are degraded in the intestines and stomach, and have the low problem of bioavailability, so the injection that adopts more.But because half-life weak point in the body of this type of medicine usually needs the multiple injection administration during clinical practice.At these problems, researcheres are followed two kinds of solution routes substantially, and the firstth, the route of administration of a high bioavailability of pharmaceutical grade protein of searching; The secondth, optimize proteinic dynamic metabolism characteristic by chemical modification, to prolong its half-life, reach long-acting stable purpose.Wherein, utilize biology can fall the type polymer and prepare Loaded Microspheres Drug Delivery System, can reach long-acting slow-release, reduce administration number of times and medicine irritation, reduce toxic and side effects, improve the purpose of curative effect for framework material.Usually embedding medicinal adopts multi-emulsion method, and the contacting of albumen and organic solvent and oil-water interfaces in preparation process all may influence proteinic structure; And stir, the interference of these extraneous factors of supersound process easily makes a series of physics or chemical changes such as it is assembled, absorption, precipitation, oxidation, deacylated tRNA amine, hydrolysis.In a single day protein structure is destroyed, and not only drug effect descends, and may produce immunogenicity and other untoward reaction in vivo.In order to increase the stability of protein drug in the microsphere process; generally need with its with carry out lyophilizing after some protective agent solution mix and handle; protective agent commonly used mainly contains two classes: polyethylene glycols and saccharide; but residual mensuration and removal are brought difficulty, be unfavorable for large-scale industrial production.
In order to overcome protein and the easy ruined problem of other pharmaceutically actives in the embedding process, available have the microsphere absorption medicine of loose structure to reach the medicine carrying purpose.Because have the conventional microsphere that the microsphere of loose structure is compared equal size, more specific surface area can be provided, when preparing the medicine carrying microballoons preparation, can significantly improve the useful load of medicine with absorption method.The homogeneity of particle diameter is a microsphere key in application problem, because the particle diameter heterogeneity certainly will cause the problem of preparation repeatability and treatment poor repeatability, it is clinical to be difficult to declaration.Use the porous polylactic acid microball particle diameter and the pore-size distribution heterogeneity of paddling process preparation in the Chinese patent (publication number CN101361716A), be difficult to improve carrying drug ratio and accurately regulating medicine discharge and experiment batch between repeatability.
Can discharging fully of drug loading also is the subject matter that restriction drug-carrying polymer microsphere enters clinical practice, non-specific adsorption easily takes place between hydrophobic polymeric material and the protein drug that loaded, cause the incomplete release of medicine, cause the waste of medicine and bioavailability to reduce.The micro-sphere material of the absorption medicine that uses in the Chinese patent (Granted publication CN100388970C) is hydrophobic polylactic acid (PLA) copolymer, and this hydrophobic material causes the incomplete release of medicine easily in the later stage of protein medicaments discharges.And the non-specific adsorption effect between film material and the albumen easily makes albumen assemble, and reduces the activity of medicine.
At different diseases, required drug release rate difference for example, is used for the treatment of anticancer medicine needs and discharges in a large number timely, to reach effective drug level; And be used for the treatment of the medicines such as insulin of diabetes, and need slowly to discharge guarantee stable drug level, reduce frequency injection and alleviate patient's misery.Therefore, the controlled medicine carrying microballoons of preparation rate of release is very necessary.Uses ethyl cellulose to prepare the controlled porous microsphere of particle diameter in the Chinese patent (publication number CN1939281A), but the degradation speed of microsphere is not regulated and control and studied, be unfavorable for the universality of drug use as the film material.Generally speaking, when preparation porous medicine carrying microballoons, need to add perforating agent, cause residual mensuration difficulty of later stage, and reduce biological safety; And microspherulite diameter that existing technology prepares and aperture heterogeneity, carrying drug ratio is low, poor repeatability; Easy and the microsphere skeleton generation non-specific adsorption of protein drug in the dispose procedure causes medicine not exclusively to discharge and the generation aggregation, thereby produces immunogenicity, causes losing activity; The microsphere degradation process is uncontrollable, is unfavorable for that expanded application is in multiple treatment of diseases.
The present invention is directed to porous microsphere particle diameter and pore-size distribution heterogeneity, carrying drug ratio is low, can not sustained release and problem such as pharmaceutically active is low, and proposing to adopt a kind of amphipathic nature polyalcohol of two blocks is material, and the preparation porous microsphere solves an above-mentioned difficult problem as pharmaceutical carrier.
Summary of the invention
The object of the present invention is to provide a kind of porous microsphere that is used for pharmaceutical carrier.
A further object of the present invention is to provide a kind of preparation method that is used for the porous microsphere of pharmaceutical carrier.
An also purpose of the present invention is to provide a kind of drug loading method that is used for the porous microsphere of pharmaceutical carrier.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, the preparation method of described microsphere may further comprise the steps:
1) degradable two block amphipathic nature polyalcohol materials is dissolved in the organic solvent, forms oil phase O;
2) oil phase O is joined the aqueous phase W that contains stabilizing agent, form the pre-breast of O/W;
3) with step 2) the pre-breast of the O/W of gained is by microporous membrane, obtains the O/W emulsion;
4) organic solvent in the resulting emulsion of step 3) is removed, solidified,, obtain the porous medicine carrying microballoons again through centrifuge washing and lyophilization;
In the described step 1) organic solvent contain at least a kind of in water dissolubility be lower than 2% solvent, described organic solvent comprises one or more in dichloromethane, chloroform, Carbon bisulfide and the dimethylbenzene;
Described step 2) volume ratio 1: 5~20 of oil phase O and water W in.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, the size of described pre-emulsion is more preferably greater than membrane aperture, the preparation method of pre-emulsion, can be by method preparations such as common emulsifying manner such as homogenizing, ultrasonic, mechanical agitation, the removal of the organic solvent in the described emulsion can adopt reduction vaporization, normal temperature and pressure to stir in the methods such as volatilization or solvent extraction one or several.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, described pressure can be regulated between 1-2000kPa, this mainly by the preparation of the size in the microporous membrane aperture of using in the preparation process and targeted microspheres size require determine.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, described microporous membrane comprises hydrophobic and hydrophilic film, preferred hydrophilic film, as adopting hydrophilic SPG film, this SPG film is a commercial prod, in preparation process, can control the size of product by the SPG film of selecting different membrane aperture, microporous membrane aperture commonly used is 0.5-200 μ m, and preferably 1.4-50 μ m is more preferably 2.8-18 μ m.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, the selection face of described polymeric material is very wide, not only can select amphipathic nature material, as polylactic acid, polylactic acid-polyglycolic acid copolymer, polycaprolactone, poe, poly-anhydride, polyphosphazene respectively with the polymeric material of Polyethylene Glycol copolymerization gained in any one, also the composite mixing of the polymer of its variety classes different molecular weight can be used.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, described organic solvent can be selected from the organic solvent that dissolubility in the water is lower than 2% (not comprising 2%), as in the organic solvents such as dichloromethane, chloroform, Carbon bisulfide and dimethylbenzene any one or multiple, concrete kind or volume need be decided on preparation parameters such as used film materials.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, described step 3) can repeat repeatedly, and the emulsion that is about to the step 3) gained is passed through microporous membrane as pre-breast once more with pressure, meets the demands with homogeneity until the particle size of emulsion size that obtains.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, described outer water stabilizing agent is optional to wait one or more from polyvinyl alcohol, polyglyceryl fatty acid ester, Tween-81 (Tween80), polyoxyethylene sorbitol acid anhydride laurate (Tween20), dodecyl sodium sulfate (SDS), and the stabilizing agent working concentration is preferably 0.1%~10wt%.
The present invention also provides and has adopted described porous microsphere to carry out the method for drug loading, and this method may further comprise the steps:
By 1: 2~100 mass ratio medicine is mixed with porous microsphere, vibrating makes porous microsphere adsorb medicine, centrifugal collection microsphere, and the medicine that flush away does not adsorb, lyophilization obtains being adsorbed with the porous medicine carrying microballoons of medicine;
Described medicine is to be selected from a kind of in polypeptide, protide, polysaccharide, nucleic acid, the vaccine, the medicine carrying microballoons that the present invention prepares has very high release rate and keeps good biological activity for medicine, especially more obvious for polypeptide, protein matter effect, well solved an above-mentioned difficult problem.Because structure and polypeptide when polysaccharide, nucleic acid and vaccine medicine contact under intensive preparation conditions such as ultrasonic, stirring and with organic solvent, protein matter are the same, very easily destroy and cause inactivation, therefore, by porous microsphere this class medicine is adsorbed the preparation medicine carrying microballoons in the present invention, can well keep pharmaceutically active, have good effect equally.
The present invention also provides a kind of preparation method that is used for the porous microsphere of pharmaceutical carrier, said method comprising the steps of:
1) degradable two block amphipathic nature polyalcohol materials is dissolved in the solvent, forms oil phase O;
2) oil phase O is joined the aqueous phase W that contains stabilizing agent, form the pre-breast of O/W;
3) with step 2) the pre-breast of the O/W of gained is by microporous membrane, obtains the O/W emulsion;
4) organic solvent in the resulting emulsion of step 3) is removed, solidified,, obtain the porous medicine carrying microballoons again through centrifuge washing and lyophilization;
In the described step 1) solvent contain at least a kind of in water dissolubility be lower than 2% organic solvent, described organic solvent comprises one or more in dichloromethane, chloroform, Carbon bisulfide and the dimethylbenzene;
Described step 2) volume ratio 1: 5~20 of oil phase O and water W in.
The porous microsphere of size homogeneous provided by the invention, this microsphere size homogeneous, controlled, diameter Distribution coefficient (CV) are worth in 20%, and be preferred in 15%.The medicine charging ratio reaches as high as 50%, and the active conservation rate of protein and peptide drugs can abrupt release or lasting 1 thoughtful 12 weeks of release more than 90% in the dispose procedure.(Coefficient of Variation CV) adopts number ball method to measure to the particle size distribution coefficient, measures the particle diameter of 300 particles, calculates the particle size distribution coefficient (CV) of particle by following formula.
CV = ( Σ i = 1 n ( d i - d ‾ ) 2 N ) 1 2 / d ‾
D wherein iBe the particle diameter of single particle,
Figure BDA0000069100290000042
Be the number average bead diameter of particle, N is the sum of particle, N>300.
According to the porous microsphere that is used for pharmaceutical carrier of the present invention, the average particle size range of described microsphere is at 500nm-100 μ m, described polymer microballoon has adopted a kind of amphipathic nature polyalcohol material of two blocks at least and has adopted a kind of dissolubility in water to be lower than the organic solvent of 2% (not comprising 2%) at least in preparation process, more help improving medicine charging ratio, keep biological activity and sustainable release.
Adopt quick film emulsification method to prepare particle diameter among the present invention and the aperture homogeneous is controlled, the carrying drug ratio height can sustained release, and the high porous microsphere of pharmaceutically active.Wherein, the film emulsifying technology has guaranteed that the medicine carrying microballoons uniform particle diameter is controlled, method preparations such as common emulsifying manner such as homogenizing, ultrasonic, mechanical agitation are at first selected in preparation during emulsion for use, the emulsion particle diameter that makes by these conventional methods is greater than membrane aperture, then under the effect of pressure with these particle diameters greater than the pre-emulsion of membrane aperture by behind the microporous membrane, just can obtain the particle diameter double emulsion consistent, can repeated operation meet the demands with homogeneity until the particle size of emulsion size that obtains with microporous membrane.
Secondly, the di-block copolymer of employing contains hydrophilic segment, in solidification process, because organic solvent produces quick bumping and pore-forming at microsphere surface, because hydrophilic segment distributes at the microsphere surface homogeneous, so bumping speed is identical, aperture, the duct homogeneous of generation; Simultaneously, by film material and the control oil-water ratio that adopts different hydrophilic segment proportion, can control the aperture of microsphere.
Once more, because the specific surface area of porous microsphere obviously improves with respect to slick microsphere, thereby the increase of the site of absorption, can obtain higher carrying drug ratio.Can control the degradation rate of microsphere by the molecular weight of controlling diaphragm material and the concentration in organic solvent, hydrophilic block proportion, oil-water ratio and the concentration of polymer in organic solvent all can influence the degradation rate of microsphere in film material molecular weight, the polymer, thereby can control release rate of drugs by regulating above parameter.Polymer molecular weight is low more, and the concentration of polymer in organic solvent is low more, and the microsphere skeleton is loose more, be beneficial to the degraded of microsphere, thereby drug release rate is very fast; Otherwise, improve polymer molecular weight and the concentration of polymer in organic solvent, microsphere skeleton consolidation, the microsphere degraded is slow, and rate of releasing drug is also slow.Wherein the shared ratio of hydrophilic block is high more in the polymer, and the chance that microsphere contacts with the ambient water environment is many more, and the speed of hydrophilic chain degraded is fast more, and the microsphere aperture is also along with the ratio of hydrophilic block increases and increases, thereby improves drug release rate; Otherwise the shared ratio of hydrophilic block wherein in the reduction polymer, rate of releasing drug decreases.Outer water volume is big more, and the microsphere aperture is big more, and dashing forward, it is big more to release; Otherwise outer water volume reduces, and the aperture is more little, dashes forward and releases reduction, therefore can prepare different porous medicine carrying microballoonss according to state of an illness needs, thereby reach the purpose of control drug release speed; Simultaneously, hydrophilic segment is distributed in microsphere surface, has avoided hydrophobicity microsphere and proteic non-specific adsorption and the incomplete release that causes.Absorption method prepares medicine carrying microballoons and has avoided preparation conditions such as ultrasonic, stirring and organic solvent and oil-water interfaces to the influence of pharmaceutically active, well keeps pharmaceutically active.
The condition that is beneficial to the preparation porous microsphere among the present invention is: use dissolubility in water is lower than 2% organic solvent, and oil phase compares less than 1: 5 with water, and the hydrophilic block proportion is 4~20% in the amphipathic condensation material.If the organic solvent dissolubility in water that uses is higher than 2%, oil-water ratio was greater than 1: 5, and the hydrophilic block proportion is lower than 4% in the amphipathic condensation material, is unfavorable for preparing porous microsphere.If oil-water ratio was less than 1: 20, the hydrophilic block proportion is higher than 20% in the amphipathic condensation material, is unfavorable for preparing the microsphere of regular spherical.(the linear copolymer that forms by hydrophobic segment and hydrophilic segment alternating polymerization because the amphipathic nature polyalcohol of two blocks, this polymer possesses hydrophilic and hydrophobicity simultaneously), can well solve the non-specific adsorption between protein medicaments and the microsphere film material, guarantee the release fully of medicine; In addition, be the microsphere that micro-sphere material can also be stablized preparation aperture homogeneous with the amphiphilic polymers, thereby can obtain higher carrying drug ratio.Because the hydrophilic parts itself in the amphipathic nature material has the character that is similar to perforating agent, does not need additionally to add perforating agent in preparation process, has reduced production cost, has solved the difficulty of residual mensuration, is beneficial to the raising biological safety.Adopt quick film emulsion process can realize preparing uniform particle diameter, the porous microsphere of controlled amount because size and drug release are closely connected, thereby can reach the purpose in sustained release cycle by regulating the microspherulite diameter size.
Preparation method disclosed by the invention compared with prior art has the following advantages:
The inventive method preparation efficiency is very high, and the flow velocity size when emulsion is crossed film is up to 10mls -1, thereby preparation process most moment finish.
The invention provides a kind of porous medicine carrying microballoons, it is characterized in that described diameter of micro ball breadth coefficient is in 20%, the medicine carrying drug ratio is up to 50%, the active conservation rate of protein and peptide drugs can abrupt release or lasting 1 thoughtful 12 weeks of release more than 90% in the dispose procedure.
The invention provides a kind of method of porous medicine carrying microballoons of quick preparation size homogeneous, and can be by microporous membrane pore size and the operating pressure size of controlling product of control in the preparation process.
The present invention has overcome the problem that prior art can't prepare the porous medicine carrying microballoons of uniform particle diameter, has guaranteed the repeatability of experiment, is beneficial to the stability and the industrial amplification production of curative effect of medication.
The present invention need additionally not add perforating agent at oil phase, can reach the effect of preparation porous microsphere, has removed the later stage from and has surveyed the residual difficulty of bringing, and is beneficial to simultaneously to reduce cost.
The present invention has overcome the problem that traditional slow release porous microsphere can not discharge fully in the later stage, and in drug loading, can both effectively keep pharmaceutically active in release and the storage process.
The inventive method is simple to operate, mild condition and be easy to industrial amplification production.
Description of drawings
Fig. 1 is the preparation flow sketch map of medicine carrying microballoons of the present invention;
Fig. 2 is the Electronic Speculum figure of the microsphere of embodiment 1 preparation;
Fig. 3 is the particle size distribution figure of the microsphere of embodiment 1 preparation;
Fig. 4 is the Electronic Speculum figure of the microsphere of embodiment 2 preparations;
Fig. 5 is the Electronic Speculum figure of the microsphere of embodiment 3 preparations;
Fig. 6 is the Electronic Speculum figure of the microsphere of embodiment 4 preparations;
Fig. 7 is the Electronic Speculum figure of the microsphere of embodiment 5 preparations.
The specific embodiment
The invention will be further described below in conjunction with embodiment, but the present invention is not limited among this embodiment.
Embodiment 1
With the aperture is that the hydrophilic porous film of 2.8 μ m places water to soak into, and makes pore membrane fully moistening.With the molecular weight of 0.4g is that 10,000 polylactic acid-polyglycol copolymer (PELA) (the shared ratio of hydrophilic block is 4%) is dissolved in the 8ml dichloromethane, as oil phase, this oil phase is joined in Polyethylene Glycol (PVA) aqueous solution of the 1%wt of 80ml, the ratio of oil phase and water is 1: 10, magnetic agitation 300rpm stirs the pre-breast of 1min preparation, again this pre-emulsion was pressed down microporous membrane device (as Fig. 1) at the operating pressure of 400kPa, obtain emulsion, emulsion is spent the film time less than 10s, again emulsion is at room temperature stirred 24h to remove organic solvent dichloromethane, promptly obtain medicine carrying microballoons through centrifuge washing again.The microsphere vacuum drying 48h of gained is obtained the finished product microsphere.Dried microsphere is dispersed in the water again, utilizes field emission scanning electron microscope (JEOL SEM Company, Japan) surface topography (as Fig. 2) of observation microsphere.(Malvern Company USA) measures (as Fig. 3), and the mean diameter of microsphere is 627nm after measured, and particle size distribution coefficient CV value is 12.53% with laser particle analyzer for the volume average particle size of microsphere and distribution thereof.The 0.2g microsphere is placed little centrifuge tube, add 5mL glucagon-like-peptide-1 (GLP-1) solution, adsorb 24h at a certain temperature, GLP-1 solution centrifugalize under 5000rpm of will not adsorb then, measure the not GLP-1 quality of absorption, quantitatively to obtain microsphere be 37.8% for the carrying drug ratio of GPL-1 by calculating.Accurate weighing 30mg lyophilizing microsphere, PBS buffer (8g NaCl, 0.2g KCl, the 0.24g KH of adding 10ml pH7.4 2PO 4, 1.81gNa 2HPO 4H 2O, 0.5g NaN 3, 0.1g Tween20 and 1000ml distilled water).Sample cell places 37 ℃ of constant temperature water bath agitators jolting (120rpm).The 1.0ml supernatant is taken out in centrifugalize regularly, mends the fresh PBS buffer of 1.0ml simultaneously.Protein content is then fixed with BCA reagent and micro-BCA test kit in the supernatant.After measured, the lasting GLP-1 of release of microsphere accumulates and reaches 97.2% in 6 weeks, and the active conservation rate of the GLP-1 that discharges is 96.5%.
Embodiment 2
With the aperture is that the hydrophilic film of 7.2 μ m places water to soak into, and makes pore membrane fully moistening.With the molecular weight of 0.7g is that 50,000 polylactic acid-polyglycolic acid and ethylene glycol copolymer (the shared ratio of hydrophilic block is 10%) are dissolved in the 10ml chloroform, as oil phase, this oil phase is joined in the PVA aqueous solution of 1.2%wt of 50ml, the ratio of oil phase and water is 1: 5, magnetic agitation 300rpm stirs the pre-breast of 1min preparation, again this pre-emulsion was pressed down the microporous membrane device at the operating pressure of 200kPa, obtain emulsion, emulsion is spent the film time less than 10s, again emulsion is at room temperature stirred 24h to remove the organic solvent chloroform, promptly obtain medicine carrying microballoons through centrifuge washing again.The microsphere vacuum drying 48h of gained is obtained the finished product microsphere.Dried microsphere is dispersed in the water again, utilizes field emission scanning electron microscope (JEOL SEM Company, Japan) surface topography (as Fig. 4) of observation microsphere.(Malvern Company USA) measures, and after measured, the mean diameter of microsphere is 4.12 μ m, and particle size distribution coefficient CV value is 12.67% with laser particle analyzer for the volume average particle size of microsphere and distribution thereof.The 0.2g microsphere is placed little centrifuge tube, add the 5mL insulin solutions, adsorb 46h at a certain temperature, the insulin solutions that will not adsorb centrifugalize under 5000rpm then, measure the not insulin quality of absorption, quantitatively to obtain microsphere be 36.9% for the carrying drug ratio of insulin by calculating.Accurate weighing 30mg lyophilizing microsphere, PBS buffer (8g NaCl, 0.2gKCl, the 0.24g KH of adding 10ml pH7.4 2PO 4, 1.81g Na 2HPO 4H 2O, 0.5g NaN 3, 0.1g Tween20 and 1000ml distilled water).Sample cell places 37 ℃ of constant temperature water bath agitators jolting (120rpm).The 1.0ml supernatant is taken out in centrifugalize regularly, mends the fresh PBS buffer of 1.0ml simultaneously.Protein content is then fixed with BCA reagent and micro-BCA test kit in the supernatant.After measured, the lasting uelralante accumulation of microsphere reaches 95.8% in 5 weeks, and the insulin active conservation rate that discharges is 94.7%.
Embodiment 3
With the aperture is that the hydrophilic film of 9 μ m places water to soak into, and makes pore membrane fully moistening.With the molecular weight of 0.8g is that 20,000 polylactic acid-polyglycol copolymer (the shared ratio of hydrophilic block is 20%) is dissolved in the 15ml Carbon bisulfide, as oil phase, this oil phase is joined in the PVA aqueous solution of 1.4%wt of 300ml, the ratio of oil phase and water is 1: 20, magnetic agitation 300rpm stirs the pre-breast of 1min preparation, again this pre-emulsion was pressed down the microporous membrane device at the operating pressure of 150kPa, obtain emulsion, emulsion is spent the film time less than 10s, again emulsion is at room temperature stirred 24h to remove the organic solvent chloroform, promptly obtain medicine carrying microballoons through centrifuge washing again.The microsphere vacuum drying 48h of gained is obtained the finished product microsphere.Dried microsphere is dispersed in the water again, utilizes field emission scanning electron microscope (JEOL SEM Company, Japan) surface topography (as Fig. 5) of observation microsphere.(Malvern Company USA) measures, and after measured, the mean diameter of microsphere is 4.17 μ m, and particle size distribution coefficient CV value is 13.74% with laser particle analyzer for the volume average particle size of microsphere and distribution thereof.The 0.2g microsphere is placed little centrifuge tube, add 5mL recombinant human growth hormone solution, adsorb 36h at a certain temperature, recombinant human somatropin's solution centrifugalize under 5000rpm of will not adsorb then, measure not recombinant human somatropin's quality of absorption, quantitatively to obtain microsphere be 22.8% for recombinant human somatropin's carrying drug ratio by calculating.Accurate weighing 30mg lyophilizing microsphere, PBS buffer (8g NaCl, 0.2g KCl, the 0.24g KH of adding 10ml pH7.4 2PO 4, 1.81g Na 2HPO 4H 2O, 0.5g NaN 3, 0.1g Tween20 and 1000ml distilled water).Sample cell places 37 ℃ of constant temperature water bath agitators jolting (120rpm).The 1.0ml supernatant is taken out in centrifugalize regularly, mends the fresh PBS buffer of 1.0ml simultaneously.Protein content is then fixed with BCA reagent and micro-BCA test kit in the supernatant.After measured, the lasting growth hormone releasing accumulation of microsphere reaches 94.8% in 7 weeks, and the active conservation rate of the growth hormone that discharges is 95.4%.
Embodiment 4
With the aperture is that the hydrophilic film of 18 μ m places water to soak into, and makes pore membrane fully moistening.With the molecular weight of 1g is that 30,000 polycaprolactone-polyethylene glycol copolymer (the shared ratio of hydrophilic block is 15%) is dissolved in the 20ml dimethylbenzene, as oil phase, this oil phase is joined in the PVA aqueous solution of 1.5%wt of 160ml, the ratio of oil phase and water is 1: 8, magnetic agitation 300rpm stirs the pre-breast of 1min preparation, again this pre-emulsion was pressed down the microporous membrane device at the operating pressure of 100kPa, obtain emulsion, emulsion is spent the film time less than 10s, again emulsion is at room temperature stirred 24h to remove the organic solvent chloroform, promptly obtain medicine carrying microballoons through centrifuge washing again.The microsphere vacuum drying 48h of gained is obtained the finished product microsphere.Dried microsphere is dispersed in the water again, utilizes field emission scanning electron microscope (JEOL SEM Company, Japan) surface topography (as Fig. 6) of observation microsphere.(Malvern Company USA) measures, and after measured, the mean diameter of microsphere is 7.62 μ m, and particle size distribution coefficient CV value is 14.65% with laser particle analyzer for the volume average particle size of microsphere and distribution thereof.The 0.2g microsphere is placed little centrifuge tube, add 5mL leuprorelin solution, adsorb 24h at a certain temperature, leuprorelin solution centrifugalize under 5000rpm of will not adsorb then, measure the not leuprorelin quality of absorption, quantitatively to obtain microsphere be 47.8% for the carrying drug ratio of leuprorelin by calculating.Accurate weighing 30mg lyophilizing microsphere, PBS buffer (8g NaCl, 0.2g KCl, the 0.24gKH of adding 10ml pH7.4 2PO 4, 1.81g Na 2HPO 4H 2O, 0.5g NaN 3, 0.1g Tween20 and 1000ml distilled water).Sample cell places 37 ℃ of constant temperature water bath agitators jolting (120rpm).The 1.0ml supernatant is taken out in centrifugalize regularly, mends the fresh PBS buffer of 1.0ml simultaneously.Leuprorelin content is then fixed with liquid phase in the supernatant.After measured, the accumulation of the lasting release of microsphere leuprorelin reaches 98.2% in 8 weeks, and the active conservation rate of the leuprorelin that discharges is 97.9%.
Embodiment 5
With the aperture is that the hydrophilic film of 50.2 μ m places water to soak into, and makes pore membrane fully moistening.With the molecular weight of 1.2g is that 40,000 polylactic acid-polyglycol copolymer (the shared ratio of hydrophilic block is 6%) is dissolved in the composite solvent (volume is 1: 1) of 30ml dichloromethane and chloroform as oil phase, this oil phase is joined in the PVA aqueous solution of 2wt% of 300ml, the ratio of oil phase and water is 1: 10, magnetic agitation 300rpm stirs the pre-breast of 1min preparation, again this pre-emulsion was pressed down the microporous membrane device at the operating pressure of 70kPa, obtain emulsion, emulsion is spent the film time less than 10s, again emulsion is at room temperature stirred 24h to remove organic solvent dichloromethane, promptly obtain medicine carrying microballoons through centrifuge washing again.The microsphere vacuum drying 48h of gained is obtained the finished product microsphere.Dried microsphere is dispersed in the water again, utilizes field emission scanning electron microscope (JEOL SEM Company, Japan) surface topography (as Fig. 7) of observation microsphere.(Malvern Company USA) measures, and after measured, the mean diameter of microsphere is 20.72 μ m, and particle size distribution coefficient CV value is 14.16% with laser particle analyzer for the volume average particle size of microsphere and distribution thereof.The 0.2g microsphere is placed little centrifuge tube, add 5mL Hepatitis B virus vaccine solution, ultrasonic at a certain temperature absorption 20h, the metakentrin that will not adsorb (LHRH) solution centrifugalize under 5000rpm then, measure the not LHRH quality of absorption, quantitatively to obtain microsphere be 39.2% for the carrying drug ratio of LHRH by calculating.Accurate weighing 30mg lyophilizing microsphere, PBS buffer (8g NaCl, 0.2g KCl, the 0.24g KH of adding 10ml pH7.4 2PO 4, 1.81g Na 2HPO 4H 2O, 0.5g NaN 3, 0.1g Tween20 and 1000ml distilled water).Sample cell places 37 ℃ of constant temperature water bath agitators jolting (120rpm).The 1.0ml supernatant is taken out in centrifugalize regularly, mends the fresh PBS buffer of 1.0ml simultaneously.LHRH is then fixed with BCA reagent and micro-BCA test kit in the supernatant.After measured, the lasting LHRH of release of microsphere accumulates and reaches 99.0% in 4 weeks, and the active conservation rate of the LHRH that discharges is 96.3%.

Claims (10)

1. a porous microsphere that is used for pharmaceutical carrier is characterized in that, the preparation method of described microsphere may further comprise the steps:
1) degradable two block amphipathic nature polyalcohol materials is dissolved in the organic solvent, forms oil phase O;
2) oil phase O is joined the aqueous phase W that contains stabilizing agent, form the pre-breast of O/W;
3) with step 2) the pre-breast of the O/W of gained is by microporous membrane, obtains the O/W emulsion;
4) organic solvent in the resulting emulsion of step 3) is removed, solidified,, obtain the porous medicine carrying microballoons again through centrifuge washing and lyophilization;
In the described step 1) organic solvent contain at least a kind of in water dissolubility be lower than 2% solvent;
Described step 2) volume ratio 1: 5~20 of oil phase O and water W in.
2. the porous microsphere that is used for pharmaceutical carrier according to claim 1 is characterized in that,
In the described step 1), described organic solvent comprises one or more in dichloromethane, chloroform, Carbon bisulfide and the dimethylbenzene;
Described step 1) two block amphipathic nature polyalcohol materials comprise the amphipathic condensation material of one or more and Polyethylene Glycol copolymerization gained in polylactic acid, polylactic acid-polyglycolic acid copolymer, polycaprolactone, poe, poly-anhydride, the polyphosphazene, its molecular weight is 10,000~100,000, and the hydrophilic block proportion is 4~20% in this amphipathic condensation material;
Described step 2) stabilizing agent of aqueous phase comprises one or more in polyvinyl alcohol, polyglyceryl fatty acid ester, Tween-81, polyoxyethylene sorbitol acid anhydride laurate and the dodecyl sodium sulfate, and stabilizer concentration is 0.1wt%~10wt%.
3. the porous microsphere that is used for pharmaceutical carrier according to claim 2, it is characterized in that, described organic solvent comprises one or both in dichloromethane and the chloroform, and described two block amphipathic nature polyalcohol materials comprise the amphipathic condensation material of polylactic acid, polylactic acid-polyglycolic acid copolymer or polycaprolactone and Polyethylene Glycol copolymerization gained.
4. the porous microsphere that is used for pharmaceutical carrier according to claim 1 is characterized in that, the aperture of microporous membrane is 0.5~200 μ m in the described step 3), and the pressure by microporous membrane is 1~2000kPa.
5. the porous microsphere that is used for pharmaceutical carrier according to claim 1 is characterized in that, described medicine is to be selected from a kind of in polypeptide, protide, polysaccharide, nucleic acid and the vaccine.
6. a preparation method that is used for the porous microsphere of pharmaceutical carrier is characterized in that, said method comprising the steps of:
1) degradable two block amphipathic nature polyalcohol materials is dissolved in the organic solvent, forms oil phase O;
2) oil phase O is joined the aqueous phase W that contains stabilizing agent, form the pre-breast of O/W;
3) with step 2) the pre-breast of the O/W of gained is by microporous membrane, obtains the O/W emulsion;
4) organic solvent in the resulting emulsion of step 3) is removed, solidified,, obtain the porous medicine carrying microballoons again through centrifuge washing and lyophilization;
In the described step 1) organic solvent contain at least a kind of in water dissolubility be lower than 2% solvent;
Described step 2) volume ratio 1: 5~20 of oil phase O and water W in.
7. the preparation method that is used for the porous microsphere of pharmaceutical carrier according to claim 6 is characterized in that,
In the described step 1), described organic solvent comprises one or more in dichloromethane, chloroform, Carbon bisulfide and the dimethylbenzene;
Described step 1) two block amphipathic nature polyalcohol materials comprise the amphipathic condensation material of one or more and Polyethylene Glycol copolymerization gained in polylactic acid, polylactic acid-polyglycolic acid copolymer, polycaprolactone, poe, poly-anhydride, the polyphosphazene, its molecular weight is 10,000~100,000, and the hydrophilic block proportion is 4~20% in this amphipathic condensation material;
Described step 2) stabilizing agent of aqueous phase comprises one or more in polyvinyl alcohol, polyglyceryl fatty acid ester, Tween-81, polyoxyethylene sorbitol acid anhydride laurate and the dodecyl sodium sulfate, and stabilizer concentration is 0.1wt%~10wt%.
8. the preparation method that is used for the porous microsphere of pharmaceutical carrier according to claim 6, it is characterized in that, described organic solvent comprises one or both in dichloromethane and the chloroform, and described two block amphipathic nature polyalcohol materials comprise the amphipathic condensation material of polylactic acid, polylactic acid-polyglycolic acid copolymer or polycaprolactone and Polyethylene Glycol copolymerization gained.
9. the preparation method that is used for the porous microsphere of pharmaceutical carrier according to claim 6 is characterized in that, the aperture of microporous membrane is 0.5~200 μ m in the described step 3), and the pressure by microporous membrane is 1~2000kPa.
10. one kind is utilized the described method that is used for the porous microsphere carrying medicament of pharmaceutical carrier of claim 1, it is characterized in that, the mass ratio by 1: 2~100 mixes medicine with porous microsphere.
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CN105434360A (en) * 2014-08-07 2016-03-30 清华大学 Hollow drug carrying microsphere used for pulmonary drug delivery and preparation method thereof
CN106421800A (en) * 2016-09-28 2017-02-22 天津医科大学口腔医院 Silk fibroin modified depression structure lactic acid-based polymer drug-carrying microsphere and method for preparing same
CN108096212A (en) * 2017-12-25 2018-06-01 河北科技大学 With the medicine microspheres preparation method that Hetastarch 200/0.5 is carrier
CN108096212B (en) * 2017-12-25 2020-06-09 河北科技大学 Preparation method of drug microspheres with hydroxyethyl starch 200/0.5 as carrier
CN108939136A (en) * 2018-08-20 2018-12-07 重庆医科大学附属永川医院 A kind of dressing and preparation method thereof for nose filling hemostasis
CN108939136B (en) * 2018-08-20 2020-12-22 重庆医科大学附属永川医院 Dressing for nasal filling hemostasis and preparation method thereof
CN109999000A (en) * 2019-05-13 2019-07-12 苏州岸谷纳米技术有限公司 A kind of preparation method of Biodegradable high molecular porous microsphere
CN111035794A (en) * 2019-12-23 2020-04-21 宁波宝亭生物科技有限公司 Preparation method of absorbable porous microsphere styptic powder
CN111035794B (en) * 2019-12-23 2023-11-14 宁波宝亭生物科技有限公司 Preparation method of absorbable porous microsphere hemostatic powder
CN111647505A (en) * 2020-06-12 2020-09-11 上海市刑事科学技术研究院 DNA (deoxyribonucleic acid) collection swab as well as preparation method and application thereof
CN111647505B (en) * 2020-06-12 2023-12-19 上海市刑事科学技术研究院 DNA acquisition swab and preparation method and application thereof
CN113880056A (en) * 2021-10-29 2022-01-04 雅邦绿色过程与新材料研究院南京有限公司 Method for preparing hydrophilic sulfur microspheres by using chemical sulfur

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