The purpose of the present study was to investigate the relationship of the classification of traditional Chinese medicine(TCM) materials with the suitable binder concentration and dosage in the preparation of personalized water-paste pills and establish a model for predicting the binder concentration and dosage. Five representative TCM materials were selected, followed by mixture uniform design. The water-paste pills were prepared by extrusion and spheronization with hypromellose E5(HPMC E5) as the binder. The quality of intermediates and final products was evaluated, and the resulting data were subjected to multivariate statistical analysis. The prediction models for binder concentration and dosage were established as follows: binder concentration: Y_1=0.378 6 + 0.570 1X_A + 2.271 2X_B-0.894 5X_C-0.458 2X_D-1.145 4X_E(when Y_1 < 0, 10% HPMC E5 was required; when Y_1 > 0, 20% HPMC E5 was required), with the accuracy reaching up to 100%; binder dosage: Y_2=32.38 + 0.25X_A + 1.85X_B-0.013X_B~2-0.002 5X_C~2(R~2=0.932 6, P < 0.001). The results showed that the binder concentration and dosage were correlated positively with the proportion of fiber material but negatively with the proportions of sugar material and brittle material. Then the validation experiments were conducted with the prediction models and all the prescriptions could be successfully prepared at one time. These demonstrated that following the classification of TCM materials and the calculation of their proportions in the prescription, the established mathematical model could be adopted for predicting the binder concentration and dosage required in the preparation of personalized water-paste pills, which contributed to reducing the pre-formulation research and guiding the actual production of personalized water-paste pills.
Drugs, Chinese Herbal ; Excipients ; Hypromellose Derivatives ; Medicine, Chinese Traditional ; Water

OBJECTIVETo investigate the release model of insoluble drug carbamazepine (CBM) based on HPMC matrix tablets.

METHODSCBM release profile from matrices and HPMC erosion rate were determined.

RESULTThe mathematical model by matrix erosion rate and drug release from HPMC K15M were established for the fractional HPMC and CBM released as M(P(t))/M(P(infinity))=-[0.8095ln((t))+1.2775]Meq((-0.0622t-0.305)) and M(d(t))/M(d(infinity))=-[0.1891t-0.1294]Meq(-0.9326). In comparison with the data of HPMC K4M matrix erosion and CBM release from HPMC K4M matrices, theoretical value agreed well with experimental data.

CONCLUSIONThe two mathematical models can be satisfactorily applied to insoluble drug release, which is governed by matrix erosion.

Carbamazepine ; administration & dosage ; chemistry ; Delayed-Action Preparations ; Hypromellose Derivatives ; Methylcellulose ; administration & dosage ; analogs & derivatives ; Models, Theoretical ; Solubility ; Tablets

We prepared the isosorbide-5-mononitrate pulsatile controlled-release pellets (PCRP) and studied the influencing factors in vitro. The isosorbide-5-mononitrate (5-ISMN) pellets prepared by extrusion-spheronization technology were coated with swelling material as the inner coating swelling layer, and with ethylcellulose aqueous dispersion as the outer coating controlled layer. The influences of the coating materials of the swelling layer, the coating levels of the swelling layer and controlled layer,and the pH values of the media on the release of 5-ISMN from PCRP were investigated. The drug release from the pellets was pulsatile. The ISMN-5-PCRP, with a lag time of 5 h and more than 80% released within the following 1.5 h,were prepared by using the low-substituted hydroxypropyl cellulose as the inner swelling layer with 15% (weight) in coating thickness, and the ethylcellulose aqueous dispersion as the outer controlling layer with 13% (weight) in coating thickness.
Capsules ; Cellulose ; analogs & derivatives ; chemistry ; Delayed-Action Preparations ; chemical synthesis ; Drug Carriers ; chemistry ; Hypromellose Derivatives ; Isosorbide Dinitrate ; administration & dosage ; analogs & derivatives ; chemistry ; Methylcellulose ; analogs & derivatives ; chemistry

The hydroxypropyl methylcellulose (HPMC) matrix tablet containing metoprolol succinate (MS) as a model drug was obtained by wet method compression tablet. The effects of the amount and viscosity of HPMC, the preparation method, compressing pressure, the amount of ethycellulose (EC), the pH of dissolution medium and the speed of basket rotation on the drug release from the matrix tablets were evaluated. The results showed that the release rate of metoprolol succinate from HPMC matrix tablets followed Higuchi equation. The release mechanism was in line with the synthetical effect of diffusion and corrosion. Drug release was influenced by the amount and viscosity of HPMC, the amount of EC in matrices, the preparation method and compressing pressure, etc. Drug release was not influenced by the pH of dissolution medium used, and not by the speed of basket rotation, either.
Delayed-Action Preparations ; Drug Compounding ; Hypromellose Derivatives ; Methylcellulose ; analogs & derivatives ; chemistry ; Metoprolol ; administration & dosage ; analogs & derivatives ; pharmacokinetics ; Pharmaceutic Aids ; chemistry ; Pharmaceutical Preparations ; chemistry ; Tablets ; Viscosity

AIMTo prepare ondansetron hydrochloride osmotic pump tablets (OND-OPT) and investigate their in vitro drug release behavior.

METHODSOND-OPT were prepared with a single punch press and pan coating technique. Osmotic active agents and plasticizer of coating film were chosen by drug release tests. The effects of the number, position and direction of drug release orifice on release behavior were investigated. The relation between drug release duration and thickness of coating film, PEG content of coating film and size of drug release orifice was established by uniform design experiment. The surface morphological change of coating film before and after drug release test was observed by scanning electron microscopy. The osmotic pumping release mechanism of OND-OPT was confirmed by drug release test with high osmotic pressure medium.

RESULTSLactose-mannitol (1:2) was chosen as osmotic active agents and PEG400 as plasticizer of coating film. The direction of drug release orifice had great effect on the drug release of OND-OPT without HPMC, and had no effect on the drug release of OND-OPT with HPMC. The OND-OPT with one drug release orifice at the centre of the coating film on one surface of tablet released their drug with little fluctuation. The drug release duration of OND-OPT correlated with thickness of coating film and PEG content of coating film, and didn't correlate significantly with the size of drug release orifice. OND-OPT released their drug with osmotic pumping mechanism predominantly.

CONCLUSIONOND-OPT are able to realize ideal controlled drug release.

Antiemetics ; chemistry ; Delayed-Action Preparations ; Drug Carriers ; Drug Delivery Systems ; Hypromellose Derivatives ; Lactose ; Mannitol ; Methylcellulose ; analogs & derivatives ; Ondansetron ; chemistry ; Osmotic Pressure ; Polyethylene Glycols ; Solubility ; Tablets ; beta-Cyclodextrins

Insoluble breviscapin was chosen as the model drug. Bi-layer osmotic pump technology and gel matrix technology were used to prepare the breviscapin sustained and controlled release preparations. Dissimilarity factors (f1) and similarity factors (f2) were applied as similar judgment index to compare the effects of in vitro conditions on the release behavior of different types of breviscapin sustained and controlled release preparations. The tolerance of in vitro release conditions of bi-layer osmotic pump technology and gel matrix technology were studied. The results showed that in vitro release conditions have a greater impact on the gel matrix sustained release formulations, while have almost no effects on the osmotic pump controlled release formulations. Therefore, osmotic pump controlled release technology is less affected by the drug release environment. And it has a very good application prospect.
Delayed-Action Preparations ; Drug Carriers ; Excipients ; Flavonoids ; administration & dosage ; Hypromellose Derivatives ; Methylcellulose ; analogs & derivatives ; chemistry ; Osmolar Concentration ; Osmosis ; Polyethylene Glycols ; chemistry ; Rotation ; Technology, Pharmaceutical ; methods ; Temperature

To prepare verapamil hydrochloride (VH) core-in-cup tablets with tri-layered tablet and four-layered tablet as core tablets, separately, which can provide biphasic release with double-pulsatile and multi-phasic release, core tablets were prepared by direct compression method, and core-in-cup tablets by dry-compression coated technology. The parameter, time-lag (T(lag)), was used to evaluate the influence of factors, such as the weight of the top cover layer, the amount of hydroxypropylmethylcellulose (HPMC), and the compression load on VH release. With the increase of the weight and HPMC amount of the top cover layer, the first lag time T(lag1) was prolonged. The second lag time T(lag2) of core-in-cup tablet with four-layered tablet as core tablet increased with the increasing amount of HPMC K100M. With the increase of compression load among the range (6 - 10 kg x cm(-2)), the two lag times were prolonged. Core-in-cup tablets with double-pulsatile and multi-phasic release released VH after the first lag time (4 -5 h), then kept sustained release for 12 h or 13 h, finally released rapidly. The drug in the core-in-cup tablet only released from the top cover layer. T(lag) is determined by the erosion rate of the inhibitor layers (the top cover layer and the sustained-release layer of the multi-layer core tablet).
Delayed-Action Preparations ; Drug Carriers ; Drug Compounding ; methods ; Drug Delivery Systems ; Excipients ; chemistry ; Hypromellose Derivatives ; Methylcellulose ; analogs & derivatives ; chemistry ; Tablets ; Verapamil ; administration & dosage

Poloxamer F127, poloxamer F68 and hydroxypropyl methylcellulose K4M were used to prepare the thermosensitive in situ gel of boanmycin hydrochloride for injection. Its gelation temperature, rheological behavior, texture characteristics, scanning electron microscopy, in vitro and in vivo drug release were evaluated. These results showed that the formulation was a fluid solution at room temperature, which could become semisolid at the temperature of 37 degrees C, and the thermally induced sol-gel transition allowed to be injectable and in situ setting. The formulation was constructed into a tridimensional network at gelation temperature. The drug release was controlled by the diffusion of the drug and the erosion of the gelmatrix. The pharmacokinetics indicated that the drug could be released slowly for up to 48 hours after subcutaneous administration in rats.
Animals ; Antibiotics, Antineoplastic ; administration & dosage ; pharmacokinetics ; Bleomycin ; administration & dosage ; analogs & derivatives ; pharmacokinetics ; Diffusion ; Drug Delivery Systems ; Gels ; Hypromellose Derivatives ; Injections, Subcutaneous ; Male ; Methylcellulose ; analogs & derivatives ; chemistry ; Microscopy, Electron, Scanning ; Poloxamer ; chemistry ; Rats ; Rats, Sprague-Dawley ; Rheology ; Temperature ; Viscosity

This paper report the development of a new dosage form - self-microemulsifying mouth dissolving films, which can improve the oral bioavailability of water insoluble drugs and have good compliance. A three factor, three-level Box-Behnken design was used for optimizing formulation, investigated the effect of amounts of microcrystalline cellulose, low-substituted hydroxypropyl cellulose and hypromellose on the weight, disintegration time, cumulative release of indomethacin after 2 min, microemulsified particle size and stretchability. Optimized self-microemulsifying mouth dissolving films could fast disintegrate in (17.09 +/- 0.72) s; obtain microemulsified particle size at (28.81 +/- 3.26) nm; and release in vitro at 2 min to (66.18 +/- 1.94)%. Self-microemulsifying mouth dissolving films with broad application prospects have good compliance, strong tensile and can be released rapidly in the mouth through fast self-microemulsifying.
Administration, Oral ; Biological Availability ; Cellulose ; analogs & derivatives ; chemistry ; Drug Compounding ; methods ; Drug Delivery Systems ; methods ; Emulsifying Agents ; chemistry ; Emulsions ; Hypromellose Derivatives ; Indomethacin ; administration & dosage ; Methylcellulose ; analogs & derivatives ; chemistry ; Particle Size ; Solubility ; Surface Properties ; Tensile Strength

This paper is to study the inhibitory effect of water soluble polymers--methyl cellulose (MC), hydroxypropyl methyl cellulose (HPMC), hydroxypropyl cellulose (HPC-M), poloxamer (F68) and polyvidon (PVP) on osthole (OST) crystallization and investigate the impact of polymer concentration and viscosity on crystallization behavior. Also, UV spectrophotometry method was used to determine the drug concentration at different time point to draw the OST concentration-time curve. Results show that HPMC has the most significant inhibition effect on OST crystallization, and drug concentration level is 1.61 times higher than that in control solution within 8 h followed by PVP (1.54) and MC (1.45) respectively. The kinetics of OST recrystallization can be described using first-order reaction, and the crystallization rate constants obtained by analyzing the regression equation indicate that HPMC-60SH-4000 and HPMC-60SH-10000 can greatly influence OST crystal formation. The dissolution rate of drugs precipitated from water-soluble polymer solutions is faster compared with controls in pH 1.2 HCl and pH 6.8 phosphate buffers, which demonstrated that water-soluble polymers can not only change the behavior of drug crystallization but markedly improve the dissolution rate of water insoluble drugs.
Cellulose ; analogs & derivatives ; chemistry ; Cnidium ; chemistry ; Coumarins ; chemistry ; isolation & purification ; Crystallization ; Hypromellose Derivatives ; Kinetics ; Methylcellulose ; analogs & derivatives ; chemistry ; Plants, Medicinal ; chemistry ; Poloxamer ; chemistry ; Polymers ; chemistry ; Povidone ; chemistry ; Solubility ; Viscosity