To evaluate the effects of Hydroxypropyl methylcellulose acetate succinate(HPMCAS MF) on absorption of silybin(SLB) from supersaturable self-nanoemulsifying drug delivery system which was pre-prepared at the early stage experiment. The cell toxicity of self-emulsifying preparation was evaluated by the MTT method, and the in vitro membrane permeability and absorption promoting effect of the self-emulsifying preparation were evaluated by establishing a Caco-2 cell monolayer model. The in vivo and in vitro supersaturation correlation was evaluated via the blood concentration of SLB. The results of MTT showed that the concentration of the preparation below 2 mg·mL~(-1)(C_(SLB) 100 μg·mL~(-1)) was not toxic to Caco-2 cells, and the addition of polymer had no significant effect on Caco-2 cells viability. As compared with the solution group, the transport results showed that the P_(app)(AP→BL) of the self-emulsifying preparation had a very significant increase; the transport rate of silybin can be reduced by polymer in 0-30 min; however, there was no difference in supersaturated transport between supersaturated SLB self-nanoemulsion drug delivery system(SLB-SSNEDDS) and SLB self-nanoemulsion drug delivery system(SLB-SNEDDS) within 2 hours. As compared with SLB suspension, pharmacokinetic parameters showed that the blood concentration of both SLB-SNEDDS and SLB-SSNEDDS groups were significantly increased, and C_(max) was 5.25 times and 9.69 times respectively of that in SLB suspension group, with a relative bioavailability of 578.45% and 1 139.44% respectively. C_(max) and relative bioavailability of SLB-SSNEDDS were 1.85 times and 197% of those of SLB-SNEDDS, respectively. Therefore, on the one hand, SSNEDDS can increase the solubility of SLB in gastrointestinal tract by maintaining stability of SLB supersaturation state; on the other hand, the osmotic transport process of SLB was regulated through the composition of its preparations, and both of them could jointly promote the transport and absorption of SLB to improve the oral bioavailability of SLB.
Administration, Oral ; Biological Availability ; Caco-2 Cells ; Drug Delivery Systems ; Emulsions ; Humans ; Methylcellulose/analogs & derivatives* ; Nanoparticles ; Particle Size ; Silybin ; Solubility

To enhance in vitro dissolution of Cur by preparing Cur solid dispersions. The ability of HPMCAS-HF,HPMCAS-MF,HPMCAS-LF and PVPK30 to maintain supersaturated solution was investigated by supersaturation test. Amorphous solid dispersions were prepared by the solvent-evaporation method. The prepared samples were characterized using infrared spectroscopy( IR) and differential scanning calorimetry( DSC),and in vitro dissolution was investigated. DSC and IR results showed that in 1 ∶3 and 1 ∶9 solid dispersions,Cur was amorphously dispersed in the carrier,and the interaction existed between drug and carrier. The supersaturation test showed that the order of the ability of polymer to inhibit crystallization of Cur was MF>HF>LF>K30. The dissolution results showed that Cur-K30 amorphous solid dispersion had the highest drug release rate; Cur-K30 and Cur-LF amorphous solid dispersions had a quicker but not stable dissolution rate,and the drug concentration decrease after 4 h; Cur-MF and Cur-HF solid dispersions had a low dissolution,which however increased steadily,attributing to the strong ability of the polymers to inhibit the crystallization of Cur. HPMCAS could inhibit the degradation of Cur better than K30,especially MF and HF. The amorphous solid dispersions of cur significantly enhanced the dissolution of Cur and improved the chemical stability of Cur. This study can provide a basis for the rational selection of the polymer used for Cur solid dispersion.
Chemistry, Pharmaceutical ; Curcumin ; chemistry ; Drug Stability ; Methylcellulose ; analogs & derivatives ; chemistry ; Polymers ; Solubility

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

Pure and drug hydrophilic matrix tablets were prepared by direct compression method with theophylline as a model drug. The characteristics of four hydrophilic matrix polymers, hydroxypropylmethylcellulose (HPMC), polyethylene oxide (PEO), sodium alginate (NaAlg) and xanthan gum (XG), were compared by investigating the water absorption, swelling, erosion and gel layer strength. The sequence of water absorption rate was XG > NaAlg (H) > PEO > NaAlg (L) > HPMC; The sequence of swelling index was XG > PEO > HPMC > NaAlg; The sequence of erosion rate was NaAlg (L) > NaAlg (H) > PEO80 > PEO200 > PEO300 > XG approximately PEO400 approximately K4M > K15M > PEO600 approximately K100M; The sequence of the gel layer strength was PEO > HPMC > XG > NaAlg. For the PEO and HPMC matrix tablets, with the polymer molecular weight increased, the drug release mechanism was gradually transferred from mainly depending on the erosion to the diffusion; for SAL matrix tablets, the drug release mainly depends on erosion mechanism; and for XG matrix tablets, the drug release mainly depends on non-Fick diffusion mechanism. Comparison of the performance difference between the polymer materials will contribute to rational design and prediction of drug release behaviors from matrix tables and ultimately to achieve clinical needs.
Alginates ; chemistry ; Bronchodilator Agents ; administration & dosage ; Delayed-Action Preparations ; Drug Carriers ; Drug Compounding ; Drug Delivery Systems ; Excipients ; chemistry ; Glucuronic Acid ; chemistry ; Hexuronic Acids ; chemistry ; Hypromellose Derivatives ; Methylcellulose ; analogs & derivatives ; chemistry ; Molecular Weight ; Polyethylene Glycols ; chemistry ; Polymers ; chemistry ; Polysaccharides, Bacterial ; chemistry ; Tablets ; Theophylline ; administration & dosage ; Water

OBJECTIVEUsing Apocynum venetum as a model drug to prepare pulsed-release tablets based on diffusion, swelling, osmotic pressure mechanism and to evaluate the release characteristics.

METHODThe pulsatile release tablets were prepared by film coating methods using HPMC E5 and Eudragit The effect of formulation on pulsatile release of A. venetum was investigated.

RESULTThe pulsed-release tablet was prepared by a swelling layer coating which contains HPMC E5 and a controlled-release membrane containning Eudragit. The delayed release time of the tablets was (5.0 +/- 0.5) h.

CONCLUSIONThe pulsatile release characteristics of A. venetum pulsatile release tablets were confirmed in vitro.

Apocynum ; chemistry ; Delayed-Action Preparations ; chemistry ; Diffusion ; Drug Compounding ; methods ; Drugs, Chinese Herbal ; chemistry ; In Vitro Techniques ; Lactose ; analogs & derivatives ; analysis ; Methylcellulose ; analogs & derivatives ; analysis ; Osmotic Pressure ; Plant Leaves ; chemistry ; Polymethacrylic Acids ; analysis ; Solubility ; Tablets ; chemistry ; Time Factors

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

To explore the influence of matrix materials in complicate ingredients on traditional Chinese medicine and investigate the excipients selection model based on balanced release characteristics of multicomponents, the influence of HPMC (K4M, K15M, K100M) and Carbomer (934P, 971P, 974P) was illustrated by testing in vitro release of ginsenoside-Rg1, ginsenoside-Rb1 and notoginsenoside-R1 in Panax notoginseng saponins (model drug, PNS). According to in vitro release results of PNS matrix tablets in water and artificial intestinal juice, the release curves were analyzed with Peppas equation and simulating factor (f). Significant differences in k value and n value among ginsenoside-Rg1, ginsenoside-Rb1 and notoginsenoside-R1 existed in various formulations. The release behaviors from various excipients could be described with Non-Fickian transport or super Case II transport pattern. The f2 values for ginsenoside-Rg1, ginsenoside-Rb1 and notoginsenoside-R1 in 971P matrix tablet containing 30% Carbomer 971P were 74.91, 53.45, 57.89 in water and 79.35, 55.51, 51.89 in artificial intestinal juice, respectively. The release profiles fit for the regulation of FDA. The result revealed that the balanced release rates of Rg1, Rb1 and R1 in 971P matrix tablet were obtained.
Acrylates ; chemistry ; Acrylic Resins ; chemistry ; Delayed-Action Preparations ; Excipients ; chemistry ; Ginsenosides ; isolation & purification ; pharmacokinetics ; Lactose ; analogs & derivatives ; chemistry ; Methylcellulose ; analogs & derivatives ; chemistry ; Panax notoginseng ; chemistry ; Plants, Medicinal ; chemistry ; Saponins ; administration & dosage ; isolation & purification ; pharmacokinetics ; Tablets

Ranolazine hydrochloride sustained-release tablet (RH-ST) was prepared and its release behavior in vitro was studied. The pharmacokinetic characteristics and bioavailability in six Beagle dogs after oral administration of RH-ST and ranolazine hydrochloride common tablets (RH-CT) as reference were compared. Three kinds of matrix, hydroxypropylmethylcellulose (HPMC K4M), ethylcellulose (EC 100cp) and acrylic resins (Eudragit RL100) were selected as functional excipients to keep ranolazine hydrochloride (RH) release for 12 hours. Through orthogonal designs, the polymers were quantified and the optimized cumulative release profile was obtained. The single oral dose of RH-ST 500 mg and RH-CT 333.3 mg was given to six dogs using a two way crossover design. Plasma levels were determined by LC-MS and the absorption fractions were calculated according to Loo-Riegelman formula. The steady-state concentration of RH in plasma of six dogs and its pharmacokinetics behaviors after continuous oral administration of RH-ST and RH-CT at different time intervals were studied by LC-MS. The steady-state pharmacokinetic parameters were computed by software program BAPP2.0. With the increase of the amount of the matrix, the drug release was decreased. The most important factor influencing drug release is the quantity of HPMC K4M. Drug release within the period (from 0 h to 12 h) fitted well into Higuchi model. The correlation coefficient (r) between the dissolution in vitro in release media of the distilled water and the absorptin fraction in vivo was 0.9550. To compare with RH-CT, RH-ST in vivo has a steady and slow release behavior, Tmax was obviously delayed (3.00 +/- 0.50) h and the relative bioavailability was over 80 percentage. The combined use of multiple polymers can decrease the tablet weight effectively, and the drug release rate can be decreased both in vitro and in vivo.
Acetanilides ; administration & dosage ; pharmacokinetics ; Acrylic Resins ; chemistry ; Administration, Oral ; Animals ; Area Under Curve ; Biological Availability ; Cellulose ; analogs & derivatives ; chemistry ; Cross-Over Studies ; Delayed-Action Preparations ; Dogs ; Excipients ; Female ; Hypromellose Derivatives ; Male ; Methylcellulose ; analogs & derivatives ; chemistry ; Piperazines ; administration & dosage ; pharmacokinetics ; Ranolazine ; Tablets

This study involves mathematical simulation model such as in vitro-in vivo correlation (IVIVC) development for various extended release formulations of nimesulide loaded hydroxypropylmethylcellulose (HPMC) microparticles (M1, M2 and M3 containing 1, 2, and 3 g HPMC, respectively and 1 g drug in each) having variable release characteristics. In vitro dissolution data of these formulations were correlated to their relevant in vivo absorption profiles followed by predictability worth analysis of these Level A IVIVC. Nimaran was used as control formulation to validate developed formulations and their respective models. The regression coefficients of IVIVC plots for M1, M2, M3 and Nimaran were 0.834 9, 0.831 2, 0.927 2 and 0.898 1, respectively. The internal prediction error for all formulations was within limits, i.e., < 10%. A good IVIVC was found for controlled release nimesulide loaded HPMC floating M3 microparticles. In other words, this mathematical simulation model is best fit for biowaiver studies which involves study parameters as those adopted for M3 because the value of its IVIVC regression coefficient is the closest to 1 as compared to M1 and M2.
Anti-Inflammatory Agents, Non-Steroidal ; administration & dosage ; pharmacokinetics ; Cross-Over Studies ; Cyclooxygenase 2 Inhibitors ; administration & dosage ; pharmacokinetics ; Delayed-Action Preparations ; Humans ; Hypromellose Derivatives ; Methylcellulose ; analogs & derivatives ; Microspheres ; Models, Chemical ; Sulfonamides ; administration & dosage ; pharmacokinetics