Your search keyword '"Wen, Haoyang"' showing total 5 results

1. Flexibility of 3D Extruded Printing for a Novel Controlled-Release Puerarin Gastric Floating Tablet: Design of Internal Structure.

Author

Li P, Zhang S, Sun W, Cui M, Wen H, Li Q, Pan W, and Yang X

Subjects

Delayed-Action Preparations pharmacokinetics, Drug Liberation, Excipients chemistry, Humans, Isoflavones pharmacokinetics, Delayed-Action Preparations chemistry, Isoflavones administration & dosage, Printing, Three-Dimensional, Stomach, Tablets administration & dosage

Abstract

The objective of this study was to investigate the development of a novel puerarin gastric floating system with a concentric annular internal pattern by a 3D extrusion-based printing technique and to explore the flexibility of turning the release behavior through the design of the internal structure. The composition consisted of the conventional sustained-release pharmaceutical excipients without addition of foaming agent or light materials. First, the proper alcohol/water proportion was selected for the binding agent. The desired drug release behaviors and good floating properties were obtained either through modification of the formulation composition or adjustment of the internal structure. In vitro, the printed tablets were evaluated for drug release, mechanical properties, lag time, and floating duration time. The in vivo behaviors of the formulations were noted at certain time intervals through assessment of the radiographic pictures of healthy volunteers. The gastric retention time in the 3D-printed tablet was approximately 6 h in vivo. Results indicated these puerarin gastric floating 3D-printed tablets had great potential to achieve good gastric residence time and controlled release. Therefore, 3D extrusion-based printing appears to be appropriate for the production of oral administration systems, owing to its flexibility and the great floating ability and controlled-release capacity of its products.

Published

2019

2. In vitro and in vivo evaluation of controlled-release matrix tablets of highly water-soluble drug applying different mw polyethylene oxides (PEO) as retardants.

Author

Wen H, Li X, Li Y, Wang H, Wang Y, Wang T, Pan W, and Yang X

Subjects

Animals, Area Under Curve, Dogs, Drug Compounding, Drug Delivery Systems, Hardness, Hydrogen-Ion Concentration, Molecular Weight, Solubility, Tablets, Delayed-Action Preparations pharmacokinetics, Excipients chemistry, Polyethylene Glycols chemistry

Abstract

The aim of the work presented is to prepare a controlled-release hydrophilic matrix tablet (CMT) controlling release of highly water-soluble drug applying pure combination of high- and low-Mw PEO as matrix materials, to avoid the lag time of drug release, and to overcome incomplete release in later stages. The influences of types and amounts of different Mw PEOs used, drug loading, pH of release medium and agitation rate on drug release were evaluated. The study of uptake and erosion of matrix was conducted and mechanism of improving drug release was discussed. In vivo pharmacokinetics of the CMT and reference preparation self-made controlled-release osmotic pump tablets (COPT) were performed in beagle dogs. The optimized formulation containing 43% PEO WSR 303 and 32% PEO N750 showed a zero order release from 1 h to 12 h. In vivo results demonstrated that the CMT had similar AUC 0-48 h and C max with the COPT but smaller T max than the COPT and provided a more stable therapeutic concentration compared to the COPT. In conclusion, hydrophilic matrix tablet combining only different Mw PEOs as matrix materials had very good potential to be developed into a controlled-release drug delivery system for highly water-soluble drug. Besides, its manufacturing processes were succinct which would be preferable for modern medicine industry.

Published

2018

3. Design of a Time-Controlled Pulsatile Release System for Propranolol Using the Dry-Coated Method: In Vitro and In Vivo Evaluation.

Author

Chen K, Wang Y, Gai X, Wang H, Li Y, Wen H, Pan W, and Yang X

Subjects

Administration, Oral, Animals, Dogs, Drug Liberation, Excipients chemistry, Propranolol chemistry, Propranolol pharmacokinetics, Delayed-Action Preparations, Propranolol administration & dosage, Tablets, Technology, Pharmaceutical

Abstract

The objective of this study was to design a time-controlled pulsatile release (TCPR) system containing propranolol (PNH) as an active pharmaceutical ingredient. Here, the developed dosage forms were coated with hydroxypropyl-methylcellulose (HPMC) and other excipients as barrier layer using dry-coated technology. The influence of HPMC, microcrystalline cellulose (MCC), and lactose in the outer coating and the coating weight on drug release were investigated. Then, a three-factor, five-level central composite design (CCD) and response surface method were used to optimize the formula of the coating. After data processing, the optimal prescription was found to be as follows: HPMC E50(X 1 ) 86.2 mg, MCC(X 2 ) 43.8 mg, and lactose (X 3 ) 21.3 mg in the coating. Moreover, the in vitro tests showed that the optimized formulation of TCPR had a lag time of 4 h followed by a 4-h drug release. Also, determination of the extent of erosion of the TCPR tablets revealed that the lag time is related to the coating erosion speed. The in vivo test in beagle dogs and comparison of the parameters for the TCPR tablets and reference preparations showed significant differences for T max (7.83 ± 0.408 and 2 ± 0.00) and C max (185.45 ± 28.561 and 587 ± 45.27 ng/ml) but no significant differences in the AUC 0-∞ (1757.876 ± 208.832 and 1779.69 ± 229.02 ng h/ml). These results demonstrated that the TCPR tablets successfully prolonged the lag time and controlled the release of propranolol.

Published

2017

4. Preparation and investigation of controlled-release glipizide novel oral device with three-dimensional printing.

Author

Li Q, Wen H, Jia D, Guan X, Pan H, Yang Y, Yu S, Zhu Z, Xiang R, and Pan W

Subjects

Tablets, Delayed-Action Preparations, Glipizide administration & dosage, Printing, Three-Dimensional, Technology, Pharmaceutical

Abstract

The purpose of this study was to explore the feasibility of combining fused deposition modeling (FDM) 3D printing technology with hot melt extrusion (HME) to fabricate a novel controlled-release drug delivery device. Glipizide used in the treatment of diabetes was selected as model drug, and was successfully loaded into commercial polyvinyl alcohol (PVA) filaments by HME method. The drug-loaded filaments were printed through a dual-nozzle 3D printer, and finally formed a double-chamber device composed by a tablet embedded within a larger tablet (DuoTablet), each chamber contains different contents of glipizide. The drug-loaded 3D printed device was evaluated for drug release under in vitro dissolution condition, and we found the release profile fit Korsmeyer-Peppas release kinetics. With the double-chamber design, it is feasible to design either controlled drug release or delayed drug release behavior by reasonably arranging the concentration distribution of the drug in the device. The characteristics of the external layer performed main influence on the release profile of the internal compartment such as lag-time or rate of release. The results of this study suggest the potential of 3D printing to fabricate controlled-release drug delivery system containing multiple drug concentration distributions via hot melt extrusion method and specialized design configurations., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

5. Design and Evaluation of Hydrophilic Matrix System Containing Polyethylene Oxides for the Zero-Order Controlled Delivery of Water-Insoluble Drugs.

Author

Wang L, Chen K, Wen H, Ouyang D, Li X, Gao Y, Pan W, and Yang X

Subjects

Chemistry, Pharmaceutical methods, Drug Carriers chemistry, Drug Delivery Systems methods, Drug Liberation, Excipients chemistry, Hydrophobic and Hydrophilic Interactions, Kinetics, Polymers chemistry, Solubility, Tablets chemistry, Viscosity, Delayed-Action Preparations chemistry, Polyethylene Glycols chemistry, Water chemistry

Abstract

The aim of this study was to design a polyethylene oxide (PEO) binary hydrophilic matrix controlled system and investigate the most important influence(s) on the in vitro water-insoluble drug release behavior of this controlled system. Direct-compressed PEO binary matrix tablets were obtained from a variety of low viscosity hydrophilic materials as a sustained agent, using anhydrous drugs as a model drug. Water uptake rate, swelling rate, and erosion rate of matrices were investigated for the evaluation of the PEO hydrophilic matrix systems. The effect of the dose, the solubility of water-insoluble drug, and the rheology of polymers on in vitro release were also discussed. Based on the in vitro release kinetics study, three optimized PEO binary matrices were selected for further research. And, these PEO binary matrices had shown the similar release behavior that had been evaluated by the similarity factor f 2 . Further study indicated that they had identical hydration, swelling, and erosion rate. Moreover, rheology study exhibited the similar rheological equation of Herschel-Bulkley and their viscosity was also within the same magnitude. Therefore, viscosity plays the most important role to control drug release compared to other factors in PEO binary matrix system. This research provides fundamental understanding of in vitro drug release of PEO binary hydrophilic matrix tablets and helps pharmaceutical workers to develop a hydrophilic controlled system, which will effectively shorten the process of formulation development by reducing trial-and-error.

Published

2017