Development and Evaluation of PEG-gelatin-based Microparticles to Enhance the Oral Delivery of Insulin.

BACKGROUND: Diabetes mellitus is a global disease identified by hyperglycemia due to defects in insulin secretion, insulin action, or both. OBJECTIVE: The main objective of this research was to evaluate the ability of gelatinized Poly(ethylene glycol) (PEG) microparticles to be used as carriers for oral insulin delivery via double emulsion preparation. METHODS: Five different batches of the formulation consisting of gelatin:PEG were prepared as follows: 0:1 (W1), 1:0 (W2), 1:1 (W3), 1:3 (W4), and 3:1 (W5). The prepared microparticles (from insulin-loaded batches) had particle sizes ranging from 19.5 ± 0.32-23.9 ± 0.22 µm and encapsulation and loading capacities ranging from 78.8 ± 0.24-88.9 ± 0.95 and 22.2 ± 0.96-29.7 ± 0.86%, respectively. The minimum and maximum in vitro release rates were 8.0 and 66.0%, respectively, for batches W1 and W2 at 8 h. RESULTS: Insulin-loaded MPs induced a significant decrease in glucose levels, with a reduction from 100 to 33.35% in batch W5 at 9 h compared to that of subcutaneous insulin (100 to 22.63%). A liver function study showed that the formulation caused no obvious toxicity to the experimental rats. CONCLUSION: Gelatinized PEG-based microparticles as insulin delivery systems may open a new window into the development of oral insulin for diabetic treatment.

Insulin-loaded mucoadhesive nanoparticles based on mucin-chitosan complexes for oral delivery and diabetes treatment.

In this study, insulin-loaded nanoparticles (NPs) were prepared via self-gelation method using chitosan and aqueous soluble snail mucin as natural polymers. Herein, mucins were ionically interacted with chitosan at different concentrations to obtained insulin-loaded NPs, labelled as A1 (1:1) (i.e., chitosan 2 % w/v + mucin 2 % w/v) and A2 (2:1) (chitosan 4 % w/v + mucin 2 % w/v), using poloxamer and poly vinyl alcohol as solid surfactant. Such formulation was selected to provide the necessary dynamics for the formation of the nanoparticles while maintaining the surface properties that will favor the encapsulation of insulin. Each system was characterized in terms of their particle size distribution, morphology, zeta potential, and polydispersity index. In vitro release of insulin was evaluated in acidic solution (pH 1.2) and phosphate buffer solution (pH 7.4), and the hypoglycaemic activity was evaluated in diabetes rats. The prepared insulin-loaded NPs displayed particles with relatively smooth surfaces and an average particle size of 479.6 and 504.1 nm for A1 and A2, respectively. Zeta potential and polydispersity index, ranged from 22.1 to 31.2 mV and 0.155-0.185, respectively. The encapsulating efficiency for the systems A1 and A2 were 88.6 and 92.5, respectively, and a self-sustained release of encapsulated insulin was observed for over a period of 8 h. In vivo studies revealed a pronounced hypoglycaemic effect in diabetic rats after peroral administration of the insulin-loaded NPs compared to the effect caused by free oral insulin solution. In addition, both the pharmacokinetic and toxicity results showed low plasma clearance of insulin and no signs of toxicity on the liver enzyme and cell viability, which suggested good biocompatibility of the NPs formulations. Overall, the formation of NPs of insulin with chitosan and snail mucin represents a potentially safe and promising approach to protect insulin and enhance its peroral delivery.

Surface-modified mucoadhesive microparticles as a controlled release system for oral delivery of insulin.

To overcome barriers and improve oral bioavailability of insulin delivery has been a mirage to formulation scientists due to instability of the insulin after oral administration. Microparticle (MP) composed of chitosan and snail mucin was prepared via double emulsion method for oral delivery of insulin. Microparticles were characterized by differential scanning calorimetry, Fourier transform infrared spectroscopy and scanning electron microscopy. The encapsulation efficiency (EE) of the insulin-loaded MPs were evaluated. Insulin release behavior was evaluated in acidic and phosphate buffer (pH 1.2 and 7.4) at 37 °C. Bioactivities of insulin-loaded MPs were evaluated in a diabetic animal model after oral administration. The insulin-loaded MPs showed irregular shape with a zeta potential (>29 mV). The encapsulation efficiency and drug loading were >75 and 28 %, respectively. The in vitro release shows >80 % release of insulin over 12 h in a sustained manner. The insulin-MPs significantly reduced blood glucose levels (>50 %) compared to positive control and the effect lasted for over 8 h. This study suggests that insulin-MPs as prepared would be potential carriers for oral delivery of insulin.

Anti-inflammatory and pharmacokinetics evaluation of PEGylated ibuprofen tablet formulation.

To develop a novel PEGylated ibuprofen tablet formulations and evaluate its anti-inflammatory activity and pharmacokinetics profile in an animal model. Six batches of PEGylated ibuprofen tablets were prepared by direct compression using Avicel® and lactose as the binder diluents. In vivo anti-inflammatory activity of the tablets was carried out as well as the pharmacokinetics profiles. The PEGylated ibuprofen tablet reduced carrageenan-induced inflammation in experimental animals and sustained its anti-inflammatory action for over 10 h. The pharmacokinetics profile of the optimized formulations were greater than that of the marketed sample and the pure drug sample. In conclusion, PEGylation of ibuprofen conferred a high level of anti-inflammatory activity and slowed plasma clearance level, indicating sustained release. Thus, further exploration of this novel formulation to be used as an alternative carrier for this drug is required.