Pharmacodynamical effects of orally administered exenatide nanoparticles embedded in gastro-resistant microparticles.

One of the major disadvantages associated with macromolecules therapy is that most of them can only be administered parenterally. Exenatide, an efficient anti-diabetic drug, incretin mimetic, is currently administered subcutaneously (SC) causing compliance issues. Nanoparticles (NPs) are considered a promising solution for oral delivery of this drug. In order to overcome exenatide's inability to cross the enterocytes and to increase its stability in the gastrointestinal (GI) tract, we encapsulated exenatide into a nano-in-micro delivery system. This drug delivery system (DDS) improved the relative oral bioavailability of exenatide, in comparison to Byetta® injection SC. In this study, we report about the efficacy of this DDS to improve glycemic parameters in diabetic ob/ob mice. Our results suggested that our DDS successfully lowered blood glucose levels (BGL) raised insulin levels, decreased glycated hemoglobin and maintained the body weight of the mice. These findings validate the efficacy of this DDS in promoting oral delivery of exenatide and will hopefully improve patient compliance and adherence. The potential of this DDS to encapsulate other leading peptides and proteins, such as insulin, was also evaluated in this study. It was found that peptides up to 6 kDa can be efficiently encapsulated, but the in-vivo performance is also dependent on other physicochemical properties.

Improved oral absorption of exenatide using an original nanoencapsulation and microencapsulation approach.

Oral delivery is the most convenient and favorable route for chronic administration of peptides and proteins to patients. However, many obstacles are faced when developing such a delivery route. Nanoparticles (NPs) are among the leading innovative solutions for delivery of these drugs. Exenatide is a peptidic drug administered subcutaneously (SC) twice a day chronically as an add-on therapy for the worldwide pandemic disease, diabetes. Many attempts to develop oral nanocarriers for this drug have been unsuccessful due to the inability to retain this hydrophilic macromolecule under sink conditions or to find a suitable cross-linker which does not harm the chemical integrity of the peptide. In this study, we report about an original oral delivery solution based on a mixture of albumin and dextran NPs cross-linked using sodium trimetaphosphate (STMP). Moreover, we suggest a second defense line of gastro-resistant microparticles (MPs) composed of an appropriate ratio of Eudragit® L100-55 (Eudragit L) and hydroxypropylmethylcellulose (HPMC), for additional protection to these NPs presumably allowing them to be absorbed in the intestine intact. Our results demonstrate that such a system indeed improves the relative oral bioavailability of exenatide to a level of about 77% compared to subcutaneous injection due to the presence of dextran in the coating wall of the NPs which apparently promotes the lymphatic uptake in the enterocytes. This technology may be a milestone on the way to deliver other peptides and proteins orally.