Sublingual Administration of Teucrium Polium-Loaded Nanofibers with Ultra-Fast Release in the Treatment of Diabetes Mellitus: In Vitro and In Vivo Evaluation.

In this study, Teucrium polium (TP) methanolic extract, which has antidiabetic activity and protects the ß-cells of the pancreas, was loaded in polyethylene oxide/sodium alginate nanofibers by electrospinning and administered sublingually to evaluate their effectiveness in type-2 diabetes mellitus (T2DM) by cell culture and in vivo studies. The gene expressions of insulin, glucokinase, GLUT-1, and GLUT-2 improved in TP-loaded nanofibers (TPF) on human beta cells 1.1B4 and rat beta cells BRIN-BD11. Fast-dissolving (<120 s) sublingual TPF exhibited better sustainable anti-diabetic activity than the suspension form, even in the twenty times lower dosage in streptozotocin/nicotinamide-induced T2DM rats. The levels of GLP-1, GLUT-2, SGLT-2, PPAR-γ, insulin, and tumor necrosis factor-alpha were improved. TP and TPF treatments ameliorated morphological changes in the liver, pancreas, and kidney. The fiber diameter increased, tensile strength decreased, and the working temperature range enlarged by loading TP in fibers. Thus, TPF has proven to be a novel supportive treatment approach for T2DM with the features of being non-toxic, easy to use, and effective.

In vitro and in vivo evaluation of 3D printed sodium alginate/polyethylene glycol scaffolds for sublingual delivery of insulin: Preparation, characterization, and pharmacokinetics.

Delivery of therapeutic peptides via sublingual administration is extremely desired and 3D printed scaffolds are potential candidates as carriers to enhance insulin delivery. 3D printed sublingual sodium alginate (SA)/polyethylene glycol (PEG) composite scaffolds were produced for enhancing insulin delivery by examining the chemical, morphological, mechanical, thermal, cytotoxic, and pharmacokinetic features. The tensile strength and flexibility of scaffolds increased after loading insulin due to the crystalline structure of insulin. Furthermore, insulin-loaded 9SA/3PEG scaffolds showed ultrafast wetting (<1 s), disintegration (<6 s), and also dissolution (<30 s) according to Hixson-Crowell kinetic model. The cell viability of L929 cells on 3D printed scaffolds was examined and these scaffolds could be safely applied on animals. Pharmacokinetic parameters and blood glucose level were evaluated following sublingual administration of scaffolds to type-1 diabetic rats. A single dose of scaffold presented a longer hypoglycemic effect, reducing ~60% of glycemia after 30 min and it lasted for 12 h by increasing the bioavailability of insulin. Scaffolds indicated a sustained profile for serum insulin levels, which continued to increase slightly after 3 h during the study. The polymeric scaffold with a high safety and efficacy holds a new promising delivery strategy for administering injectable insulin through the sublingual route.