In silico mechanistic disposition and in vivo evaluation of zero-order drug release from a novel triple-layered tablet matrix.

OBJECTIVES: The purpose of this study was to formulate novel triple-layered tablet (TLT) matrices employing modified polyamide 6,10 (mPA6,10) and salted-out poly(lactic-co-glycolic acid) (s-PLGA) in an attempt to achieve stratified zero-order drug release. METHODS: mPA6,10 and s-PLGA were employed as the outer drug-carrier matrices, whereas poly(ethylene oxide) (PEO) was used as the middle-layer drug matrix. Diphenhydramine HCl, ranitidine HCl and promethazine were selected as model drugs to pre-optimize the TLT, whereas atenolol, acetylsalicylic acid and simvastatin were employed as a comparable fixed dose combination to test the TLT prototype in vitro and in vivo (Large White Pig model). A total of 17 formulations that varied in terms of polymer stoichiometry, salt addition and polymer-polymer ratios were generated using a Box-Behnken experimental design. RESULTS: The in vitro drug release analysis revealed that release from the mPA6,10 layer was relatively linear with a burst release, which upon addition of sodium sulfate was reduced. Furthermore, formulations with higher quantities of mPA6,10 provided more controlled zero-order drug release and increased the matrix hardness. The addition of PEO to the s-PLGA layer significantly reduced the initial burst release that occurred when s-PLGA was used alone. CONCLUSIONS: The formulation with a lower s-PLGA:PEO ratio displayed superior zero-order release. Relatively, linear drug release was achieved from the middle-layer. The in vivo results proved the applicability of optimized TLT formulation in a therapeutic cardiovascular drug treatment regimen.

Oral drug delivery systems comprising altered geometric configurations for controlled drug delivery.

Recent pharmaceutical research has focused on controlled drug delivery having an advantage over conventional methods. Adequate controlled plasma drug levels, reduced side effects as well as improved patient compliance are some of the benefits that these systems may offer. Controlled delivery systems that can provide zero-order drug delivery have the potential for maximizing efficacy while minimizing dose frequency and toxicity. Thus, zero-order drug release is ideal in a large area of drug delivery which has therefore led to the development of various technologies with such drug release patterns. Systems such as multilayered tablets and other geometrically altered devices have been created to perform this function. One of the principles of multilayered tablets involves creating a constant surface area for release. Polymeric materials play an important role in the functioning of these systems. Technologies developed to date include among others: Geomatrix(®) multilayered tablets, which utilizes specific polymers that may act as barriers to control drug release; Procise(®), which has a core with an aperture that can be modified to achieve various types of drug release; core-in-cup tablets, where the core matrix is coated on one surface while the circumference forms a cup around it; donut-shaped devices, which possess a centrally-placed aperture hole and Dome Matrix(®) as well as "release modules assemblage", which can offer alternating drug release patterns. This review discusses the novel altered geometric system technologies that have been developed to provide controlled drug release, also focusing on polymers that have been employed in such developments.