4.6 Article

Metformin hydrochloride sustained release biopolymeric system composed by PLLA-CMC microparticles

Journal

JOURNAL OF APPLIED POLYMER SCIENCE
Volume 138, Issue 33, Pages -

Publisher

WILEY
DOI: 10.1002/app.50806

Keywords

biopolymers and renewable polymers; cellulose and other wood products; drug delivery systems

Funding

  1. University of the Region of Joinville (UNIVILLE, Brazil)
  2. Fundo de Apoio a Pesquisa - FAP/UNIVILLE (Brazil)

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This study aimed to develop a MetHCl sustained release biopolymeric system to minimize the issues caused by the drug's high hydrophilicity. The results showed that the increase in CMC concentration was positively correlated with emulsion stability and encapsulation efficiency. DSC findings indicated that the choice of the first emulsifier influenced the crystallinity of the polymer particles, which in turn affected the drug release behavior. In vitro studies demonstrated that the encapsulation of MetHCl in PLLA-CMC microparticles is a promising sustained release system compatible with a zero-order kinetic mechanism.
Metformin hydrochloride (MetHCl) is a drug extensively used to treat diabetes mellitus Type 2. However, its high hydrophilicity drastically reduces its metabolic absorption. Consequently, high drug concentrations should be taken by patients to achieve the desired therapeutical efficiency, causing several side effects. The present study proposes the development of a MetHCl sustained release biopolymeric system composed of poly(l-lactic acid) (PLLA) and carboxymethyl cellulose (CMC) as a strategy to minimize the problems aforementioned. The PLLA-CMC microparticles were produced by the double emulsion-solvent evaporation technique using two distinct emulsifiers in the first emulsion (Spam 80 and Tween 80). The microparticles were characterized by ultraviolet-visible spectrophotometry, scanning electron microscopy with field emission gun, thermalgravimetric analyses, and differential scanning calorimetry (DSC). Additionally, in vitro drug release assays were performed. The results demonstrated that the emulsion stability and encapsulation efficiency increased in a dependent fashion way with the CMC concentration. DSC findings showed that the choice of the emulsifier of the first emulsion influences the polymer particle's crystallinity and, consequently, the releasing behavior of the drug. The in vitro studies revealed that the encapsulation of MetHCl in PLLA-CMC microparticles is a promising sustained release system compatible with a zero-order kinetic mechanism.

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