Tetracycline-Loaded Electrospun Poly(L-lactide-co-ε-caprolactone) Membranes for One-Step Periodontal Treatment

In this research, a one-step periodontal membrane, with the required function and properties, has been designed as an alternative method of tissue regenerative treatments. Designed nanoporous prototypes from poly(l-lactide-co-ε-caprolactone) (PLCL, 70:30 mol %) were fabricated by electrospinning, denoted as S-PLCL. They were subsequently loaded with tetracycline (TC) in order to enhance periodontal regeneration and deliver an anti-inflammatory and antibiotic drug. It was found that TC loading did not have any significant effect on the fiber diameter but did increase hydrophilicity. With the increase in TC loading, the water vapor permeability (WVP) of the S-PLCL membrane decreased within the range of 31–56% when compared with neat S-PLCL membranes, while in the solvent-cast film (F-PLCL), no significant change in WVP was observed. Moreover, S-PLCL demonstrated a controllable slow release rate of TC. S-PLCL loaded with 1500 μg/mL of TC showed a release concentration of 30 ppm over a certain time period to promote greater levels of human oral fibroblast and human oral keratinocyte cell proliferation and plaque inhibition. In conclusion, a TC-loaded S-PLCL fibrous membrane has been designed and fabricated to provide the ideal conditions for cell proliferation and antibiotic activity during treatment, outperforming nonfibrous F-PLCL loaded with TC at the same concentration

Preparation and Characterization of PLG Microparticles by the Multiple Emulsion Method for the Sustained Release of Proteins

Rapid release and diminished stability are two of the limitations associated with the growth factors that are essentially used in dental applications. These growth factors are employed to enhance the quality and quantity of tissue or bone matter during regeneration. Therefore, drug delivery devices and systems have been developed to address these limitations. In this study, bovine serum albumin (BSA), as a representative growth factor, was successfully sustained by encapsulation with the medium-absorbable copolymer, poly(L-lactide-co-glycolide) (PLG) 70:30% mol, via the multiple emulsion method. Different PLG, PVA, and BSA concentrations were used to investigate their effects on the BSA encapsulation efficiency. The suitable ratios leading to a better characterization of microparticles and a higher encapsulation efficiency in producing encapsulated PLG microparticles were 8% (w/v) of PLG, 0.25% (w/v) of PVA, and 8% (w/v) of BSA. Furthermore, an in vitro release study revealed a bursting release of BSA from the encapsulated PLG microsphere in the early phase of development. Subsequently, a gradual release was observed over a period of eight weeks. Furthermore, to encapsulate LL-37, different proteins were used in conjunction with PLG under identical conditions with regard to the loading efficiency and morphology, thereby indicating high variations and poor reproducibility. In conclusion, the encapsulated PLG microparticles could effectively protect the protein during encapsulation and could facilitate sustainable protein release over a period of 60 days. Importantly, an optimal method must be employed in order to achieve a high degree of encapsulation efficiency for all of the protein or growth factors. Accordingly, the outcomes of this study will be useful in the manufacture of drug delivery devices that require medium-sustained release growth factors, particularly in dental treatments