Effects of three drying methods on the physical properties and drug delivery in chitosan microspheres

doi:10.7518/hxkq.2019.02.005

Abstract

Abstract:

Objective The purpose of this study is to investigate the effects of different drying methods on the physical properties and drug delivery of chitosan microspheres. Methods Three types of drying methods were utilized, including air drying and freeze drying after freezing at -20 ℃ (slow cooling) and at -80 ℃ (fast cooling). The physical properties of microspheres were characterized. Utilizing bovine serum albumin (BSA) as the model drug, the in-vitro release behaviors of drug-loaded beads were investigated. Results By comparing the physical properties of the different drying methods, the microspheres’ diameters, porosities, and surface area were observed to increase successively from air drying and slow cooling to fast cooling, whereas the pore size and the swelling and degradation rates varied. The drug-loading experiments revealed that the loading capacity of air-dried microspheres was the lowest and the release rate was the slowest. Although the loading capacity of fast cooling microspheres was high, an obvious burst release was observed. The loading capacity of slow cooling microspheres was similar to that of the fast cooling microspheres and the loaded BSA can be released continuously. Conclusion The results indicate that different drying methods can affect the physical properties of chitosan microspheres, which further influence drug loading and release.

Key words: chitosan microsphere, drying methods, physical properties, drug delivery

CLC Number:

R783.2

Fei Xu,Yang Cao,Ping Yin,Liwei Ma,Jijia Li,Changyun Fang. Effects of three drying methods on the physical properties and drug delivery in chitosan microspheres[J]. West China Journal of Stomatology, 2019, 37(2): 149-154.

Figures/Tables 7

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组别	孔隙率/%	直径/μm	比表面积/（m²·g^-1）	孔径/nm
自然干燥微球	10.74±3.15	232.17±41.76	0.003 2	-
慢速冻干微球	67.89±3.73*	365.36±78.05*	2.687 6	610.25±170.42
快速冻干微球	77.50±2.18*^&	389.37±69.85*^&	3.233 2	273.34±62.91^&