阿奇霉素阳离子非卵磷脂纳米/微粒可提高生物利用度和靶向效率。

Azithromycin cationic non-lecithoid nano/microparticles improve bioavailability and targeting efficiency.

作者信息

Zhong Meng, Feng Yue, Liao Hong, Hu Xueyuan, Wan Shengli, Zhu Biyue, Zhang Mi, Xiong Huarong, Zhou Yunli, Zhang Jingqing

机构信息

Medicine Engineering Research Center, Chongqing Medical University, Chongqing, 400016, People's Republic of China.

出版信息

Pharm Res. 2014 Oct;31(10):2857-67. doi: 10.1007/s11095-014-1382-7. Epub 2014 Sep 11.

DOI:10.1007/s11095-014-1382-7

PMID:25208873

Abstract

PURPOSE

The purpose of this study was to develop and evaluate the azithromycin cationic non-lecithoid nano/microparticles with high bioavailability and lung targeting efficiency.

METHODS

The cationic niosomes with different sizes (AMCNS-S and AMCNS-L) along with varied built-in characteristics were produced to achieve high bioavailability and lung targeting efficiency of azithromycin (AM) via two administration routes widely used in clinical practice, i.e., oral and intravenous routes, instead of transdermal route (by which the only marketed niosome-based drug delivery dermatologic products were given). The possible explanations for improved bioavailability and lung targeting efficacy were put forward here.

RESULTS

AMCNS-S (or AMCNS-L) had high bioavailability, for example, the oral (or intravenous) relative bioavailability of AMCNS-S (or AMCNS-L) to free AM increased to 273.19% (or 163.50%). After intravenous administration, AMCNS-S (or AMCNS-L) had obvious lung targeting efficiency, for example, the lung AM concentration of AMCNS-S (or AMCNS-L) increased 16 (or 28) times that of free AM at 12 h; the AM concentration of AMCNS-S (or AMCNS-L) in lung was higher than that in heart and kidney all the time.

CONCLUSIONS

The development of niosome-based AM nanocarriers provides valuable tactics in antibacterial therapy and in non-lecithoid niosomal application.

摘要

目的

本研究旨在开发并评估具有高生物利用度和肺靶向效率的阿奇霉素阳离子非卵磷脂纳米/微粒。

方法

制备了具有不同尺寸（AMCNS-S和AMCNS-L）以及不同内在特性的阳离子脂质体，通过临床实践中广泛使用的两种给药途径，即口服和静脉途径，而非透皮途径（目前唯一基于脂质体的上市药物递送皮肤科产品的给药途径），来实现阿奇霉素（AM）的高生物利用度和肺靶向效率。本文还提出了生物利用度提高和肺靶向疗效改善的可能原因。

结果

AMCNS-S（或AMCNS-L）具有高生物利用度，例如，AMCNS-S（或AMCNS-L）相对于游离AM的口服（或静脉）相对生物利用度提高到了273.19%（或163.50%）。静脉给药后，AMCNS-S（或AMCNS-L）具有明显的肺靶向效率，例如，在12小时时，AMCNS-S（或AMCNS-L）的肺AM浓度比游离AM增加了16（或28）倍；AMCNS-S（或AMCNS-L）在肺中的AM浓度始终高于心脏和肾脏中的浓度。

结论

基于脂质体的AM纳米载体的开发为抗菌治疗和非卵磷脂脂质体应用提供了有价值的策略。

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阿奇霉素阳离子非卵磷脂纳米/微粒可提高生物利用度和靶向效率。

Azithromycin cationic non-lecithoid nano/microparticles improve bioavailability and targeting efficiency.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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