瑞舒伐他汀钙纳米粒：通过制剂和稳定性协同设计提高生物利用度。

Rosuvastatin calcium nanoparticles: Improving bioavailability by formulation and stabilization codesign.

机构信息

Kayyali chair for Pharmaceutical Industries, Department of Pharmaceutics, College of Pharmacy, King Saud University, Riyadh, Saudi Arabia.

Department of Pharmaceutics, College of pharmacy, Al-Azhar University, Assiut, Egypt.

出版信息

PLoS One. 2018 Jul 9;13(7):e0200218. doi: 10.1371/journal.pone.0200218. eCollection 2018.

DOI:10.1371/journal.pone.0200218

PMID:29985967

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6037357/

Abstract

PURPOSE

Rosuvastatin calcium (ROSCa) is a poorly soluble drug with bioavailability not exceeding 20%. Decreasing the particle size may enhance its solubility, dissolution rate and bioavailability. Therefore, the aim of the current study is to prepare ROSCa nanoparticles by wet milling technique using planetary ball mill. The codesign between formulation and stabilization of nanoparticles was studied to achieve both high dissolution as well as bioavailability.

METHODOLOGY

ROSCa nanosuspensions was prepared by wet milling technique using planetary ball mill, by applying milling ball size of 0.1 mm at speed of 800 rpm for 3 cycles each cycle composed of 10 minutes. HPMC, PVP k-30, pluronic F-127, Tween 80 and PEG 6000 were used as stabilizers. The nanosuspensions were then freeze-dried, and the dried nanoparticles were evaluated for particle size, zeta potential, in-vitro dissolution test, XRPD and in-vivo study.

RESULTS

ROSCa nanoparticles stabilized with 10% PVP (P3) had a good stability with smallest particle size, which in turn enhanced the dissolution rate. The particle size of the leading formula was 461.8 ± 16.68 nm with zeta potential of -31.8 ± 7.22 mV compared to untreated drug that has a particle size of 618μm. The percent of ROSCa dissolved after 1 hour enhanced significantly which reached 72% and 58.25% for leading nanoparticle formula and untreated ROSCa, respectively (P < 0.05). The in-vivo study of ROSCa from the leading nanoparticle formula showed a significant enhancement in the Cmax after 2 h (82.35 ng/ml) compared to 9.2 ng/ml for untreated drug.

CONCLUSION

Wet milling technique is a successful method to prepare ROSCa nanoparticles. From different stabilizer used, PVP (10%) was able to produce stable nanoparticle with small particle size which significantly enhance the dissolution rate and pharmacokinetics parameters of ROSCa.

摘要

目的

瑞舒伐他汀钙（ROSCa）是一种水溶性差的药物，生物利用度不超过 20%。减小粒径可以提高其溶解度、溶出速率和生物利用度。因此，本研究旨在通过行星球磨机的湿磨技术制备 ROSCa 纳米粒子。研究了制剂与纳米粒子稳定化的协同设计，以实现高溶解率和高生物利用度。

方法

采用行星球磨机的湿磨技术制备 ROSCa 纳米混悬液，以 0.1mm 的研磨球粒径在 800rpm 的速度下进行 3 个循环，每个循环由 10 分钟组成。HPMC、PVPk-30、PluronicF-127、Tween80 和 PEG6000 用作稳定剂。纳米混悬液随后进行冷冻干燥，对干燥的纳米粒子进行粒径、Zeta 电位、体外溶出度试验、XRPD 和体内研究。

结果

用 10%PVP（P3）稳定的 ROSCa 纳米粒子具有良好的稳定性，粒径最小，从而提高了溶出速率。主要配方的粒径为 461.8±16.68nm，Zeta 电位为-31.8±7.22mV，而未处理药物的粒径为 618μm。1 小时后 ROSCa 的溶解百分比显著提高，达到 72%和 58.25%，分别为主要纳米粒子配方和未处理的 ROSCa（P<0.05）。从主要纳米粒子配方中得到的 ROSCa 的体内研究表明，与未处理药物的 9.2ng/ml 相比，在 2 小时后 Cmax 显著提高至 82.35ng/ml。

结论

湿磨技术是制备 ROSCa 纳米粒子的成功方法。在使用的不同稳定剂中，PVP（10%）能够产生稳定的纳米粒子，粒径较小，显著提高了 ROSCa 的溶出速率和药代动力学参数。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f848/6037357/31ba49dd1fcb/pone.0200218.g001.jpg

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瑞舒伐他汀钙纳米粒：通过制剂和稳定性协同设计提高生物利用度。

Rosuvastatin calcium nanoparticles: Improving bioavailability by formulation and stabilization codesign.

机构信息

出版信息

PURPOSE

METHODOLOGY

RESULTS

CONCLUSION

目的

方法

结果

结论

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