分离表面能和表面积对药用粉末内聚力的贡献。

Decoupling the contribution of surface energy and surface area on the cohesion of pharmaceutical powders.

作者信息

Shah Umang V, Olusanmi Dolapo, Narang Ajit S, Hussain Munir A, Tobyn Michael J, Hinder Steve J, Heng Jerry Y Y

机构信息

Surfaces and Particle Engineering Laboratory (SPEL), Department of Chemical Engineering, Imperial College London, South Kensington Campus, London, SW7 2AZ, UK.

出版信息

Pharm Res. 2015 Jan;32(1):248-59. doi: 10.1007/s11095-014-1459-3. Epub 2014 Jul 19.

DOI:10.1007/s11095-014-1459-3

PMID:25037862

Abstract

PURPOSE

Surface area and surface energy of pharmaceutical powders are affected by milling and may influence formulation, performance and handling. This study aims to decouple the contribution of surface area and surface energy, and to quantify each of these factors, on cohesion.

METHODS

Mefenamic acid was processed by cryogenic milling. Surface energy heterogeneity was determined using a Surface Energy Analyser (SEA) and cohesion measured using a uniaxial compression test. To decouple the surface area and surface energy contributions, milled mefenamic acid was "normalised" by silanisation with methyl groups, confirmed using X-ray Photoelectron Spectroscopy.

RESULTS

Both dispersive and acid-base surface energies were found to increase with increasing milling time. Cohesion was also found to increase with increasing milling time. Silanised mefenamic acid possessed a homogenous surface with a surface energy of 33.1 ± 1.4 mJ/m(2) , for all milled samples. The cohesion for silanised mefenamic acid was greatly reduced, and the difference in the cohesion can be attributed solely to the increase in surface area. For mefenamic acid, the contribution from surface energy and surface area on cohesion was quantified to be 57% and 43%, respectively.

CONCLUSIONS

Here, we report an approach for decoupling and quantifying the contribution from surface area and surface energy on powder cohesion.

摘要

目的

药物粉末的表面积和表面能会受到研磨的影响，并可能影响制剂、性能和处理过程。本研究旨在分离表面积和表面能的贡献，并量化这些因素对凝聚力的影响。

方法

对甲芬那酸进行低温研磨。使用表面能分析仪（SEA）测定表面能非均质性，并使用单轴压缩试验测量凝聚力。为了分离表面积和表面能的贡献，用甲基进行硅烷化处理对研磨后的甲芬那酸进行“归一化”，并用X射线光电子能谱进行确认。

结果

发现随着研磨时间的增加，色散表面能和酸碱表面能均增加。还发现凝聚力也随着研磨时间的增加而增加。对于所有研磨样品，硅烷化甲芬那酸具有均匀的表面，表面能为33.1±1.4 mJ/m²。硅烷化甲芬那酸的凝聚力大大降低，凝聚力的差异可完全归因于表面积的增加。对于甲芬那酸，表面能和表面积对凝聚力的贡献分别量化为57%和43%。

结论

在此，我们报告了一种分离和量化表面积和表面能对粉末凝聚力贡献的方法。

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分离表面能和表面积对药用粉末内聚力的贡献。

Decoupling the contribution of surface energy and surface area on the cohesion of pharmaceutical powders.

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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