引用本文: | 明良山,朱琳,李哲,丁媛,毛志旋,王可馨,吴嘉仪.片剂薄膜包衣过程激光共聚焦成像及近红外光谱建模分析[J].中国现代应用药学,2021,38(11):1281-1288. |
| MING Liangshan,ZHU Lin,LI Zhe,DING Yuan,MAO Zhixuan,WANG Kexin,WU Jiayi.Quality Assessment of Film Coating Tablet Samples Using Confocal Laser Scanning Microscopy Imaging and Near Infrared Spectroscopy[J].Chin J Mod Appl Pharm(中国现代应用药学),2021,38(11):1281-1288. |
|
本文已被:浏览 1882次 下载 783次 |
码上扫一扫! |
|
片剂薄膜包衣过程激光共聚焦成像及近红外光谱建模分析 |
明良山, 朱琳, 李哲, 丁媛, 毛志旋, 王可馨, 吴嘉仪
|
江西中医药大学高等研究院, 现代中药制剂教育部重点实验室, 中医基础理论分化发展研究中心, 药学院, 南昌 330004
|
|
摘要: |
目的 研究薄膜包衣的微观成膜过程,实现对包衣质量无损检测模型的构建。方法 采用聚乙烯吡咯烷酮为包衣材料对微晶纤维素片进行包衣,在包衣材料中加入罗丹明为示踪剂。测定包衣过程不同时间包衣增重和衣膜厚度,并通过激光共聚焦显微镜成像系统和近红外光谱技术分别测定包衣片衣膜的微观结构和宏观图谱,最后采用化学计量学的方法关联近红外图谱与衣膜质量,构建包衣过程的控制模型。结果 衣膜在片芯表面呈现非均匀分布,先分布于片芯两侧表面,后分布于片芯曲面,这种差异随包衣的进行逐渐降低,且在衣膜表面存有微小的孔隙结构。多元散色矫正预处理后的近红外光谱图形能够构建包衣质量的精确控制和预测模型。结论 激光共聚焦成像及近红外光谱技术能够分别从微观和宏观角度增进对薄膜包衣过程的理解和控制,有助于促进薄膜包衣技术的进一步开发利用。 |
关键词: 薄膜包衣 近红外光谱 激光共聚焦 片剂 偏最小二乘回归 |
DOI:10.13748/j.cnki.issn1007-7693.2021.11.001 |
分类号:R944.4 |
基金项目:国家自然科学基金项目(82003953);中国博士后科学基金资助项目(2019M662278);江西省自然科学基金项目(20202BAB216039);江西省教育厅科学技术研究项目(GJJ190688);江西省博士后科研项目择优资助(2019KY42);江西中医药大学校级课题(2004/538200010402) |
|
Quality Assessment of Film Coating Tablet Samples Using Confocal Laser Scanning Microscopy Imaging and Near Infrared Spectroscopy |
MING Liangshan, ZHU Lin, LI Zhe, DING Yuan, MAO Zhixuan, WANG Kexin, WU Jiayi
|
Institute for Advanced Study, Key Laboratory of Modern Preparation of TCM, Ministry of Education, Research Center for Differentiation and Development of TCM Basic Theory, College of Pharmacy, Jiangxi University of Chinese Medicine, Nanchang 330004, China
|
Abstract: |
OBJECTIVE To study the microscopic film-forming process of film coating, and realize the construction of non-destructive testing model for coating quality. METHODS The microcrystalline cellulose tablets were coated with polyvinylpyrrolidone as a coating shell material, and rhodamine was added as a tracer in the coating shell material. The coating weight gain and film thickness of coated tablets were measured at different coating times, and the microstructure and macroscopic profiles of the coated film were determined by confocal laser scanning microscopy and near infrared spectroscopy, respectively. Then chemometrics method was utilized to correlate the near infrared spectra with the film quality, and finally the control models for the coating process was constructed. RESULTS The film was inhomogeneously distributed on the surface of the tablets. It was primarily disturbed on both sides of the tablet and subsequently distributed on the curved portions. This difference gradually decreased with the progress of the coating. In addition, the microstructure indicated that there exists microporous structure on the surface of the film. Near infrared spectra after multiple scattering correction pretreatment could accurately control and predict the coating quality. CONCLUSION Confocal laser scanning microscopy and near infrared spectroscopy can enhance the understanding and control of film coating from microscopic and macroscopic aspects, and help to develop and utilize the film coating technology. |
Key words: film coating near infrared spectroscopy confocal laser scanning microscopy tablets partial least squares |