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Processing of calamine with modern analytical techniques: Processed with Huanglian Decoction (黄连汤) and Sanhuang Decoction (三黄汤)
Processing of calamine with modern analytical techniques: Processed with Huanglian Decoction (黄连汤) and Sanhuang Decoction (三黄汤)
- 中国结合医学杂志(英文版) 2017年23卷第11期 页码:850-857
- Affiliations:
1. Department of Herbology, College of Oriental Medicine, Dongguk University, Gyeongju, Republic of Korea
2. Institute of Pharmaceutical & Food Engineering, Shanxi University of Traditional Chinese Medicine,Shanxi Province,Jinzhong,China
3. Institute of Coal Chemistry, Chinese Academy of Sciences, Key Laboratory of Carbon Materials,Taiyuan,China
4. Hubei University of Medicine,Hubei Province,Shiyan,China
- Author bio:
- Funds:Supported by the the Key Technology Research for TCM Modernization of Shanxi Province "Zhendong" Special Project (No. 2014ZD0302)
DOI:10.1007/s11655-017-2798-9
中图分类号:纸质出版日期:2017,
网络出版日期:2017-7-28,
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Meng, Xl., Ma, Jn., Guo, Xh. et al. Processing of calamine with modern analytical techniques: Processed with Huanglian Decoction (黄连汤) and Sanhuang Decoction (三黄汤)., Chin. J. Integr. Med. 23, 850–857 (2017). https://doi.org/10.1007/s11655-017-2798-9
Xiang-long Meng, Jun-nan Ma, Xiao-hui Guo, et al. Processing of calamine with modern analytical techniques: Processed with Huanglian Decoction (黄连汤) and Sanhuang Decoction (三黄汤)[J]. Chinese Journal of Integrative Medicine, 2017,23(11):850-857.
Meng, Xl., Ma, Jn., Guo, Xh. et al. Processing of calamine with modern analytical techniques: Processed with Huanglian Decoction (黄连汤) and Sanhuang Decoction (三黄汤)., Chin. J. Integr. Med. 23, 850–857 (2017). https://doi.org/10.1007/s11655-017-2798-9 DOI:
Xiang-long Meng, Jun-nan Ma, Xiao-hui Guo, et al. Processing of calamine with modern analytical techniques: Processed with Huanglian Decoction (黄连汤) and Sanhuang Decoction (三黄汤)[J]. Chinese Journal of Integrative Medicine, 2017,23(11):850-857. DOI: 10.1007/s11655-017-2798-9.
摘要
To determine the pyrolysis characteristics of calcined and processed calamine
qualitatively and quantitatively compare the contents of related elements
morphology and functional groups of the pyrolysis products dried at different heating temperatures and explore the critical temperature and the optimal drying temperature for the process of calamine with Huanglian Decoction (HLD
黄连汤) and San Huang Decoction (SHD
三黄汤). Pyrolysis products were prepared by programmable and constantly heating the calcined and processed calamine to or at different heating temperatures. Thermogravimetry (TG) was used to test their pyrolysis characteristics. Fourier transform infrared spectroscopy and scanning electron microscopeenergy dispersive spectrometer were used to determine their morphology
functional groups and element contents. Page model was used to investigate the constant drying kinetics of processed calamine. The adding of HLD or SHD to calcined calamine (CC) can slow its weight loss in drying pyrolysis process. The temperature ranges where HLD and SHD can affect its weight loss were 65–150 °C and 74–180 °C
respectively. The drying temperature was optimized as 90 °C. The drying kinetic for the processed calamine fits Page model shows good linearity. Conclusions: The critical temperature and the optimal drying temperature where HLD and SHD can affect the weight loss rate in the process of calamine were explored using the theories and methods of both biophysical chemistry and processing of Chinese materia medica. This work provides a good example for the study of the process of other Chinese medicines using modern analytical techniques.
Abstract
To determine the pyrolysis characteristics of calcined and processed calamine
qualitatively and quantitatively compare the contents of related elements
morphology and functional groups of the pyrolysis products dried at different heating temperatures and explore the critical temperature and the optimal drying temperature for the process of calamine with Huanglian Decoction (HLD
黄连汤) and San Huang Decoction (SHD
三黄汤). Pyrolysis products were prepared by programmable and constantly heating the calcined and processed calamine to or at different heating temperatures. Thermogravimetry (TG) was used to test their pyrolysis characteristics. Fourier transform infrared spectroscopy and scanning electron microscopeenergy dispersive spectrometer were used to determine their morphology
functional groups and element contents. Page model was used to investigate the constant drying kinetics of processed calamine. The adding of HLD or SHD to calcined calamine (CC) can slow its weight loss in drying pyrolysis process. The temperature ranges where HLD and SHD can affect its weight loss were 65–150 °C and 74–180 °C
respectively. The drying temperature was optimized as 90 °C. The drying kinetic for the processed calamine fits Page model shows good linearity. Conclusions: The critical temperature and the optimal drying temperature where HLD and SHD can affect the weight loss rate in the process of calamine were explored using the theories and methods of both biophysical chemistry and processing of Chinese materia medica. This work provides a good example for the study of the process of other Chinese medicines using modern analytical techniques.
关键词
processing of Chinese materia medicacalcined calamineprocessed Calaminethermogravimetryfourier transformation infrared spectrometryscanning electron microscope-energy dispersive spectrometer
Keywords
processing of Chinese materia medicacalcined calamineprocessed Calaminethermogravimetryfourier transformation infrared spectrometryscanning electron microscope-energy dispersive spectrometer
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