Objective To establish the UPLC fingerprint chromatogram combined with chemometric analysis for the quality evaluation of classical formula Linggui Zhugan Decoction.Methods SHIMADZU Shim-Pack GIST C18 column(100 mm×2.1 mm,2.0 μm)was used with acetonitrile-0.1%phosphoric acid aqueous solution as mobile phase,gradient elution;flow rate was 0.2 mL/min;the detection wavelength was 266 nm for the first 30 minutes and 235 nm for the last 36 minutes;the column temperature was 30℃.The UPLC fingerprint of Linggui Zhugan Decoction was established by Similarity Evaluation System for Chromatographic Fingerprint of TCM(2012.130723 version),and the common peak was determined and the similarity evaluation was carried out.Based on the peak area determination results of the common peak of the fingerprint,the quality of different batches of Linggui Zhugan Decoction was evaluated by chemometrics such as clustering analysis and principal component analysis.Results A total of 24 common peaks were confirmed and 14 components were identified by using reference substances.The similarity of 10 batches of Linggui Zhugan Decoction samples was greater than 0.950,which could be divided into two categories by chemometrics,and the principal component 1-4 were the main factors affecting its quality evaluation.OPLS-DA identified 6 differential markers.Conclusion The fingerprint research method established in the study is simple,reliable and reproducible.Through the method of fingerprint combined with chemometrics analysis,the differences between Linggui Zhugan Decoction from different origins of medicinal materials are identified,which provides a reference for the internal quality evaluation of Linggui Zhugan Decoction.

OBJECTIVE To clarify the components of volatile oil in branches and leaves of Rhododendron anthopogonoides, Rhododendron capitatum, Rhododendron thymifolium and Rhododendron przewalskii. METHODS The total volatile oil in leaves and branches of these plants were obtained by supercritical CO2 extraction. After that, the chemical composition of the total volatile oil was analyzed and identified by GC-MS, and the contents of different parts and varieties were compared. RESULTS The results showed that the highest oil yield of leaves was Rhododendron thymifolium(6.97%), and the highest oil yield of branches was Rhododendron anthopogonoides(20.53%). Thirty-five, eighty, fifty-eight and forty compounds were detected in the branch oil of Rhododendron anthopogonoides, Rhododendron capitatum, Rhododendron thymifolium and Rhododendron przewalskii respectively, among which Rhododendron capitatum was rich in compounds. Forty-eight, fifty-seven, sixty-two and fifty compounds were detected in the leaf oil, among which the compounds of Rhododendron anthopogonoides were the richest. Among the detected components, squalene(34.92%, 26.90%) was the highest content in the branches and leaves of Rhododendron anthopogonoides. 1-Eicosanol(26.79%) was the highest content in the branch oil of Rhododendron capitatum, and octadecyl acetate(42.32%) was the highest content in the leaf oil. The highest content of bisabola-3,10-diene-2-one(34.66%, 28.20%) was found in the branches and leaves of Rhododendron thymifolium, and 15-oxoETE(38.20%, 40.40%) was the highest content in the branches and leaves of Rhododendron przewalskii. The results showed that the contents of oil in branches and leaves of Rhododendron capitatum were quite different in different parts. In the comparison of different varieties, the compounds with the highest content of four rhododendrons were all different. CONCLUSION According to the difference of the content of active components of different rhododendrons and parts, the appropriate species and parts for purposeful development and utilization should be selected. The research results can provide scientific basis for rational development and utilization of Rhododendron resources.