Objective:To compare the differences in chemical compositions before and after processing by different processing methods; To optimize the processing method of Atractylodes lancea Rhizoma.Methods:Atractylodes lancea Rhizoma was processed by stir-frying with bran and treating with rice washing water. The volatile and non-volatile components of raw Atractylodes lancea Rhizoma, bran-fried Atractylodes lancea Rhizoma and rice washing water treated Atractylodes lancea Rhizome were qualitatively analyzed by headspace gas chromatography-mass spectrometry (HS-GC-MS) and ultra-performance liquid chromatography-quadrupole-electrostatic field orbitrap high-resolution mass spectrometry (UPLC-Q-Orbitrap HRMS), and the differences in chemical composition before and after processing were compared.Results:The volatile components of the three different products were determined to have 18 common components, such as agarospirol, β-eudesol, etc. In addition, 86 non-volatile components were determined. The peak area response value of atractylodin, the index component prescribed by pharmacopoeia, decreased after processing, but there was little difference in bran stir-frying and rice-washed water frying.Conclusions:Different processing methods have certain effects on the chemical composition of Atractylodes lancea Rhizoma. Among them, the bran-frying method is superior in improving the quality of preparations, reducing production costs and improving production efficiency. The bran-fried product can be used as raw material for preparation production.

Objective To evaluate the systematic and random set-up errors in patients immobilized with thermoplastic device during radiotherapy, and to determine the proper margins extended from clinical target volume ( CTV ) or internal target volume ( ITV ) to planning target volume ( PTV ). Methods From March 2007 to September 2007,120 patients were included in this study, including 13 receiving head and neck irradiation, 67 thoracic irradiation and 40 abdominal irradiation. All patients were immobilized with thermoplastic device and received CT simulation and intensity modulated radiation therapy(IMRT). X-ray cone beam CT was regularly performed before treatment and the images were compared with the simulation CT images. The shift and rotation in right-left( R-L), superior-inferior(S-I) and anterior-posterior(A-P) directions were recorded and analyzed. The shift margin from CTV or ITV to PTV was calculated with the equation, margin = 2'mean + 0.7'standard deviation. Results In head and neck region, the shift errors in R-L,S-I and A-P directions were(0.13 ±0.15) cm, (0.13 ±0.17) cm and(0.11 ±0.14) cm,and the corresponding rotation errors were 1.05°± 0.77°,0.87°± 1.13° and 0.68°±0.89°. The margins from CTV to PTV were 0.37 cm,0.38 cm and 0.31 cm,respectively. In thoraci region,the shift errors in R-L,S-I and AP directions were(0.20 ±0.27) cm, (0.34 ±0.44) cm and(0.25±0.31 ) cm,and the corresponding rotation errors were 1.06°±1.45° ,0.85°±1.23° and 0.78°±1.08°. The shift margins from ITV to PTV were 0.59 cm, 1.00 cm and 0.72 cm. In abdominal region, the shift errors in R-L, S-I and A-P directions were (0.23 ± 0.30) cm, (0.37 ±0.45 ) cm and ( 0.27 ±0.34 ) cm, and the corresponding rotation errors were 1.22°±1.56°, 1.05°± 1.44°and 0.98°± 1.24°. The shift margins from CTV or ITV to PTV were 0.66 cm, 1.05 cm and 0.78 cm. Conclusions Cone beam CT can be used in the precise measure of set-up errors,which can provide institution-specific margins for PTV designing in patients immobilized with thermoplastic device.