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題 名 | 動態式楔形濾板穿透因子之測量=A Measurement of the Transmission Factors of Dynamic Wedges |
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作 者 | 黃英明; 郭珍妮; 陳海雯; 王裕文; | 書刊名 | 放射治療與腫瘤學 |
卷 期 | 4:1 1997.03[民86.03] |
頁 次 | 頁45-48 |
分類號 | 415.12 |
關鍵詞 | 放射治療; 動態式楔形濾板; 穿透因子; 劑量學; Radiation therapy; Dynamic wedge filter; Transmission factor; |
語 文 | 中文(Chinese) |
中文摘要 | 目的:本篇主要測量 Varian CL-2100C/D sn:48 I 動態式楔形濾板在不同照野的 穿透因子,以做為建立臨床動態式楔形濾板劑量學資料之一環,並與固定式楔形濾板因子做比 較,以了解動態式楔形濾板劑量上不同於固定式楔形濾板的特性,增加對動態式楔形濾板劑量 學上的了解及使用上應考量的因素。 材料與方法: 以 N.E. 0.6 cc Farmer Type 游離腔置於 Scanditronix RFA-300 水假體射 束中心軸深度 5 cm ( 6 MV )及 10 cm ( 15 MV )處,將水假體表面置於 100 cm 處, 游離腔長軸與濾板橫切面呈垂直, 分別測量 15 °、30 °、45 °、60 °固定式及動態式 楔形濾板各正方形照野之穿透因子,以觀察並比較其變化。 結果:固定式楔形濾板之穿透因子隨照野變大有增大之趨勢,平均約增加 3%; 動態式楔形 濾板穿透因子一般較固定式楔形濾板之穿透因子大,與照野大小之變化關係則呈不規則之變 小趨勢,相差最大達 35%。 結論:動態式楔形濾板在國內應用之經驗尚淺,對其劑量學上之特性應予多方了解,比如等 劑量分佈曲線,穿透因子與照野之關係等,由本文之結果得知動態式楔形濾板穿透因子與照 野之關係不呈規則性變化,對臨床應用上,由於變化極大,劑量計算時應視其照野大小正確 查得其因子,以求得正確之監測單位;另外,欲對一般電腦治療計畫系統建立動態式楔形濾 板資料庫時,亦應對穿透因子的不規則變化仔細考慮其劑量學的準確性。 |
英文摘要 | Purpose:The transmission factors of each dynamic and fixed wedge were measured for Varian CL-2100 C/D sn:481 linear accelerator. The factors were used to set-up the clinical treatment data tables for clinical dosimetry for dynamic wedges utilization. The data will be used to set-up the computer treatment planning database also. Materials and Methods: The N.E. 0.6 cc Farmer type chamber (Type:2571)connected to Ionex Dosemaster 2590 was installed on the chamber frame of Scanditronix RFA-300 water phantom with water prove protector. The axis of the chamber is perpendicular to the transverse plane of the wedge. Output factors in water were measured on the central axis of each field at 5-cm depth for 6 MV and 10-cm depth for 15 MV X-rays. The phantom was positioned with the water surface at 100 cm SSD. Measurements were performed for field sizes ranging from 4.0-20.0 cm and for equivalent square field to 25 cm. the measurements were performed for open, for fixed and dynamic wedge angles. The transmission factor of each field size was calculated from the output with/without wedge. Results:The transmission factors of each fixed wedges were increased as field size increase. The increment is around 3%. The factors of the dynamic wedge were larger than the fix ones, but the factors were decreased irregularly when field size increase. The maximum decrement is 35%. Conclusion:Tranmission factor is an important parameter in clinical applications of wedge filters. The variation of the factors of dynamic wedges verse field size is not the same as fixed ones and more complex. Due to the variation of the factors, one should take more attention in the application and the data input of the planning system. |
本系統中英文摘要資訊取自各篇刊載內容。