用于自屏蔽神经放射外科系统的精确机器特定参考和小场剂量学。

Department of Radiation Medicine, Medstar Georgetown University Hospital, Washington, District of Columbia, USA.

Metrology Research Centre, National Research Council, Ottawa, Ontario, Canada.

Med Phys. 2024 Jun;51(6):4423-4433. doi: 10.1002/mp.17111. Epub 2024 May 2.

BACKGROUND

The newly available ZAP-X stereotactic radiosurgical system is designed for the treatment of intracranial lesions, with several unique features that include a self-shielding, gyroscopic gantry, wheel collimation, non-orthogonal kV imaging, short source-axis distance, and low-energy megavoltage beam. Systematic characterization of its radiation as well as other properties is imperative to ensure its safe and effective clinical application.

PURPOSE

To accurately determine the radiation output of the ZAP-X with a special focus on the smaller diameter cones and an aim to provide useful recommendations on quantification of small field dosimetry.

METHODS

Six different types of detectors were used to measure relative output factors at field sizes ranging from 4 to 25 mm, including the PTW microSilicon and microdiamond diodes, Exradin W2 plastic scintillator, Exradin A16 and A1SL ionization chambers, and the alanine dosimeter. The 25 mm cone served as the reference field size. Absolute dose was determined with both TG-51-based dosimetry using a calibrated PTW Semiflex ion chamber and measurements using alanine dosimeters.

RESULTS

The average radiation output factors (maximum deviation from the average) measured with the microDiamond, microSilicon, and W2 detectors were: for the 4 mm cone, 0.741 (1.0%); for the 5 mm cone: 0.817 (1.0%); for the 7.5 mm cone: 0.908 (1.0%); for the 10 mm cone: 0.946 (0.4%); for the 12.5 mm cone: 0.964 (0.2%); for the 15 mm cone: 0.976 (0.1%); for the 20 mm cone: 0.990 (0.1%). For field sizes larger than 10 mm, the A1SL and A16 micro-chambers also yielded consistent output factors within 1.5% of those obtained using the microSilicon, microdiamond, and W2 detectors. The absolute dose measurement obtained with alanine was within 1.2%, consistent with combined uncertainties, compared to the PTW Semiflex chamber for the 25 mm reference cone.

CONCLUSION

For field sizes less than 10 mm, the microSilicon diode, microDiamond detector, and W2 scintillator are suitable devices for accurate small field dosimetry of the ZAP-X system. For larger fields, the A1SL and A16 micro-chambers can also be used. Furthermore, alanine dosimetry can be an accurate verification of reference and absolute dose typically measured with ion chambers. Use of multiple suitable detectors and uncertainty analyses were recommended for reliable determination of small field radiation outputs.

背景

新推出的 ZAP-X 立体定向放射外科系统专为颅内病变治疗而设计，具有几项独特的特点，包括自屏蔽、陀螺仪龙门架、车轮准直、非正交千伏成像、短源轴距和低能量兆伏射线。为确保其安全有效的临床应用，必须对其辐射特性及其他特性进行系统的特征描述。

目的

准确确定 ZAP-X 的辐射输出，特别关注较小直径的准直器，并旨在为小射野剂量学的量化提供有用的建议。

方法

使用六种不同类型的探测器测量从 4 毫米至 25 毫米的射野尺寸的相对输出因子，包括 PTW 微硅和微金刚石二极管、Exradin W2 塑料闪烁体、Exradin A16 和 A1SL 电离室以及丙氨酸剂量计。25 毫米准直器用作参考射野尺寸。使用基于 TG-51 的剂量学通过经过校准的 PTW Semiflex 电离室和使用丙氨酸剂量计进行绝对剂量测量来确定。

结果

使用 microDiamond、microSilicon 和 W2 探测器测量的平均辐射输出因子（平均值的最大偏差）为：4 毫米准直器为 0.741（1.0%）；5 毫米准直器为 0.817（1.0%）；7.5 毫米准直器为 0.908（1.0%）；10 毫米准直器为 0.946（0.4%）；12.5 毫米准直器为 0.964（0.2%）；15 毫米准直器为 0.976（0.1%）；20 毫米准直器为 0.990（0.1%）。对于大于 10 毫米的射野尺寸，A1SL 和 A16 微室的输出因子也在使用 microSilicon、microdiamond 和 W2 探测器获得的输出因子的 1.5%以内。与 25 毫米参考准直器的 PTW Semiflex 腔相比，使用丙氨酸进行的绝对剂量测量的不确定度在 1.2%以内。

结论

对于小于 10 毫米的射野尺寸，microSilicon 二极管、microDiamond 探测器和 W2 闪烁体是 ZAP-X 系统精确小射野剂量学的合适设备。对于较大的射野，A1SL 和 A16 微室也可以使用。此外，丙氨酸剂量计可以作为参考和绝对剂量的精确验证，通常使用电离室进行测量。建议使用多种合适的探测器和不确定性分析，以可靠地确定小射野辐射输出。