光子放射治疗中的CT值校准审核

Nakao Minoru, Ozawa Shuichi, Miura Hideharu, Yamada Kiyoshi, Hayata Masahiro, Hayashi Kosuke, Kawahara Daisuke, Nakashima Takeo, Ochi Yusuke, Okumura Takuro, Kunimoto Haruhide, Kawakubo Atsushi, Kusaba Hayate, Nozaki Hiroshige, Habara Kosaku, Tohyama Naoki, Nishio Teiji, Nakamura Mitsuhiro, Minemura Toshiyuki, Okamoto Hiroyuki, Ishikawa Masayori, Kurooka Masahiko, Shimizu Hidetoshi, Hotta Kenji, Saito Masahide, Nakano Masahiro, Tsuneda Masato, Nagata Yasushi

Hiroshima High-Precision Radiotherapy Cancer Center, Hiroshima, Japan.

Department of Radiation Oncology, Graduate School of Biomedical & Health Sciences, Hiroshima University, Hiroshima, Japan.

Med Phys. 2024 Mar;51(3):1571-1582. doi: 10.1002/mp.16887. Epub 2023 Dec 19.

BACKGROUND

Inadequate computed tomography (CT) number calibration curves affect dose calculation accuracy. Although CT number calibration curves registered in treatment planning systems (TPSs) should be consistent with human tissues, it is unclear whether adequate CT number calibration is performed because CT number calibration curves have not been assessed for various types of CT number calibration phantoms and TPSs.

PURPOSE

The purpose of this study was to investigate CT number calibration curves for mass density (ρ) and relative electron density (ρ ).

METHODS

A CT number calibration audit phantom was sent to 24 Japanese photon therapy institutes from the evaluating institute and scanned using their individual clinical CT scan protocols. The CT images of the audit phantom and institute-specific CT number calibration curves were submitted to the evaluating institute for analyzing the calibration curves registered in the TPSs at the participating institutes. The institute-specific CT number calibration curves were created using commercial phantom (Gammex, Gammex Inc., Middleton, WI, USA) or CIRS phantom (Computerized Imaging Reference Systems, Inc., Norfolk, VA, USA)). At the evaluating institute, theoretical CT number calibration curves were created using a stoichiometric CT number calibration method based on the CT image, and the institute-specific CT number calibration curves were compared with the theoretical calibration curve. Differences in ρ and ρ over the multiple points on the curve (Δρ and Δρ , respectively) were calculated for each CT number, categorized for each phantom vendor and TPS, and evaluated for three tissue types: lung, soft tissues, and bones. In particular, the CT-ρ calibration curves for Tomotherapy TPSs (ACCURAY, Sunnyvale, CA, USA) were categorized separately from the Gammex CT-ρ calibration curves because the available tissue-equivalent materials (TEMs) were limited by the manufacturer recommendations. In addition, the differences in ρ and ρ for the specific TEMs (Δρ and Δρ , respectively) were calculated by subtracting the ρ or ρ of the TEMs from the theoretical CT-ρ or CT-ρ calibration curve.

RESULTS

The mean ± standard deviation (SD) of Δρ and Δρ for the Gammex phantom were -1.1 ± 1.2 g/cm and -0.2 ± 1.1, -0.3 ± 0.9 g/cm and 0.8 ± 1.3, and -0.9 ± 1.3 g/cm and 1.0 ± 1.5 for lung, soft tissues, and bones, respectively. The mean ± SD of Δρ and Δρ for the CIRS phantom were 0.3 ± 0.8 g/cm and 0.9 ± 0.9, 0.6 ± 0.6 g/cm and 1.4 ± 0.8, and 0.2 ± 0.5 g/cm and 1.6 ± 0.5 for lung, soft tissues, and bones, respectively. The mean ± SD of Δρ for Tomotherapy TPSs was 2.1 ± 1.4 g/cm for soft tissues, which is larger than those for other TPSs. The mean ± SD of Δρ for the Gammex brain phantom (BRN-SR2) was -1.8 ± 0.4, implying that the tissue equivalency of the BRN-SR2 plug was slightly inferior to that of other plugs.

CONCLUSIONS

Latent deviations between human tissues and TEMs were found by comparing the CT number calibration curves of the various institutes.

背景

计算机断层扫描（CT）数值校准曲线不准确会影响剂量计算的准确性。尽管治疗计划系统（TPS）中记录的CT数值校准曲线应与人体组织一致，但由于尚未针对各种类型的CT数值校准体模和TPS评估CT数值校准曲线，因此尚不清楚是否进行了充分的CT数值校准。

目的

本研究的目的是研究质量密度（ρ）和相对电子密度（ρ ）的CT数值校准曲线。

方法

将一个CT数值校准审核体模从评估机构发送到24家日本光子治疗机构，并使用其各自的临床CT扫描协议进行扫描。审核体模的CT图像和各机构特定的CT数值校准曲线被提交给评估机构，以分析参与机构TPS中记录的校准曲线。各机构特定的CT数值校准曲线是使用商业体模（Gammex，Gammex公司，美国威斯康星州米德尔顿）或CIRS体模（计算机化成像参考系统公司，美国弗吉尼亚州诺福克）创建的。在评估机构，基于CT图像使用化学计量CT数值校准方法创建理论CT数值校准曲线，并将各机构特定的CT数值校准曲线与理论校准曲线进行比较。针对每个CT数值，计算曲线上多个点处ρ和ρ的差异（分别为Δρ和Δρ），按每个体模供应商和TPS进行分类，并针对三种组织类型（肺、软组织和骨骼）进行评估。特别是，由于制造商的建议限制了可用的组织等效材料（TEM），Tomotherapy TPS（美国加利福尼亚州桑尼维尔的ACCURAY公司）的CT-ρ校准曲线与Gammex CT-ρ校准曲线分开分类。此外，通过从理论CT-ρ或CT-ρ校准曲线中减去TEM的ρ或ρ来计算特定TEM的ρ和ρ差异（分别为Δρ和Δρ）。

结果

对于Gammex体模，肺、软组织和骨骼的Δρ和Δρ的平均值±标准差（SD）分别为-1.1±1.2 g/cm和-0.2±1.1、-0.3±0.9 g/cm和0.8±1.3、-0.9±1.3 g/cm和1.0±1.5。对于CIRS体模，肺、软组织和骨骼的Δρ和Δρ的平均值±SD分别为0.3±0.8 g/cm和0.9±0.9、0.6±0.6 g/cm和1.4±0.8、0.2±0.5 g/cm和1.6±0.5。Tomotherapy TPS的软组织Δρ平均值±SD为2.1±1.4 g/cm，大于其他TPS。Gammex脑体模（BRN-SR2）的Δρ平均值±SD为-1.8±0.4, 这意味着BRN-SR2插件的组织等效性略逊于其他插件。