Department of Transdisciplinary Studies, Graduate School of Convergence Science and Technology, Program in Biomedical Radiation Sciences, Seoul National University, Seoul, 08826, Korea.
Isotope Production Division, Pakistan Institute of Nuclear Science and Technology, Nilore, Islamabad, 44000, Pakistan.
Med Phys. 2019 Nov;46(11):5238-5248. doi: 10.1002/mp.13778. Epub 2019 Sep 13.
Micrometer spatial resolution dosimetry has become inevitable for advanced radiotherapy techniques. A new approach using radiochromic films was developed to measure a radiation dose at a micrometer spatial resolution by confocal Raman spectroscopy.
The commercial radiochromic films (RCF), EBT3 and EBT-XD, were irradiated with known doses using 50, 100, 200, and 300 kVp, and 6-MV x rays. The dose levels ranged from 0.3 to 50 Gy. The Raman mapping technique developed in our early study was used to readout an area of 100 × 100 µm on RCF with improved lateral and depth resolutions with confocal Raman spectrometry. The variation in Raman spectra of C-C-C deformation and C≡C stretching modes of diacetylene polymers around 676 and 2060 cm , respectively, as a function of therapeutic x-ray doses, was measured. The single peak (SP) of C≡C and the peak ratio (PR) of C≡C band height to C-C-C band height with a spatial resolution of 10 µm on both types of RCF were evaluated, averaged, and plotted as a function of dose. An achievable spatial resolution, clinically useful dose range, dosimetric sensitivity, dose uniformity, and postirradiation stability as well as the orientation, energy, and dose rate dependence, of both types of RCFs, were characterized by the technique developed in this study.
A spatial resolution on RCF achieved by SP and PR methods was ~4.5 and ~2.9 µm, respectively. Raman spectroscopy data showed dose nonuniformity of ~11% in SP method and <3% in PR method. The SP method provided dose ranges of up to ~10 and ~20 Gy for EBT3 and EBT-XD films, respectively while the PR method up to ~30 and ~50 Gy. The PR method diminished the orientation effect. The percent difference between landscape and portrait orientations for the EBT3 and the EBT-XD films at 4 Gy had an acceptable level of 1.2% and 2.4%, respectively. With both SP and PR methods, the EBT3 and the EBT-XD films showed weak energy (within ~10% and ~3% for SP and PR methods, respectively) and dose rate dependence (within ~5% and ~3% for SP and PR methods, respectively) and had a stable response after 24-h postirradiation.
A technique for micrometer-resolution dosimetry was successfully developed by detecting radiation-induced Raman shift on EBT3 and EBT-XD. Both types of RCFs were suitable for micrometer-resolution dosimetry using CRS. With CRS both lateral and depth resolutions on RCF were improved. The PR method provided superior characteristics in dose uniformity, dose ranges, orientation dependence, and laser effect for both types of RCFs. The overall dosimetric characteristics of the RCFs determined by this technique were similar to those known by optical density scanning. The CRS with the PR method is advantageous over other the traditional scanning systems as a spatial resolution of <10 µm on RCF can be achieved with less deviations.
微米空间分辨率剂量测量对于先进的放疗技术来说已经是必不可少的了。本研究开发了一种新的方法,使用具有共焦拉曼光谱的放射色迹胶片来测量微米空间分辨率下的辐射剂量。
使用 50、100、200 和 300 kVp 和 6 MV X 射线对商用放射色迹胶片(RCF)EBT3 和 EBT-XD 进行已知剂量照射。剂量水平从 0.3 到 50 Gy 不等。我们早期研究中开发的拉曼映射技术用于读出 RCF 上 100×100 µm 的区域,具有改进的横向和深度分辨率,使用共焦拉曼光谱仪。测量了二乙炔聚合物 C-C-C 变形和 C≡C 伸缩模式的喇曼光谱随治疗 X 射线剂量的变化,其分别位于 676 和 2060 cm-1 附近。评估了两种 RCF 上的 C≡C 单峰(SP)和 C≡C 带高与 C-C-C 带高的峰比(PR),空间分辨率为 10 µm,对两种 RCF 进行了平均和绘图作为剂量的函数。通过本研究中开发的技术,对两种 RCF 的可实现空间分辨率、临床有用剂量范围、剂量灵敏度、剂量均匀性、辐照后稳定性以及方向、能量和剂量率依赖性进行了表征。
SP 和 PR 方法在 RCF 上实现的空间分辨率分别约为 4.5 µm 和 2.9 µm。喇曼光谱数据显示 SP 方法的剂量不均匀性约为 11%,PR 方法的剂量不均匀性小于 3%。SP 方法分别为 EBT3 和 EBT-XD 胶片提供了高达约 10 和 20 Gy 的剂量范围,而 PR 方法分别高达约 30 和 50 Gy。PR 方法减弱了方向效应。EBT3 和 EBT-XD 胶片在 4 Gy 时的景观和 portrait 方向之间的百分差分别具有可接受的 1.2%和 2.4%水平。使用 SP 和 PR 方法,EBT3 和 EBT-XD 胶片在能量方面表现出较弱的依赖性(分别在 SP 和 PR 方法中约为 10%和 3%)和剂量率依赖性(分别在 SP 和 PR 方法中约为 5%和 3%),并且在辐照后 24 小时具有稳定的响应。
通过检测 EBT3 和 EBT-XD 上的放射致喇曼位移,成功开发了用于微米分辨率剂量测量的技术。两种类型的 RCF 都适合使用 CRS 进行微米分辨率剂量测量。使用 CRS 可以提高 RCF 的横向和深度分辨率。PR 方法在两种 RCF 的剂量均匀性、剂量范围、方向依赖性和激光效应方面提供了更好的特性。该技术确定的 RCF 整体剂量特性与通过光学密度扫描所了解的特性相似。与其他传统扫描系统相比,具有 PR 方法的 CRS 具有优势,因为可以在较小偏差的情况下在 RCF 上实现<10 µm 的空间分辨率。
