Yannick Kuhl, Florian Mueller, Julian Thull, Stephan Naunheim, David Schug, Volkmar Schulz
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However, complex positioning calibration processes limit their use in PET systems, especially in large-scale clinical systems.</p>\n </section>\n \n <section>\n \n <h3> Purpose</h3>\n \n <p>This work proposes a new 3D positioning in-system calibration method for fast and convenient (re-)calibration and quality control of assembled PET scanners. The method targets all kinds of PET detectors that achieve the best performance with individual calibration, including complex segmented detector designs. The in-system calibration method is evaluated and empirically compared to a state-of-the-art fan-beam calibration for a small-diameter proof of concept (PoC) scanner. A simulation study evaluates the method's applicability to different scanner geometries.</p>\n </section>\n \n <section>\n \n <h3> Methods</h3>\n \n <p>A PoC scanner geometry of 120 mm inner diameter and 150 mm axial extent was set up consisting of five identical finely segmented slab detectors (one detector under test and four collimation detectors). A <sup>2</sup><sup>2</sup>Na point source was moved in a circular path inside the FoV. Utilizing virtual collimation and by selecting gamma rays incident approximately perpendicular to the detector normal of the detector under test, training data was created for the training of a 2D positioning model with the machine-learning technique gradient tree boosting (GTB). Data with oblique ray angles was acquired in the same measurement for subsequent angular DOI calibration. For this, a 2D position estimate in the detector under test was calculated first. On this basis, the DOI label was calculated geometrically from the ray path within the detector to finally establish up to 3D training data.</p>\n </section>\n \n <section>\n \n <h3> Results</h3>\n \n <p>With a mean absolute error (MAE) of 0.8 and 1.19 mm full-width at half maximum (FWHM) along the planar-monolithic slab dimension, the in-system methods performed similarly within 1% to the fan-beam collimator results. The DOI performance was at ∼90% with 1.13 mm MAE and 2.47 mm FWHM to the fan-beam collimator. Analytical calculations suggest an improved performance for larger scanner geometries.</p>\n </section>\n \n <section>\n \n <h3> Conclusion</h3>\n \n <p>The functionality of the 3D in-system positioning calibration method was successfully demonstrated with the measurements within a PoC scanner configuration with similar positioning performance as the bench-top fan-beam setup. The in-system calibration method can be used to calibrate and test fully assembled PET systems to enable more complex light-sharing detector architectures in, for example, large PET systems with many detectors. The acquired data can further be used for more complex energy and time calibrations.</p>\n </section>\n </div>","PeriodicalId":18384,"journal":{"name":"Medical physics","volume":"52 1","pages":"232-245"},"PeriodicalIF":3.2000,"publicationDate":"2024-11-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11699997/pdf/","citationCount":"0","resultStr":"{\"title\":\"3D in-system calibration method for PET detectors\",\"authors\":\"Yannick Kuhl, Florian Mueller, Julian Thull, Stephan Naunheim, David Schug, Volkmar Schulz\",\"doi\":\"10.1002/mp.17475\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div>\\n \\n \\n <section>\\n \\n <h3> Background</h3>\\n \\n <p>Light-sharing detector designs for positron emission tomography (PET) systems have sparked interest in the scientific community. Particularly, (semi-)monoliths show generally good performance characteristics regarding 2D positioning, energy-, and timing resolution, as well as readout area. This is combined with intrinsic depth-of-interaction (DOI) capability to ensure a homogeneous spatial resolution across the entire field of view (FoV). However, complex positioning calibration processes limit their use in PET systems, especially in large-scale clinical systems.</p>\\n </section>\\n \\n <section>\\n \\n <h3> Purpose</h3>\\n \\n <p>This work proposes a new 3D positioning in-system calibration method for fast and convenient (re-)calibration and quality control of assembled PET scanners. The method targets all kinds of PET detectors that achieve the best performance with individual calibration, including complex segmented detector designs. The in-system calibration method is evaluated and empirically compared to a state-of-the-art fan-beam calibration for a small-diameter proof of concept (PoC) scanner. A simulation study evaluates the method's applicability to different scanner geometries.</p>\\n </section>\\n \\n <section>\\n \\n <h3> Methods</h3>\\n \\n <p>A PoC scanner geometry of 120 mm inner diameter and 150 mm axial extent was set up consisting of five identical finely segmented slab detectors (one detector under test and four collimation detectors). A <sup>2</sup><sup>2</sup>Na point source was moved in a circular path inside the FoV. Utilizing virtual collimation and by selecting gamma rays incident approximately perpendicular to the detector normal of the detector under test, training data was created for the training of a 2D positioning model with the machine-learning technique gradient tree boosting (GTB). Data with oblique ray angles was acquired in the same measurement for subsequent angular DOI calibration. For this, a 2D position estimate in the detector under test was calculated first. 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The in-system calibration method can be used to calibrate and test fully assembled PET systems to enable more complex light-sharing detector architectures in, for example, large PET systems with many detectors. 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引用次数: 0
摘要
背景:正电子发射断层扫描(PET)系统的分光探测器设计引发了科学界的兴趣。特别是(半)单片探测器在二维定位、能量和时间分辨率以及读出面积方面显示出普遍良好的性能特点。这种性能与固有的交互深度(DOI)能力相结合,确保了整个视场(FoV)的均匀空间分辨率。然而,复杂的定位校准过程限制了它们在 PET 系统中的使用,尤其是在大型临床系统中。目的:这项工作提出了一种新的三维定位系统内校准方法,用于快速、方便地(重新)校准和质量控制组装好的 PET 扫描仪。该方法针对各种通过单独校准实现最佳性能的 PET 探测器,包括复杂的分段探测器设计。对系统内校准方法进行了评估,并将其与小口径概念验证(PoC)扫描仪的最先进扇形光束校准方法进行了实证比较。模拟研究评估了该方法对不同扫描仪几何形状的适用性:方法:建立了一个内径 120 毫米、轴向范围 150 毫米的 PoC 扫描仪几何结构,由五个相同的精细分割平板探测器(一个被测探测器和四个准直探测器)组成。一个 2 2Na 点源在 FoV 内沿环形路径移动。利用虚拟准直技术,选择大约垂直于被测探测器法线的伽马射线入射,创建了训练数据,以便利用机器学习技术梯度树增强(GTB)训练二维定位模型。在同一次测量中还获取了斜射线角度的数据,用于后续的角度 DOI 校准。为此,首先要计算出被测探测器的二维位置估计值。在此基础上,根据探测器内的射线路径以几何方式计算 DOI 标签,最终建立三维训练数据:结果:系统内方法的平均绝对误差(MAE)为 0.8,沿平面-单片板尺寸的半最大全宽(FWHM)分别为 1.19 毫米,与扇形光束准直器的结果相差 1%。扇形光束准直器的 DOI 性能为 1.13 mm MAE 和 2.47 mm FWHM,与扇形光束准直器相比,DOI 性能达到了 ∼ 90%。分析计算表明,扫描仪的几何尺寸越大,性能越好:通过在 PoC 扫描仪配置中进行测量,成功展示了三维系统内定位校准方法的功能,其定位性能与台式扇形光束装置类似。系统内校准方法可用于校准和测试完全组装好的 PET 系统,以便在具有许多探测器的大型 PET 系统中实现更复杂的光共享探测器结构。获取的数据可进一步用于更复杂的能量和时间校准。
Light-sharing detector designs for positron emission tomography (PET) systems have sparked interest in the scientific community. Particularly, (semi-)monoliths show generally good performance characteristics regarding 2D positioning, energy-, and timing resolution, as well as readout area. This is combined with intrinsic depth-of-interaction (DOI) capability to ensure a homogeneous spatial resolution across the entire field of view (FoV). However, complex positioning calibration processes limit their use in PET systems, especially in large-scale clinical systems.
Purpose
This work proposes a new 3D positioning in-system calibration method for fast and convenient (re-)calibration and quality control of assembled PET scanners. The method targets all kinds of PET detectors that achieve the best performance with individual calibration, including complex segmented detector designs. The in-system calibration method is evaluated and empirically compared to a state-of-the-art fan-beam calibration for a small-diameter proof of concept (PoC) scanner. A simulation study evaluates the method's applicability to different scanner geometries.
Methods
A PoC scanner geometry of 120 mm inner diameter and 150 mm axial extent was set up consisting of five identical finely segmented slab detectors (one detector under test and four collimation detectors). A 22Na point source was moved in a circular path inside the FoV. Utilizing virtual collimation and by selecting gamma rays incident approximately perpendicular to the detector normal of the detector under test, training data was created for the training of a 2D positioning model with the machine-learning technique gradient tree boosting (GTB). Data with oblique ray angles was acquired in the same measurement for subsequent angular DOI calibration. For this, a 2D position estimate in the detector under test was calculated first. On this basis, the DOI label was calculated geometrically from the ray path within the detector to finally establish up to 3D training data.
Results
With a mean absolute error (MAE) of 0.8 and 1.19 mm full-width at half maximum (FWHM) along the planar-monolithic slab dimension, the in-system methods performed similarly within 1% to the fan-beam collimator results. The DOI performance was at ∼90% with 1.13 mm MAE and 2.47 mm FWHM to the fan-beam collimator. Analytical calculations suggest an improved performance for larger scanner geometries.
Conclusion
The functionality of the 3D in-system positioning calibration method was successfully demonstrated with the measurements within a PoC scanner configuration with similar positioning performance as the bench-top fan-beam setup. The in-system calibration method can be used to calibrate and test fully assembled PET systems to enable more complex light-sharing detector architectures in, for example, large PET systems with many detectors. The acquired data can further be used for more complex energy and time calibrations.
期刊介绍:
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