{"title":"Clinical boundary conditions for propagation-based X-ray phase contrast imaging: from bio-sample models targeting to clinical applications.","authors":"M S S Gobo, D R Balbin, M G Hönnicke, M E Poletti","doi":"10.3233/XST-230425","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>Typical propagation-based X-ray phase contrast imaging (PB-PCI) experiments using polyenergetic sources are tested in very ideal conditions: low-energy spectrum (mainly characteristic X-rays), small thickness and homogeneous materials considered weakly absorbing objects, large object-to-detector distance, long exposure times and non-clinical detector.</p><p><strong>Objective: </strong>Explore PB-PCI features using boundary conditions imposed by a low power polychromatic X-ray source (X-ray spectrum without characteristic X-rays), thick and heterogenous materials and a small area imaging detector with high low-detection radiation threshold, elements commonly found in a clinical scenario.</p><p><strong>Methods: </strong>A PB-PCI setup implemented using a microfocus X-ray source and a dental imaging detector was characterized in terms of different spectra and geometric parameters on the acquired images. Test phantoms containing fibers and homogeneous materials with close attenuation characteristics and animal bone and mixed soft tissues (bio-sample models) were analyzed. Contrast to Noise Ratio (CNR), system spatial resolution and Kerma values were obtained for all images.</p><p><strong>Results: </strong>Phase contrast images showed CNR up to 15% higher than conventional contact images. Moreover, it is better seen when large magnifications (>3) and object-to-detector distances (>13 cm) were used. The influence of the spectrum was not appreciable due to the low efficiency of the detector (thin scintillator screen) at high energies.</p><p><strong>Conclusions: </strong>Despite the clinical boundary condition used in this work, regarding the X-ray spectrum, thick samples, and detection system, it was possible to acquire phase contrast images of biological samples.</p>","PeriodicalId":49948,"journal":{"name":"Journal of X-Ray Science and Technology","volume":" ","pages":"1163-1175"},"PeriodicalIF":1.7000,"publicationDate":"2024-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of X-Ray Science and Technology","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.3233/XST-230425","RegionNum":3,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"INSTRUMENTS & INSTRUMENTATION","Score":null,"Total":0}
引用次数: 0
Abstract
Background: Typical propagation-based X-ray phase contrast imaging (PB-PCI) experiments using polyenergetic sources are tested in very ideal conditions: low-energy spectrum (mainly characteristic X-rays), small thickness and homogeneous materials considered weakly absorbing objects, large object-to-detector distance, long exposure times and non-clinical detector.
Objective: Explore PB-PCI features using boundary conditions imposed by a low power polychromatic X-ray source (X-ray spectrum without characteristic X-rays), thick and heterogenous materials and a small area imaging detector with high low-detection radiation threshold, elements commonly found in a clinical scenario.
Methods: A PB-PCI setup implemented using a microfocus X-ray source and a dental imaging detector was characterized in terms of different spectra and geometric parameters on the acquired images. Test phantoms containing fibers and homogeneous materials with close attenuation characteristics and animal bone and mixed soft tissues (bio-sample models) were analyzed. Contrast to Noise Ratio (CNR), system spatial resolution and Kerma values were obtained for all images.
Results: Phase contrast images showed CNR up to 15% higher than conventional contact images. Moreover, it is better seen when large magnifications (>3) and object-to-detector distances (>13 cm) were used. The influence of the spectrum was not appreciable due to the low efficiency of the detector (thin scintillator screen) at high energies.
Conclusions: Despite the clinical boundary condition used in this work, regarding the X-ray spectrum, thick samples, and detection system, it was possible to acquire phase contrast images of biological samples.
背景:使用多能源的典型传播型 X 射线相衬成像(PB-PCI)实验是在非常理想的条件下进行测试的:低能量光谱(主要是特征 X 射线)、被认为是弱吸收物体的小厚度和均质材料、物体到探测器的大距离、长曝光时间和非临床探测器:利用低功率多色 X 射线源(X 射线光谱无特征 X 射线)、厚而异质的材料以及具有高低检测辐射阈值的小面积成像探测器(这些元素通常在临床场景中发现)所施加的边界条件,探索 PB-PCI 的特征:方法:利用微聚焦 X 射线源和牙科成像探测器实施 PB-PCI 设置,根据所获图像的不同光谱和几何参数对其进行表征。对包含纤维和具有接近衰减特性的均质材料的测试模型以及动物骨骼和混合软组织(生物样本模型)进行了分析。获得了所有图像的对比度与噪声比(CNR)、系统空间分辨率和 Kerma 值:结果:相位对比图像显示的 CNR 比传统接触式图像高出 15%。此外,当放大倍数(大于 3 倍)和物体到探测器的距离(大于 13 厘米)较大时,相位对比度更高。由于探测器(薄闪烁屏)在高能量时效率较低,光谱的影响并不明显:尽管这项研究在 X 射线光谱、厚样本和检测系统方面采用了临床边界条件,但仍有可能获得生物样本的相衬图像。
期刊介绍:
Research areas within the scope of the journal include:
Interaction of x-rays with matter: x-ray phenomena, biological effects of radiation, radiation safety and optical constants
X-ray sources: x-rays from synchrotrons, x-ray lasers, plasmas, and other sources, conventional or unconventional
Optical elements: grazing incidence optics, multilayer mirrors, zone plates, gratings, other diffraction optics
Optical instruments: interferometers, spectrometers, microscopes, telescopes, microprobes