Nute Jessica L, Jacobsen Megan C, Chandler Adam, Cody Dianna D, Schellingerhout Dawid
From the *The University of Texas Graduate School of Biomedical Sciences at Houston; †The University of Texas MD Anderson Cancer Center, Houston, TX; ‡GE Healthcare, Waukesha, WI; Departments of §Imaging Physics, ∥Diagnostic Radiology, and ¶Cancer Systems Imaging, The University of Texas MD Anderson Cancer Center, Houston, TX.
Invest Radiol. 2017 Jan;52(1):30-41. doi: 10.1097/RLI.0000000000000300.
The aim of this study was to develop a diagnostic framework for distinguishing calcific from hemorrhagic cerebral lesions using dual-energy computed tomography (DECT) in an anthropomorphic phantom system.
An anthropomorphic phantom was designed to mimic the CT imaging characteristics of the human head. Cylindrical lesion models containing either calcium or iron, mimicking calcification or hemorrhage, respectively, were developed to exhibit matching, and therefore indistinguishable, single-energy CT (SECT) attenuation values from 40 to 100 HU. These lesion models were fabricated at 0.5, 1, and 1.5 cm in diameter and positioned in simulated cerebrum and skull base locations within the anthropomorphic phantom. All lesion sizes were modeled in the cerebrum, while only 1.5-cm lesions were modeled in the skull base. Images were acquired using a GE 750HD CT scanner and an expansive dual-energy protocol that covered variations in dose (36.7-132.6 mGy CTDIvol, n = 12), image thickness (0.625-5 mm, n = 4), and reconstruction filter (soft, standard, detail, n = 3) for a total of 144 unique technique combinations. Images representing each technique combination were reconstructed into water and calcium material density images, as well as a monoenergetic image chosen to mimic the attenuation of a 120-kVp SECT scan. A true single-energy routine brain protocol was also included for verification of lesion SECT attenuation. Points representing the 3 dual-energy reconstructions were plotted into a 3-dimensional space (water [milligram/milliliter], calcium [milligram/milliliter], monoenergetic Hounsfield unit as x, y, and z axes, respectively), and the distribution of points analyzed using 2 approaches: support vector machines and a simple geometric bisector (GB). Each analysis yielded a plane of optimal differentiation between the calcification and hemorrhage lesion model distributions. By comparing the predicted lesion composition to the known lesion composition, we identified the optimal combination of CTDIvol, image thickness, and reconstruction filter to maximize differentiation between the lesion model types. To validate these results, a new set of hemorrhage and calcification lesion models were created, scanned in a blinded fashion, and prospectively classified using the planes of differentiation derived from support vector machine and GB methods.
Accuracy of differentiation improved with increasing dose (CTDIvol) and image thickness. Reconstruction filter had no effect on the accuracy of differentiation. Using an optimized protocol consisting of the maximum CTDIvol of 132.6 mGy, 5-mm-thick images, and a standard filter, hemorrhagic and calcific lesion models with equal SECT attenuation (Hounsfield unit) were differentiated with over 90% accuracy down to 70 HU for skull base lesions of 1.5 cm, and down to 100 HU, 60 HU, and 60 HU for cerebrum lesions of 0.5, 1.0, and 1.5 cm, respectively. The analytic method that yielded the best results was a simple GB plane through the 3-dimensional DECT space. In the validation study, 96% of unknown lesions were correctly classified across all lesion sizes and locations investigated.
We define the optimal scan parameters and expected limitations for the accurate classification of hemorrhagic versus calcific cerebral lesions in an anthropomorphic phantom with DECT. Although our proposed DECT protocol represents an increase in dose compared with routine brain CT, this method is intended as a specialized evaluation of potential brain hemorrhage and is thus counterbalanced by increased diagnostic benefit. This work provides justification for the application of this technique in human clinical trials.
本研究的目的是在拟人化体模系统中使用双能计算机断层扫描(DECT)开发一种区分钙化性和出血性脑病变的诊断框架。
设计了一个拟人化体模以模拟人类头部的CT成像特征。分别开发了含有钙或铁的圆柱形病变模型,分别模拟钙化或出血,以呈现匹配的单能CT(SECT)衰减值,范围为40至100HU,因此难以区分。这些病变模型的直径分别为0.5、1和1.5cm,并放置在拟人化体模内的模拟大脑和颅底位置。所有病变大小均在大脑中建模,而仅在颅底建模1.5cm的病变。使用GE 750HD CT扫描仪和扩展双能协议采集图像,该协议涵盖了剂量变化(36.7 - 132.6 mGy CTDIvol,n = 12)、图像厚度(0.625 - 5mm,n = 4)和重建滤波器(软组织、标准、细节,n = 3),共有144种独特的技术组合。将代表每种技术组合的图像重建为水和钙物质密度图像,以及选择用于模拟120 kVp SECT扫描衰减的单能图像。还包括一个真正的单能常规脑协议以验证病变的SECT衰减。将代表3种双能重建的点绘制到三维空间(水[毫克/毫升]、钙[毫克/毫升]、单能亨氏单位分别作为x、y和z轴),并使用两种方法分析点的分布:支持向量机和简单几何平分线(GB)。每种分析都得出了钙化和出血病变模型分布之间的最佳区分平面。通过将预测的病变成分与已知的病变成分进行比较,我们确定了CTDIvol、图像厚度和重建滤波器的最佳组合,以最大限度地区分病变模型类型。为了验证这些结果,创建了一组新的出血和钙化病变模型,以盲法进行扫描,并使用从支持向量机和GB方法得出的区分平面进行前瞻性分类。
随着剂量(CTDIvol)和图像厚度的增加,区分的准确性提高。重建滤波器对区分的准确性没有影响。使用由最大CTDIvol为132.6 mGy、5mm厚图像和标准滤波器组成的优化协议,对于1.5cm的颅底病变,具有相等SECT衰减(亨氏单位)的出血性和钙化性病变模型的区分准确率超过90%,对于0.5、1.0和1.5cm的大脑病变,分别低至70HU、100HU、60HU和60HU。产生最佳结果的分析方法是通过三维DECT空间的简单GB平面。在验证研究中,在所有研究的病变大小和位置上,96% 的未知病变被正确分类。
我们定义了在拟人化体模中使用DECT准确分类出血性与钙化性脑病变的最佳扫描参数和预期局限性。尽管我们提出的DECT协议与常规脑CT相比剂量有所增加,但该方法旨在对潜在的脑出血进行专门评估,因此增加的诊断益处可抵消这一影响。这项工作为该技术在人体临床试验中的应用提供了依据。
