Technical Note: Design and implementation of a high-throughput pipeline for reconstruction and quantitative analysis of CT image data.

PURPOSE With recent substantial improvements in modern computing, interest in quantitative imaging with CT has seen a dramatic increase. As a result, the need to both create and analyze large, high-quality datasets of clinical studies has increased as well. At present, no efficient, widely available method exists to accomplish this. The purpose of this technical note is to describe an open-source high-throughput computational pipeline framework for the reconstruction and analysis of diagnostic CT imaging data to conduct large-scale quantitative imaging studies and to accelerate and improve quantitative imaging research. METHODS The pipeline consists of two, primary "blocks": reconstruction and analysis. Reconstruction is carried out via a graphics processing unit (GPU) queuing framework developed specifically for the pipeline that allows a dataset to be reconstructed using a variety of different parameter configurations such as slice thickness, reconstruction kernel, and simulated acquisition dose. The analysis portion then automatically analyzes the output of the reconstruction using "modules" that can be combined in various ways to conduct different experiments. Acceleration of analysis is achieved using cluster processing. Efficiency and performance of the pipeline are demonstrated using an example 142 subject lung screening cohort reconstructed 36 different ways and analyzed using quantitative emphysema scoring techniques. RESULTS The pipeline reconstructed and analyzed the 5112 reconstructed datasets in approximately 10 days, a roughly 72× speedup over previous efforts using the scanner for reconstructions. Tightly coupled pipeline quality assurance software ensured proper performance of analysis modules with regard to segmentation and emphysema scoring. CONCLUSIONS The pipeline greatly reduced the time from experiment conception to quantitative results. The modular design of the pipeline allows the high-throughput framework to be utilized for other future experiments into different quantitative imaging techniques. Future applications of the pipeline being explored are robustness testing of quantitative imaging metrics, data generation for deep learning, and use as a test platform for image-processing techniques to improve clinical quantitative imaging.

[1]  Jonathan G Goldin,et al.  Emphysema: effect of reconstruction algorithm on CT imaging measures. , 2004, Radiology.

[2]  Richard C. Pais,et al.  The Lung Image Database Consortium (LIDC) and Image Database Resource Initiative (IDRI): a completed reference database of lung nodules on CT scans. , 2011, Medical physics.

[3]  Michael F. McNitt-Gray,et al.  Assessing nodule detection on lung cancer screening CT: the effects of tube current modulation and model observer selection on detectability maps , 2016, SPIE Medical Imaging.

[4]  Pechin Lo,et al.  The effect of radiation dose reduction on computer‐aided detection (CAD) performance in a low‐dose lung cancer screening population , 2017, Medical physics.

[5]  Adam Wunderlich,et al.  Evaluation of the impact of tube current modulation on lesion detectability using model observers , 2008, 2008 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[6]  Qiu Wang,et al.  A low dose simulation tool for CT systems with energy integrating detectors. , 2013, Medical physics.

[7]  Takeshi Yoshikawa,et al.  Emphysema quantification by low-dose CT: potential impact of adaptive iterative dose reduction using 3D processing. , 2012, AJR. American journal of roentgenology.

[8]  Kyle J Myers,et al.  Task-based measures of image quality and their relation to radiation dose and patient risk , 2015, Physics in medicine and biology.

[9]  John Hoffman,et al.  Characterizing and Minimizing the Impacts of Diagnostic Computed Tomography Acquisition and Reconstruction Parameter Selection on Quantitative Emphysema Scoring , 2018 .

[10]  Ehsan Samei,et al.  A generic framework to simulate realistic lung, liver and renal pathologies in CT imaging , 2014, Physics in medicine and biology.

[11]  Leticia Gallardo-Estrella,et al.  Normalized emphysema scores on low dose CT: Validation as an imaging biomarker for mortality , 2017, PloS one.

[12]  F Noo,et al.  TH-AB-207A-09: Tailoring TCM Schemes to a Task: Evaluating the Impact of Customized TCM Profiles On Detection of Lung Nodules in Simulated CT Lung Cancer Screening. , 2016, Medical physics.

[13]  Rongping Zeng,et al.  Seamless Insertion of Pulmonary Nodules in Chest CT Images , 2015, IEEE Transactions on Biomedical Engineering.

[14]  Feng Lin,et al.  Low-Dose CT With a Residual Encoder-Decoder Convolutional Neural Network , 2017, IEEE Transactions on Medical Imaging.

[15]  Xinhui Duan,et al.  Technical Note: Development and validation of an open data format for CT projection data. , 2015, Medical physics.

[16]  Frédéric Noo,et al.  Technical Note: FreeCT_ICD: An open‐source implementation of a model‐based iterative reconstruction method using coordinate descent optimization for CT imaging investigations , 2018, Medical physics.

[17]  Eran A Barnoy,et al.  Toward clinically usable CAD for lung cancer screening with computed tomography , 2014, European Radiology.

[18]  Jin Hwan Kim,et al.  Comparison of standard- and low-radiation-dose CT for quantification of emphysema. , 2007, AJR. American journal of roentgenology.

[19]  M. Prokop,et al.  The effect of iterative reconstruction on computed tomography assessment of emphysema, air trapping and airway dimensions , 2012, European Radiology.

[20]  M. McNitt-Gray,et al.  Variability in CT lung-nodule volumetry: Effects of dose reduction and reconstruction methods. , 2015, Medical physics.

[21]  Jason C Woods,et al.  Effects of CT section thickness and reconstruction kernel on emphysema quantification relationship to the magnitude of the CT emphysema index. , 2010, Academic radiology.

[22]  M. Roizen Reduced Lung-Cancer Mortality with Low-Dose Computed Tomographic Screening , 2012 .

[23]  N. Müller,et al.  "Density mask". An objective method to quantitate emphysema using computed tomography. , 1988, Chest.

[24]  John Hoffman,et al.  Technical Note: FreeCT_wFBP: A robust, efficient, open-source implementation of weighted filtered backprojection for helical, fan-beam CT. , 2016, Medical physics.

[25]  Jin Mo Goo,et al.  Quantitative analysis of emphysema and airway measurements according to iterative reconstruction algorithms: comparison of filtered back projection, adaptive statistical iterative reconstruction and model-based iterative reconstruction , 2014, European Radiology.

[26]  Philip F. Judy,et al.  Normalizing computed tomography data reconstructed with different filter kernels: effect on emphysema quantification , 2015, European Radiology.