Quantifying pulmonary perfusion from noncontrast computed tomography
| Autor: | Girish B. Nair, Sarah Westergaard, Scott Emerson, Craig W. Stevens, Edward M. Castillo, Nicholas Myziuk, Thomas Guerrero, Yevgeniy Vinogradskiy, Richard Castillo, Sayf Al-Katib, Thomas J. Quinn, Danielle Turner-Lawrence |
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| Jazyk: | angličtina |
| Rok vydání: | 2021 |
| Předmět: |
Lung Neoplasms
Image registration computer.software_genre Spearman's rank correlation coefficient perfusion 030218 nuclear medicine & medical imaging 03 medical and health sciences 0302 clinical medicine Voxel Carcinoma Non-Small-Cell Lung QUANTITATIVE IMAGING AND IMAGE PROCESSING Medicine Sign test Humans Lung volumes Four-Dimensional Computed Tomography deformable image registration Lung Research Articles 4DCT Tomography Emission-Computed Single-Photon business.industry ventilation computed tomography General Medicine Confidence interval 030220 oncology & carcinogenesis Tomography Nuclear medicine business SPECT perfusion Pulmonary Ventilation computer Research Article |
| Zdroj: | Medical Physics |
| ISSN: | 2473-4209 0094-2405 |
| Popis: | PURPOSE Computed tomography (CT)-derived ventilation methods compute respiratory induced volume changes as a surrogate for pulmonary ventilation. Currently, there are no known methods to derive perfusion information from noncontrast CT. We introduce a novel CT-Perfusion (CT-P) method for computing the magnitude mass changes apparent on dynamic noncontrast CT as a surrogate for pulmonary perfusion. METHODS CT-Perfusion is based on a mass conservation model which describes the unknown mass change as a linear combination of spatially corresponding inhale and exhale HU estimated voxel densities. CT-P requires a deformable image registration (DIR) between the inhale/exhale lung CT pair, a preprocessing lung volume segmentation, and an estimate for the Jacobian of the DIR transformation. Given this information, the CT-P image, which provides the magnitude mass change for each voxel within the lung volume, is formulated as the solution to a constrained linear least squares problem defined by a series of subregional mean magnitude mass change measurements. Similar to previous robust CT-ventilation methods, the amount of uncertainty in a subregional sample mean measurement is related to measurement resolution and can be characterized with respect to a tolerance parameter τ . Spatial Spearman correlation between single photon emission CT perfusion (SPECT-P) and the proposed CT-P method was assessed in two patient cohorts via a parameter sweep of τ . The first cohort was comprised of 15 patients diagnosed with pulmonary embolism (PE) who had SPECT-P and 4DCT imaging acquired within 24 h of PE diagnosis. The second cohort was comprised of 15 nonsmall cell lung cancer patients who had SPECT-P and 4DCT images acquired prior to radiotherapy. For each test case, CT-P images were computed for 30 different uncertainty parameter values, uniformly sampled from the range [0.01, 0.125], and the Spearman correlation between the SPECT-P and the resulting CT-P images were computed. RESULTS The median correlations between CT-P and SPECT-P taken over all 30 test cases ranged between 0.49 and 0.57 across the parameter sweep. For the optimal tolerance τ = 0.0385, the CT-P and SPECT-P correlations across all 30 test cases ranged between 0.02 and 0.82. A one-sample sign test was applied separately to the PE and lung cancer cohorts. A low Spearmen correlation of 15% was set as the null median value and two-sided alternative was tested. The PE patients showed a median correlation of 0.57 (IQR = 0.305). One-sample sign test was statistically significant with 96.5 % confidence interval: 0.20-0.63, P |
| Databáze: | OpenAIRE |
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