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Multi-Site Concordance of Diffusion-Weighted Imaging Quantification for Assessing Prostate Cancer Aggressiveness.
- McGarry, Sean;
- Brehler, Michael;
- Bukowy, John;
- Lowman, Allison;
- Bobholz, Samuel;
- Duenweg, Savannah;
- Banerjee, Anjishnu;
- Hurrell, Sarah;
- Malyarenko, Dariya;
- Chenevert, Thomas;
- Cao, Yue;
- Li, Yuan;
- You, Daekeun;
- Fedorov, Andrey;
- Bell, Laura;
- Quarles, C;
- Prah, Melissa;
- Schmainda, Kathleen;
- Taouli, Bachir;
- LoCastro, Eve;
- Mazaheri, Yousef;
- Shukla-Dave, Amita;
- Yankeelov, Thomas;
- Hormuth, David;
- Madhuranthakam, Ananth;
- Hulsey, Keith;
- Li, Kurt;
- Huang, Wei;
- Huang, Wei;
- Muzi, Mark;
- Jacobs, Michael;
- Solaiyappan, Meiyappan;
- Hectors, Stefanie;
- Antic, Tatjana;
- Paner, Gladell;
- Palangmonthip, Watchareepohn;
- Jacobsohn, Kenneth;
- Hohenwalter, Mark;
- Duvnjak, Petar;
- Griffin, Michael;
- See, William;
- Nevalainen, Marja;
- Iczkowski, Kenneth;
- LaViolette, Peter
- et al.
Published Web Location
https://doi.org/10.1002/jmri.27983Abstract
BACKGROUND: Diffusion-weighted imaging (DWI) is commonly used to detect prostate cancer, and a major clinical challenge is differentiating aggressive from indolent disease. PURPOSE: To compare 14 site-specific parametric fitting implementations applied to the same dataset of whole-mount pathologically validated DWI to test the hypothesis that cancer differentiation varies with different fitting algorithms. STUDY TYPE: Prospective. POPULATION: Thirty-three patients prospectively imaged prior to prostatectomy. FIELD STRENGTH/SEQUENCE: 3 T, field-of-view optimized and constrained undistorted single-shot DWI sequence. ASSESSMENT: Datasets, including a noise-free digital reference object (DRO), were distributed to the 14 teams, where locally implemented DWI parameter maps were calculated, including mono-exponential apparent diffusion coefficient (MEADC), kurtosis (K), diffusion kurtosis (DK), bi-exponential diffusion (BID), pseudo-diffusion (BID*), and perfusion fraction (F). The resulting parametric maps were centrally analyzed, where differentiation of benign from cancerous tissue was compared between DWI parameters and the fitting algorithms with a receiver operating characteristic area under the curve (ROC AUC). STATISTICAL TEST: Levenes test, P < 0.05 corrected for multiple comparisons was considered statistically significant. RESULTS: The DRO results indicated minimal discordance between sites. Comparison across sites indicated that K, DK, and MEADC had significantly higher prostate cancer detection capability (AUC range = 0.72-0.76, 0.76-0.81, and 0.76-0.80 respectively) as compared to bi-exponential parameters (BID, BID*, F) which had lower AUC and greater between site variation (AUC range = 0.53-0.80, 0.51-0.81, and 0.52-0.80 respectively). Post-processing parameters also affected the resulting AUC, moving from, for example, 0.75 to 0.87 for MEADC varying cluster size. DATA CONCLUSION: We found that conventional diffusion models had consistent performance at differentiating prostate cancer from benign tissue. Our results also indicated that post-processing decisions on DWI data can affect sensitivity and specificity when applied to radiological-pathological studies in prostate cancer. LEVEL OF EVIDENCE: 1 TECHNICAL EFFICACY: Stage 3.
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