Combination of Peri-Tumoral and Intra-Tumoral Radiomic Features on Bi-Parametric MRI Accurately Stratifies Prostate Cancer Risk: A Multi-Site Study

Algohary, Ahmad; Shiradkar, Rakesh; Pahwa, Shivani; Purysko, Andrei S.; Verma, Sadhna; Moses, Daniel; Shnier, Ron; Haynes, Anne‐Maree; Delprado, Warick; Thompson, James; Tirumani, Sree H.; Mahran, Amr; Rastinehad, Ardeshir R.; Ponsky, Lee; Stricker, Phillip D.; Madabhushi, Anant

doi:10.3390/cancers12082200

Cited by 55 publications

(75 citation statements)

References 37 publications

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“…Patch-based deep learning approaches using convolutional neural networks have been used to detect and characterise prostate cancer; 17,18 however, these studies did not make use of important information in the peritumoural region, which has been shown to improve disease characterisation and classification performance. 15,16,26 Algohary and colleagues 19 showed the benefit of extracting radiomic representations from peritumoural regions along with intratumoural regions. They highlighted the differences in concentration of epithelial cells and lymphocytes between low-risk and high-risk regions by mapping the representative peritumoural regions on biparametric MRI to the whole-mount pathology slides.…”

Section: Discussionmentioning

confidence: 99%

“…We aimed to construct an integrated nomogram (referred to as ClaD) combining deep learning-based imaging predictions, PI-RADS scoring, and clinical variables using multivariable logistic regression to identify clinically significant prostate cancer on biparametric MRI. Since previous research 19 has suggested the importance of the peritumoural region for characterisation of prostate cancer on biparametric MRI, we explored multiple input configurations of the deep learning network, with patches extracted at different scales and each subsequent scale incorporating additional information from the peritumoural region.…”

Section: Implications Of All the Available Evidencementioning

confidence: 99%

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An integrated nomogram combining deep learning, Prostate Imaging–Reporting and Data System (PI-RADS) scoring, and clinical variables for identification of clinically significant prostate cancer on biparametric MRI: a retrospective multicentre study

Hiremath

Shiradkar

et al. 2021

The Lancet Digital Health

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Background Biparametric MRI (comprising T2-weighted MRI and apparent diffusion coefficient maps) is increasingly being used to characterise prostate cancer. Although previous studies have combined Prostate Imaging-Reporting & Data System (PI-RADS)-based MRI findings with routinely available clinical variables and with deep learning-based imaging predictors, respectively, for prostate cancer risk stratification, none have combined all three. We aimed to construct an integrated nomogram (referred to as ClaD) combining deep learning-based imaging predictions, PI-RADS scoring, and clinical variables to identify clinically significant prostate cancer on biparametric MRI.Methods In this retrospective multicentre study, we included patients with prostate cancer, with histopathology or biopsy reports and a screening or diagnostic MRI scan in the axial view, from four cohorts in the USA (from University Hospitals Cleveland Medical Center, Icahn School of Medicine at Mount Sinai, Cleveland Clinic, and Long Island Jewish Medical Center) and from the PROSTATEx Challenge dataset in the Netherlands. We constructed an integrated nomogram combining deep learning, PI-RADS score, and clinical variables (prostate-specific antigen, prostate volume, and lesion volume) using multivariable logistic regression to identify clinically significant prostate cancer on biparametric MRI. We used data from the first three cohorts to train the nomogram and data from the remaining two cohorts for independent validation. We compared the performance of our ClaD integrated nomogram with that of integrated nomograms combining clinical variables with either the deep learning-based imaging predictor (referred to as DIN) or PI-RADS score (referred to as PIN) using area under the receiver operating characteristic curves (AUCs). We also compared the ability of the nomograms to predict biochemical recurrence on a subset of patients who had undergone radical prostatectomy. We report cross-validation AUCs as means for the training set and used AUCs with 95% CIs to assess the performance on the test set. The difference in AUCs between the models were tested for statistical significance using DeLong's test. We used log-rank tests and Kaplan-Meier curves to analyse survival. FindingsWe investigated 592 patients (823 lesions) with prostate cancer who underwent 3T multiparametric MRI at five hospitals in the USA between Jan 8, 2009, and June 3, 2017. The training data set consisted of 368 patients from three sites (the PROSTATEx Challenge cohort [n=204], University Hospitals Cleveland Medical Center [n=126], and Icahn School of Medicine at Mount Sinai [n=38]), and the independent validation data set consisted of 224 patients from two sites (Cleveland Clinic [n=151] and Long Island Jewish Medical Center [n=73]). The ClaD clinical nomogram yielded an AUC of 0•81 (95% CI 0•76−0•85) for identification of clinically significant prostate cancer in the validation data set, significantly improving performance over the DIN (0•74 [95% CI 0•69−0•80], p=0•0005) and PIN (0•76...

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Section: Discussionmentioning

confidence: 99%

Section: Implications Of All the Available Evidencementioning

confidence: 99%

An integrated nomogram combining deep learning, Prostate Imaging–Reporting and Data System (PI-RADS) scoring, and clinical variables for identification of clinically significant prostate cancer on biparametric MRI: a retrospective multicentre study

Hiremath

Shiradkar

et al. 2021

The Lancet Digital Health

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“…The 27 studies, and by extension, the CAD systems presented or evaluated within them, were categorized as either ROI Classification (ROI-C), Lesion Localization and Classification (LL&C), or Patient Classification (PAT-C); the categories are shown diagrammatically in Figure 2. ROI-C refers to (n = 16) studies where CAD systems classified pre-defined regions of interest (ROI), e.g., manually contoured lesions [19][20][21][22][23][24][25][26][27][28][29][30][31][32]44,45], LL&C refers to (n = 10) studies where CAD systems performed simultaneous lesion localization and classification [33][34][35][36][37][38][39][40][41][42], and PAT-C refers to (n = 1) studies where CAD systems classified patients directly [43].…”

Section: Literature Searchmentioning

confidence: 99%

“…All 27 included studies used a retrospective study design. The median size of patient cohorts used for evaluation was 98 (range 30 to 417, n = 26) for studies where the size of the evaluation patient cohort was reported [19][20][21][22][23][24][25][26][27][28][29][31][32][33][34][35][36][37][38][39][40][41][42][43][44][45]. Most studies (n = 18) considered clinically suspected patient cohorts [20][21][22][23]27,31,[34][35][36][37][38][39][40][41][42][43][44][45], while fewer studies (n = 9) considered patient cohorts with biopsy-proven prostate cancer [19,[24][25][26]…”

Section: Patient and Study Characteristicsmentioning

confidence: 99%

Artificial Intelligence Compared to Radiologists for the Initial Diagnosis of Prostate Cancer on Magnetic Resonance Imaging: A Systematic Review and Recommendations for Future Studies

Syer

Mehta

Antonelli

et al. 2021

Cancers

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Computer-aided diagnosis (CAD) of prostate cancer on multiparametric magnetic resonance imaging (mpMRI), using artificial intelligence (AI), may reduce missed cancers and unnecessary biopsies, increase inter-observer agreement between radiologists, and alleviate pressures caused by rising case incidence and a shortage of specialist radiologists to read prostate mpMRI. However, well-designed evaluation studies are required to prove efficacy above current clinical practice. A systematic search of the MEDLINE, EMBASE, and arXiv electronic databases was conducted for studies that compared CAD for prostate cancer detection or classification on MRI against radiologist interpretation and a histopathological reference standard, in treatment-naïve men with a clinical suspicion of prostate cancer. Twenty-seven studies were included in the final analysis. Due to substantial heterogeneities in the included studies, a narrative synthesis is presented. Several studies reported superior diagnostic accuracy for CAD over radiologist interpretation on small, internal patient datasets, though this was not observed in the few studies that performed evaluation using external patient data. Our review found insufficient evidence to suggest the clinical deployment of artificial intelligence algorithms at present. Further work is needed to develop and enforce methodological standards, promote access to large diverse datasets, and conduct prospective evaluations before clinical adoption can be considered.

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“…8 Medical imaging enables a non-invasive analysis of the functional and physiological properties of tumors, and the different available modalities are increasingly recognized for containing high-dimensional mineable data, which in turn can be used to improve medical decision making. 9,10 Imaging can also help in characterizing peritumoral regions, which are not always surgically removed for molecular characterization 11,12 and may convey information related to the tumor microenvironment. 13,14 For example, imaging characteristics of tumors are increasingly being used to predict gene expression.…”

Section: Introductionmentioning

confidence: 99%

Radiogenomics in brain, breast, and lung cancer: opportunities and challenges

2021

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The field of radiogenomics largely focuses on developing imaging surrogates for genomic signatures and integrating imaging, genomic, and molecular data to develop combined personalized biomarkers for characterizing various diseases. Our study aims to highlight the current state-of-the-art and the role of radiogenomics in cancer research, focusing mainly on solid tumors, and is broadly divided into four sections. The first section reviews representative studies that establish the biologic basis of radiomic signatures using gene expression and molecular profiling information. The second section includes studies that aim to non-invasively predict molecular subtypes of tumors using radiomic signatures. The third section reviews studies that evaluate the potential to augment the performance of established prognostic signatures by combining complementary information encoded by radiomic and genomic signatures derived from cancer tumors. The fourth section includes studies that focus on ascertaining the biological significance of radiomic phenotypes. We conclude by discussing current challenges and opportunities in the field, such as the importance of coordination between imaging device manufacturers, regulatory organizations, health care providers, pharmaceutical companies, academic institutions, and physicians for the effective standardization of the results from radiogenomic signatures and for the potential use of these findings to improve precision care for cancer patients. © The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.

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Combination of Peri-Tumoral and Intra-Tumoral Radiomic Features on Bi-Parametric MRI Accurately Stratifies Prostate Cancer Risk: A Multi-Site Study

Cited by 55 publications

References 37 publications

An integrated nomogram combining deep learning, Prostate Imaging–Reporting and Data System (PI-RADS) scoring, and clinical variables for identification of clinically significant prostate cancer on biparametric MRI: a retrospective multicentre study

An integrated nomogram combining deep learning, Prostate Imaging–Reporting and Data System (PI-RADS) scoring, and clinical variables for identification of clinically significant prostate cancer on biparametric MRI: a retrospective multicentre study

Artificial Intelligence Compared to Radiologists for the Initial Diagnosis of Prostate Cancer on Magnetic Resonance Imaging: A Systematic Review and Recommendations for Future Studies

Radiogenomics in brain, breast, and lung cancer: opportunities and challenges

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