Computer‐aided detection of metastatic brain tumors using automated three‐dimensional template matching

Ambrosini, Robert; Wang, Peng; O’Dell, Walter G.

doi:10.1002/jmri.22009

Cited by 87 publications

(95 citation statements)

References 29 publications

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“…The true positive over false positive ratio T p : F p in [10] is approximately 1:10 versus 1:2.7 per brain in our case. Fig.…”

Section: Introductionmentioning

confidence: 43%

“…Subsequent affine adaptation and asymmetrybased pruning stages result in low false positive F p tumor detections. Our average 95.3% detection rate, average 3-10 false positives F p per brain (Table 1), and under 3 minute run-time (on a standard PC running Intel Core i7) are an improvement over state-of-the-art algorithms (average detection rate 90%, average F p per brain 34.8 by [9][10], and 30 minutes using template matching in [10]). The detection results can also be applied to other brain abnormality detection tasks using the final 3D blobs as features.…”

Section: Resultsmentioning

confidence: 99%

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3D blob based brain tumor detection and segmentation in MR images

Ruppert

Collins

et al. 2014

2014 IEEE 11th International Symposium on Biomedical Imaging (ISBI)

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Automatic detection and segmentation of brain tumors in 3D MR neuroimages can significantly aid early diagnosis, surgical planning, and follow-up assessment. However, due to diverse location and varying size, primary and metastatic tumors present substantial challenges for detection. We present a fully automatic, unsupervised algorithm that can detect single and multiple tumors from 3 to 28,079 mm 3 in volume. Using 20 clinical 3D MR scans containing from 1 to 15 tumors per scan, the proposed approach achieves between 87.84% and 95.30% detection rate and an average end-to-end running time of under 3 minutes. In addition, 5 normal clinical 3D MR scans are evaluated quantitatively to demonstrate that the approach has the potential to discriminate between abnormal and normal brains.Index Terms-brain tumor detection, MRI brain asymmetry, 3D separable Laplacian of Gaussian, 3D blob detection

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“…The true positive over false positive ratio T p : F p in [10] is approximately 1:10 versus 1:2.7 per brain in our case. Fig.…”

Section: Introductionmentioning

confidence: 43%

Section: Resultsmentioning

confidence: 99%

3D blob based brain tumor detection and segmentation in MR images

Ruppert

Collins

et al. 2014

2014 IEEE 11th International Symposium on Biomedical Imaging (ISBI)

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“…Computational image descriptors quantify visual characteristics at different scales from ROIs, which can be readily translated into radiological image analysis pertaining to tumor volumetric shapes and visual appearance dynamics. For example, the scale-invariant feature transform (SIFT) 2122 is computed through key point detection by using a difference-of-gaussians (DoG) function and local image gradient measurment with radius and scale selections (as illustrated in Fig.1). This permits a quantitative measurement of the tumor shape so that subtle variation during treatment (i.e.…”

Section: Quantitative Image Feature Extractionmentioning

confidence: 99%

Radiomics in Brain Tumor: Image Assessment, Quantitative Feature Descriptors, and Machine-Learning Approaches

Zhou¹,

Scott

Chaudhury

et al. 2017

AJNR Am J Neuroradiol

310

213

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Radiomics describes a broad set of computational methods that extract quantitative features from radiographic images. The resulting features can be used to inform imaging diagnosis, prognosis, and therapy response in oncology. However, major challenges remain for methodological developments to optimize feature extraction and provide rapid information flow in clinical settings. Equally important, to be clinically useful, predictive radiomic properties must be clearly linked to meaningful biological characteristics as well as qualitative imaging properties familiar to radiologist. Here we use a cross-disciplinary approach to highlight studies in radiomics. We review brain tumor radiological studies (e.g., imaging interpretation) through computational models (e.g., computer vision and machine learning) that provide novel clinical insights. In particular, we outline current quantitative image feature extraction and prediction strategies with different level of available clinical classes for supporting clinical decision making. We further discuss machine learning challenges and data opportunities to advance radiomic studies.

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“…The addition of these algorithms to human interpretation could potentially lead to greater sensitivity and improved accuracy of intracranial metastases characterization, based both on standard postcontrast exams as well as advanced physiologic imaging such as perfusion-related acquisitions (Ambrosini et al, 2010; Yang et al, 2013; Szwarc et al, 2015). …”

Section: Enhancing Detection Of Small Metastasesmentioning

confidence: 99%

Brain metastases: neuroimaging

Pope

2018

Handbook of Clinical Neurology

148

130

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Magnetic resonance imaging (MRI) is the cornerstone for evaluating patients with brain masses such as primary and metastatic tumors. Important challenges in effectively detecting and diagnosing brain metastases and in accurately characterizing their subsequent response to treatment remain. These difficulties include discriminating metastases from potential mimics such as primary brain tumors and infection, detecting small metastases, and differentiating treatment response from tumor recurrence and progression. Optimal patient management could be benefited by improved and well-validated prognostic and predictive imaging markers, as well as early response markers to identify successful treatment prior to changes in tumor size. To address these fundamental needs, newer MRI techniques including diffusion and perfusion imaging, MR spectroscopy, and positron emission tomography (PET) tracers beyond traditionally used 18-fluorodeoxyglucose are the subject of extensive ongoing investigations, with several promising avenues of added value already identified. These newer techniques provide a wealth of physiologic and metabolic information that may supplement standard MR evaluation, by providing the ability to monitor and characterize cellularity, angiogenesis, perfusion, pH, hypoxia, metabolite concentrations, and other critical features of malignancy. This chapter reviews standard and advanced imaging of brain metastases provided by computed tomography, MRI, and amino acid PET, focusing on potential biomarkers that can serve as problem-solving tools in the clinical management of patients with brain metastases.

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Computer‐aided detection of metastatic brain tumors using automated three‐dimensional template matching

Cited by 87 publications

References 29 publications

3D blob based brain tumor detection and segmentation in MR images

3D blob based brain tumor detection and segmentation in MR images

Radiomics in Brain Tumor: Image Assessment, Quantitative Feature Descriptors, and Machine-Learning Approaches

Brain metastases: neuroimaging

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