Vessel-aligned Multi-planar Image Representation for Automated Pulmonary Embolism Detection with Convolutional Neural Networks

Jianming Liang (Inventor)

Research output: Patent

Abstract

Pulmonary embolism (PE) is a common cardiovascular emergency. Quick and accurate diagnosis of PE is critical, so that scientifically proven and efficacious life-saving treatment can be administered appropriately. Suspected PE is typically diagnosed with CT pulmonary angiography (CTPA), but even with recent increases in diagnostic accuracy, this technique still has several issues with interpretation of intricate branching structures, artifacts that may obscure or mimic embolisms, suboptimal contrast, and inhomogeneities. Computer-aided diagnosis (CAD) could play a major role in diagnosing PE, however, to achieve a clinically acceptable sensitivity, existing CAD systems generate a high number of false positives, imposing extra burdens on radiologists. Researchers at Arizona State University have developed novel approaches for automated computer-aided detection of emboli in CTPA. One technique automatically registers the vessel orientation in display, providing compelling demonstration of arterial filling defects, if present, and allowing the radiologist to thoroughly inspect the vessel lumen from multiple perspectives and report any filling defects with high confidence. Another uses neural networks and vessel-aligned multi-planar representations to eliminate false positives. The flexibility of these systems, coupled with their precise detection of both acute and chronic PE, significantly reduces radiologist workload and improves the efficiency and accuracy of PE diagnosis in CTPA. Applications Accurate & Automated diagnosis of PE in CTPA images Benefits and Applications Detects both acute and chronic pulmonary emboli Allows visualization of vascular intensity levels and local vascular structure and occlusion Navigates the vessel based on its local structure Enables thorough inspection of the vessel lumen from multiple perspectives through automatic registration Incrementally reports any detection to facilitate real-time support Efficient and compact - concisely summarizing the 3D contextual information around an embolus Consistent - automatically aligning the embolus according to its containing vessel orientation Expandablenaturally supporting data augmentation for training Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Liangs laboratory webpage
Original languageEnglish (US)
StatePublished - Mar 17 2015

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Pulmonary Embolism
Embolism
Lung
Blood Vessels
Inventors
Workload
Artifacts
Emergencies
Research Personnel
Computed Tomography Angiography
Research
Radiologists

Cite this

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title = "Vessel-aligned Multi-planar Image Representation for Automated Pulmonary Embolism Detection with Convolutional Neural Networks",
abstract = "Pulmonary embolism (PE) is a common cardiovascular emergency. Quick and accurate diagnosis of PE is critical, so that scientifically proven and efficacious life-saving treatment can be administered appropriately. Suspected PE is typically diagnosed with CT pulmonary angiography (CTPA), but even with recent increases in diagnostic accuracy, this technique still has several issues with interpretation of intricate branching structures, artifacts that may obscure or mimic embolisms, suboptimal contrast, and inhomogeneities. Computer-aided diagnosis (CAD) could play a major role in diagnosing PE, however, to achieve a clinically acceptable sensitivity, existing CAD systems generate a high number of false positives, imposing extra burdens on radiologists. Researchers at Arizona State University have developed novel approaches for automated computer-aided detection of emboli in CTPA. One technique automatically registers the vessel orientation in display, providing compelling demonstration of arterial filling defects, if present, and allowing the radiologist to thoroughly inspect the vessel lumen from multiple perspectives and report any filling defects with high confidence. Another uses neural networks and vessel-aligned multi-planar representations to eliminate false positives. The flexibility of these systems, coupled with their precise detection of both acute and chronic PE, significantly reduces radiologist workload and improves the efficiency and accuracy of PE diagnosis in CTPA. Applications Accurate & Automated diagnosis of PE in CTPA images Benefits and Applications Detects both acute and chronic pulmonary emboli Allows visualization of vascular intensity levels and local vascular structure and occlusion Navigates the vessel based on its local structure Enables thorough inspection of the vessel lumen from multiple perspectives through automatic registration Incrementally reports any detection to facilitate real-time support Efficient and compact - concisely summarizing the 3D contextual information around an embolus Consistent - automatically aligning the embolus according to its containing vessel orientation Expandablenaturally supporting data augmentation for training Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Liangs laboratory webpage",
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language = "English (US)",
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}

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AU - Liang, Jianming

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Y1 - 2015/3/17

N2 - Pulmonary embolism (PE) is a common cardiovascular emergency. Quick and accurate diagnosis of PE is critical, so that scientifically proven and efficacious life-saving treatment can be administered appropriately. Suspected PE is typically diagnosed with CT pulmonary angiography (CTPA), but even with recent increases in diagnostic accuracy, this technique still has several issues with interpretation of intricate branching structures, artifacts that may obscure or mimic embolisms, suboptimal contrast, and inhomogeneities. Computer-aided diagnosis (CAD) could play a major role in diagnosing PE, however, to achieve a clinically acceptable sensitivity, existing CAD systems generate a high number of false positives, imposing extra burdens on radiologists. Researchers at Arizona State University have developed novel approaches for automated computer-aided detection of emboli in CTPA. One technique automatically registers the vessel orientation in display, providing compelling demonstration of arterial filling defects, if present, and allowing the radiologist to thoroughly inspect the vessel lumen from multiple perspectives and report any filling defects with high confidence. Another uses neural networks and vessel-aligned multi-planar representations to eliminate false positives. The flexibility of these systems, coupled with their precise detection of both acute and chronic PE, significantly reduces radiologist workload and improves the efficiency and accuracy of PE diagnosis in CTPA. Applications Accurate & Automated diagnosis of PE in CTPA images Benefits and Applications Detects both acute and chronic pulmonary emboli Allows visualization of vascular intensity levels and local vascular structure and occlusion Navigates the vessel based on its local structure Enables thorough inspection of the vessel lumen from multiple perspectives through automatic registration Incrementally reports any detection to facilitate real-time support Efficient and compact - concisely summarizing the 3D contextual information around an embolus Consistent - automatically aligning the embolus according to its containing vessel orientation Expandablenaturally supporting data augmentation for training Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Liangs laboratory webpage

AB - Pulmonary embolism (PE) is a common cardiovascular emergency. Quick and accurate diagnosis of PE is critical, so that scientifically proven and efficacious life-saving treatment can be administered appropriately. Suspected PE is typically diagnosed with CT pulmonary angiography (CTPA), but even with recent increases in diagnostic accuracy, this technique still has several issues with interpretation of intricate branching structures, artifacts that may obscure or mimic embolisms, suboptimal contrast, and inhomogeneities. Computer-aided diagnosis (CAD) could play a major role in diagnosing PE, however, to achieve a clinically acceptable sensitivity, existing CAD systems generate a high number of false positives, imposing extra burdens on radiologists. Researchers at Arizona State University have developed novel approaches for automated computer-aided detection of emboli in CTPA. One technique automatically registers the vessel orientation in display, providing compelling demonstration of arterial filling defects, if present, and allowing the radiologist to thoroughly inspect the vessel lumen from multiple perspectives and report any filling defects with high confidence. Another uses neural networks and vessel-aligned multi-planar representations to eliminate false positives. The flexibility of these systems, coupled with their precise detection of both acute and chronic PE, significantly reduces radiologist workload and improves the efficiency and accuracy of PE diagnosis in CTPA. Applications Accurate & Automated diagnosis of PE in CTPA images Benefits and Applications Detects both acute and chronic pulmonary emboli Allows visualization of vascular intensity levels and local vascular structure and occlusion Navigates the vessel based on its local structure Enables thorough inspection of the vessel lumen from multiple perspectives through automatic registration Incrementally reports any detection to facilitate real-time support Efficient and compact - concisely summarizing the 3D contextual information around an embolus Consistent - automatically aligning the embolus according to its containing vessel orientation Expandablenaturally supporting data augmentation for training Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Liangs laboratory webpage

M3 - Patent

ER -