Magazine for AI Special
Testimonials, white papers, and articles about AI from users of Canon Medical Systems’ AI technologies
Technical references
Á. V. Juanco Müller, J. F. C. Mota, C. Hoogendoorn
Segmentation of Skin Lesions by Superpixel Classification with Graph-Context CNN
MIUA 2021
Schrempf, P., Watson, H., Park, E., Pajak, M., MacKinnon, H., Muir, K.W., Harris-Birtill, D. and O’Neil, A.Q. (2021). Templated text synthesis for expert-guided multi-label extraction from radiology reports. Machine Learning and Knowledge Extraction, 3(2), pp.299-317.
Anderson, O., Kidd, A.C., Goatman, K.A., Weir, A.J., Voisey, J., Dilys, V., Siebert, J.P., and Blyth, K.G. (2020). Fully automated volumetric measurement of malignant pleural mesothelioma from computed tomography images by deep learning: Preliminary results of an internal validation. In Proceedings of the 13th International Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2020) – Volume 2: BIOIMAGING, pp. 64–73, SCITEPRESS.
Elskhawy, A., Lisowska, A., Keicher, M., Henry, J., Thomson, P. and Navab, N. (2020). Continual Class Incremental Learning for CT Thoracic Segmentation. In MICCAI workshop on “Domain Adaptation and Representation Transfer” (DART).
Jacenków, G., O’Neil, A.Q., Mohr, B. and Tsaftaris, S.A. (2020). INSIDE: Steering Spatial Attention with Non-imaging Information in CNNs. In International Conference on Medical Image Computing and Computer-Assisted Intervention (pp. 385-395). Springer, Cham.
Liu, X., Thermos, S., Chartsias, A., O’Neil, A. and Tsaftaris, S.A. (2021). Disentangled Representations for Domain-Generalized Cardiac Segmentation. In MICCAI workshop on “Statistical Atlases and Computational Models of the Heart” (STACOM), submission to the Multi-Centre, Multi-Vendor & Multi-Disease Cardiac Image Segmentation (M&Ms) Challenge.
Schrempf, P., Watson, H., Mikhael, S., Pajak, M., Falis, M., Lisowska, A., Muir, K.W., Harris-Birtill, D. and O’Neil, A.Q. (2020). Paying Per-Label Attention for Multi-label Extraction from Radiology Reports. In MICCAI workshop on “Large-scale Annotation of Biomedical Data and Expert Label Synthesis” (LABELS).
Shaw, S., Pajak, M., Lisowska, A., Tsaftaris, S.A., O’Neil, A.Q., (2020). Teacher-Student chain for efficient semi-supervised histology image classification. In ICLR workshop on “AI for Affordable Healthcare” (AI4AH).
Appelgren, M., Schrempf, P., Falis, M., Ikeda, S. and O’Neil, A.Q., (2019). Language Transfer for Early Warning of Epidemics from Social Media. In NeurIPS workshop on “Artificial Intelligence for Humanitarian Assistance and Disaster Response” (AI+HADR).
Falis, M., Pajak, M., Lisowska, A., Schrempf, P., Deckers, L., Mikhael, S., Tsaftaris, S. and O’Neil, A. Q., (2019). Ontological attention ensembles for capturing semantic concepts in ICD code prediction from clinical text. In EM NLP Workshop “Tenth International Workshop on Health Text Mining and Information Analysis” (LOUHI), p. 168-177.
Jacenków, G., Chartsias, A., Mohr, B. and Tsaftaris, S.A. (2019). Conditioning Convolutional Segmentation Architectures with Non-Imaging Data. Medical Imaging with Deep Learning (Extended Abstract Track).
Zotova, D., Lisowska, A., Anderson, O., Dilys, V. and O’Neil, A. Q., (2019). Comparison of active learning strategies applied to lung nodule segmentation in CT scans. In MICCAI workshop on “Large-scale Annotation of Biomedical Data and Expert Label Synthesis” (LABELS).
Daykin, M., Sellathurai, M. and Poole, I., 2018, July. A Comparison of Unsupervised Abnormality Detection Methods for Interstitial Lung Disease . In Annual Conference on Medical Image Understanding and Analysis (pp. 287-298). Springer, Cham.
Lisowska, A., O’Neil, A. and Poole, I. (2018) Cross-cohort Evaluation of Machine Learning Approaches to Fall Detection from Accelerometer Data . In Proceedings of the 11th International Joint Conference on Biomedical Engineering Systems and Technologies – Volume 5: HEALTHINF, January 2018, ISBN 978-989-758-281-3, pages 77-82.
O’Neil, A.Q., Kascenas, A., Henry, J., Wyeth, D., Shepherd, M., Beveridge, E., Clunie, L., Sansom, C., Šeduikytė, E., Muir, K. and Poole, I., (2018). Attaining human-level performance with atlas location autocontext for anatomical landmark detection in 3D CT data . ECCV 2018 Workshop “Geometry Meets Deep Learning”.
O’Neil, A.Q., Kascenas, A., Henry, J., Wyeth, D., Shepherd, M., Beveridge, E., Clunie, L., Sansom, C., Šeduikytė, E., Muir, K. and Poole, I., (2018). Attaining human-level performance with atlas location autocontext for anatomical landmark detection in 3D CT data . ECCV 2018 Workshop “Geometry Meets Deep Learning”.
Sloan, J., Goatman, K. and Siebert, J. (2018). Learning Rigid Image Registration – Utilizing Convolutional Neural Networks for Medical Image Registration . In Proceedings of the 11th International Joint Conference on Biomedical Engineering Systems and Technologies – Volume 2: BIOIMAGING, ISBN 978-989-758-278-3, pages 89-99.
Healthcare Information Technology
Rava et al. | Assessment of an Artificial Intelligence Algorithm for Detection of Intracranial Hemorrhage | World Neurosurgery (2021)
Rava et al. | Validation of an Artificial Intelligence Driven Large Vessel Occlusion Detection Algorithm for Acute Ischemic Stroke Patients | The Neuroradiology Journal (2021)
Rava et al. | Assessment of a Bayesian Vitrea CT Perfusion Analysis to Predict Final Infarct and Penumbra Volumes in Patients with Acute Ischemic Stroke: A Comparison with RAPID | American Journal of Neuroradiology (AJNR) (2020)
Rava et al. | Assessment of computed tomography perfusion software in predicting spatial location and volume of infarct in acute ischemic stroke patients: a comparison of Sphere, Vitrea, and RAPID | Journal of NeuroInterventional Surgery (JNIS) (2020)
Rava et al. | Enhancing performance of a computed tomography perfusion software for improved prediction of final infarct volume in acute ischemic stroke patients | The Neuroradiology Journal (2021)
Ohno et al. | Machine learning for lung CT texture analysis: Improvement of inter-observer agreement for radiological finding classification in patients with pulmonary diseases | Eur J Radiol. (2021)
MRI
Sagawa et al. | Deep Learning-based Noise Reduction for Fast Volume Diffusion Tensor Imaging: Assessing the Noise Reduction Effect and Reliability of Diffusion Metrics| Magn Reson Med Sci (2020)
Kidoh et al. | Deep Learning Based Noise Reduction for Brain MR Imaging: Tests on Phantoms and Healthy Volunteers | Magn Reson Med Sci (2020)
Yokota et al. | Effects of Deep Learning Reconstruction Technique in High-Resolution Non-contrast Magnetic Resonance Coronary Angiography at a 3-Tesla Machine | Can Assoc Radiol J (2021)
Mori et al. | Ultrashort echo time time-spatial labeling inversion pulse magnetic resonance angiography with denoising deep learning reconstruction for the assessment of abdominal visceral arteries | J Magn Reson Imaging (2021)
Ueda et al. | Compressed sensing and deep learning reconstruction for women’s pelvic MRI denoising: Utility for improving image quality and examination time in routine clinical practice | Eur J Radiol (2021)
X-Ray
Brestel et al. | RadBot-CXR: Classification of Four Clinical Finding Categories in Chest X-Ray Using Deep Learning | Medicine (2018)
CT
Nakamura et al. | Diagnostic value of deep learning reconstruction for radiation dose reduction at abdominal ultra-high-resolution CT | European Radiology | (2021)
Matsukiyo et al. | Deep learning-based and hybrid-type iterative reconstructions for CT: comparison of capability for quantitative and qualitative image quality improvements and small vessel evaluation at dynamic CE-abdominal CT with ultra-high and standard resolutions | Jpn J Radiol | (2021)
Greffier et al. | Comparison of two versions of a deep learning image reconstruction algorithm on CT image quality and dose reduction: A phantom study | Medical Physics | (2021)
Greffier at al. | Comparison of two deep learning image reconstruction algorithms in chest CT images: A task-based image quality assessment on phantom data | Diagn Interv Imaging | (2021)
Brady et al. | Improving Image Quality and Reducing Radiation Dose for Pediatric CT by Using Deep Learning Reconstruction | Radiology | (2021)
McLeavy et al. | The future of CT: deep learning reconstruction | Clin Radiol. (2021)
Matsuura et al. | Feature-Aware Deep-Learning Reconstruction for Context-Sensitive X-ray Computed Tomography | IEEE (2021)
Bernard et al. | Deep learning reconstruction versus iterative reconstruction for cardiac CT angiography in a stroke imaging protocol: reduced radiation dose and improved image quality. | Quant Imaging Med Surg. (2021)
Higaki et al. | Deep Learning Reconstruction at CT: Phantom Study of the Image Characteristics | Academic Radiology | (2020)
Akagi et al. | Deep learning reconstruction of equilibrium phase CT images in obese patients | Eur J Radiol | (2020)
Singh et al. | Image Quality and Lesion Detection on Deep Learning Reconstruction and Iterative Reconstruction of Submillisievert Chest and Abdominal CT | AJR Am J Roentgenol | (2020)
Lenfant et al. | Deep Learning Versus Iterative Reconstruction for CT Pulmonary Angiography in the Emergency Setting: Improved Image Quality and Reduced Radiation Dose | Diagnostics (2020)
Nakamura et al.| Possibility of Deep Learning in Medical Imaging Focusing Improvement of Computed Tomography Image Quality | J Comput Assist Tomogr (2019)
Higaki et al. | Improvement of image quality at CT and MRI using deep learning | Japanese Journal of Radiology (2019)
Nakamura et al. | Diagnostic value of deep learning reconstruction for radiation dose reduction at abdominal ultra-high-resolution CT | Eur Radiol (2021)
Urikura et al. | Deep learning-based reconstruction in ultra-high-resolution computed tomography: Can image noise caused by high definition detector and the miniaturization of matrix element size be improved? | Phys Med. (2021)
Matsukiyo et al. | Deep learning-based and hybrid-type iterative reconstructions for CT: comparison of capability for quantitative and qualitative image quality improvements and small vessel evaluation at dynamic CE-abdominal CT with ultra-high and standard resolutions | Jpn J Radiol (2021)
Tamura et al. | Superior objective and subjective image quality of deep learning reconstruction for low-dose abdominal CT imaging in comparison with model-based iterative reconstruction and filtered back projection | Br J Radiol. (2021)
Narita et al. | Deep learning reconstruction of drip-infusion cholangiography acquired with ultra-high-resolution computed tomography | Abdom Radiol (NY) 2020
Eye Care
Kadomoto et al. | Enhanced Visualization of Retinal Microvasculature in Optical Coherence Tomography Angiography Imaging via Deep Learning | J Clin Med (2020)
Sawai et al. | Usefulness of Denoising Process to Depict Myopic Choroidal Neovascularisation Using a Single Optical Coherence Tomography Angiography Image | Sci Rep (2020)
Mc Grath et al. | Clinical Utility of Artificial Intelligence Algorithms to Enhance Wide-Field Optical Coherence Tomography Angiography Images | J Imaging (2021)
Kawai et al. | Image evaluation of Artificial Intelligence-supported Optical Coherence Tomography Angiography Imaging using OCT-A1 device in diabetic retinopathy | Retina (2021)