Literature DB >> 30511281

Convolutional Neural Networks for the Detection and Measurement of Cerebral Aneurysms on Magnetic Resonance Angiography.

Joseph N Stember1, Peter Chang2, Danielle M Stember3, Michael Liu4, Jack Grinband4, Christopher G Filippi5, Philip Meyers4, Sachin Jambawalikar4.   

Abstract

Aneurysm size correlates with rupture risk and is important for treatment planning. User annotation of aneurysm size is slow and tedious, particularly for large data sets. Geometric shortcuts to compute size have been shown to be inaccurate, particularly for nonstandard aneurysm geometries. To develop and train a convolutional neural network (CNN) to detect and measure cerebral aneurysms from magnetic resonance angiography (MRA) automatically and without geometric shortcuts. In step 1, a CNN based on the U-net architecture was trained on 250 MRA maximum intensity projection (MIP) images, then applied to a testing set. In step 2, the trained CNN was applied to a separate set of 14 basilar tip aneurysms for size prediction. Step 1-the CNN successfully identified aneurysms in 85/86 (98.8% of) testing set cases, with a receiver operating characteristic (ROC) area-under-the-curve of 0.87. Step 2-automated basilar tip aneurysm linear size differed from radiologist-traced aneurysm size on average by 2.01 mm, or 30%. The CNN aneurysm area differed from radiologist-derived area on average by 8.1 mm2 or 27%. CNN correctly predicted the area trend for the set of aneurysms. This approach is to our knowledge the first using CNNs to derive aneurysm size. In particular, we demonstrate the clinically pertinent application of computing maximal aneurysm one-dimensional size and two-dimensional area. We propose that future work can apply this to facilitate pre-treatment planning and possibly identify previously missed aneurysms in retrospective assessment.

Entities:  

Keywords:  Aneurysm; Cerebral aneurysm; Convolutional neural networks; Deep learning; MRA; U-net

Mesh:

Year:  2019        PMID: 30511281      PMCID: PMC6737124          DOI: 10.1007/s10278-018-0162-z

Source DB:  PubMed          Journal:  J Digit Imaging        ISSN: 0897-1889            Impact factor:   4.056


  24 in total

1.  Evaluation of the stability of small ruptured aneurysms with a small neck after embolization with Guglielmi detachable coils: correlation between coil packing ratio and coil compaction.

Authors:  Yutaka Kai; Jun-ichiro Hamada; Motohiro Morioka; Shigetoshi Yano; Jun-ichi Kuratsu
Journal:  Neurosurgery       Date:  2005-04       Impact factor: 4.654

2.  The relation between packing and reopening in coiled intracranial aneurysms: a prospective study.

Authors:  Marjan J Slob; Menno Sluzewski; Willem Jan van Rooij
Journal:  Neuroradiology       Date:  2005-12       Impact factor: 2.804

3.  Quantified aneurysm shape and rupture risk.

Authors:  Madhavan L Raghavan; Baoshun Ma; Robert E Harbaugh
Journal:  J Neurosurg       Date:  2005-02       Impact factor: 5.115

4.  Underdiagnosis of posterior communicating artery aneurysm in noninvasive brain vascular studies.

Authors:  Valerie I Elmalem; Patricia A Hudgins; Beau B Bruce; Nancy J Newman; Valérie Biousse
Journal:  J Neuroophthalmol       Date:  2011-06       Impact factor: 3.042

5.  Automated computerized scheme for detection of unruptured intracranial aneurysms in three-dimensional magnetic resonance angiography.

Authors:  Hidetaka Arimura; Qiang Li; Yukunori Korogi; Toshinori Hirai; Hiroyuki Abe; Yasuyuki Yamashita; Shigehiko Katsuragawa; Ryuji Ikeda; Kunio Doi
Journal:  Acad Radiol       Date:  2004-10       Impact factor: 3.173

6.  The non-invasive detection of intracranial aneurysms: are neuroradiologists any better than other observers?

Authors:  Philip M White; Joanna M Wardlaw; Kenneth W Lindsay; Stuart Sloss; Dilip K B Patel; Evelyn M Teasdale
Journal:  Eur Radiol       Date:  2002-06-28       Impact factor: 5.315

7.  Ellipsoid approximation versus 3D rotational angiography in the volumetric assessment of intracranial aneurysms.

Authors:  M Piotin; B Daghman; C Mounayer; L Spelle; J Moret
Journal:  AJNR Am J Neuroradiol       Date:  2006-04       Impact factor: 3.825

8.  Computer-aided detection of intracranial aneurysms in MR angiography.

Authors:  Xiaojiang Yang; Daniel J Blezek; Lionel T E Cheng; William J Ryan; David F Kallmes; Bradley J Erickson
Journal:  J Digit Imaging       Date:  2009-11-24       Impact factor: 4.056

9.  Relation between aneurysm volume, packing, and compaction in 145 cerebral aneurysms treated with coils.

Authors:  Menno Sluzewski; Willem Jan van Rooij; Marian J Slob; Javier Oliván Bescós; Cornelis H Slump; Douwe Wijnalda
Journal:  Radiology       Date:  2004-04-29       Impact factor: 11.105

10.  Blood flow dynamics in patient-specific cerebral aneurysm models: the relationship between wall shear stress and aneurysm area index.

Authors:  Alvaro Valencia; Hernan Morales; Rodrigo Rivera; Eduardo Bravo; Marcelo Galvez
Journal:  Med Eng Phys       Date:  2007-06-06       Impact factor: 2.242
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  15 in total

Review 1.  Artificial Intelligence in the Management of Intracranial Aneurysms: Current Status and Future Perspectives.

Authors:  Z Shi; B Hu; U J Schoepf; R H Savage; D M Dargis; C W Pan; X L Li; Q Q Ni; G M Lu; L J Zhang
Journal:  AJNR Am J Neuroradiol       Date:  2020-03-12       Impact factor: 3.825

2.  Artificial Intelligence in Neuroradiology: Current Status and Future Directions.

Authors:  Y W Lui; P D Chang; G Zaharchuk; D P Barboriak; A E Flanders; M Wintermark; C P Hess; C G Filippi
Journal:  AJNR Am J Neuroradiol       Date:  2020-07-30       Impact factor: 3.825

3.  Deep learning for automated cerebral aneurysm detection on computed tomography images.

Authors:  Xilei Dai; Lixiang Huang; Yi Qian; Shuang Xia; Winston Chong; Junjie Liu; Antonio Di Ieva; Xiaoxi Hou; Chubin Ou
Journal:  Int J Comput Assist Radiol Surg       Date:  2020-02-13       Impact factor: 2.924

4.  Foundations of Lesion Detection Using Machine Learning in Clinical Neuroimaging.

Authors:  Manoj Mannil; Nicolin Hainc; Risto Grkovski; Sebastian Winklhofer
Journal:  Acta Neurochir Suppl       Date:  2022

5.  Towards Automated Brain Aneurysm Detection in TOF-MRA: Open Data, Weak Labels, and Anatomical Knowledge.

Authors:  Tommaso Di Noto; Guillaume Marie; Sebastien Tourbier; Yasser Alemán-Gómez; Oscar Esteban; Guillaume Saliou; Meritxell Bach Cuadra; Patric Hagmann; Jonas Richiardi
Journal:  Neuroinformatics       Date:  2022-08-18

6.  Deep Learning-Based Software Improves Clinicians' Detection Sensitivity of Aneurysms on Brain TOF-MRA.

Authors:  B Sohn; K-Y Park; J Choi; J H Koo; K Han; B Joo; S Y Won; J Cha; H S Choi; S-K Lee
Journal:  AJNR Am J Neuroradiol       Date:  2021-08-12       Impact factor: 4.966

7.  Automated Aneurysm Detection: Emerging from the Shallow End of the Deep Learning Pool.

Authors:  David F Kallmes; Bradley J Erickson
Journal:  Radiology       Date:  2020-11-03       Impact factor: 11.105

8.  Identification of Small, Regularly Shaped Cerebral Aneurysms Prone to Rupture.

Authors:  S F Salimi Ashkezari; F Mut; M Slawski; C M Jimenez; A M Robertson; J R Cebral
Journal:  AJNR Am J Neuroradiol       Date:  2022-03-24       Impact factor: 3.825

9.  Deep neural network-based detection and segmentation of intracranial aneurysms on 3D rotational DSA.

Authors:  Xinke Liu; Junqiang Feng; Zhenzhou Wu; Zhonghao Neo; Chengcheng Zhu; Peifang Zhang; Yan Wang; Yuhua Jiang; Dimitrios Mitsouras; Youxiang Li
Journal:  Interv Neuroradiol       Date:  2021-03-09       Impact factor: 1.764

10.  Eye Tracking for Deep Learning Segmentation Using Convolutional Neural Networks.

Authors:  J N Stember; H Celik; E Krupinski; P D Chang; S Mutasa; B J Wood; A Lignelli; G Moonis; L H Schwartz; S Jambawalikar; U Bagci
Journal:  J Digit Imaging       Date:  2019-08       Impact factor: 4.056
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