MR and ultrasound cardiac image dynamic visualization and synchronization over Internet for distributed heart function diagnosis
•Introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers.•Develop a novel approach that allows p...
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| Published in | Computerized medical imaging and graphics Vol. 88; p. 101850 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Elsevier Ltd
01.03.2021
Elsevier Science Ltd |
| Subjects | |
| Online Access | Get full text |
| ISSN | 0895-6111 1879-0771 1879-0771 |
| DOI | 10.1016/j.compmedimag.2020.101850 |
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| Abstract | •Introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers.•Develop a novel approach that allows precise visualization of intracardiac structures within a beating heart,using Node.js framework and Socket.IO library to create real-time bidirectional connections between the server and clients.•Create algorithms for loading and processing a series of cardiac MR and ultrasound images, and outline an ECG-gated dual-modality cardiac data acquisition procedure and an intensity-based image registration algorithm .•When compared with traditional multi-modality image visualization software running on stand-alone computers, our Internet-based solutions can lead to enhanced accessibility and information sharing.•The software framework provides cardiologists with instant information in appreciating the anatomic complexity of beating heart and sharing feedback with collaborators using web browsers during the process of distributed diagnosis of cardiac function.
Dual-modality 4D cardiac data visualization can convey a significant amount of complementary image information from various sources into a single and meaningful display. Even though there are existing publications on combining multiple medical images into a unique representation, there has been no work on rendering a series of cardiac image sequences, acquired from multiple sources, using web browsers and synchronizing the result over the Internet in real time. The ability to display multi-modality beating heart images using Web-based technology is hampered by the lack of efficient algorithms for fusing and visualizing constantly updated multi-source images and streaming the rendering results using internet protocols. To address this practical issue, in this paper we introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers. Taking advantage of the bidirectional WebSocket protocol and WebGL-based graphics acceleration, internal cardiac structures are dynamically displayed, and the results of rendering and data exploration are synchronized among all the connected client computers. The presented research and software have the potential to provide clinicians with comprehensive information and intuitive feedback relating to cardiac behavior and anatomy and could impact areas such as distributed diagnosis of cardiac function and collaborative treatment planning for various heart diseases. |
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| AbstractList | •Introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers.•Develop a novel approach that allows precise visualization of intracardiac structures within a beating heart,using Node.js framework and Socket.IO library to create real-time bidirectional connections between the server and clients.•Create algorithms for loading and processing a series of cardiac MR and ultrasound images, and outline an ECG-gated dual-modality cardiac data acquisition procedure and an intensity-based image registration algorithm .•When compared with traditional multi-modality image visualization software running on stand-alone computers, our Internet-based solutions can lead to enhanced accessibility and information sharing.•The software framework provides cardiologists with instant information in appreciating the anatomic complexity of beating heart and sharing feedback with collaborators using web browsers during the process of distributed diagnosis of cardiac function.
Dual-modality 4D cardiac data visualization can convey a significant amount of complementary image information from various sources into a single and meaningful display. Even though there are existing publications on combining multiple medical images into a unique representation, there has been no work on rendering a series of cardiac image sequences, acquired from multiple sources, using web browsers and synchronizing the result over the Internet in real time. The ability to display multi-modality beating heart images using Web-based technology is hampered by the lack of efficient algorithms for fusing and visualizing constantly updated multi-source images and streaming the rendering results using internet protocols. To address this practical issue, in this paper we introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers. Taking advantage of the bidirectional WebSocket protocol and WebGL-based graphics acceleration, internal cardiac structures are dynamically displayed, and the results of rendering and data exploration are synchronized among all the connected client computers. The presented research and software have the potential to provide clinicians with comprehensive information and intuitive feedback relating to cardiac behavior and anatomy and could impact areas such as distributed diagnosis of cardiac function and collaborative treatment planning for various heart diseases. Dual-modality 4D cardiac data visualization can convey a significant amount of complementary image information from various sources into a single and meaningful display. Even though there are existing publications on combining multiple medical images into a unique representation, there has been no work on rendering a series of cardiac image sequences, acquired from multiple sources, using web browsers and synchronizing the result over the Internet in real time. The ability to display multi-modality beating heart images using Web-based technology is hampered by the lack of efficient algorithms for fusing and visualizing constantly updated multi-source images and streaming the rendering results using internet protocols. To address this practical issue, in this paper we introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers. Taking advantage of the bidirectional WebSocket protocol and WebGL-based graphics acceleration, internal cardiac structures are dynamically displayed, and the results of rendering and data exploration are synchronized among all the connected client computers. The presented research and software have the potential to provide clinicians with comprehensive information and intuitive feedback relating to cardiac behavior and anatomy and could impact areas such as distributed diagnosis of cardiac function and collaborative treatment planning for various heart diseases. Highlights•Introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers. •Develop a novel approach that allows precise visualization of intracardiac structures within a beating heart,using Node.js framework and Socket.IO library to create real-time bidirectional connections between the server and clients. •Create algorithms for loading and processing a series of cardiac MR and ultrasound images, and outline an ECG-gated dual-modality cardiac data acquisition procedure and an intensity-based image registration algorithm . •When compared with traditional multi-modality image visualization software running on stand-alone computers, our Internet-based solutions can lead to enhanced accessibility and information sharing. •The software framework provides cardiologists with instant information in appreciating the anatomic complexity of beating heart and sharing feedback with collaborators using web browsers during the process of distributed diagnosis of cardiac function. Dual-modality 4D cardiac data visualization can convey a significant amount of complementary image information from various sources into a single and meaningful display. Even though there are existing publications on combining multiple medical images into a unique representation, there has been no work on rendering a series of cardiac image sequences, acquired from multiple sources, using web browsers and synchronizing the result over the Internet in real time. The ability to display multi-modality beating heart images using Web-based technology is hampered by the lack of efficient algorithms for fusing and visualizing constantly updated multi-source images and streaming the rendering results using internet protocols. To address this practical issue, in this paper we introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers. Taking advantage of the bidirectional WebSocket protocol and WebGL-based graphics acceleration, internal cardiac structures are dynamically displayed, and the results of rendering and data exploration are synchronized among all the connected client computers. The presented research and software have the potential to provide clinicians with comprehensive information and intuitive feedback relating to cardiac behavior and anatomy and could impact areas such as distributed diagnosis of cardiac function and collaborative treatment planning for various heart diseases.Dual-modality 4D cardiac data visualization can convey a significant amount of complementary image information from various sources into a single and meaningful display. Even though there are existing publications on combining multiple medical images into a unique representation, there has been no work on rendering a series of cardiac image sequences, acquired from multiple sources, using web browsers and synchronizing the result over the Internet in real time. The ability to display multi-modality beating heart images using Web-based technology is hampered by the lack of efficient algorithms for fusing and visualizing constantly updated multi-source images and streaming the rendering results using internet protocols. To address this practical issue, in this paper we introduce a new Internet-based algorithm and a software platform running on a Node.js server, where a series of registered cardiac images from both magnetic resonance (MR) and ultrasound are employed to display dynamic fused cardiac structures in web browsers. Taking advantage of the bidirectional WebSocket protocol and WebGL-based graphics acceleration, internal cardiac structures are dynamically displayed, and the results of rendering and data exploration are synchronized among all the connected client computers. The presented research and software have the potential to provide clinicians with comprehensive information and intuitive feedback relating to cardiac behavior and anatomy and could impact areas such as distributed diagnosis of cardiac function and collaborative treatment planning for various heart diseases. |
| ArticleNumber | 101850 |
| Author | Zhang, Qi Peters, Terry M. Samani, Abbas |
| Author_xml | – sequence: 1 givenname: Qi surname: Zhang fullname: Zhang, Qi email: qzhan10@ilstu.edu organization: School of Information Technology, Illinois State University, 100 North University Street, Normal, IL 61761, United States – sequence: 2 givenname: Abbas surname: Samani fullname: Samani, Abbas email: asamani@uwo.ca organization: Department of Medical Biophysics, Western University, London, Ontario, Canada N6A 5C1 – sequence: 3 givenname: Terry M. surname: Peters fullname: Peters, Terry M. email: tpeters@robarts.ca organization: Department of Medical Biophysics, Western University, London, Ontario, Canada N6A 5C1 |
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| Keywords | Dual-modality Bidirectional Internet connection Web-based rendering Synchronization Dynamic medical visualization Cardiac image fusing |
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| SubjectTerms | Algorithms Bidirectional Internet connection Cardiac image fusing Cardiovascular diseases Computer programs Computers Coronary artery disease Data visualization Diagnosis Digital media Dual-modality Dynamic medical visualization Heart diseases Heart function Image acquisition Internal Medicine Internet Magnetic resonance Magnetic resonance imaging Medical diagnosis Medical imaging Medical treatment Other Rendering Scientific visualization Sequences Software Synchronism Synchronization Ultrasonic imaging Ultrasound Visualization Web browsers Web-based rendering |
| Title | MR and ultrasound cardiac image dynamic visualization and synchronization over Internet for distributed heart function diagnosis |
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