We present a computational method for real-time, patient-specific simulation of 2D ultrasound (US) images. The method uses a large number of tracked ultrasound images to learn a function that maps position and orientation of the transducer to ultrasound images. This is a first step towards realistic patient-specific simulations that will enable improved training and retrospective examination of complex cases. Our models can simulate a 2D image in under 4 ms (well within real-time constraints), and produce simulated images that preserve the content (anatomical structures and artefacts) of real ultrasound images.</p
Abstract. Medical ultrasound interpretation requires a great deal of experience. Real-time simulatio...
Medical imagery has been on a continuous development in the last decades, as computers have gotten m...
Monte-Carlo ray tracing, which enables realistic simulation of ultrasound-tissue interactions such a...
This paper presents an artificial intelligence-based ultrasound simulator suitable for medical simul...
Purpose Given the high level of expertise required for navigation and interpretation of ultrasound i...
Medical ultrasound imaging relies heavily on high-quality signal processing to provide reliable and ...
Sonography synthesis has a wide range of applications, including medical procedure simulation, clini...
Ultrasound imaging systems provide a low-cost, real-time, noninvasive and safe way to examine soft t...
Ultrasound (US) imaging is a low-cost, non-invasive and non-radioactive technique, often preferred a...
Sonography synthesis has a wide range of applications, including medical procedure simulation, clini...
When learning ultrasound (US) imaging, trainees must learn how to recognize structures, interpret te...
Current medical ultrasound datasets used in training simulators lack adequate coverage due to imagin...
Intraoperative ultrasound is an imaging modality frequently used to provide delineation of tissue bo...
A study is presented in which a new convolution-based methodology has been developed to simulate ult...
Medical ultrasound interpretation requires a great deal of experience. Real-time simulation of medic...
Abstract. Medical ultrasound interpretation requires a great deal of experience. Real-time simulatio...
Medical imagery has been on a continuous development in the last decades, as computers have gotten m...
Monte-Carlo ray tracing, which enables realistic simulation of ultrasound-tissue interactions such a...
This paper presents an artificial intelligence-based ultrasound simulator suitable for medical simul...
Purpose Given the high level of expertise required for navigation and interpretation of ultrasound i...
Medical ultrasound imaging relies heavily on high-quality signal processing to provide reliable and ...
Sonography synthesis has a wide range of applications, including medical procedure simulation, clini...
Ultrasound imaging systems provide a low-cost, real-time, noninvasive and safe way to examine soft t...
Ultrasound (US) imaging is a low-cost, non-invasive and non-radioactive technique, often preferred a...
Sonography synthesis has a wide range of applications, including medical procedure simulation, clini...
When learning ultrasound (US) imaging, trainees must learn how to recognize structures, interpret te...
Current medical ultrasound datasets used in training simulators lack adequate coverage due to imagin...
Intraoperative ultrasound is an imaging modality frequently used to provide delineation of tissue bo...
A study is presented in which a new convolution-based methodology has been developed to simulate ult...
Medical ultrasound interpretation requires a great deal of experience. Real-time simulation of medic...
Abstract. Medical ultrasound interpretation requires a great deal of experience. Real-time simulatio...
Medical imagery has been on a continuous development in the last decades, as computers have gotten m...
Monte-Carlo ray tracing, which enables realistic simulation of ultrasound-tissue interactions such a...