Journal ArticleDOI
Three-Dimensional Ultrasound Imaging
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TLDR
A review article describes the developments of a number of 3D ultrasound imaging systems using mechanical, free-hand and 2D array scanning techniques and the sources of errors in the reconstruction techniques as well as formulae relating design specification to geometric errors.Abstract:
Ultrasound is an inexpensive and widely used imaging modality for the diagnosis and staging of a number of diseases. In the past two decades, it has benefited from major advances in technology and has become an indispensable imaging modality, due to its flexibility and non-invasive character. In the last decade, research investigators and commercial companies have further advanced ultrasound imaging with the development of 3D ultrasound. This new imaging approach is rapidly achieving widespread use with numerous applications. The major reason for the increase in the use of 3D ultrasound is related to the limitations of 2D viewing of 3D anatomy, using conventional ultrasound. This occurs because: (a) Conventional ultrasound images are 2D, yet the anatomy is 3D, hence the diagnostician must integrate multiple images in his mind. This practice is inefficient, and may lead to variability and incorrect diagnoses. (b) The 2D ultrasound image represents a thin plane at some arbitrary angle in the body. It is difficult to localize the image plane and reproduce it at a later time for follow-up studies. In this review article we describe how 3D ultrasound imaging overcomes these limitations. Specifically, we describe the developments of a number of 3D ultrasound imaging systems using mechanical, free-hand and 2D array scanning techniques. Reconstruction and viewing methods of the 3D images are described with specific examples. Since 3D ultrasound is used to quantify the volume of organs and pathology, the sources of errors in the reconstruction techniques as well as formulae relating design specification to geometric errors are provided. Finally, methods to measure organ volume from the 3D ultrasound images and sources of errors are described.read more
Citations
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Journal ArticleDOI
A New Three-Dimensional Ultrasound Microimaging Technology for Preclinical Studies Using a Transgenic Prostate Cancer Mouse Model
Lauren A. Wirtzfeld,Guojun Wu,Michael Bygrave,Yasuto Yamasaki,Hideki Sakai,Madeleine Moussa,Jonathan I. Izawa,Donal B. Downey,Norman M. Greenberg,Aaron Fenster,Jim W. Xuan,James C. Lacefield +11 more
TL;DR: Compared with other microim imaging and molecular imaging modalities, the application of three-dimensional ultrasound imaging to prostate cancer in mice showed advantages, such as high spatial resolution and contrast in soft tissue, fast and uncomplicated protocols, and portable and economical equipment that will likely enable ultrasound to become a new microimaging modality for mouse preclinical trial studies.
Journal ArticleDOI
Prostate boundary segmentation from 3D ultrasound images.
Ning Hu,Ning Hu,Donal B. Downey,Donal B. Downey,Donal B. Downey,Aaron Fenster,Aaron Fenster,Aaron Fenster,Hanif M. Ladak,Hanif M. Ladak +9 more
TL;DR: An algorithm is described for semiautomatic segmentation of the prostate from 3D ultrasound images using model-based initialization and mesh refinement using an efficient deformable model to improve the final results.
Journal ArticleDOI
Review of ultrasound image guidance in external beam radiotherapy part II: intra-fraction motion management and novel applications.
Tuathan O'Shea,Jeffrey C. Bamber,Davide Fontanarosa,Davide Fontanarosa,Skadi van der Meer,Frank Verhaegen,Frank Verhaegen,Emma J. Harris +7 more
TL;DR: The basic technology for US motion estimation, and its current clinical application to the prostate, is described here, along with recent developments in robust motion-estimation algorithms, and three dimensional (3D) imaging.
Proceedings ArticleDOI
A Rapid Calibration Method for Registration and 3D Tracking of Ultrasound Images Using Spatial Localizer
TL;DR: The purpose of this study is to enhance previously known calibration methods by introducing a novel calibration fixture and process, which is inexpensive, easy to construct,easy to scan, while yielding more data points per image than previously known designs.
Journal ArticleDOI
Theoretical and experimental quantification of carotid plaque volume measurements made by three-dimensional ultrasound using test phantoms.
Anthony Landry,Aaron Fenster +1 more
TL;DR: This study investigates the accuracy and variability of plaque volume measurement by three-dimensional ultrasound using vascular plaque phantoms over a range of 68.2 mm3 to 285.5 mm3 and develops a theoretical description for the variance in measurement of plaqueVolume using manual planimetry.
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