Volume Measurement in Sequential Freehand 3-D Ultrasound

Treece, Graham M.; Prager, Richard W.; Gee, Andrew H.; Berman, Laurence

doi:10.1007/3-540-48714-x_6

Cited by 10 publications

(9 citation statements)

References 171 publications

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“…This problem has been addressed by many authors, trying to align centroids before interpolation, and scale the cross-sections to match bounding rectangles, etc, but still not generate correct surfaces in complex cases. Treece [99] recognized that the problem is in the definition of connectivity, because the correspondence evaluating entire contours is too coarse. He proposed the disc-guided interpolation, where the interpolation is guided by using correspondence of regions of the cross-sections.…”

Section: Shape Based Interpolationmentioning

confidence: 99%

“…Much effort is required for detection and handling of special cases to allow a correct triangulation. An alternative to the direct reconstruction approach is to use the crosssections to estimate a 3D function that represents the measure of distance from any point to the surface [99]. Among these method belongs the shapebased interpolation proposed by Raya and Udupa [85], which uses the cityblock distance to the surface.…”

Section: Shape Based Interpolationmentioning

confidence: 99%

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Geometric Methods for Vessel Visualization and Quantification — A Survey

Bühler

Felkel

Cruz

2004

Geometric Modeling for Scientific Visualization

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Summary. Visualization and quantitative analysis of vessel data is an important preprocessing step in diagnosis of vascular diseases, monitoring, surgery planning, blood flow simulation, education and training of surgeons. This paper surveys several geometrie methods to solve basie visualization and quantification problems like centerline computation, boundary detection, projection teehniques, and geometrie model generation.

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Section: Shape Based Interpolationmentioning

confidence: 99%

Section: Shape Based Interpolationmentioning

confidence: 99%

Geometric Methods for Vessel Visualization and Quantification — A Survey

Bühler

Felkel

Cruz

2004

Geometric Modeling for Scientific Visualization

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show abstract

“…Such operations are labeled Type 1. Examples of such operations are: image gray level slice interpolation methods (linear, spline-based methods) [57], shape-based (binary as well as gray-level) interpolation [57][58][59][60][61], image-based registration (via mutual information/correlation) [62,63], diffusive filtering [64][65][66], inhomogeneity correction [67], all non-user-steered slice-byslice segmentation methods (such as clustering techniques), non-connected isosurface detection, and structure manipulation [46,54]. There are other CAVA operations, which work (chunk-by-chunk) in the above sense but some further operation is needed to combine the outputs produced by the chunks to yield the final output.…”

Section: Parallel Visualizationmentioning

confidence: 99%

CAVASS: a computer assisted visualization and analysis software system - visualization aspects

Grevera

Udupa

Odhner

et al. 2007

Medical Imaging 2007: Visualization and Image-Guided Procedures

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The Medical Image Processing Group (MIPG) at the University of Pennsylvania has been developing and distributing medical image analysis and visualization software systems for a long period of time. Our most recent system, 3DVIEWNIX, was first released in 1993. Since that time, a number of significant advancements have taken place with regard to computer platforms and operating systems, networking capability, the rise of parallel processing standards, and the development of open source toolkits. The development of CAVASS by our group is the next generation of 3DVIEWNIX. CAVASS will be freely available, open source, and is integrated with toolkits such as ITK and VTK. CAVASS runs on Windows, Unix, and Linux but shares a single code base. Rather than requiring expensive multiprocessor systems, it seamlessly provides for parallel processing via inexpensive COWs (Cluster of Workstations) for more time consuming algorithms. Most importantly, CAVASS is directed at the visualization, processing, and analysis of medical imagery, so support for 3D and higher dimensional medical image data and the efficient implementation of algorithms is given paramount importance. This paper focuses on aspects of visualization. All of the most of the popular modes of visualization including various 2D slice modes, reslicing, MIP, surface rendering, volume rendering, and animation are incorporated into CAVASS.

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“…Such operations are labeled Type 1. Examples of such operations are: image gray level slice interpolation methods (linear, spline-based methods) [30], shape-based (binary as well as gray-level) interpolation [30][31][32][33][34], image-based registration (via mutual information/correlation) [35,36], diffusive filtering [37][38][39], inhomogeneity correction [40], all non-user-steered slice-byslice segmentation methods (such as clustering techniques), non-connected isosurface detection, and structure manipulation [17,24]. There are other CAVA operations, which work (chunk-by-chunk) in the above sense but some further operation is needed to combine the outputs produced by the chunks to yield the final output.…”

Section: Fig 2 Examples Of Overlaid Slice Display (Left) and Triangmentioning

confidence: 99%

Introducing CAVASS: a Computer-Assisted Visualization and Analysis Software System

et al. 2007

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The Medical Image Processing Group (MIPG) at the University of Pennsylvania has been developing (and distributing with source code) medical image analysis and visualization software systems for a long period of time. Our most recent system, 3DVIEWNIX, was first released in 1993. Since that time, a number of significant advancements have taken place with regard to computer platforms and operating systems, networking capability, the rise of parallel processing standards, and the development of open source toolkits. The development of CAVASS by our group is the next generation of 3DVIEWNIX. CAVASS will be freely available, open source, and is integrated with toolkits such as ITK and VTK. CAVASS runs on Windows, Unix, and Linux but shares a single code base. Rather than requiring expensive multiprocessor systems, it seamlessly provides for parallel processing via inexpensive COWs (Cluster of Workstations) for more time consuming algorithms. Most importantly, CAVASS is directed at the visualization, processing, and analysis of 3D and higher dimensional medical imagery, so support for DICOM data and the efficient implementation of algorithms is given paramount importance.

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Volume Measurement in Sequential Freehand 3-D Ultrasound

Cited by 10 publications

References 171 publications

Geometric Methods for Vessel Visualization and Quantification — A Survey

Geometric Methods for Vessel Visualization and Quantification — A Survey

CAVASS: a computer assisted visualization and analysis software system - visualization aspects

Introducing CAVASS: a Computer-Assisted Visualization and Analysis Software System

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