Initial Experience with an Internally Rotating Transthoracic Three‐Dimensional Echocardiographic Probe and Image Acquisition on a Conventional Echocardiogram Machine

Papavassiliou, Dimitrios; Doelling, R B A Nancy; Bowman, Michael K.; Yeung, Marie; Rock, Jim; Klas, Berthold; Chung, Kevin K.; Fyfe, Derek A.

doi:10.1111/j.1540-8175.1998.tb00618.x

Cited by 8 publications

(4 citation statements)

References 15 publications

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“…Es wurde in den letzten Jahren zu einer leistungsfähigen, multimodalen 3-D-Workstation weiterentwickelt, die mittlerweile die weiteste Verbreitung im Rahmen der verfügbaren 3-D-Techniken gefunden hat. Dabei erfolgt die Akquisition eines 3-D-Datensatzes beim "sequential scanning" durch Veränderungen der Bildebene in der Weise, das diese parallel [1], fächerartig [4] oder um eine zentrale Achse rotierend [5,6] computerkontrolliert bewegt wird. Dabei ist die Datenakquisition entweder über modifizierte handelsübliche Ultraschallsonden und gleichzeitige Verwendung einer 3-D-Workstation oder mit einer bereits in das Ultraschallsystem integrierten automatisierten Akquisitionstechnik transthorakal und transösopha-geal möglich.…”

Section: Dynamische 3-d-echokardiographiedatenakquisitionunclassified

3-D-Echokardiographie: neue Entwicklungen und Zukunftsperspektiven

Müller¹,

Bartel²,

Pachinger³

et al. 2002

Herz

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Due to limitations in transthoracic and occasionally transesophageal 2-D echocardiography with respect to volumetric analysis and morphologic and functional assessment in patients with congenital malformations and valvular heart disease, additional diagnostic tools have been established. In parallel with the rapid evolution in computer technology, 3-D echocardiography has grown into a well-developed technique, such as volume-rendered 3-D reconstruction, capable of displaying dynamic morphology depicting depth of the structures, their attachment, and spatial relation to the surrounding tissue. Nevertheless, the complexity of data acquisition and data processing required for adequate dynamic 3-D echocardiographic imaging and volumetric analysis does not allow to use this approach routinely. The commonly used dynamic 3-D echocardiography means off-line computer-assisted image reconstruction from a series of cross-sectional echocardiographic images using currently available transesophageal and transthoracic transducers. Alternatively, real-time 3-D echocardiography based on novel matrix, phased-array transducer technology has been introduced. Although this technique can be easily combined with any routine examination, its clinical use is limited because of a lower image quality in comparison with dynamic 3-D echocardiography. Up to now, there is no transesophageal approach available using real-time 3-D echocardiography. Recently, dynamic 3-D echocardiographic technique has matured noticeably. Beside the well-known sequential scanning, which is characterized by a fixed probe and patient in space and predetermined motion of the transducer, the freehand scanning using an electromagnetic location system has found its way to clinical environment. The main advantage of this technique is that the transducer can be freely moved by the examiner and, thus, the data set acquired within a routine examination. Also 3-D rendering and display have been developed further. In this respect, especially the "real-time rendering mode" allowing the reconstructed 3-D image to be animated and moved in space and to look at it from different perspectives has gained increasing acceptance. In valvular heart disease, reconstructive surgical treatment is aspired. 3-D echocardiographic imaging is the only technique providing "surgical views" prior to opening the heart. It is capable of distinguishing particular destructive substructures of the valves and the valvular apparatus. Especially in mitral valvular reconstruction, it is of clinical importance to achieve optimal surgical results. With respect to volumetric and mass analysis, 3-D echocardiography is more accurate and reproducible in comparison with conventional 2-D analysis. It provides data independent of geometric assumptions, what may considerably influence the results in the presence of wall motion abnormalities, especially in aneurysmatic ventricles. Volumetric analysis of the aneurysmal portion may also be helpful prior to surgical resection. 3-D echocardiography can also be recommend...

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Section: Dynamische 3-d-echokardiographiedatenakquisitionunclassified

3-D-Echokardiographie: neue Entwicklungen und Zukunftsperspektiven

Müller¹,

Bartel²,

Pachinger³

et al. 2002

Herz

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“…Fig. 1.9) [15] [31]. Nonetheless, despite the practical advantages, the precordial system was not widely accepted because there were still too many artifacts due to the relatively long scanning time causing both displacement of the transducer and motion of the patient due to growing restlessness.…”

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confidence: 99%

Three-dimensional echocardiography: lessons in overcoming time and space

Roelandt¹,

Kisslo²

2015

Three-Dimensional Echocardiography

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“…The initial experience with a prototype handheld transducer with an internally rotating crystal array for multiplane image acquisition was reported recently. 7 The transthoracic echocardiography transducer is comparable in size to conventional probes and is stable during multitomographic data acquisition, because the rotating crystal array is not in direct contact with the body surface.Using the 180°continuous-rotation mode of the multiplane transducer, we developed a rapid 3D image-acquisition technique that addresses the issue of clinical practicality of 3D echocardiography.The purpose of this study was to assess the clinical feasibility and the precision and accuracy of the new rapid, 3D echocardiographic acquisition technique for measuring LV end-diastolic (LVEDV) and end-systolic (LVESV) volumes. Electron-beam computed tomography (EBCT) was used as the reference standard.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Rapid Three-Dimensional Echocardiography

et al. 2001

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Background-Clinical applicability of conventional ultrasonographic systems using mechanical adapters for 3D echocardiographic imaging has been limited by long acquisition and processing times. We developed a rapid (6-s) acquisition technique that collects apical tomograms using a continuously internally rotating transthoracic transducer. This study was performed to examine the clinical feasibility of rapid-acquisition 3D echocardiography to estimate left ventricular end-diastolic and end-systolic volumes using electron-beam computed tomography as the reference standard. Methods and Results-We collected a series of 6 to 11 apical echocardiographic tomograms, depending on heart rate, in 11 patients. There was good correlation, low variability, and low bias between rapid 3D echocardiography and electron-beam computed tomography for measuring left ventricular end-diastolic volume (rϭ0.96; standard error of the estimate, 21.34 mL; bias, Ϫ4.93 mL) and left ventricular end-systolic volume (rϭ0.96; standard error of the estimate, 14.78 mL; bias, Ϫ6.97 mL). Conclusions-The rapid-acquisition 3D echocardiography extends the use of a multiplane, internally rotating handheld transducer so that it becomes a precise and clinically feasible tool for assessing left ventricular volumes and function. A rapid-image acquisition time of 6 s would allow repeated image collection during the course of a clinical echocardiographic examination. Additional work must address rapid and automated data processing. hree-dimensional echocardiography has demonstrated superior accuracy and reproducibility over conventional 2D echocardiography for measuring left ventricular (LV) volume, because no geometric assumptions are necessary about LV shape. 1 Real-time volumetric 3D echocardiography 2 with a very fast, internally rotating crystal array for real-time 3D imaging, 3 various mechanical adapters for rotation or translation with conventional transthoracic echocardiography transducers, 4 or free-hand 3D image acquisition with magnetic 5 or spark-gap 6 spatial positioning systems were investigated in an effort to use the 3D approach in a clinical setting. However, the clinical application of these techniques is not widespread because of compromised image quality, challenging technical design, or slow acquisition times. The initial experience with a prototype handheld transducer with an internally rotating crystal array for multiplane image acquisition was reported recently. 7 The transthoracic echocardiography transducer is comparable in size to conventional probes and is stable during multitomographic data acquisition, because the rotating crystal array is not in direct contact with the body surface.Using the 180°continuous-rotation mode of the multiplane transducer, we developed a rapid 3D image-acquisition technique that addresses the issue of clinical practicality of 3D echocardiography.The purpose of this study was to assess the clinical feasibility and the precision and accuracy of the new rapid, 3D echocardiographic acquisition technique for...

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Initial Experience with an Internally Rotating Transthoracic Three‐Dimensional Echocardiographic Probe and Image Acquisition on a Conventional Echocardiogram Machine

Cited by 8 publications

References 15 publications

3-D-Echokardiographie: neue Entwicklungen und Zukunftsperspektiven

3-D-Echokardiographie: neue Entwicklungen und Zukunftsperspektiven

Three-dimensional echocardiography: lessons in overcoming time and space

Rapid Three-Dimensional Echocardiography

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