A clinical system for three-dimensional extended-field-of-view ultrasound

Dyer, Ellen; Ijaz, Umer Zeeshan; Housden, James; Prager, Richard W.; Gee, Andrew H.; Treece, Graham M.

doi:10.1259/bjr/46007369

Cited by 12 publications

(6 citation statements)

References 14 publications

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“…In 3D-US, the resulting 3D datasets can be reconstructed in the three standard dimensions and evaluated post hoc, in accordance with computed tomography (CT) and magnetic resonance imaging (MRI) [12]. Indeed, the interpretation of 3D-US images may be less prone to inter-observer variability, given the clearer and more objective images [13]. However, 3D-US presents some limitations [12].…”

Section: Discussionmentioning

confidence: 99%

“…Another approach used in 3D-US is the enlargement of the detectable anatomical context through the assembly (stitching) of two or more 3D datasets. This strategy has been investigated in different fields (gynecology, urology, gastrointestinal, cardiology, and orthopedics) [7,12,13,[15][16][17][18], but not yet in thyroid studies. Additionally, the above studies did not focus on volumetric analysis but rather on distance measurements or comparisons between 3D-US EFOV and CT data.…”

Section: Discussionmentioning

confidence: 99%

“…Orientation of 3D-US datasets before stitching can be performed automatically or semi-automatically [12,13,16,17,[19][20][21]; however, in this study, we opted for a manual approach based on the phantom landmarks, with a time span of not more than 2 min. The results show Rho*: correlation coefficient according to Bravais-Pearson analyses; 95% CI: 95% confidence interval of the mean; LOA: Limit of agreement; em: ellipsoid mode; mt: manual tracing that the manual adjustment and the stitching of separately obtained 3D-US datasets acquired via sensor-navigated probe was possible and in fact accurate.…”

Section: Discussionmentioning

confidence: 99%

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Stitching of sensor-navigated 3D ultrasound datasets for the determination of large thyroid volumes – a phantom study

Freesmeyer¹,

Knichel²,

Kühnel³

et al. 2018

Med Ultrason

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Aims: Thyroid volume has to be measured in goiters prior to radioiodine treatment to calculate the needed amount of radioactivity. Modern clinical equipment for ultrasonography shows the trend to smaller probes, so that larger goiters do not fit any longer into the probe’s field of view. This study evaluated the feasibility and accuracy of stitching procedures applied to thyroid volumetric analysis performed using three-dimensional ultrasound (3D-US).Material and methods: Ad hoc thyroid phantoms of different shapes (regular, nodular, thickened isthmus) and volumes (ranging between 50 and 400 mL) were developed. In 15 such phantoms the left and right lobes were separately scanned, and the 3D-US datasets were then assembled (stitched) using predefined landmarks and dedicated software. Volumetric analysis was then assessed via a conventional ellipsoid model (em) and manual tracing (mt). The correlation of measured and reference volumes was determined using Pearson’s correlation coefficients and Bland and Altman limits of agreement.Results: The results showed a high level of agreement (with correlation coefficients ranging from 0.974 to 0.999) for all shapes and volumes tested, including the largest volume of 400 mL. The mt method, although more time consuming, proved superior to the em.Conclusions: Stitching-mediated thyroid volumetric analysis is accurate, and its clinical performance should be investigated in future studies

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Stitching of sensor-navigated 3D ultrasound datasets for the determination of large thyroid volumes – a phantom study

Freesmeyer¹,

Knichel²,

Kühnel³

et al. 2018

Med Ultrason

View full text Add to dashboard Cite

show abstract

“…This restricts the interpretation of anatomical contexts and particularly limits the measurement of large thyroid volumes. Therefore, several EFOV approaches have been investigated [21,[30][31][32][33]. One strategy, stitching of two or more separately acquired 3D-US datasets, has been published in different fields, e.g.…”

Section: Discussionmentioning

confidence: 99%

Stitching of 3D ultrasound datasets for the determination of large thyroid volumes – phantom study part II: mechanically-swept probes

Seifert¹,

Winkens²,

Knichel³

et al. 2019

Med Ultrason

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Aims: To investigate the feasibility and accuracy of 3D-US extended field of view volumetric analyses acquired with mechanically-swept ultrasound probes with different measurement methods for large volume thyroid phantoms.Materials and methods: Fifteen thyroid phantoms with different shapes (regular, nodular, thickened isthmus) and volumes (50-400 mL) were created. Two different mechanically-swept US probes were used for the separate scanning of the left and right lobes: convex and linear probe. After specific modifications, the 3D-US datasets were stitched together to an extended field of view using predefined landmarks. Volumetric analyses were performed by conventional ellipsoid model and manual tracing methods. The correspondence of measured and reference volumes was calculated using Pearson’s correlation coefficients and limits of agreement according to Bland and Altman.Results: The C-probe proved feasible for the acquisition and processing of the three-dimensional ultrasound extended field of view images; very high levels of agreement (correlation coefficients for volume analyses: 0.9843-0.9992) were observed for all shapes and volumes investigated. The manual tracing method showed superior results in comparison to the ellipsoid model, but was more time consuming. The linear probe was only applicable for the 50 mL phantoms due to its limited field of view.Conclusions: The investigated mechanically-swept convex probe was suitable for the three-dimensional ultrasound extended field of view stitching of large volume thyroid phantoms. Accurate volume analyses could be carried out. The mechanically-swept linear probe is limited to a maximum of 50 m

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“…In the traditional ultrasonic extended field of view imaging technology, it is an effective method to obtain wide range images by image stitching using feature point matching [8]. The feature points in image stitching come from the processed image obtained by certain processing of the original image, and the matching of the original ultrasonic image is realized by matching the feature points and their matching relationship [9].…”

Section: Introductionmentioning

confidence: 99%

Dual-Enhanced Registration for Field of View Ultrasound Sonography

et al. 2020

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Extended Field of View Ultrasound Sonography (EFOV-US) uses the existing ultrasound images for image stitching, so as to display the shape and scope of organ occupation and the relationship with surrounding tissues comprehensively. However, there are still some problems in Extended Field of View Ultrasound Sonography, such as matching error and unstable quality of image stitching. In view of these problems, we propose Dual-enhanced EFOV-US method that overcomes the limitation and produces higher quality results. Firstly, the gray enhancement method is used to improve the image contrast and reduce the noise interference. Then the super-resolution method based on the generative adversarial network is used to improve the resolution of the ultrasonic image further and increase the number of feature point matching between stitching images. The high quality ultrasound wide-range image is gotten by stitching and fusing the double enhanced image. The experimental results show that the proposed method is effective and practical.

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A clinical system for three-dimensional extended-field-of-view ultrasound

Cited by 12 publications

References 14 publications

Stitching of sensor-navigated 3D ultrasound datasets for the determination of large thyroid volumes – a phantom study

Stitching of sensor-navigated 3D ultrasound datasets for the determination of large thyroid volumes – a phantom study

Stitching of 3D ultrasound datasets for the determination of large thyroid volumes – phantom study part II: mechanically-swept probes

Dual-Enhanced Registration for Field of View Ultrasound Sonography

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