The effect of abdominal wall morphology on ultrasonic pulse distortion. Part I. Measurements

Hinkelman, Laura M.; Mast, T. Douglas; Metlay, Leon A.; Waag, Robert C.

doi:10.1121/1.423946

Cited by 92 publications

(66 citation statements)

References 29 publications

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“…Pomaroli et al [70] performed a histologic analysis and showed that fatty tissues with more connective tissues appeared to be more echogenic in B-mode than fatty tissues with fewer connective tissues. Moreover, Hinkelman et al [66] also mentioned that thick layers of fat may cause poor B-mode image quality at the abdominal wall because they distort ultrasound beams due to their scattering and absorption effects.…”

Section: Difficulties In Segmentation Of Fat In Ultrasound Imagesmentioning

confidence: 99%

“…As suggested by Hinkelman at el. [66], the subcutaneous fat has greater energy level and waveform distortion than muscle when they investigated the effect of abdominal wall morphology on ultrasonic pulse distortion. Therefore, we imply that the high variation in the tissue structure of subcutaneous fat causes more fluctuations in the received spectrum, and this results in a greater change in the spectrum variance.…”

Section: Unimodal Thresholdingmentioning

confidence: 99%

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Automatic Measurement of Human Subcutaneous Fat with Ultrasound

Rohling

Lawrence

2009

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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Measuring human subcutaneous fat is useful for assessing health risks due to obesity and for monitoring athletes' health status, body shapes and weight for various sports competitions such as gymnastics and wrestling. Our aim is to investigate the use of ultrasound imaging in automatically measuring human subcutaneous fat thickness.We proposed to use the spectrum properties extracted from the raw radio frequency (RF) signals of ultrasound for the purpose of fat boundary detection. Our fat detection framework consists of four main steps. The first step is capturing RF data from 11 beam steering angles and at four focal positions. Secondly, two spectrum properties (spectrum variance and integrated backscatter coefficient) are calculated from the local spectrum of RF data using the short time Fourier transform and moment analysis. The values of the spectrum properties are encoded as gray-scale parametric images. Thirdly, spatial compounding is used to reduce speckle noise in the parametric images and improve the visualization of the subcutaneous fat layer. Finally, we apply Rosin's thresholding and Random Sample Consensus boundary detection on the parametric images to extract the fat boundary.The detection framework was tested on 36 samples obtained at the suprailiac, thigh and triceps of nine human participants in vivo. When compared to manual boundary detection on ultrasound images, the best result was obtained from segmenting the spatial compounded spectrum variance values averaged over multiple focuses. A reasonable result could also be obtained by using a single focus. Further, our automatic detection results were compared with the results using skinfold caliper measurements. We found that the correlation is high between our automatic detection and skinfold caliper measurement, and is similar to the previous studies which are not automatic.Our work has shown that the spatial compounded spectrum properties of RF data can be used to segment the subcutaneous fat layer. Based on our results, it is feasible to detect fat at the suprailiac, thigh and triceps sites using the spectrum variance. The values of spectrum variance change more rapidly in the fat tissue than the non-fat tissue.iii

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Section: Difficulties In Segmentation Of Fat In Ultrasound Imagesmentioning

confidence: 99%

Section: Unimodal Thresholdingmentioning

confidence: 99%

Automatic Measurement of Human Subcutaneous Fat with Ultrasound

Rohling

Lawrence

2009

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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“…Data acquisition was performed with an apparatus used in previously reported aberration measurements on tissue specimens. 2,13 Ultrasonic pulses with 3.75 MHz center frequency and 2.2 MHz -6-dB bandwidth were emitted from a hemispheric source positioned 185 mm below a 128-element linear array with the same center frequency and bandwidth. The lateral array pitch was 0.72 mm, and the elements were masked to produce an effective height of 1.44 mm in the out-of-plane direction.…”

Section: Aberration Propertiesmentioning

confidence: 99%

“…Aberration is particularly severe when imaging through the abdominal wall where sound speed variations and strong scattering can occur in both muscle layers and subcutaneous fat. [1][2][3] Arrival time, energy level, and shape changes in propagating waveforms are often encountered, resulting in a decrease in the peak amplitude at the focus, a broader focus, and an increase in the peripheral energy. This focus degradation is a major barrier to achieving diffraction-limited resolution with large aperture transducers.…”

Section: Introductionmentioning

confidence: 99%

Distributed aberrators for emulation of ultrasonic pulse distortion by abdominal wall

Lacefield

Pilkington

Waag

2002

Acoustics Research Letters Online

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“…In this case, the parameter set consists of the two depths of the planar interfaces, given by D 1 and D 2 . The scalar error that is minimized is given by E(p) = n (y n − y(n; p)) 2 where y n and y(n; p) are the data signal and the synthesized signal respectively.…”

Section: Iterative Inversionmentioning

confidence: 99%

Modeling and Analysis of Ultrasonic Echoes Reflected from a Surface under Two Layers

Dey

Kanade

2000

Medical Image Computing and Computer-Assisted Intervention – MICCAI 2000

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Abstract. Fat and muscle layers in the human soft-tissue causes degradation of resolution and distortions of shape in ultrasound images of organs. Novel ultrasonic applications such as registration between CT and ultrasound images, requiring comparable levels of accuracies between modalities could suffer from the distortions in ultrasound images. In this work, we describe a possible method to compensate or correct for these distortions in ultrasound images. This can be used as a pre-processing step before registration with other modalities. We derived a model of ultrasound field after reflection from an interface embedded in two layers. Experiments were performed using single-element transducers and custom made tissue mimicking phantoms of fat and muscle and a steel-block. We fit the model to the experimental data using Levenberg-Marquardt inversion.

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The effect of abdominal wall morphology on ultrasonic pulse distortion. Part I. Measurements

Cited by 92 publications

References 29 publications

Automatic Measurement of Human Subcutaneous Fat with Ultrasound

Automatic Measurement of Human Subcutaneous Fat with Ultrasound

Distributed aberrators for emulation of ultrasonic pulse distortion by abdominal wall

Modeling and Analysis of Ultrasonic Echoes Reflected from a Surface under Two Layers

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