3-D Super-Resolution Ultrasound Imaging With a 2-D Sparse Array

Harput, Sevan; Tortoli, Piero; Eckersley, Robert J.; Dunsby, Chris; Tang, Meng-Xing; Christensen-Jeffries, Kirsten; Ramalli, Alessandro; Brown, Jemma; Zhu, Jiaqi; Zhang, Ge; Leow, Chee Hau; Toulemonde, Matthieu; Boni, Enrico

doi:10.1109/tuffc.2019.2943646

Cited by 85 publications

(59 citation statements)

References 68 publications

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“…The major advantage is that the volume is focused in all three directions including the elevation direction, which yields a resolution of (1.17λ × 2.12λ × 0.63λ ) at a depth of 15 mm. This was attained for a modest 62 elements, which both reduces the amount of data from the probe by a factor of 8 compared to previous 3-D SRI [13] as well as the beamforming time for a probe with 4 times the area of a 1024 elements 2-D matrix probe. Points outside in y-z plane Fig.…”

Section: Discussionmentioning

confidence: 96%

3-D Super Resolution Imaging using a 62+62 Elements Row-Column Array

Jensen

Tomov

Schou

et al. 2019

2019 IEEE International Ultrasonics Symposium (IUS)

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Current 2-D Super Resolution (SR) imaging is limited by the slice thickness determined by the elevation focus. The fixed, geometric elevation focus is often poor due to its high F-number. SR images are, thus, a summation of vessels across the elevation plane without the possibility to track scatterers in 3-D for full visualization. 3-D SR imaging has been obtained by translating the probe, but this does not remove the elevation summation. Full 3-D can be acquired using 2-D matrix probes, but the equipment is expensive, and the amount of data is excessive, when channel data are acquired over thousands of elements for minutes. This paper demonstrates that full volumetric SRI can be attained using a 62+62 channels Row-Column (RC) probe with a high frame rate and with µm precision. Data were acquired by a 3 MHz 62+62 PZT RC probe with λ /2 pitch connected to the SARUS scanner. A synthetic aperture scan sequence with 32 positive and 32 negative emissions was employed for pulse inversion (PI) imaging with an MI of 0.3. The pulse repetition frequency was 10 kHz for a 156 Hz volume rate. A PEGDA 700 g/mol based hydrogel flow-microphantom was 3-D printed by stereo-lithography. It contains a single cylindrical 200 µm diameter channel placed 3 mm from the top surface of the phantom. After a 5.8 mm long inlet, the channel bends 90 • into a 7 mm long central region before bending 90 • again into the 5.8 mm outlet. The flow channel was infused at 1.61 µL/s with Sonovue (Bracco) in a 1:10 dilution. The received RF signals from the 62 row elements were beamformed with PI to yield a full volume of 15 x 15 x 15 mm 3. The interpolated 3-D positions of the bubbles were estimated after local maximum detection. The reconstructed 3-D SR volume clearly shows the 200 µm channel shape with a high resolution in all three dimensions. The center line for the channel was found by fitting a line to all bubble positions, and their radial position calculated. The observed fraction of bubbles falling outside the channel was used for estimating the location precision. The precision was 16.5 µm in the y − z plane and 23.0 µm in the x − z plane. The point spread function had a size of 0.58 x 1.05 x 0.31 mm 3 , so the interrogated volume was 15,700 times smaller than for normal volumetric B-mode imaging. This demonstrates that full 3-D SRI can be attained with just 62 receive channels. The SA sequence has a low MI, but attains a large measured penetration depth of 14 cm in a tissue mimicking phantom, due to the large RC probe size. The 156 Hz volume rate also makes it possible to track high velocities in 3-D in the volume.

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Section: Discussionmentioning

confidence: 96%

3-D Super Resolution Imaging using a 62+62 Elements Row-Column Array

Jensen

Tomov

Schou

et al. 2019

2019 IEEE International Ultrasonics Symposium (IUS)

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“…In the future, with the development of fast 3D ultrasound imaging technology using a 2D transducer matrix 32 , vUS can be easily adopted for 3D velocimetry of the whole rodent brain. In addition, in combination with oxygenation measurements using multispectral photoacoustic tomography (mPAT) and given the blood flow (velocity) measured by vUS, the direct biomarker indicating neuron activity, i.e., the metabolic rate of oxygen, can be readily measured, which will greatly facilitate neuroscience research.…”

Section: Discussionmentioning

confidence: 99%

Functional ultrasound speckle decorrelation-based velocimetry of the brain

Tang

Postnov

Kılıç

et al. 2019

Preprint

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We present a high-speed, contrast free, quantitative ultrasound velocimetry (vUS) for blood flow velocity imaging of the whole coronal section of rodent brain, complementing the high-speed, non-quantitative functional ultrasound imaging (fUS) and the low-speed, quantitative velocimetry by ultrasound localization microscopy (vULM). We developed the theory for analyzing the normalized first order temporal autocorrelation function of ultrasound speckle dynamics to quantify 'angle-independent' blood flow velocity. Further, by utilizing an ULM spatial constraint on the bulk motion rejected data, vUS provides high resolution blood flow velocity images at a frame rate of 1 frame/s, compared to ~ 2 mins per frame with vULM. vUS was validated with numerical simulation, phantom experiments, and in vivo measurements against vULM. We demonstrated the functional imaging ability of vUS by monitoring blood flow velocity changes during whisker stimulation in awake mice.

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“…In vivo, this apparatus was able to reconstruct entire super-resolved volumes of the rat brain, alleviating the previously described drawbacks with 3-D tracking and motion correction. Harput et al (2019b) reduced the number of connected channels by implementing super-resolution on a 2-D sparse array. 3-D super-resolution could even be performed with a clinical scanner as described by Christensen-Jeffries et al (2018).…”

Section: Three Dimensionsmentioning

confidence: 99%

“…In the past decade it has been well reported that the vaporization of such phase-change nanodroplets into microbubbles can be controlled by acoustic pressure (Sheeran et al 2012). This phase transition also depends on nanodroplet characteristics (e.g., size distribution and boiling point of the gas) and external factors (e.g., microvessel confinement [Lin et al 2018] and attachment to cells [Zhang et al 2019b]).…”

Section: Super-resolution Ultrasound Using Phase-shift Agentsmentioning

confidence: 99%

“…However, motion that occurs orthogonal to the image plane remains a challenge. In this context, advancing CEUS imaging from 2-D to true 3-D using matrix transducers, which has been done in vitro (Harput et al 2019a;Heiles et al 2019), may not only allow display of the vascular network in much greater comprehensiveness and detail, but also holds promise for a precise motion correction in all directions (Harput et al 2019b).…”

Section: Oncologymentioning

confidence: 99%

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Super-resolution Ultrasound Imaging

Christensen-Jeffries¹,

Couture²,

Dayton³

et al. 2020

Ultrasound in Medicine & Biology

Self Cite

315

173

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The majority of exchanges of oxygen and nutrients are performed around vessels smaller than 100 mm, allowing cells to thrive everywhere in the body. Pathologies such as cancer, diabetes and arteriosclerosis can profoundly alter the microvasculature. Unfortunately, medical imaging modalities only provide indirect observation at this scale. Inspired by optical microscopy, ultrasound localization microscopy has bypassed the classic compromise between penetration and resolution in ultrasonic imaging. By localization of individual injected microbubbles and tracking of their displacement with a subwavelength resolution, vascular and velocity maps can be produced at the scale of the micrometer. Super-resolution ultrasound has also been performed through signal fluctuations with the same type of contrast agents, or through switching on and off nano-sized phase-change contrast agents. These techniques are now being applied pre-clinically and clinically for imaging of the microvasculature of the brain, kidney, skin, tumors and lymph nodes.

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3-D Super-Resolution Ultrasound Imaging With a 2-D Sparse Array

Cited by 85 publications

References 68 publications

3-D Super Resolution Imaging using a 62+62 Elements Row-Column Array

3-D Super Resolution Imaging using a 62+62 Elements Row-Column Array

Functional ultrasound speckle decorrelation-based velocimetry of the brain

Super-resolution Ultrasound Imaging

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