Deep Neural Networks for Ultrasound Beamforming

Luchies, Adam; Byram, Brett

doi:10.1109/tmi.2018.2809641

Cited by 145 publications

(36 citation statements)

References 20 publications

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“…Recently, inspired by the tremendous success of deep learning, many researchers have investigated deep learning approaches for various inverse problems [10]- [21]. In US literature, the works in [22], [23] were among the first to apply deep learning approaches to US image reconstruction. In particular, Allman et al [22] proposed a machine learning method to identify and remove reflection artifacts in photoacoustic channel data.…”

Section: Introductionmentioning

confidence: 99%

“…In particular, Allman et al [22] proposed a machine learning method to identify and remove reflection artifacts in photoacoustic channel data. Luchies and Byram [23] proposed a frequency domain deep learning method for suppressing offaxis scattering in ultrasound channel data. In [24], a deep neural network is designed to estimate the attenuation characteristics of sound in human body.…”

Section: Introductionmentioning

confidence: 99%

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Adaptive and Compressive Beamforming Using Deep Learning for Medical Ultrasound

Khan

Huh

2020

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

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In ultrasound (US) imaging, various types of adaptive beamforming techniques have been investigated to improve the resolution and contrast to noise ratio of the delay and sum (DAS) beamformers. Unfortunately, the performance of these adaptive beamforming approaches degrade when the underlying model is not sufficiently accurate and the number of channels decreases. To address this problem, here we propose a deep learning-based end-to-end beamformer to generate significantly improved images over widely varying measurement conditions and channel subsampling patterns. In particular, our deep neural network is designed to directly process full or sub-sampled radio-frequency (RF) data acquired at various subsampling rates and detector configurations so that it can generate high quality ultrasound images using a single beamformer. The origin of such adaptivity is also theoretically analyzed. Experimental results using B-mode focused ultrasound confirm the efficacy of the proposed methods.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Adaptive and Compressive Beamforming Using Deep Learning for Medical Ultrasound

Khan

Huh

2020

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

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“…One of the most important recent developments in the field of image reconstruction is the introduction of deep learning approaches [38]. Motivated by the tremendous success of deep learning for image classification [153], [154], image segmentation [155], denoising [156], etc, many groups have recently successfully applied deep learning approaches to various image reconstruction problems such as in X-ray CT [157]- [163], MRI [33], [162], [164]- [168], PET [169], [170] ultrasound [171], [172], and optics [173]- [175]. As of mid 2019, two commercial CT vendors received FDA approval for deep learning image reconstruction [176] [177].…”

Section: Deep Learning Methodsmentioning

confidence: 99%

Image Reconstruction: From Sparsity to Data-Adaptive Methods and Machine Learning

2020

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The field of medical image reconstruction has seen roughly four types of methods. The first type tended to be analytical methods, such as filtered back-projection (FBP) for X-ray computed tomography (CT) and the inverse Fourier transform for magnetic resonance imaging (MRI), based on simple mathematical models for the imaging systems. These methods are typically fast, but have suboptimal properties such as poor resolution-noise trade-off for CT. A second type is iterative reconstruction methods based on more complete models for the imaging system physics and, where appropriate, models for the sensor statistics. These iterative methods improved image quality by reducing noise and artifacts. The FDA-approved methods among these have been based on relatively simple regularization models. A third type of methods has been designed to accommodate modified data acquisition methods, such as reduced sampling in MRI and CT to reduce scan time or radiation dose. These methods typically involve mathematical image models involving assumptions such as sparsity or lowrank. A fourth type of methods replaces mathematically designed models of signals and systems with data-driven or adaptive models inspired by the field of machine learning. This paper focuses on the two most recent trends in medical image reconstruction: methods based on sparsity or low-rank models, and data-driven methods based on machine learning techniques.

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“…This raises an interesting question: If it is known what information is desired or desirable at any given point during surgery, is it possible to prospectively acquire an image that is most informative in that particular context? First steps in this direction have recently been reported, exploiting ultrasound image formation to suppress scatter [89] or beamforming a B-mode image [90], [91] together with producing its segmentation [69]. Zaech et al [92] use an AI-based algorithm to recommend task-optimal and patient specific C-arm X-ray trajectories during conebeam CT of spinal fusion surgery, and similar ideas arise for ultrasound transducer positioning [93].…”

Section: Towards Prospectively Planned Intelligent Imagingmentioning

confidence: 99%

CAI4CAI: The Rise of Contextual Artificial Intelligence in Computer-Assisted Interventions

et al. 2020

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Data-driven computational approaches have evolved to enable extraction of information from medical images with a reliability, accuracy and speed which is already transforming their interpretation and exploitation in clinical practice. While similar benefits are longed for in the field of interventional imaging, this ambition is challenged by a much higher heterogeneity. Clinical workflows within interventional suites and operating theatres are extremely complex and typically rely on poorly integrated intra-operative devices, sensors, and support infrastructures. Taking stock of some of the most exciting developments in machine learning and artificial intelligence for computer assisted interventions, we highlight the crucial need to take context and human factors into account in order to address these challenges. Contextual artificial intelligence for computer assisted intervention, or CAI4CAI, arises as an emerging opportunity feeding into the broader field of surgical data science. Central challenges being addressed in CAI4CAI include how to integrate the ensemble of prior knowledge and instantaneous sensory information from experts, sensors and actuators; how to create and communicate a faithful and actionable shared representation of the surgery among a mixed human-AI actor team; how to design interventional systems and associated cognitive shared control schemes for online uncertainty-aware collaborative decision making ultimately producing more precise and reliable interventions.Index Terms-Artificial intelligence, computer assisted interventions, interventional workflow, intra-operative imaging, surgical planning, data fusion, surgical scene understanding, contextaware user interface, machine and deep learning, surgical data science

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Deep Neural Networks for Ultrasound Beamforming

Cited by 145 publications

References 20 publications

Adaptive and Compressive Beamforming Using Deep Learning for Medical Ultrasound

Adaptive and Compressive Beamforming Using Deep Learning for Medical Ultrasound

Image Reconstruction: From Sparsity to Data-Adaptive Methods and Machine Learning

CAI4CAI: The Rise of Contextual Artificial Intelligence in Computer-Assisted Interventions

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