Are All Deep Learning Architectures Alike for Point‐of‐Care Ultrasound?: Evidence From a Cardiac Image Classification Model Suggests Otherwise

Blaivas, Michael; Blaivas, Laura N

doi:10.1002/jum.15206

Cited by 25 publications

(28 citation statements)

References 16 publications

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“…To overcome this and offer interpretation assistance at the point of care, early investigations involving several convolutional neural networks (CNN) have shown promise. Contrary to what has been found in other studies using artificial intelligence for non-ultrasound images, the simpler rather than more complex CNNs may be more apt to perform well on the greyscale grainy images characteristic of ultrasound [67]. One commercially available product is harnessing POCUS images on a cloud-based storage system to facilitate deep learning that hopefully will eventually be employed to aid the inexperienced user.…”

Section: Future Directionsmentioning

confidence: 88%

Point-of-Care Ultrasound

Lee

DeCara

2020

Curr Cardiol Rep

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Purpose of the Review Point-of-care ultrasound using small ultrasound devices has expanded beyond emergency and critical care medicine to many other subspecialties. Awareness of the strengths and limitations of the technology and knowledge of the appropriate settings and common indications for point-of-care ultrasound is important. Recent Findings Point-of-care ultrasound is widely embraced as an extension of the physical exam and is employed in acute care and medical education settings. Echocardiography laboratories involved in education must individualize training to the intended scope of practice of the user. Advances in artificial intelligence may assist in image acquisition and interpretation by novice users. Summary Point-of-care ultrasound is widely available in a variety of clinical settings. The field has advanced substantially in the past 2 decades and will likely continue to expand with advancement in technology, reduced cost, and improved opportunities to assist new users.

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Section: Future Directionsmentioning

confidence: 88%

Point-of-Care Ultrasound

Lee

DeCara

2020

Curr Cardiol Rep

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“…Code for VGG‐16 is available from various public sources including github.com. VGG‐16, which won the ImageNet Large Scale Visual Recognition Challenge (ILSVRC) competition in 2014, is an early convolutional neural network using 16 layers and has been shown to be superior for ultrasound deep learning applications in prior work 17 . LSTM refers to a structure that incorporates a convolutional neural network into a structure that tracks temporal changes on ultrasound images and is used in non‐medical circles to identify specific action on sports video and even predict outcomes of movements or actions.…”

Section: Methodsmentioning

confidence: 99%

Artificial intelligence versus expert: a comparison of rapid visual inferior vena cava collapsibility assessment between POCUS experts and a deep learning algorithm

et al. 2020

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Objectives We sought to create a deep learning algorithm to determine the degree of inferior vena cava (IVC) collapsibility in critically ill patients to enable novice point‐of‐care ultrasound (POCUS) providers. Methods We used publicly available long short term memory (LSTM) deep learning basic architecture that can track temporal changes and relationships in real‐time video, to create an algorithm for ultrasound video analysis. The algorithm was trained on public domain IVC ultrasound videos to improve its ability to recognize changes in varied ultrasound video. A total of 220 IVC videos were used, 10% of the data was randomly used for cross correlation during training. Data were augmented through video rotation and manipulation to multiply effective training data quantity. After training, the algorithm was tested on the 50 new IVC ultrasound video obtained from public domain sources and not part of the data set used in training or cross validation. Fleiss’ κ was calculated to compare level of agreement between the 3 POCUS experts and between deep learning algorithm and POCUS experts. Results There was very substantial agreement between the 3 POCUS experts with κ = 0.65 (95% CI = 0.49–0.81). Agreement between experts and algorithm was moderate with κ = 0.45 (95% CI = 0.33–0.56). Conclusions Our algorithm showed good agreement with POCUS experts in visually estimating degree of IVC collapsibility that has been shown in previously published studies to differentiate fluid responsive from fluid unresponsive septic shock patients. Such an algorithm could be adopted to run in real‐time on any ultrasound machine with a video output, easing the burden on novice POCUS users by limiting their task to obtaining and maintaining a sagittal proximal IVC view and allowing the artificial intelligence make real‐time determinations.

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“…35 However, before machine learning approaches can be relied upon to produce accurate RWE, the algorithms must be tested, refined, and retested in real-world situations to ensure high accuracy. 37 Challenges with Using AI and RWD Although AI shows promise for application in the healthcare industry, the diverse, complex, and observational nature of RWD presents challenges for data analysis. 9 For example, claims data are typically generated for insurance billing purposes, not adjudicated in terms of data quality, and medical errors can exist.…”

Section: How Can Artificial Intelligence Be Used To Generate Rwe?mentioning

confidence: 99%

“…Initial attempts to elevate the quality of analysis might include combining multiple data sources, the consideration of doctor shorthand in language processing, and systematic comparisons of machine learning algorithms within or across therapeutic areas. 34,35,37,38 In some countries, data aggregation may pose an equally significant challenge. Legal barriers around data privacy, eg, European Union General Data Protection Regulation (GDPR), 39 practical barriers related to data storage across multiple organizations (ie, data silos), and economic barriers involving lack of incentives for organizations to collaborate and share data, all affect the availability of RWD to which AI tools can be applied.…”

Section: Adaptive Boostingmentioning

confidence: 99%

<p>Harnessing Real-World Data for Regulatory Use and Applying Innovative Applications</p>

Zou¹,

Li²,

Imperato³

et al. 2020

JMDH

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A vast quantity of real-world data (RWD) are available to healthcare researchers. Such data come from diverse sources such as electronic health records, insurance claims and billing activity, product and disease registries, medical devices used in the home, and applications on mobile devices. The analysis of RWD produces real-world evidence (RWE), which is clinical evidence that provides information about usage and potential benefits or risks of a drug. This review defines and explains RWD, and it also details how regulatory authorities are using RWD and RWE. The main challenges in harnessing RWD include collating and analyzing numerous disparate types or categories of available information including both structured (eg, field entries) and unstructured (eg, doctor notes, discharge summaries, social media posts) data. Although the use of artificial intelligence to capture, amalgamate, standardize, and analyze RWD is still evolving, it has the potential to support the increased use of RWE to improve global health and healthcare.

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Are All Deep Learning Architectures Alike for Point‐of‐Care Ultrasound?: Evidence From a Cardiac Image Classification Model Suggests Otherwise

Cited by 25 publications

References 16 publications

Point-of-Care Ultrasound

Point-of-Care Ultrasound

Artificial intelligence versus expert: a comparison of rapid visual inferior vena cava collapsibility assessment between POCUS experts and a deep learning algorithm

<p>Harnessing Real-World Data for Regulatory Use and Applying Innovative Applications</p>

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