Challenges of implementing computer-aided diagnostic models for neuroimages in a clinical setting

Leming, Matthew; Bron, Esther E.; Bruffaerts, Rose; Ou, Yangming; Iglesias, Juan Eugenio; Gollub, Randy L.; Im, Hyungsoon

doi:10.1038/s41746-023-00868-x

Cited by 10 publications

(6 citation statements)

References 127 publications

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“…CE-marked and FDA-approved commercial tools for clinical decision support by brain morphometry have meanwhile become available for application in patients with multiple sclerosis and various forms of dementia. Despite formal approval for diagnostic purposes, a deficiency of these tools is that validation, especially in clinical terms, in many cases still is an open topic of research (Pemberton et al, 2021; Mendelson et al, 2023) due to a multitude of factors (Haller et al, 2022; Leming et al, 2023; Hedderich et al, 2023). This is remarkable, since an international survey among practitioners investigating their application of (commercial or scientific) brain morphometry tools has clearly shown that user acceptance is associated with the availability of technical and clinical validation studies (Vernooij et al, 2019).…”

Section: Summary and Discussionmentioning

confidence: 99%

Cortical thickness and grey-matter volume anomaly detection in individual MRI scans: Comparison of two methods

Romascano,

Rebsamen,

Radojewski

et al. 2024

Preprint

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Over the past decades, morphometric analysis of brain MRI has contributed substantially to the understanding of healthy brain structure, development and aging as well as to improved characterisation of disease related pathologies. Certified commercial tools based on normative modeling of these metrics are meanwhile available for diagnostic purposes, but they are cost intensive and their clinical evaluation is still in its infancy. Here we have compared the performance of "ScanOMetrics", an open-source research-level tool for detection of statistical anomalies in individual MRI scans, depending on whether it is operated on the output of FreeSurfer or of the deep learning based brain morphometry tool DL+DiReCT. When applied to the public OASIS3 dataset, containing patients with Alzheimer's disease (AD) and healthy controls (HC), cortical thickness anomalies in patient scans were mainly detected in regions that are known as predilection areas of cortical atrophy in AD, regardless of the software used for extraction of the metrics. By contrast, anomaly detections in HCs were up to twenty-fold reduced and spatially unspecific using both DL+DiReCT and FreeSurfer. Progression of the atrophy pattern with clinical dementia rating (CDR) was clearly observable with both methods. DL+DiReCT provided results in less than 25 minutes, more than 15 times faster than FreeSurfer. This difference in computation time might be relevant when considering application of this or similar methodology as diagnostic decision support for neuroradiologists.

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Section: Summary and Discussionmentioning

confidence: 99%

Cortical thickness and grey-matter volume anomaly detection in individual MRI scans: Comparison of two methods

Romascano,

Rebsamen,

Radojewski

et al. 2024

Preprint

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“…With industry salaries increasing relative to what healthcare systems can pay, finding staff to fill such roles is becoming more and more of a challenge. [2] Several no-code platforms for training ML models exist from companies like Amazon, Apple, Calrifai, Google, and Microsoft. [9] Some of these platforms have been tested on publicly available medical imaging datasets.…”

Section: Introductionmentioning

confidence: 99%

“…[1] However, this pace of AI adoption within healthcare has been slow. [2] One cause of this is that hospitals are cost strapped and still reeling from pandemic, and a tiny fraction of FDA-approved AI devices are covered by insurance. [3] A perhaps even bigger and more serious issue is that external validations of AI algorithms often show substantial drops in performance compared to what was originally reported in the FDA submission.…”

Section: Introductionmentioning

confidence: 99%

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No-code machine learning in radiology: implementation and validation of a platform that allows clinicians to train their own models

Elton,

Dasegowda,

Sato

et al. 2024

Preprint

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Machine learning models can assist clinicians and researchers in many tasks within radiology such as diagnosis, triage, segmentation/measurement, and quality assurance. To better leverage machine learning we have developed a platform that allows users to label data and train models without requiring any programming knowledge. The technology stack consists of a TypeScript web application running on .NET for user interaction, Python, PyTorch, and MONAI for machine learning, DICOM WADO-RS to retrieve data from clinical systems, and Docker for model management. As a first trial of the system, researchers used it to train a model for clavicle fracture detection as part of an IRB-approved retrospective study. The researchers labeled 4,135 clavicle radiographs from 2,039 patients across 13 sites. The platform automatically split the data into training, validation, and test sets and trained a model until the validation loss plateaued. The system then returned a receiver operating characteristic curve, AUC, F1, and other metrics. The resulting model identifies clavicle fractures with 90% sensitivity, 87% specificity, and 88% accuracy with an AUC of 0.95. This model performance is equivalent to or better than similar models reported in the literature. More recently, our system was used to train a model to identify if ultrasound frames that contain personally identifiable information (PII). After validation, the model was used to help de-identify a large dataset that was to be used for research. This first-of-its-kind system streamlines model development and deployment and opens up an exciting new pathway for the use of AI within healthcare.

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“…They struggle to generalize : they cannot perform as well on new data as on the data used for development. This may be due to differences in demographics—such as age, sex, acuity of presentation, and disease prevalence—as well as technical differences in hardware and protocols from the carefully curated datasets normally used to train the AI [10, 13]. The performance gap may be immediately evident, or drifting conditions may cause it to appear over time [12].…”

Section: Introductionmentioning

confidence: 99%

Conformal Triage for Medical Imaging AI Deployment

Angelopoulos,

Pomerantz,

et al. 2024

Preprint

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Background: The deployment of black-box AI models in medical imaging presents significant challenges, especially in maintaining reliability across different clinical settings. These challenges are compounded by distribution shifts that can lead to failures in reproducing the accuracy attained during the AI model's original validations. Method: We introduce the conformal triage algorithm, designed to categorize patients into low-risk, high-risk, and uncertain groups within a clinical deployment setting. This method leverages a combination of a black-box AI model and conformal prediction techniques to offer statistical guarantees of predictive power for each group. The high-risk group is guaranteed to have a high positive predictive value, while the low-risk group is assured a high negative predictive value. Prediction sets are never constructed; instead, conformal techniques directly assure high accuracy in both groups, even in clinical environments different from those in which the AI model was originally trained, thereby ameliorating the challenges posed by distribution shifts. Importantly, a representative data set of exams from the testing environment is required to ensure statistical validity. Results: The algorithm was tested using a head CT model previously developed by Do and colleagues [9] and a data set from Massachusetts General Hospital. The results demonstrate that the conformal triage algorithm provides reliable predictive value guarantees to a clinically significant extent, reducing the number of false positives from 233 (45%) to 8 (5%) while only abstaining from prediction on 14% of data points, even in a setting different from the training environment of the original AI model. Conclusions: The conformal triage algorithm offers a promising solution to the challenge of deploying black-box AI models in medical imaging across varying clinical settings. By providing statistical guarantees of predictive value for categorized patient groups, this approach significantly enhances the reliability and utility of AI in optimizing medical imaging workflows, particularly in neuroradiology.

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Challenges of implementing computer-aided diagnostic models for neuroimages in a clinical setting

Cited by 10 publications

References 127 publications

Cortical thickness and grey-matter volume anomaly detection in individual MRI scans: Comparison of two methods

Cortical thickness and grey-matter volume anomaly detection in individual MRI scans: Comparison of two methods

No-code machine learning in radiology: implementation and validation of a platform that allows clinicians to train their own models

Conformal Triage for Medical Imaging AI Deployment

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