Sharing Biomedical Data: Strengthening AI Development in Healthcare

Pereira, Tânia; Morgado, Joana; Silva, Francisco; Pelter, Michele M.; Dias, Vasco; Barros, Rita de Cássia Nogueira; Freitas, Cláudia de; Negrão, Eduardo; Lima, Beatriz Flor de; Silva, Miguel Correia da; Madureira, António J.; Ramos, Isabel; Hespanhol, Venceslau; Costa, José Luís; Cunha, António; Oliveira, Hélder P.

doi:10.3390/healthcare9070827

Cited by 18 publications

(17 citation statements)

References 62 publications

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“…Model representing patient and data relationship for improving models, while balancing impact on patient security [17] With a continuation of these trends as found in this research, AI systems that make improvements to data standardization, would increase the accuracy of diagnoses drastically enough to make ML an extremely valuable tool in healthcare. Within Yoo's study, the application of AI was limited because the specific cohort of participants for the study included a really small number of lung cancer positive patients, and the actual clinical prevalence of positive encounters for national lung screening trials would be extremely rare.…”

Section: Figure IIImentioning

confidence: 69%

“…Throughout many studies in the application of AI against human and algorithmic performance, a large risk that remains present in these studies would be that the models have limited to no clinical context, including the patient's medical history or prior laboratory findings, which can be critical in finding the proper treatment plans [18]. When it comes to the processing of data, there are a lot of times in which the systems connecting and supplying each other information automatically, are distributed through multiple heterogeneous and semantically incompatible systems, which leads to interoperability problems and inconsistencies [17]. When subsystems of a medical center are inconsistent with each other, and the data transferred between systems gets processed at each stage, there is increased potential for data loss and context misinterpretation.…”

Section: Data Pre-processingmentioning

confidence: 99%

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Exploring AI in Healthcare: How the Acceleration of Data Processing can Impact Life Saving Diagnoses

Janes

Bansal

Baron

2022

Electronic Workshops in Computing

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Artificial Intelligence (AI) is one of the biggest topics being discussed in the realm of Computer Science and it has made incredible breakthroughs possible in so many different industries. One of the largest issues with utilizing computational resources in the health industry historically is centered around the quantity of data, the specificity of conditions for accurate results, and the general risks associated with being incorrect in an analysis. Although these all have been major issues in the past, the application of artificial intelligence has opened up an entirely different realm of possibilities because accessing massive amounts of patient data, is essential for generating an extremely accurate model in machine learning (ML). This paper presents an analysis of tools and algorithm design techniques used in recent times to accelerate data processing in the realm of healthcare, but one of the most important discoveries is that the standardization of conditioned data being fed into the models is almost more important than the algorithms or tools being used combined.

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Section: Figure IIImentioning

confidence: 69%

Section: Data Pre-processingmentioning

confidence: 99%

Exploring AI in Healthcare: How the Acceleration of Data Processing can Impact Life Saving Diagnoses

Janes

Bansal

Baron

2022

Electronic Workshops in Computing

View full text Add to dashboard Cite

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“…Lack of large datasets remains a problem for healthcare solutions since models cannot learn how to deal with complex data due to insufficient training samples [ 205 , 206 ]. The difficult access to the medical data has slowed the progress of CAD development.…”

Section: Discussionmentioning

confidence: 99%

Towards Machine Learning-Aided Lung Cancer Clinical Routines: Approaches and Open Challenges

Silva

Pereira

Neves

et al. 2022

JPM

Self Cite

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Advancements in the development of computer-aided decision (CAD) systems for clinical routines provide unquestionable benefits in connecting human medical expertise with machine intelligence, to achieve better quality healthcare. Considering the large number of incidences and mortality numbers associated with lung cancer, there is a need for the most accurate clinical procedures; thus, the possibility of using artificial intelligence (AI) tools for decision support is becoming a closer reality. At any stage of the lung cancer clinical pathway, specific obstacles are identified and “motivate” the application of innovative AI solutions. This work provides a comprehensive review of the most recent research dedicated toward the development of CAD tools using computed tomography images for lung cancer-related tasks. We discuss the major challenges and provide critical perspectives on future directions. Although we focus on lung cancer in this review, we also provide a more clear definition of the path used to integrate AI in healthcare, emphasizing fundamental research points that are crucial for overcoming current barriers.

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“…The use of synthetic data has also been applied in the biomedical field, where augmented data has been developed to increase the number and variability of examples [55]. Furthermore, different studies with a similar goal as this paper's have also focused on generating synthetic data to incorporate it to the training set and avoid class imbalance problems [56][57][58].…”

Section: Generation Of Synthetic Datamentioning

confidence: 99%

A Vision-Based System for Stage Classification of Parkinsonian Gait Using Machine Learning and Synthetic Data

Chavez

Tang

2022

Sensors

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Parkinson’s disease is characterized by abnormal gait, which worsens as the condition progresses. Although several methods have been able to classify this feature through pose-estimation algorithms and machine-learning classifiers, few studies have been able to analyze its progression to perform stage classification of the disease. Moreover, despite the increasing popularity of these systems for gait analysis, the amount of available gait-related data can often be limited, thereby, hindering the progress of the implementation of this technology in the medical field. As such, creating a quantitative prognosis method that can identify the severity levels of a Parkinsonian gait with little data could help facilitate the study of the Parkinsonian gait for rehabilitation. In this contribution, we propose a vision-based system to analyze the Parkinsonian gait at various stages using linear interpolation of Parkinsonian gait models. We present a comparison between the performance of a k-nearest neighbors algorithm (KNN), support-vector machine (SVM) and gradient boosting (GB) algorithms in classifying well-established gait features. Our results show that the proposed system achieved 96–99% accuracy in evaluating the prognosis of Parkinsonian gaits.

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Sharing Biomedical Data: Strengthening AI Development in Healthcare

Cited by 18 publications

References 62 publications

Exploring AI in Healthcare: How the Acceleration of Data Processing can Impact Life Saving Diagnoses

Exploring AI in Healthcare: How the Acceleration of Data Processing can Impact Life Saving Diagnoses

Towards Machine Learning-Aided Lung Cancer Clinical Routines: Approaches and Open Challenges

A Vision-Based System for Stage Classification of Parkinsonian Gait Using Machine Learning and Synthetic Data

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