Classifying high-dimensional phenotypes with ensemble learning

Devine, Jay; Kurki, Helen K.; Epp, Jonathan R.; González, Paula N.; Claes, Peter; Hallgrímsson, Benedikt

doi:10.1101/2023.05.29.542750

Cited by 3 publications

(1 citation statement)

References 53 publications

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“…Recently, the utility of machine learning (ML) has been shown in the fields of clinical and translational medicine [10][11][12][13] . ML is capable of identifying nonlinear relationships between variables and predicting multiclass outcomes 14 . However, different ML algorithms may show various prediction performance in diverse application scenarios, so an ensemble strategy can combine the merits of several selected ML classifiers 15 .…”

Section: Introductionmentioning

confidence: 99%

Early Prognostication of Critical Patients With Spinal Cord Injury

Fan,

Liu,

Yang

et al. 2023

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Study Design: A retrospective case-series. Objective: The study aims to use machine-learning (ML) to predict the discharge destination of spinal cord injury (SCI) patients in the intensive care unit (ICU). Summary of Background Data: Prognostication following SCI is vital, especially for critical patients who need intensive care. Methods: Clinical data of patients diagnosed with SCI were extracted from a publicly available ICU database. The firstly recorded data of the included patients were used to develop a total of 98 ML classifiers, seeking to predict discharge destination (e.g. death, further medical care, home). The micro-average area under the curve (AUC) was the main indicator to assess discrimination. The best average-AUC classifier and the best death-sensitivity classifier were integrated into an ensemble classifier. The discrimination of the ensemble classifier was compared with top death-sensitivity classifiers and top average-AUC classifiers. Additionally, prediction consistency and clinical utility were also assessed. Results: A total of 1485 SCI patients were included. The ensemble classifier had a micro-average AUC of 0.851, which was only slightly inferior to the best average-AUC classifier (P=0.10) The best average-AUC classifier death sensitivity was much lower than that of the ensemble classifier. The ensemble classifier had a death sensitivity of 0.452, which was inferior to top 8 death-sensitivity classifiers, whose micro-average AUC were inferior to the ensemble classifier (P<0.05). Additionally, the ensemble classifier demonstrated a comparable Brier score and superior Net benefit in the decision curve analysis, when compared to the performance of the origin classifiers. Conclusions: The ensemble classifier shows an overall superior performance in predicting discharge destination considering discrimination ability, prediction consistency and clinical utility. This classifier system may aid in the clinical management of critical SCI patients in the early phase following injury. Level of Evidence: 3

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Section: Introductionmentioning

confidence: 99%

Early Prognostication of Critical Patients With Spinal Cord Injury

Fan,

Liu,

Yang

et al. 2023

Spine

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Opportunities and Challenges in Applying AI to Evolutionary Morphology

He,

Mulqueeney,

Watt

et al. 2024

Integrative Organismal Biology

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Artificial intelligence (AI) is poised to revolutionise many aspects of science, including the study of evolutionary morphology. While classical AI methods such as principal component analysis and cluster analysis have been commonplace in the study of evolutionary morphology for decades, recent years have seen increasing application of deep learning to ecology and evolutionary biology. As digitised specimen databases become increasingly prevalent and openly available, AI is offering vast new potential to circumvent long standing barriers to rapid, big data analysis of phenotypes. Here, we review the current state of AI methods available for the study of evolutionary morphology, which are most developed in the area of data acquisition and processing. We introduce the main available AI techniques, categorising them into three stages based on their order of appearance: (i) machine learning, (ii) deep learning, and (iii) the most recent advancements in large-scale models and multimodal learning. Next, we present case studies of existing approaches using AI for evolutionary morphology, including image capture and segmentation, feature recognition, morphometrics, and phylogenetics. We then discuss the prospectus for near-term advances in specific areas of inquiry within this field, including the potential of new AI methods that have not yet been applied to the study of morphological evolution. In particular, we note key areas where AI remains underutilised and could be used to enhance studies of evolutionary morphology. This combination of current methods and potential developments have the capacity to transform the evolutionary analysis of the organismal phenotype into evolutionary phenomics, leading to an era of “Big Data'' that aligns the study of phenotypes with genomics and other areas of bioinformatics.

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pheble: Classifying High-Dimensional Phenotypes with Ensemble Learning

Devine,

Hallgrimsson

2023

CRAN: Contributed Packages

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Classifying high-dimensional phenotypes with ensemble learning

Cited by 3 publications

References 53 publications

Early Prognostication of Critical Patients With Spinal Cord Injury

Early Prognostication of Critical Patients With Spinal Cord Injury

Opportunities and Challenges in Applying AI to Evolutionary Morphology

pheble: Classifying High-Dimensional Phenotypes with Ensemble Learning

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