Saved in:
Bibliographic Details
Main Authors: Rosito, Fernando Barcelos, Menezes, Sebastião De Jesus, Sturza, Simone Ferreira, Seixas, Adriana, Franco, Muriel Figueredo
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.14534
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917412112171008
author Rosito, Fernando Barcelos
Menezes, Sebastião De Jesus
Sturza, Simone Ferreira
Seixas, Adriana
Franco, Muriel Figueredo
author_facet Rosito, Fernando Barcelos
Menezes, Sebastião De Jesus
Sturza, Simone Ferreira
Seixas, Adriana
Franco, Muriel Figueredo
contents Purpose. Athlete monitoring is constrained by small cohorts, heterogeneous biomarker scales, limited feasibility of repeated sampling, and the lack of reliable injury ground truth. These limitations reduce the interpretability and utility of traditional univariate and binary risk models. This study addresses these challenges by proposing an unsupervised multivariate framework to identify latent physiological states in athletes using real data. Methods. We propose a modular computational framework that operates in the joint biomarker space, integrating preprocessing, clinical safety screening, unsupervised clustering, and centroid-based physiological interpretation. Profiles are learned exclusively from amateur soccer players during a competitive microcycle. Synthetic data augmentation evaluates robustness and scalability. Ward hierarchical clustering supports monitoring and etiological differentiation, while Gaussian Mixture Models (GMM) enable structural stability analysis in high-dimensional settings. Results. The framework identifies coherent profiles that distinguish mechanical damage from metabolic stress while preserving homeostatic states. Synthetic data augmentation demonstrates feasibility and detection of latent silent risk phenotypes typically missed by univariate monitoring. Structural analyses indicate robustness under augmentation and higher-dimensional settings. Conclusion. The framework enables interpretable identification of latent physiological states from multivariate biomarker data without injury labels. By distinguishing mechanisms and revealing silent risk patterns not captured by conventional monitoring, it provides actionable insights for individualized athlete monitoring and decision making.
format Preprint
id arxiv_https___arxiv_org_abs_2604_14534
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle An unsupervised decision-support framework for multivariate biomarker analysis in athlete monitoring
Rosito, Fernando Barcelos
Menezes, Sebastião De Jesus
Sturza, Simone Ferreira
Seixas, Adriana
Franco, Muriel Figueredo
Machine Learning
Applications
Purpose. Athlete monitoring is constrained by small cohorts, heterogeneous biomarker scales, limited feasibility of repeated sampling, and the lack of reliable injury ground truth. These limitations reduce the interpretability and utility of traditional univariate and binary risk models. This study addresses these challenges by proposing an unsupervised multivariate framework to identify latent physiological states in athletes using real data. Methods. We propose a modular computational framework that operates in the joint biomarker space, integrating preprocessing, clinical safety screening, unsupervised clustering, and centroid-based physiological interpretation. Profiles are learned exclusively from amateur soccer players during a competitive microcycle. Synthetic data augmentation evaluates robustness and scalability. Ward hierarchical clustering supports monitoring and etiological differentiation, while Gaussian Mixture Models (GMM) enable structural stability analysis in high-dimensional settings. Results. The framework identifies coherent profiles that distinguish mechanical damage from metabolic stress while preserving homeostatic states. Synthetic data augmentation demonstrates feasibility and detection of latent silent risk phenotypes typically missed by univariate monitoring. Structural analyses indicate robustness under augmentation and higher-dimensional settings. Conclusion. The framework enables interpretable identification of latent physiological states from multivariate biomarker data without injury labels. By distinguishing mechanisms and revealing silent risk patterns not captured by conventional monitoring, it provides actionable insights for individualized athlete monitoring and decision making.
title An unsupervised decision-support framework for multivariate biomarker analysis in athlete monitoring
topic Machine Learning
Applications
url https://arxiv.org/abs/2604.14534