Your search keyword '"Lucas PJ"' showing total 4 results

1. Understanding disease processes by partitioned dynamic Bayesian networks.

Author

Bueno ML, Hommersom A, Lucas PJ, Lappenschaar M, and Janzing JG

Subjects

Depression, Humans, Psychotic Disorders, Sensitivity and Specificity, Algorithms, Bayes Theorem

Abstract

For many clinical problems in patients the underlying pathophysiological process changes in the course of time as a result of medical interventions. In model building for such problems, the typical scarcity of data in a clinical setting has been often compensated by utilizing time homogeneous models, such as dynamic Bayesian networks. As a consequence, the specificities of the underlying process are lost in the obtained models. In the current work, we propose the new concept of partitioned dynamic Bayesian networks to capture distribution regime changes, i.e. time non-homogeneity, benefiting from an intuitive and compact representation with the solid theoretical foundation of Bayesian network models. In order to balance specificity and simplicity in real-world scenarios, we propose a heuristic algorithm to search and learn these non-homogeneous models taking into account a preference for less complex models. An extensive set of experiments were ran, in which simulating experiments show that the heuristic algorithm was capable of constructing well-suited solutions, in terms of goodness of fit and statistical distance to the original distributions, in consonance with the underlying processes that generated data, whether it was homogeneous or non-homogeneous. Finally, a study case on psychotic depression was conducted using non-homogeneous models learned by the heuristic, leading to insightful answers for clinically relevant questions concerning the dynamics of this mental disorder., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

2. Learning Bayesian networks for clinical time series analysis.

Author

van der Heijden M, Velikova M, and Lucas PJ

Subjects

Aged, Algorithms, Area Under Curve, Artificial Intelligence, Bayes Theorem, Computer Simulation, Diagnosis, Computer-Assisted, Female, Humans, Lung physiology, Male, Middle Aged, Monitoring, Ambulatory methods, Probability, Signal Processing, Computer-Assisted, Time Factors, Decision Support Systems, Clinical, Pulmonary Disease, Chronic Obstructive therapy

Abstract

Introduction: Autonomous chronic disease management requires models that are able to interpret time series data from patients. However, construction of such models by means of machine learning requires the availability of costly health-care data, often resulting in small samples. We analysed data from chronic obstructive pulmonary disease (COPD) patients with the goal of constructing a model to predict the occurrence of exacerbation events, i.e., episodes of decreased pulmonary health status., Methods: Data from 10 COPD patients, gathered with our home monitoring system, were used for temporal Bayesian network learning, combined with bootstrapping methods for data analysis of small data samples. For comparison a temporal variant of augmented naive Bayes models and a temporal nodes Bayesian network (TNBN) were constructed. The performances of the methods were first tested with synthetic data. Subsequently, different COPD models were compared to each other using an external validation data set., Results: The model learning methods are capable of finding good predictive models for our COPD data. Model averaging over models based on bootstrap replications is able to find a good balance between true and false positive rates on predicting COPD exacerbation events. Temporal naive Bayes offers an alternative that trades some performance for a reduction in computation time and easier interpretation., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2014

3. An autonomous mobile system for the management of COPD.

Author

van der Heijden M, Lucas PJ, Lijnse B, Heijdra YF, and Schermer TR

Subjects

Artificial Intelligence, Computer Security, Disease Management, Feasibility Studies, Humans, Internet, Models, Theoretical, Pilot Projects, Probability, ROC Curve, Pulmonary Disease, Chronic Obstructive therapy, Telemedicine

Abstract

Introduction: Managing chronic disease through automated systems has the potential to both benefit the patient and reduce health-care costs. We have developed and evaluated a disease management system for patients with chronic obstructive pulmonary disease (COPD). Its aim is to predict and detect exacerbations and, through this, help patients self-manage their disease to prevent hospitalisation., Materials: The carefully crafted intelligent system consists of a mobile device that is able to collect case-specific, subjective and objective, physiological data, and to alert the patient by a patient-specific interpretation of the data by means of probabilistic reasoning. Collected data are also sent to a central server for inspection by health-care professionals., Methods: We evaluated the probabilistic model using cross-validation and ROC analyses on data from an earlier study and by an independent data set. Furthermore a pilot with actual COPD patients has been conducted to test technical feasibility and to obtain user feedback., Results: Model evaluation results show that we can reliably detect exacerbations. Pilot study results suggest that an intervention based on this system could be successful., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

4. Dynamic Bayesian networks as prognostic models for clinical patient management.

Author

van Gerven MA, Taal BG, and Lucas PJ

Subjects

Algorithms, Bayes Theorem, Humans, Prognosis, Risk Factors, Survival Analysis, Survival Rate, Carcinoid Tumor diagnosis, Carcinoid Tumor mortality, Decision Support Systems, Clinical, Diagnosis, Computer-Assisted methods, Neural Networks, Computer, Risk Assessment methods

Abstract

Prognostic models in medicine are usually been built using simple decision rules, proportional hazards models, or Markov models. Dynamic Bayesian networks (DBNs) offer an approach that allows for the incorporation of the causal and temporal nature of medical domain knowledge as elicited from domain experts, thereby allowing for detailed prognostic predictions. The aim of this paper is to describe the considerations that must be taken into account when constructing a DBN for complex medical domains and to demonstrate their usefulness in practice. To this end, we focus on the construction of a DBN for prognosis of carcinoid patients, compare performance with that of a proportional hazards model, and describe predictions for three individual patients. We show that the DBN can make detailed predictions, about not only patient survival, but also other variables of interest, such as disease progression, the effect of treatment, and the development of complications. Strengths and limitations of our approach are discussed and compared with those offered by traditional methods.

Published

2008