Urs Frey1. 1. Department of Paediatric Respiratory Medicine, University Children's Hospital of Berne, Inselspital, 3010 Berne, Switzerland. urs.frey@insel.ch
Abstract
PURPOSE OF REVIEW: Predicting asthma episodes is notoriously difficult but has potentially significant consequences for the individual, as well as for healthcare services. The purpose of this review is to describe recent insights into the prediction of acute asthma episodes in relation to classical clinical, functional or inflammatory variables, as well as present a new concept for evaluating asthma as a dynamically regulated homeokinetic system. RECENT FINDINGS: Risk prediction for asthma episodes or relapse has been attempted using clinical scoring systems, considerations of environmental factors and lung function, as well as inflammatory and immunological markers in induced sputum or exhaled air, and these are summarized here. We have recently proposed that newer mathematical methods derived from statistical physics may be used to understand the complexity of asthma as a homeokinetic, dynamic system consisting of a network comprising multiple components, and also to assess the risk for future asthma episodes based on fluctuation analysis of long time series of lung function. SUMMARY: Apart from the classical analysis of risk factor and functional parameters, this new approach may be used to assess asthma control and treatment effects in the individual as well as in future research trials.
PURPOSE OF REVIEW: Predicting asthma episodes is notoriously difficult but has potentially significant consequences for the individual, as well as for healthcare services. The purpose of this review is to describe recent insights into the prediction of acute asthma episodes in relation to classical clinical, functional or inflammatory variables, as well as present a new concept for evaluating asthma as a dynamically regulated homeokinetic system. RECENT FINDINGS: Risk prediction for asthma episodes or relapse has been attempted using clinical scoring systems, considerations of environmental factors and lung function, as well as inflammatory and immunological markers in induced sputum or exhaled air, and these are summarized here. We have recently proposed that newer mathematical methods derived from statistical physics may be used to understand the complexity of asthma as a homeokinetic, dynamic system consisting of a network comprising multiple components, and also to assess the risk for future asthma episodes based on fluctuation analysis of long time series of lung function. SUMMARY: Apart from the classical analysis of risk factor and functional parameters, this new approach may be used to assess asthma control and treatment effects in the individual as well as in future research trials.
Authors: Maria Patricia Fabian; Gary Adamkiewicz; Natasha Kay Stout; Megan Sandel; Jonathan Ian Levy Journal: J Allergy Clin Immunol Date: 2013-07-31 Impact factor: 10.793
Authors: Gang Luo; Bryan L Stone; Bernhard Fassl; Christopher G Maloney; Per H Gesteland; Sashidhar R Yerram; Flory L Nkoy Journal: BMC Med Inform Decis Mak Date: 2015-10-14 Impact factor: 2.796
Authors: M Patricia Fabian; Natasha K Stout; Gary Adamkiewicz; Amelia Geggel; Cizao Ren; Megan Sandel; Jonathan I Levy Journal: Environ Health Date: 2012-09-18 Impact factor: 5.984