Abstract
BackgroundFractional-order (FrOr) models have a high potential to improve pulmonary science. These models could be useful for biomechanical studies and diagnostic purposes, offering accurate models with an improved ability to describe nature. This paper evaluates the performance of the Forced Oscillation (FO) associated with integer (InOr) and FrOr models in the analysis of respiratory alterations in work-related asthma (WRA).MethodsSixty-two individuals were evaluated: 31 healthy and 31 with WRA with mild obstruction. Patients were analyzed pre- and post-bronchodilation. The diagnostic accuracy was evaluated using the area under the receiver operating characteristic curve (AUC). To evaluate how well do the studied models correspond to observed data, we analyzed the mean square root of the sum (MSEt) and the relative distance (Rd) of the estimated model values to the measured resistance and reactance measured values.Results and discussionInitially, the use of InOr and FrOr models increased our understanding of the WRA physiopathology, showing increased peripheral resistance, damping, and hysteresivity. The FrOr model (AUC = 0.970) outperformed standard FO (AUC = 0.929), as well as InOr modeling (AUC = 0.838) in the diagnosis of respiratory changes, achieving high accuracy. FrOr improved the curve fitting (MSEt = 0.156 ± 0.340; Rd = 3.026 ± 1.072) in comparison with the InOr model (MSEt = 0.367 ± 0.991; Rd = 3.363 ± 1.098). Finally, we demonstrated that bronchodilator use increased dynamic compliance, as well as reduced damping and peripheral resistance.ConclusionsTaken together, these results show clear evidence of the utility of FO associated with fractional-order modeling in patients with WRA, improving our knowledge of the biomechanical abnormalities and the diagnostic accuracy in this disease.
Highlights
Fractional-order (FrOr) models have a high potential to improve pulmonary science
Taken together, these results show clear evidence of the utility of Forced Oscillation (FO) associated with fractional-order modeling in patients with work-related asthma (WRA), improving our knowledge of the biomechanical abnormalities and the diagnostic accuracy in this disease
Work-related asthma (WRA) is characterized by obstructive airways and hyperreactivity due to conditions in the workplace rather than stimuli from outside the workplace. It is divided into two categories: occupational asthma (OA), attributed to the particular causes and conditions of the work environment, and exacerbated occupational asthma (EOA), referred to as pre-existing or concurrent asthma that is aggravated by occupational exposures
Summary
Fractional-order (FrOr) models have a high potential to improve pulmonary science. These models could be useful for biomechanical studies and diagnostic purposes, offering accurate models with an improved ability to describe nature. Asthma is an umbrella label for various conditions characterized by chronic airway and/or lung disease This condition includes several different phenotypes and is likely to have several different underlying mechanisms [1]. Work-related asthma (WRA) is characterized by obstructive airways and hyperreactivity due to conditions in the workplace rather than stimuli from outside the workplace. It is divided into two categories: occupational asthma (OA), attributed to the particular causes and conditions of the work environment, and exacerbated occupational asthma (EOA), referred to as pre-existing or concurrent asthma that is aggravated by occupational exposures. Occupational and environmental pollution in the form of dust, fumes, vapors, and toxic gases are essential risk factors for this disease
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