Combined Effect of Lung Function Level and Decline Increases Morbidity and Mortality Risks

Overview

Journal Eur J Epidemiol

Specialty Public Health

Date 2012 Dec 15

PMID 23238697

Citations 43

Authors

Penelope Baughman

Jacob L Marott

Peter Lange

Christopher J Martin

Anoop Shankar

Edward L Petsonk

Eva Hnizdo

Affiliations

Soon will be listed here.

Abstract

Lung function level and decline are each predictive of morbidity and mortality. Evaluation of the combined effect of these measurements may help further identify high-risk groups. Using Copenhagen City Heart Study longitudinal spirometry data (n = 10,457), 16-21 year risks of chronic obstructive pulmonary disease (COPD) morbidity, COPD or coronary heart disease mortality, and all-cause mortality were estimated from combined effects of level and decline in forced expiratory volume in one second (FEV(1)). Risks were evaluated using Cox proportional hazards models for individuals grouped by combinations of baseline predicted FEV(1) and quartiles of slope. Hazard ratios (HR) and 95 % confidence intervals (CI) were estimated using stratified analysis by gender, smoking status, and baseline age (≤45 and >45). For COPD morbidity, quartiles of increasing FEV(1) decline increased HRs (95 % CI) for individuals with FEV(1) at or above the lower limit of normal (LLN) but below 100 % predicted, reaching 5.11 (2.58-10.13) for males, 11.63 (4.75-28.46) for females, and 3.09 (0.88-10.86) for never smokers in the quartile of steepest decline. Significant increasing trends were also observed for mortality and in individuals with a baseline age ≤45. Groups with 'normal' lung function (FEV(1) at or above the LLN) but excessive declines (fourth quartile of FEV(1) slope) had significantly increased mortality risks, including never smokers and individuals with a baseline age ≤45.

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