Asthma is an extremely common disorder, which is becoming more prevalent. The purpose of this study is to examine how nocturnal lung volumes contribute to asthma severity, which may explain part of the link between asthma and obesity. The investigators seek to test the hypothesis that raising lung volumes during the night will improve asthma symptoms. The investigators work may lead to new targets for therapy.
Asthma is a chronic respiratory disease characterized by airway inflammation and airway hyperresponsiveness, which causes airflow obstruction. It is extremely prevalent, affecting an estimated 22 million Americans, and costly with loss of productivity and direct healthcare costs in the billions of dollars. The incidence and prevalence of asthma are increasing, both in the US and around the world. This increase comes despite greater understanding of the inflammatory and allergic basis for asthma, and despite better antiinflammatory medications. One explanation for the increasing prevalence of asthma is the concomitant increase in obesity, with the majority of Americans now overweight or obese. Numerous studies have convincingly linked asthma and obesity, and demonstrated increased obstruction with weight gain and decreased obstruction with weight loss. However, the mechanisms that underlie this linkage are not known. We believe that low lung volumes contribute to the pathogenesis and severity of asthma. End-expiratory lung volume is decreased in obesity, and likely falls further during sleep, particularly in overweight and obese patients. Both upper and lower airway resistance increase with decreasing lung volumes, as airways become smaller. However, prior work has shown that lower airway resistance increases out of proportion to the decrease in lung volume that occurs during sleep in asthma patients. This difference between controls and people with asthma has not been further explored, yet may provide insight into asthma pathogenesis and provide potential targets for therapy. Therefore, we propose a series of experiments to define the impact of lung volumes during sleep on airway resistance. One of these experiments will be to to test the hypothesis that lung stretch can be used therapeutically by tonically and dynamically increasing lung volumes during sleep using bi-level positive airway pressure. This research can help delineate asthma pathogenesis and may help improve therapeutic options in this exceedingly common disease.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
31
Subjects will use bilevel PAP each night for 4 weeks. The pressure levels will be adjusted by the investigators to increase lung volumes during the night.
Subjects will continue with their usual asthma care. Investigators will make no changes to their medications or other habits.
Subjects will continue with their usual asthma care in between the Usual Care and Bilevel PAP periods. Investigators will make no changes to their medications or other habits.
Brigham and Women's Hospital
Boston, Massachusetts, United States
Asthma Control Test
Well validated questionnaire of asthma symptoms which includes 5 written questions. Each question is answered on a scale of 1-5, which are summed to report a range of asthma control from 5 to 25 (higher score indicates better asthma control).
Time frame: Every 4 weeks during the 12 week study (at the start and end of the Usual Care period, and at the start and end of the Bilevel PAP intervention period)
Airway Reactivity as Measured by Methacholine Challenge (PC20)
This is a physiological measurement derived from repeated breathing maneuvers which measures airway reactivity. Subjects are exposed to higher and higher concentrations of an airway irritant (in this case methacholine), and between each dose perform spirometry. The test is stopped after the forced expiratory volume in 1 second (FEV1) falls 20% below the baseline. The concentration of methacholine at which this occurs is called the PC20. Methacholine challenges are routinely used in the diagnosis of asthma, and in many asthma research studies to measure changes in airway reactivity.
Time frame: Every 4 weeks during the 12 week study (at the start and end of the usual care period, and at the start and end of the Bilevel PAP intervention period)
Epworth Sleepiness Scale (ESS)
8 item questionnaire to measure daytime sleepiness, with total score reported 0 (less sleepy) to 24 (most sleepy). Scores greater than or equal to 10 are considered excessive daytime sleepiness.
Time frame: Every 4 weeks during the 12 week study (at the start and end of the usual care period, and at the start and end of the Bilevel PAP intervention period)
Pittsburgh Sleep Quality Index (PSQI)
Well validated questionnaire used frequently to measure sleep quality over the prior 1 month. It consists of 19 individual items that combine to form 7 components summed to create one global score. The overall score is between 0 (better sleep) and 21 (worse sleep).
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Time frame: Every 4 weeks during the 12 week study (at the start and end of the usual care period, and at the start and end of the Bilevel PAP intervention period)
Short Form (SF-36) Health Survey
Well validated quality of life questionnaire that measures eight sub-sections, which are summed to yield a score from 0 (maximal disability) to 100 (no disability). The eight subsections are: vitality, physical functioning, bodily pain, general health perceptions, physical role functioning, emotional role functioning, social role functioning, mental health.
Time frame: Every 4 weeks during the 12 week study (at the start and end of the usual care period, and at the start and end of the Bilevel PAP intervention period)
FEV1 %Predicted
Performed as part of spirometry
Time frame: Every 4 weeks during the 12 week study (at the start and end of the usual care period, and at the start and end of the Bilevel PAP intervention period)