Study Results
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Basic Information
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COMPLETED
NA
25 participants
INTERVENTIONAL
2020-08-07
2025-08-31
Brief Summary
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Detailed Description
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OSA and AF often co-exist and indeed share some risk factors, such as hypertension. AF Patients are more likely to have OSA, with reported prevalence rates of OSA (apnea-hypopnea index \[AHI\] ≥15) as high as 62% in AF cohorts from hospital-based studies. In community-based cohort studies, a cross-sectional analysis from sleep heart health study (SHSS) found those with sleep-disordered breathing(SDB)/sleep apnea (SA) (respiratory disturbance index \[RDI\] ≥ 30) had four times the odds of a polysomnography (PSG)-detected nocturnal AF as compared to those without SDB/SA after adjusting confounders. Following from this, a cross-sectional study on Outcomes of Sleep Disorders in Older Men Study (MrOS Sleep Study) showed a dose-response association between RDI and AF.
There are several pathophysiological mechanisms by which OSA could potentially increase the risk of development of new AF, or trigger a recurrence of AF in a patient with an established history of AF. OSA is characterized by repetitive collapse of the upper airway (UA) during sleep. The UA collapses when sleep-related loss in UA dilator muscle tone is superimposed upon a narrow and/or collapsible airway. These obstructive apneas or hypopneas, characterized by unsuccessful inspiratory efforts against an occluded airway, lead to 1) exaggerated negative intrathoracic pressure swings 2) hypoxia, and 3) co-activation of sympathetic and parasympathetic systems, all of which have been shown to potentiate a pro-arrhythmic state. Given that these mechanisms are pro-arrhythmic, CPAP (continuous positive airway pressure), the gold standard therapy for OSA, works by splinting the upper airway open during sleep with subsequent abolition of swings in pressure, hypoxia and arousals, can potentially modify the risk of development of AF or recurrence of AF in OSA patients.
There is a growing body of literature supporting that OSA being as a risk factor for recurrence of AF after cardioversion or ablation and treatment of OSA with CPAP decreased the risk of recurrence of AF. Nevertheless, all of the aforementioned studies are observational or retrospective in nature. Recently, Caples et al. conducted the first randomized control trial using CPAP in patients with AF and OSA but failed to find a difference of recurrence of AF between those treated with CPAP versus usual care. Notably, there are several issues in the study design and methodology that do not allow for firm conclusion from the results of this study. It was a single-center study, enrolling very small number of patients, and used a low cut-off AHI\>5/h as inclusion criteria. More importantly, only patients with persistent AF scheduled for cardioversion were included. Given the natural time-course from paroxysmal AF to persistent AF, long-term remodeling or established atrial arrythmogenic substrate in persistent AF may be less or not reversible even when the initial risk factor is removed. In this regard, early intervention with CPAP in patients with paroxysmal AF and OSA, which has never been done in previous studies, should confer a better antiarrythmic effect. Therefore, the investigators aim to test the hypothesis that treatment of OSA with CPAP would reduce the burden of AF in patients with paroxysmal AF.
Conditions
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Study Design
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RANDOMIZED
PARALLEL
TREATMENT
NONE
Study Groups
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CPAP treatment for 12 months
CPAP treatment for 12 months
continuous positive airway pressure
CPAP treatment at night. Treat AF as cardiologist's discretion.
Placebo
observation
Placebo
Observation. Treat AF as cardiologist's discretion.
Interventions
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continuous positive airway pressure
CPAP treatment at night. Treat AF as cardiologist's discretion.
Placebo
Observation. Treat AF as cardiologist's discretion.
Eligibility Criteria
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Inclusion Criteria
2. paroxysmal AF, diagnosed based on the ACC/AHA/HRS 2014 guideline, and is defined as AF that terminates spontaneously or with intervention within 7 d of onset either by 12-lead EKG, 24-hr Holter, or 14-day ECG monitor.
3. OSA, defined as an AHI\>15/hr of sleep, of which \>50% of events are obstructive.
4. Informed consent signed
Exclusion Criteria
2. post heart surgery
3. Uncontrolled systemic hypertension or pulmonary hypertension
4. Use of psychoactive or other drugs that could influence breathing patterns
5. Current use of CPAP treatment
6. Epworth sleepiness scale\>10
7. Congestive heart failure (LVEF≦45%)
8. Chronic obstructive pulmonary disease
9. History of stroke or neuromuscular disease
10. Severe insomnia
18 Years
80 Years
ALL
No
Sponsors
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National Taiwan University Hospital
OTHER
Responsible Party
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Principal Investigators
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Chih-Chieh Yu, MD.PhD
Role: PRINCIPAL_INVESTIGATOR
National Taiwan University Hospital
Locations
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National Taiwan University Hospital
Taipei, , Taiwan
Countries
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Other Identifiers
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202002128RINC
Identifier Type: -
Identifier Source: org_study_id
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