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1.  Morbidity in nocturnal asthma: sleep quality and daytime cognitive performance. 
Thorax  1991;46(8):569-573.
Most patients with asthma waken with nocturnal asthma from time to time. To assess morbidity in patients with nocturnal asthma nocturnal sleep quality, daytime sleepiness, and daytime cognitive performance were measured prospectively in 12 patients with nocturnal asthma (median age 43 years) and 12 age and intellect matched normal subjects. The median (range) percentage overnight fall in peak expiratory flow rate (PEF) was 22 (15 to 50) in the patients with nocturnal asthma and 4 (-4 to 7) in the normal subjects. The patients with asthma had poorer average scores for subjective sleep quality than the normal subjects (median paired difference 1.1 (95% confidence limits 0.1, 2.3)). Objective overnight sleep quality was also worse in the asthmatic patients, who spent more time awake at night (median difference 51 (95% CL 8.1, 74) minutes), had a longer sleep onset latency (12 (10, 30) minutes), and tended to have less stage 4 (deep) sleep (-33 (-58, 4) minutes). Daytime cognitive performance was worse in the patients with nocturnal asthma, who took a longer time to complete the trail making tests (median difference 62 (22, 75) seconds) and achieved a lower score on the paced serial addition tests (-10 (-24, -3)). Mean daytime sleep latency did not differ significantly between the two groups (2 (-3, 7) minutes). It is concluded that hospital outpatients with stable nocturnal asthma have impaired sleep quality and daytime cognitive performance even when having their usual maintenance asthma treatment.
PMCID: PMC463276  PMID: 1926025
2.  Is nocturnal asthma caused by changes in airway cholinergic activity? 
Thorax  1988;43(9):720-724.
A randomised, double blind, placebo controlled crossover trial of high dose nebulised ipratropium was carried out in 10 asthmatic patients with documented nocturnal bronchoconstriction. Patients received nebulised saline or ipratropium 1 mg at 10 pm and 2 am on two nights. Absolute peak flow (PEF) rates were higher throughout the night after the patients had received ipratropium (at 2 am, for example, mean (SEM) PEF was 353 after ipratropium and 285 l/min after placebo). The fall in PEF overnight, however, was similar with ipratropium and placebo. Patients were given a further 1 mg nebulised ipratropium at 6 am on both nights. There was a significant overnight fall in PEF on the ipratropium night even when comparisons were made between the times that maximal cholinergic blockade would be expected, PEF falling between 11.30 pm and 7.30 am from 429 to 369 l/min. The percentage increase in PEF, though not the absolute values, was greater after ipratropium at 6 am than at 10 pm. These results confirm that ipratropium raises PEF throughout the night in asthmatic patients, but suggest that nocturnal bronchoconstriction is not due solely to an increase in airway cholinergic activity at night.
PMCID: PMC461462  PMID: 2973665
3.  Breathing patterns during sleep in patients with nocturnal asthma. 
Thorax  1987;42(8):600-603.
Breathing patterns early and late in the night, at the same sleep stage, were compared in six healthy subjects and 15 adults with nocturnal asthma, to try to identify changes of overnight bronchoconstriction, and breathing patterns at different sleep stages, to see whether there were changes related to sleep stages that were indicative of bronchoconstriction. Despite an average 31% fall in FEV1 overnight in the patients with asthma, neither breathing frequency nor expiratory time, which might be expected to change during bronchoconstriction, was different early in the night from late in the night, nor did they differ between sleep stages. There was no evidence of asynchronous movement of the chest and abdomen in any patient. This study did not identify any abnormality of breathing pattern that would indicate the development of nocturnal asthma without the need to awaken the patient.
PMCID: PMC460860  PMID: 3509951
4.  Ketotifen and nocturnal asthma. 
Thorax  1983;38(11):845-848.
Patients with asthma often wheeze at night and they also become hypoxic during sleep. To determine whether ketotifen, a drug with sedative properties, is safe for use at night in patients with asthma, we performed a double blind crossover study comparing the effects of a single 1 mg dose of ketotifen and of placebo on arterial oxygen saturation (SaO2), breathing patterns, electroencephalographic (EEG) sleep stage, and overnight change in FEV1 in 10 patients with stable asthma. After taking ketotifen, the patients slept longer and their sleep was less disturbed than after taking placebo, true sleep occupying 387 (SEM 8) minutes after ketotifen and 336 (19) minutes after placebo (p less than 0.02). On ketotifen nights the patients had less wakefulness and drowsiness (EEG sleep stages 0 and 1) and more non-rapid eye movement (non-REM) sleep than on placebo nights, but the duration of REM sleep was similar on the two occasions. Nocturnal changes in SaO2, the duration of irregular breathing, and overnight change in FEV1 were unaffected by ketotifen.
PMCID: PMC459674  PMID: 6359563
5.  Effect of sleep deprivation on overnight bronchoconstriction in nocturnal asthma. 
Thorax  1986;41(9):676-680.
Nocturnal cough and wheeze are common in asthma. The cause of nocturnal asthma is unknown and there is conflicting evidence on whether sleep is a factor. Twelve adult asthmatic subjects with nocturnal wheeze were studied on two occasions: on one night subjects were allowed to sleep and on the other they were kept awake all night, wakefulness being confirmed by electroencephalogram. Every patient developed bronchoconstriction overnight both on the asleep night, when peak expiratory flow (PEF) fell from a mean (SE) of 418 (40) 1 min-1 at 10 pm to 270 (46) 1 min-1 in the morning, and on the awake night (PEF 10 pm 465 (43), morning 371 (43) 1 min-1). The morning values of PEF were, however, higher (p less than 0.1) after the awake night and both the absolute and the percentage overnight falls in PEF were greater when the patients slept (asleep night 38% (6%), awake night 20% (4%); p less than 0.01). This study suggests that sleep is an important factor in determining overnight bronchoconstriction in patients with nocturnal asthma.
PMCID: PMC460429  PMID: 3787554
6.  Sodium cromoglycate in nocturnal asthma. 
Thorax  1986;41(1):39-41.
To investigate whether mast cell degranulation was important in producing nocturnal asthma, the effect of a single high dose of nebulised sodium cromoglycate on overnight bronchoconstriction, oxygen saturation, and breathing patterns in eight patients with nocturnal wheeze was examined. The study took the form of a double blind placebo controlled crossover comparison. Treatment with cromoglycate did not reduce the overnight fall in FEV1 or FVC, although it was associated with improved nocturnal oxygenation. This study suggests that mast cell degranulation may not be important in the pathogenesis of nocturnal asthma.
PMCID: PMC460250  PMID: 3085257
7.  Arterial oxygenation during sleep in patients with right-to-left cardiac or intrapulmonary shunts. 
Thorax  1983;38(5):344-348.
We have studied arterial oxygen saturation (SaO2), breathing patterns, and electroencephalographic (EEG) sleep stage during nocturnal sleep in six patients with right-to-left cardiac or intrapulmonary shunts and six patients with chronic bronchitis and emphysema, chosen because they were equally hypoxaemic when awake (SaO2 during wakefulness: bronchitis 74-90%, mean 83%; shunt 77-89%, mean 83%). The patients with bronchitis had far greater falls in SaO2 when asleep than those with shunts (maximum fall in SaO2 during sleep: bronchitis 14-47%, mean 29%; shunt 5-10%, mean 8%; p less than 0.01). Significant episodes of hypoxaemia (defined as SaO2 falls greater than 10%) occurred in all six bronchitic patients, from once to seven times per night, but in none of the patients with shunts (p less than 0.05). Twenty-four of the 27 episodes of hypoxaemia occurred in rapid-eye-movement (REM) sleep and 24 were associated with hypopnoea. The two groups of patients had similar EEG sleep patterns and the same amount of hypopnoea during sleep. Thus the level of arterial oxygenation when the patient is awake is not the sole determinant of the degree of nocturnal hypoxaemia; the pathological process is also important.
PMCID: PMC459555  PMID: 6879482

Results 1-7 (7)