Circulating catecholamines in exercise and hyperventilation induced asthma

New concepts in the pathogenesis of bronchial hyperresponsiveness and asthma

Recent studies have suggested that inflammation may play an important role in the characteristic bronchial hyperresponsiveness and symptoms of chronic asthma. The mechanisms by which inflammatory cells, mediators, and nerves interact to produce the features of asthma are still uncertain, however. Although mast cells play an important role in the immediate response to allergen (and probably exercise), pharmacologic evidence argues against a critical role in the late response or bronchial hyperresponsiveness in which other cells, such as macrophages and eosinophils, may play a more important role. Many mediators have been implicated in asthma, but only PAF causes a prolonged increase in bronchial responsiveness. PAF attracts eosinophils into tissues and potently activates these cells, which may lead to epithelial damage, a key feature of asthmatic airways. PAF is also a potent inducer of microvascular leakage in airways, which may result in submucosal edema and plasma exudation into the airway lumen in the future. PAF antagonists will reveal whether PAF plays an important role in the eosinophilic inflammation of asthma. Neural mechanisms may also make an important contribution. Inflammatory mediators may influence neurotransmitter release from airway nerves, and neurotransmitters may be proinflammatory. Neural control is complex and cholinergic, adrenergic, and NANC mechanisms may contribute to bronchial hyperresponsiveness. Many neuropeptides, which may be the transmitters of NANC nerves, have been identified in airways. Neuropeptides in airway sensory nerves, such as substance P, have potent proinflammatory effects and, if these are released by an axon reflex, may amplify the inflammatory response in asthma. Since asthma may be chronic eosinophilic bronchitis, it is logical that the primary treatment should involve drugs that suppress this inflammatory response. At present, corticosteroids appear to be the most effective therapy; they have potent effects against eosinophils and macrophages (but not on mast cells) and reduce bronchial hyperresponsiveness and symptoms. By contrast, bronchodilators, such as beta-agonists, although they reduce symptoms, do not reduce the chronic inflammatory response or bronchial hyperresponsiveness and may mask the underlying inflammation. New therapies should be directed toward controlling eosinophil infiltration and activation in airways.

The duration of action of the combination of fenoterol hydrobromide and ipratropium bromide in protecting against asthma provoked by hyperpnea

We compared the duration of the protective effect of two beta-adrenoceptor agonists, fenoterol (200 micrograms) and salbutamol (200 micrograms), the anticholinergic agent ipratropium (80 micrograms), and the combination of fenoterol (200 micrograms) and ipratropium (80 micrograms) against challenge by eucapnic voluntary hyperventilation (EVH). Twelve patients with asthma performed EVH for two or four min at 60 percent maximal voluntary ventilation, 30 min, 2 and 4 h after treatment. All treatments (Rx) produced significant bronchodilation after 30 min. The Rx containing a beta-adrenoceptor agonist maintained this bronchodilation for at least 2 h. While all the Rx with a beta-adrenoceptor agonist significantly reduced the fall in forced expiratory volume in one second after EVH at 30 min, only the combination of fenoterol and ipratropium provided significant protection after 2 h. We advise that the duration of protective effect of beta-adrenoceptor agonists is short and patients with moderate to severe exercise-induced asthma may be better controlled by combination therapy.

Salbutamol induced hypokalaemia: the effect of theophylline alone and in combination with adrenaline

1. We have previously shown that salbutamol induced hypokalaemia, like adrenaline induced hypokalaemia, is the result of stimulation of a membrane bound beta 2-adrenoreceptor linked to Na+/K+ ATPase. We have also demonstrated that adrenaline induced hypokalaemia is potentiated by therapeutic concentrations of theophylline. 2. In a single-blind study of 14 normal volunteers, we infused salbutamol in doses used in clinical practice and examined the effects of the addition of theophylline alone or combined with (-)-adrenaline on plasma potassium levels, heart rate and blood pressure. The combinations studied were (i) salbutamol + vehicle control adrenaline infusion + placebo theophylline; (ii) salbutamol + vehicle control adrenaline infusion + theophylline; (iii) salbutamol + adrenaline + theophylline. 3. In a randomised, balanced placebo controlled design oral slow release theophylline or placebo was given for 9 days. Subjects were studied twice on the active limb (days 7 and 9) and once on the placebo limb (day 9) and the procedure was identical on each of the 3 study days except for the solutions administered. 4. Theophylline increased salbutamol induced hypokalaemia and in some individuals profound hypokalaemia (less than 2.5 mmol l-1) was observed with these relatively low doses of salbutamol and theophylline. Adrenaline did not further increase the magnitude of the fall in potassium observed. Combining theophylline with salbutamol increased the tachycardia resulting from the salbutamol infusion. Salbutamol infusion caused a fall in diastolic and rise in systolic blood pressure on all 3 study days and this was not altered by either theophylline or adrenaline alone or together.(ABSTRACT TRUNCATED AT 250 WORDS)

Airway responsiveness to histamine in patients refractory to repeated exercise

To investigate the mechanisms contributing to refractoriness in exercise-induced asthma (EIA), airway responsiveness to histamine was studied in eight asthmatic patients. Patients were included in the study on the basis of their refractory response to multiple exercise challenges. Incremental challenges with inhaled histamine were performed at rest and 40 minutes after single and paired exercise tests. The geometric mean histamine concentration required to produce a 20 percent fall in FEV1 (PC20) for the challenge after paired exercise test (4.34 mg/ml) was significantly higher (p greater than 0.001) than those for the challenges after a single exercise (1.05 mg/ml) and for the challenge at rest (0.67 mg/ml). There was no significant difference between PC20 values at rest and after a single exercise test (p greater than 0.05). The results show that the response to histamine is reduced during the refractory period following paired exercise test.

A comparison of mediator and catecholamine release between exercise- and hypertonic saline-induced asthma

Serum neutrophil chemotactic activity (NCA) and plasma histamine concentrations were measured in 9 asthmatic subjects with exercise-induced asthma after inhalation challenge with ultrasonically nebulized 3.6% hypertonic saline, which was administered either in a dose-dependent manner (HSDR) or as a continuous single dose (HSC), and after cycle ergometer exercise. The mean decreases in FEV1 elicited by HSDR, HSC, and exercise were 26, 27, and 25%, respectively, and were not significantly different. There was an approximate 300% maximal increase in NCA detected after both HSC and exercise challenges. Gel filtration chromatography on columns of Ultragel ACA 34 indicated that the NCA released after HSC provocation and exercise were 600 to 700 kDa. There was an approximate 100% maximal increase in NCA after HSDR challenge, and this was significantly less (p = 0.016) than that after HSC and exercise. Exercise but not hypertonic challenge was associated with a basophilia and a significant increase in plasma histamine. There was a significant increase in plasma norepinephrine concentrations after exercise but not after HSC challenge in 7 asthmatics. Epinephrine concentrations did not change after exercise or HSC inhalation. NCA was measured in 5 subjects subjected to 2 HSC challenges that were separated by 60 min. There was an increase in NCA detected after both provocations. The increase after the second challenge was significantly greater (p = 0.27 x 10(-4)) than that observed after the initial provocation, despite a substantially reduced bronchoconstrictor response after the second challenge.

Circulating adrenaline and noradrenaline concentrations during exercise in patients with exercise induced asthma and normal subjects

A failure of the usual increase in plasma adrenaline and noradrenaline concentrations during submaximal exercise has been suggested as a contributory cause of exercise induced asthma. Six normal subjects and six asthmatic patients underwent a standard graded maximal exercise test. Measurements of oxygen consumption, minute ventilation, exercise time, blood lactate concentration, and heart rate indicated that the two groups achieved similarly high work loads during exercise. Mean FEV1 fell by 20% in asthmatic patients after exercise. Basal plasma adrenaline concentrations (nmol/l) increased in normal subjects from 0.05 to 2.7 and in asthmatic patients from 0.12 to 1.6 at peak exercise. Noradrenaline concentrations (nmol/l) increased in normal subjects from 2.0 to 14.3 and in asthmatic patients from 1.9 to 13.7 at peak exercise. The increases in adrenaline and noradrenaline in the asthmatic patients did not differ significantly from the increases in normal subjects. Thus a reduced sympathoadrenal response to exercise seems unlikely to be an important mechanism in the pathogenesis of exercise induced asthma.

Circulating concentrations of histamine, neutrophil chemotactic activity, and catecholamines during the refractory period in exercise-induced asthma

Circulating mediators and catecholamine concentrations have been measured in eight subjects with asthma who were subjected to two bouts of cycle ergometer exercise separated by 1 hour. The maximum falls in FEV1 were 21.9 +/- 2.3% (mean +/- SEM; n = 8) and 5.5 +/- 1.3% (mean +/- SEM; n = 8) after the first and second exercises, respectively. Serum neutrophil chemotactic activity (NCA) and plasma histamine and catecholamine levels in venous blood were measured with a microchemotaxis and two radioenzymatic techniques, respectively. There was a significant increase in NCA and plasma histamine concentrations after both exercise challenges, and there was no significant difference in the release of these mediators between the two exercise tests. Gel filtration chromatography demonstrated that the NCA detected after the first and second exercise tests had molecular sizes of approximately 600,000 daltons. There was no significant time-dependent increase in plasma norepinephrine and epinephrine concentrations after either exercise task, even though the patients were refractory to exercise-induced asthma after the second exercise. These results suggest that the refractory period in exercise-induced asthma is not caused by mediator depletion, as indicated by NCA and histamine measurements, or by protection of the airways through catecholamine release.

The site of the defect in asthma. Neurohumoral, mediator or smooth muscle?

The nature of the underlying defect in asthma is still unclear. This article discusses where the primary problem might lie, starting with the assumption that it is likely to be in neurohumoral control, bronchial smooth muscle or cellular dysfunction with increased release of mediators. The weight of the evidence suggests that the latter is most likely. If true, the question of why this occurs still remains.

Investigation of adrenomedullary function in atopic dermatitis

Adrenomedullary function in patients with atopic dermatitis was assessed by measurement of plasma levels of catecholamines (adrenalin and noradrenalin) and cyclic AMP in response to the stimuli of standing after lying supine, and a 5-min infusion of histamine in the standing position (i.e. histamine plus standing). Plasma clearance of adrenalin was examined by measurement of plasma catecholamine and cyclic AMP levels following a 15-min intravenous infusion of adrenalin in the supine position. Resting plasma levels of adrenalin, cyclic AMP and noradrenalin were not statistically different in atopic patients and normal controls. Standing or intravenous infusion of histamine in the standing position caused a rise in plasma catecholamine levels. Plasma adrenalin, cyclic AMP and noradrenalin levels in response to these stimuli and the rate of clearance of exogenous adrenalin from the plasma were not significantly different in patients with atopic dermatitis and in normal subjects.

Asthma: emerging concepts and potential therapies

Asthma is a disease of the airways that results in reversible airflow obstruction. Recent investigations have suggested that airway inflammation is associated with increased airway responsiveness and worsening of asthmatic symptoms. The role that mast cell mediators might play in the production of asthma has been investigated by use of newer analytical techniques and by use of fiberoptic bronchoscopy with lavage to obtain lower respiratory tract fluid and cells. In addition, new investigational compounds that interfere with the synthesis or action of inflammatory mediators have been tested. Developing lines of investigation suggest that chronic activation of inflammatory cells may be important in the pathogenesis of asthma.

The mechanism of salbutamol-induced hypokalaemia

The following four intravenous treatments were administered in a balanced, randomized Latin square design to eight healthy volunteers: (-)-adrenaline (0.06 microgram kg-1 min-1 for 90 min) + vehicle control (+)-glucose infusion (60 min), salbutamol (120 ng kg-1 min-1 for 30 min) + vehicle control (+)-glucose infusion (90 min), (-)-adrenaline (0.06 microgram kg-1 min-1 for 90 min) + salbutamol (120 ng kg-1 min-1 for 30 min) and two vehicle control infusions of (+)-glucose. All active solutions were preceded by a 1 h control infusion and the control infusion was continued for 1 h following the active solutions. Both the active solutions, (-)-adrenaline and salbutamol were increased stepwise to the above doses. Heart rate and blood pressure were recorded at frequent intervals throughout and venous blood was taken for the estimation of potassium, insulin, glucose, catecholamine and salbutamol levels. Adrenaline levels similar to those seen in acute illness were achieved using this infusion protocol. Salbutamol levels rose throughout the period of the salbutamol infusions and steady-state was not achieved. Potassium levels were unchanged on the control + control study day and fell on all active treatments (0.45 mmol l-1 following (-)-adrenaline + control; 0.48 mmol l-1 following salbutamol + control; 0.93 mmol l-1 following (-)-adrenaline + salbutamol). Insulin levels rose insignificantly after salbutamol alone and fell slightly on all other treatments.(ABSTRACT TRUNCATED AT 250 WORDS)

Postexertional airway rewarming and thermally induced asthma. New insights into pathophysiology and possible pathogenesis

To determine if postexercise thermal events play a role in exercise-induced asthma (EIA), nine normal and eight asthmatic subjects on three occasions exercised while they inhaled frigid air. During the recovery period, either cold air, air at room temperature and humidity, or air at body conditions was administered in a random fashion. On a fourth occasion, body-condition air was given during exercise. Pulmonary mechanics were measured before and after each challenge. No changes in mechanics developed when air at body conditions was inhaled during exercise, however, increasing the heat content of the air during recovery produced progressively greater obstruction in both groups. On a separate occasion, seven asthmatics hyperventilated frigid air and either recovered spontaneously or had their ventilation slowly reduced. Controlling ventilation markedly attenuated the obstructive response. These data demonstrate that the severity of EIA is dependent not only on airway cooling but also upon the rapidity and magnitude of airway rewarming postchallenge.

ABC of nutrition. Vitamins II

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Exercise and the asthmatic

Physical exercise is not hazardous to asthmatics. Some asthmatics may benefit from physical training, and almost all asthmatics can perform any kind of physical exercise. Free running was earlier thought to induce more asthma than swimming, for example; however, when ventilation is identical during running and swimming, the exercise-induced asthma will also be the same. Hyperventilation alone is as good as physical exercise to induce exercise-induced asthma. If the physical exercise provokes an asthmatic attack, this is most often easily reversed by inhaled beta 2-agonists. Pretreatment of exercise-induced asthma is most efficient by inhaled beta 2-agonist; orally dosed beta 2-agonist is not as efficient as inhaled beta 2-agonist in the pretreatment of exercise-induced asthma. Inhaled sodium cromoglycate diminishes exercise-induced asthma, and the effect seems to be better in children than in adults. Inhaled steroids have no immediate effect on exercise-induced asthma, but long term treatment with steroids diminishes exercise-induced asthma. The pathogenesis of exercise-induced asthma remains obscure. If the water content is low in the inhaled air, e.g. in cold air, the changes in ventilatory capacity following exercise. will be greater than when the exercise is performed while inhaling hot air with high humidity. Almost all asthmatics present changes in the ventilatory capacity following exercise. Seasonal changes in exercise-induced asthma are only present in asthmatics with seasonal allergies, e.g. pollen allergy. No diurnal variation is found in exercise-induced asthma. Asthmatics can do any form of physical exercise. Almost all asthmatics can prevent major changes in ventilatory capacity by pretreatment of exercise-induced asthma or be treated for exercise-induced asthma during the physical activity so that they will not suffer from asthma while performing physical exercise. Asthmatics who have been successfully treated for exercise-induced asthma can do physical exercise at the same level as non-asthmatics. Asthmatic children in particular should be encouraged to perform any sport they like, as the physiological and psychological effects may be beneficial to them. It is concluded that almost all asthmatics have exercise-induced asthma, and that physical training may be beneficial. Exercise-induced asthma is best treated and pretreated by inhalation of beta 2-agonists.

Exercise-induced bronchodilation in asthma

Of 34 symptomatic adult asthmatic patients (23 men) aged 51 +/- 13 years (mean +/- 1 SD) with moderately severe airways obstruction who underwent maximal exercise testing at room temperature (22 degrees C) and humidity (44 percent RH) using a bicycle ergometer, we identified seven male patients aged 56 +/- 9 years in whom forced expired volume in one second (FEV1) increased greater than or equal to 20 percent over the baseline pre-exercise value (exercise-induced bronchodilation). At maximal exercise, these patients achieved an O2 consumption of 1.4 +/- 0.4 L/min and a minute ventilation of 56 +/- 9 L/min. Baseline FEV1 was 1.3 +/- 0.5 L (SD) (43 +/- 12 percent predicted) and increased to 2.1 +/- 0.5 L at five minutes after exercise and persisted at least 20 minutes. Exercise was repeated in all seven patients on a separate day one to six months later, and results were similar in six. In these seven patients, three minutes of voluntary isocapnic hyperventilation achieving a minute ventilation comparable to that during maximal exercise led to an increase in FEV1 of 20 +/- 18 percent (range 0 to 54 percent). The Vmax50 was 22 +/- 30 percent before, and 10 +/- 21 percent after maximal exercise and 25 +/- 37 percent before, and 11 +/- 22 percent after isocapnic hyperventilation. Pre-treatment with acetylsalicylic acid (mean serum concentration 120 +/- 64 micrograms/ml) in the six patients with reproducible bronchodilation completely blocked exercise bronchodilation in one patient and blunted it in four others. Findings suggest that a subset of adult patients with symptomatic asthma may develop bronchodilation after six to eight minutes of exercise, that exercise-induced bronchodilation may in part be reproduced with isocapnic hyperventilation, and that it may be blocked completely or partially by acetylsalicylic acid, implying mediation by prostaglandins.

Circulating catecholamines in acute asthma

Plasma catecholamine concentrations were measured in 15 patients (six male) aged 14-63 years attending the casualty department with acute severe asthma (peak expiratory flow 27% (SEM 3%) of predicted). Nine patients were admitted and six were not. The plasma noradrenaline concentration, reflecting sympathetic nervous discharge, was two to three times normal in all patients and was significantly higher in those who required admission compared with those discharged home (mean 7.7 (SEM 0.6) v 4.7 (0.5) nmol/l (1.3 (SEM 0.1) v 0.8 (0.08) ng/ml); p less than 0.001). Plasma adrenaline concentration, however, was not increased in any patient. This surprising failure of the plasma adrenaline concentration to increase during the stress of an acute attack of asthma was unexplained and contrasts with the pronounced rise in plasma adrenaline and noradrenaline concentrations in acute myocardial infarction, heart failure, and septicaemia. The failure of plasma adrenaline concentration to increase in acute asthma is unlikely to be explained by adrenal exhaustion, but it may be another example of impaired adrenaline secretion in asthma.

Histamine reactivity during the refractory period after exercise induced asthma

An episode of exercise induced asthma will usually be followed by a period during which further exercise will not induce asthma. Postulated mechanisms include persistence of catecholamines released during exercise, development of tolerance to released mediators, and mediator depletion. To investigate the underlying mechanism further eight asthmatic men underwent three experimental protocols as follows: two treadmill runs of eight minutes; two incremental challenges with histamine inhalation; and a treadmill run of eight minutes followed by an incremental challenge with histamine inhalation. In each case the two challenges began 40 minutes apart. Patients performed the paired exercise trial first. Refractoriness to bronchoconstriction was shown in the repeated exercise studies but did not occur with repeated histamine challenge. The geometric mean histamine concentrations required to produce a 20% fall in forced expiratory volume in one second (FEV1) were 1.53 mg/ml and 0.93 mg/ml for the first and second challenges respectively (NS) and 1.4 mg/ml (NS) for the histamine challenge after exercise. It is concluded that refractoriness to exercise induced asthma is not explained by the development of smooth muscle tolerance to repeated histamine exposure or by the persistence of catecholamines released during exercise. The data are consistent with the theory of mediator depletion as the cause of refractoriness.

Effect of exercise on isoprenaline-induced lymphocyte cAMP production in atopic asthmatics and atopic and non-atopic, non-asthmatic subjects

The effect of exercise on isoprenaline-induced cyclic adenosine monophosphate (cAMP) production was studied in peripheral-blood lymphocytes obtained from ten patients with atopic asthma, seven subjects who were atopic but did not have asthma and eight non-atopic, non-asthmatic control subjects. The asthma in the atopic subjects was mild only requiring intermittent treatment with inhaled beta adrenoceptor agonists, none of which were taken in the 48 hr prior to the study. Exercise consisted of a standardized 6-min run on a treadmill sufficient to raise the subject's pulse rate to greater than 160 bpm and respiratory function was measured before and at 5, 10, 15, 20, 30 and 60 min after the test. Blood samples were taken 5 min before and at 10 and 60 min after exercise, lymphocytes were separated by density gradient centrifugation and cAMP measured by a competitive radioimmunoassay. Exercise led to a significant decrease (27%) in the forced expiratory volume in 1 sec (FEV1) in the ten atopic asthmatic subjects but no change (less than 3%) in the non-atopic and atopic non-asthmatics. There was no significant difference in the unstimulated cAMP levels before exercise in the three groups, but stimulation with isoprenaline caused a significantly greater rise in cAMP in the non-atopic, non-asthmatic subjects when compared to both the atopic asthmatics and the atopic subjects without asthma. Exercise led to a significant elevation of cAMP in all three groups of subjects, but the same differences between the groups remained.(ABSTRACT TRUNCATED AT 250 WORDS)

[Blockade of exercise-induced bronchial asthma by fenoterol]

The bronchoconstrictor response to cold air breathing during exercise shows a wide interindividual variation in asthmatic patients. We investigated whether the protective effect of a single, inhaled dose of 0.2 mg fenoterol powder is dependent on the severity of airways obstruction, following placebo pretreatment of an inhalative thermal burden precisely matched in terms of respiratory heat exchange. In ten asthmatic patients 0.2 mg fenoterol powder or placebo were administered via an inhalator in a single blind and random order fashion on separate days. Lung function was measured before and 30 min after treatment (baseline value) and 3, 10, 15 and 30 min after an inhalative provocation consisting of cold air breathing during exercise. After placebo the maximal increase of airway resistance compared to the baseline value ranged from 682% to 50% (means +/- SD: 344.1 +/- 312.2) whereas fenoterol shifted the corresponding data to 58% and -23.0% (means +/- SD: 13.4 +/- 29.2). The protective effect of fenoterol did not depend on the reactivity of the airways to the stimulus applied. The results indicate that the inhalative pretreatment with 0.2 mg fenoterol powder is sufficient to block exercise-induced asthma even in those patients whose airways are highly sensitive to respiratory heat loss.

Refractory period following induced asthma: contributions of exercise and isocapnic hyperventilation

To compare the refractory period that follows exercise and isocapnic hyperventilation, 10 asthmatic children performed two pairs of challenge tests in random order at least six hours apart. In pair A a hyperventilation challenge was followed by an exercise challenge and in pair B the order was reversed. Both pairs of tests were done while the children were breathing cold dry air. Tests were matched in terms of work load, ventilation, and end tidal carbon dioxide tension (PCO2). The mean percentage fall in FEV1 (delta FEV1) after the first challenge (hyperventilation) of pair A and the first challenge (exercise) of pair B were the same (30% (SEM 2%)) and 30% (4%) respectively). The mean delta FEV1 of the exercise test following hyperventilation in pair A and of hyperventilation following exercise in pair B was 22% (4%) and 18% (4%) respectively. Both these latter results were significantly lower than the respective delta FEV1 when the challenge was the first test of the pair. Although the mean refractoriness index (reduction in induced asthma in the second test of each pair compared with the first test) was greater when exercise was the first challenge, the difference was not significant.

The bronchial response to cold air challenge: evidence for different mechanisms in normal and asthmatic subjects

We have investigated possible mechanisms of response to airway cooling by studying the effects of sodium cromoglycate and ipratropium bromide on the changes in airways resistance that followed eucapnic hyperventilation with subfreezing air in a group of 12 patients with mild asthma and 10 normal subjects. We have also studied the period of refractoriness to repeated challenge. Maximum bronchoconstriction was not reduced after the second challenge, but in the asthmatics the one-second forced expiratory volume recovered more rapidly after the second challenge. The response in normal subjects was completely abolished by ipratropium bromide (p less than 0.0005) whereas sodium cromoglycate was without effect. In the asthmatics both ipratropium and cromoglycate were effective in attenuating the response (p less than 0.005). These results suggest that in normal subjects the response to airway cooling is produced predominantly via neural mechanisms, whereas in asthmatics there is an additional mechanism which can be abolished by sodium cromoglycate.

Serum dopamine beta-hydroxylase and free fatty acids in exercise-induced asthma

Serum dopamine beta-hydroxylase activity, which is thought to reflect noradrenaline secretion, and free fatty acid level were measured in twenty atopic asthmatic children, of whom ten had exercise-induced asthma (EIA), after exercise on the treadmill. There was a significant decrease in the level of serum dopamine beta-hydroxylase activity in the asthmatics who developed EIA and this closely accompanied the onset of airflow obstruction. There was no change in the free fatty acid levels. In contrast, the asthmatics, who did not have EIA showed a significant rise in the levels of dopamine beta-hydroxylase activity and free fatty acids after the same exercise task. Our results suggest that the atopic children studied, who developed EIA, may have had an impaired noradrenaline response to exercise. It is further suggested that this impaired noradrenaline secretion may facilitate mediator release and contribute to the airflow obstruction in EIA.

Effect of a 2 week course of oral salbutamol on adrenomedullary function in normal subjects

1 The adrenal medullary response to intravenous histamine infusions (0.1 and 0.4 micrograms kg-1 min-1 histamine base) was studied in six normal subjects. 2 After a 2 week course of oral salbutamol (8 mg slow release twice daily) plasma adrenaline levels, thought to reflect adrenomedullary function, were unchanged both at rest and in response to histamine infusion. 3 The present study does not support our original hypothesis that salbutamol may be capable of suppressing the adrenal medulla in normal subjects.

Sympathoadrenal reactivity in exercise-induced asthma

The possibility that sympathoadrenal activity is altered in asthma was examined in eight patients with a history of exercise-induced asthma (EIA), eight matched patients with nonexercise induced asthma (NEIA), and eight matched healthy control subjects. No medication was allowed for at least one week before examination. In a pretrial exercise test diagnosis of EIA was confirmed and each individual's work capacity (Vo2 max) was determined. The trial consisted of an orthostatic test and a standardized exercise test at 80 to 90 percent of VO2 max on a treadmill. The trial exercise test caused a decrease in FEV1 in EIA patients only, whereas measurements of Sgaw revealed a significant but less pronounced postexercise bronchoconstriction in NEIA-patients as well. Basal plasma catecholamine levels were similar in all groups. Noradrenaline and adrenaline levels were approximately doubled by the orthostatic test and increased approximately ten-fold following exercise, with no differences between the groups. Plasma cAMP levels were approximately doubled by the exercise test. In the EIA patients there was an inverse correlation between increases in plasma cAMP and decreases in Sgaw. Our study does not support earlier claims that exaggerated catecholamine response to exercise causes postexercise bronchoconstriction by alpha-adrenoceptor stimulation in EIA. Differences in study results appear to have methodologic explanations.

Hyperventilation-induced asthma: evidence for two mechanisms

The mechanism by which airway cooling induces airflow obstruction in asthmatic subjects has not yet been established. Using a pair of isocapnic hyperventilation challenges, with a 40-minute interval, we looked for the presence of a refractory period in 19 asthmatic patients (aged 9-18 years). The subjects fell into two groups. The eight in the "non-refractory" group showed less than a 25% reduction in response to the second challenge, but the 11 in the "refractory" group showed at least a 35% reduction. Twelve subjects also performed a hyperventilation challenge after cholinergic blockade with inhaled ipratropium bromide. In five, in whom no refractoriness after hyperventilation was seen, there was a significant protection from cholinergic blockade (p less than 0.05). In these a vagal (cholinergic) reflex seems likely. The remaining seven, who had a refractory period, received no significant protection from cholinergic blockade and therefore no evidence for the presence of any cholinergic mechanism. We conclude that two mechanisms are responsible for hyperventilation-induced asthma, one of which is a vagal reflex while mediator release may be the other.

Prazosin, an alpha 1-adrenoceptor antagonist, partially inhibits exercise-induced asthma

The effect of prazosin, a potent and specific alpha 1-adrenoceptor antagonist given by inhalation (total nebulized 2 mg) was compared with placebo in a double-blind randomized study of 10 atopic asthmatic children. Prazosin significantly (p less than 0.01) reduced the severity of post-exercise bronchoconstriction (maximum fall in peak expiratory flow after exercise 21.4% +/- SEM 6.3% after prazosin compared with 42.5% +/- 7.3% after placebo). This protective action of prazosin suggests that activation of alpha 1-adrenoceptor may be involved in the pathogenesis of exercise-induced asthma either by facilitation of mast-cell mediator release or by direct contraction of bronchial smooth muscle. Prazosin did not significantly change resting bronchomotor tone or histamine-induced bronchoconstriction, suggesting no effect on bronchial smooth muscle contractility.