1465-9921-8-19 RRJ Research <p>Overcoming beta-agonist tolerance: high dose salbutamol and ipratropium bromide. Two randomised controlled trials</p> Haney Sarah sas_haney@yahoo.co.uk Hancox J Robert bob.hancox@otago.ac.nz

Department of Respiratory Medicine, Sunderland Royal Hospital, Sunderland, UK

Department Respiratory Medicine, Waikato Hospital, Hamilton, New Zealand

Dunedin Multidisciplinary Health and Development Research Unit, Dunedin School of Medicine, University of Otago, Dunedin, New Zealand

 Respiratory Research 1465-9921 2007 8 1 19 http://respiratory-research.com/content/8/1/19 17341317 10.1186/1465-9921-8-19 29 6 2006 06 3 2007 06 3 2007 2007 Haney and Hancox; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Asthmatics treated with long-acting beta-agonists have a reduced bronchodilator response to moderate doses of inhaled short acting beta-agonists during acute bronchoconstriction. It is not known if the response to higher doses of nebulised beta-agonists or other bronchodilators is impaired. We assessed the effect of long-acting beta-agonist treatment on the response to 5 mg nebulised salbutamol and to ipratropium bromide.

Methods

Two double-blind, placebo-controlled, crossover studies of inhaled formoterol 12 μg twice daily in patients with asthma.

High-dose salbutamol: 36 hours after the last dose of 1 week of formoterol or placebo treatment, 11 subjects inhaled methacholine to produce a 20% fall in FEV1. Salbutamol 5 mg was then administered via nebuliser and the FEV1 was monitored for 20 minutes. Ipratropium: 36 hours after the last dose of 1 week of formoterol or placebo treatment, 11 subjects inhaled 4.5% saline to produce a 20% fall in FEV1. Salbutamol 200 μg or ipratropium bromide 40 μg was then inhaled and the FEV1 was monitored for 30 minutes. Four study arms compared the response to each bronchodilator after formoterol and placebo. Analyses compared the area under the bronchodilator response curves, adjusting for changes in pre-challenge FEV1, dose of provocational agent and FEV1 fall during the challenge procedure.

Results

The response to nebulised salbutamol was 15% lower after formoterol therapy compared to placebo (95% confidence 5 to 25%, p = 0.008). The response to ipratropium was unchanged.

Conclusion

Long-acting beta-agonist treatment induces tolerance to the bronchodilator effect of beta-agonists, which is not overcome by higher dose nebulised salbutamol. However, the bronchodilator response to ipratropium bromide is unaffected.

Background

Patients with asthma who are poorly controlled on inhaled corticosteroids are often prescribed long-acting beta-agonists 12. However, most asthmatics continue to need short acting beta-agonists for relief of breakthrough symptoms and for treatment during asthma exacerbations. Despite accumulating evidence that tolerance develops to the bronchodilator effects of beta-agonists, the effect of regular long-acting beta-agonists on the response to treatment of exacerbations is rarely considered in treatment guidelines.

Tolerance to the systemic 3 and bronchoprotective 4 effects of beta-agonists is known to occur during regular beta-agonist use. It was previously thought that tolerance to bronchodilation did not occur. However, recent studies have shown that tolerance to bronchodilation is easily demonstrated when tested from a bronchoconstricted state, such as after methacholine or exercise challenge 5678910111213. Patients using regular long-acting beta-agonists may therefore be less responsive to further beta-agonist treatment during acute bronchoconstriction. This is potentially a serious problem for patients who are taking these drugs and experience an exacerbation of asthma.

Studies of bronchodilator tolerance have demonstrated that regular beta-agonist treatment impairs the bronchodilator response to moderate doses of up to 400 μg of salbutamol 56789101112. It has been suggested that this tolerance can easily be overcome by administering higher doses of beta-agonists, but this has never been formally examined 14. Treatment of asthma exacerbations in emergency departments usually includes higher doses of beta-agonists given via a nebuliser, typically up to 5 mg salbutamol 12. There have been no randomised controlled trials of the effects of regular long-acting beta-agonists on this emergency treatment.

It is also unknown whether beta-agonist tolerance use affects the airway response to other bronchodilators. The anticholinergic bronchodilator ipratropium bromide is often added to emergency asthma treatment in severe bronchoconstriction and in those who respond poorly to beta-agonist alone 215. It is likely that the bronchodilator response to ipratropium is not affected by prior long-acting beta-agonist treatment since it acts via a different receptor. However, beta2-receptors and muscarinic cholinergic receptors share some intracellular secondary messengers and their signalling pathways may interact 1617. Hence it is plausible that bronchodilator responsiveness to ipratropium could be affected by beta-agonist tolerance. Moreover, it is possible that beta-agonists have a non-specific effect on airway smooth muscle tone thereby altering the response to other bronchodilators regardless of intracellular signalling pathways 1819.

Given the role of high dose beta-agonist and ipratropium bromide in the management of asthma exacerbations, it is important to assess their effectiveness in the setting of long-acting beta-agonist treatment. We performed two studies to address the following questions:

Study 1: Does high dose salbutamol overcome the bronchodilator tolerance associated with regular long-acting beta-agonist use?

Study 2: Does beta-agonist bronchodilator tolerance affect the bronchodilator response to ipratropium bromide?

Methods

Subjects

Subjects had physician-diagnosed asthma with a provocative dose to cause a 20% fall in FEV1 (PD20) less than 1.5 mg of methacholine (study 1) or less than 30 ml saline (study 2) at screening (see below). Subjects were not using long-acting beta-agonists prior to the study and had not changed their asthma medications nor had a respiratory tract infection for 6 weeks prior to study entry. The studies were approved by the Waikato Ethics Committee. All subjects provided written informed consent.

Study design

Both studies were random-order, double-blind, cross-over studies comparing formoterol 12 μg twice daily with placebo. Randomisation was by computer-coded bottles of identical capsules for use with the Foradil Aeroliser (Novartis, Auckland, New Zealand). Additional beta-agonists were not allowed throughout the studies. Ipratropium was used for symptom relief.

Study 1: High-dose salbutamol

This was a crossover study with 2 arms. Subjects inhaled formoterol or placebo twice daily for 1 week. Thirty-six hours after the last dose, subjects underwent a methacholine challenge and salbutamol response as described below. Subjects then crossed to the other medication for a repeat sequence of 1 week of treatment, methacholine challenge and salbutamol response.

Methacholine challenge was performed using a modified Yan technique 20. Subjects inhaled doubling doses of nebulised methacholine until the FEV1 had fallen by ≥ 20%. The PD20 methacholine was calculated by linear interpolation of the last two doses. Immediately after completion of the methacholine challenge, subjects were given 5 mg salbutamol via a Sidestream nebuliser and System 22 aerosol mask (Profile, Bognor Regis, UK) powered by oxygen at a rate of 6 L/minute. FEV1 was measured at 5, 10, 15 and 20 minutes after starting the nebuliser.

Study 2: Ipratropium bromide

This was a crossover study with four arms. For each arm subjects inhaled formoterol 12 μg or placebo twice daily for 1 week. Thirty-six hours after the last dose, subjects underwent a hypertonic saline challenge and bronchodilator response as described below. Subjects then received the alternative medication and started the next arm of the study. Two study arms compared the bronchodilator response to salbutamol after formoterol and placebo treatment and the other two arms compared the response to ipratropium bromide after formoterol and placebo.

Hypertonic saline challenge was performed according to the method of the European Respiratory Society 21. Subjects inhaled 4.5% saline until the FEV1 fell by ≥ 20%. The PD20 saline was calculated by linear interpolation of the last two doses. Immediately after the challenge, 200 μg salbutamol or 40 μg ipratropium was given via a metered dose inhaler and large volume spacer. FEV1 was measured 5, 10, 15, 20 and 30 minutes after the bronchodilator.

Analysis

The main outcome measurement was the area under the salbutamol or ipratropium response curves (AUC), expressed as a percentage of the fall in FEV1 induced by challenge. Comparisons between treatments were adjusted for baseline FEV1 and dose of provocational agent given using analysis of covariance. A secondary outcome for each study was the final post-bronchodilator FEV1, which was also adjusted for the fall in FEV1 during challenge. Post hoc comparisons between placebo and formoterol treatments were were made using Tukey's exact method. Comparisons of pre-challenge FEV1 and of PD20 were made using paired Student's t-tests. PD20 values were log-transformed for analysis.

Previous studies indicated that a sample size of 12 subjects would detect a 30% fall in AUC with 80% power at α = 0.05 5.

Results

Study 1: High dose salbutamol

Eleven subjects were recruited and completed the study. Baseline characteristics of the subjects are shown in table 1. There was no significant effect of order of treatment on AUC, pre-challenge FEV1 or PD20 methacholine. The pre-challenge FEV1 and PD20 methacholine were not significantly different between placebo and formoterol arms (table 2).

<p>Table 1</p>

Baseline characteristics of subjects

Study

1. High dose salbutamol

2. Ipratropium

Number of subjects

11

11

Male

3

3

Age (range)

37 (22 to 62)

34 (19 to 53)

Number on inhaled steroids Dose range (μg)(budesonide equivalent)

9 (200 to 1200)

10 (200 to 2000)

FEV1% predicted at screening (range)

79 (61 to 101)

86 (65 to 103)

 <p>Table 2</p>

Results of the high dose salbutamol study (study 1)

Treatment

Placebo

Formoterol

Pre-challenge FEV1 (L) (SD)

2.55 (0.75)

2.57 (0.72)

Post challenge FEV1 (L) (SD)

1.92 (0.59)

2.00 (0.51)

PD20 methacholine (mg) (geometric mean, 95% CI)

0.08 (0.03, 0.22)

0.10 (0.04, 0.25)

AUC salbutamol (%.time) (SD)

412 (140)

339 (201)

Difference: paired t-test (95% CI)

73 (-4, 149) p = 0.06

Difference: covariate analysis (placebo-formoterol) (least squares means, 95% CI)

63 (22, 105) p = 0.008

Post-salbutamol FEV1 at 20 mins (L) (SD)

2.79 (0.86)

2.67 (0.84)

Difference: paired t-test (95% CI)

0.12 (0.03, 0.20) p = 0.008

Difference: covariate analysis (placebo-formoterol) (least squares means, 95% CI)

0.12 (0.06, 0.19) p = 0.003

The salbutamol response, expressed as area under the curve, was 15% lower in the formoterol period compared to placebo (95% confidence interval 5 to 25%). This was a significant difference when taking the covariates into account (p = 0.008) (table 2, figure 1).

<p>Figure 1</p>

Response to high dose salbutamol (n = 11)

Response to high dose salbutamol (n = 11).

The final FEV1 20 minutes after challenge after 5 mg salbutamol was 2.67 L in the formoterol arm compared to 2.79 L after placebo (95% CI for difference 0.06 to 0.19 L; p = 0.003).

Study 2: Ipratropium bromide

Thirteen subjects were recruited to the study. Two subjects withdrew during the first treatment period, one with uncontrolled asthma and one with a respiratory infection (taking formoterol and placebo respectively). Baseline characteristics are shown in table 1. There was no effect of order of treatment.

The mean pre-challenge FEV1 and PD20 saline did not change significantly between formoterol and placebo arms. However, one subject experienced a less than 15% fall in FEV1 with inhalation of saline after taking formoterol. For analytical purposes, the PD20 saline for these challenges has been assumed to be 30 ml (the maximum value available for inhalation). Exclusion of this subject from analysis does not materially alter the results.

The response to ipratropium, expressed as the AUC, was not significantly different between formoterol or placebo treatment arms (table 3, figure 2). The final FEV1, 30 minutes after ipratropium was not significantly different between the formoterol or placebo arms.

<p>Table 3</p>

Results of the ipratropium study (study 2)

Bronchodilator

Ipratropium

Salbutamol

Treatment

Placebo

Formoterol

Placebo

Formoterol

Pre-challenge FEV1 (L) (SD)

2.77 (0.50)

2.67 (0.41)

2.62 (0.50)

2.67 (0.63)

Post-challenge FEV1(L)(SD)

2.15 (0.38)

2.07 (0.37)

2.06 (0.41)

2.11 (0.60)

PD20 saline (ml) (95% CI)

11.8 (7.4–19)

8.0 (4.6–13.8)

8.9 (4.9–16.0)

8.6 (5.0–14.6)

AUC %.time (SD)

447 (215)

401 (154)

759 (203)

557 (131)

Difference: paired t-test (95% CI)

138 (-48,138) p = 0.303

202 (66, 339) p = 0.008

Difference: covariate analysis (placebo-formoterol) (least squares mean, 95% CI)

88 (-31, 207) p = 0.126

202 (42, 362) p = 0.019

FEV1 at 30 mins (L) (SD)

2.81 (0.54)

2.67 (0.45)

2.91 (0.56)

2.74 (0.64)

Difference: paired t-test (95% CI)

0.22 (0–0.30) p = 0.056

0.10 (-0.05, 0.39) p = 0.117

Difference: covariate analysis (placebo-formoterol) (least squares mean, 95% CI)

0.11 (-0.06, 0.28) p = 0.172

0.22 (0.05, 0.38) p = 0.015

 <p>Figure 2</p>

Response to salbutamol and ipratropium bromide (n = 11)

Response to salbutamol and ipratropium bromide (n = 11).

The response to salbutamol was reduced in the formoterol arm compared to placebo. The mean difference in the AUC was 26% (95% CI 6 to 46%; p = 0.02) (table 3, figure 2). The FEV1 30 minutes after salbutamol was also lower in the formoterol arm compared to placebo, 2.74 L compared to 2.91 L (95% CI for difference 0.05 to 0.38; p = 0.02 by covariate analysis).

Discussion

These studies confirm that the response to salbutamol is reduced in subjects taking long-acting beta-agonists. This reduction in response was evident even when 5 mg salbutamol was given via nebuliser. By contrast, the bronchodilator response to ipratropium was not affected by prior use of formoterol.

It is known that tolerance to bronchodilation occurs following regular formoterol. This has usually been demonstrated by measuring the bronchodilator response to up to 400 μg of salbutamol via metered dose inhaler. In terms of bronchodilation, 2.5 mg via a nebuliser is equivalent to 800 μg via metered dose inhaler and spacer 22. We used a 5 mg dose of nebulised salbutamol in this study as this is commonly used in the emergency treatment of asthma. Higher single doses of salbutamol in a nebuliser are not recommended 2. We found that the response to 5 mg of salbutamol was impaired after 1 week of regular formoterol use, indicating that patients using long-acting beta-agonists are likely to respond poorly to first-line treatment of acute severe asthma even if high doses of nebulised beta-agonist are used. Although the differences in the dose-response curves and final FEV1 shown in this study may appear modest, it has been shown that the degree of beta-agonist tolerance increases with the degree of bronchoconstriction 7. Patients with acute severe asthma will have much more severe bronchoconstriction than the 20% fall in FEV1 induced in this study 223. They are therefore likely to have a much greater impairment in response to beta-agonists. In practice, many patients are given repeated doses of beta-agonists via nebuliser during an acute exacerbation. It was not possible to test the effects of repeated nebulisations using this model owing to the time taken for nebulisation (around 5 minutes) and the effect of spontaneous recovery from methacholine-induced bronchoconstriction.

The findings of the salbutamol study appear to contrast with those of a study which found no difference in the response to emergency department beta-agonist treatment between patients who had been taking long-acting beta-agonists and those who had not 24. However, this emergency department study did not assess the preceding use of short-acting beta-agonists. Since almost all asthmatics take large doses of beta-agonists before presenting to hospital 25 and tolerance to beta-agonists develops rapidly 11, it is highly likely that the 'control' group had also developed tolerance.

The bronchodilator response to ipratropium bromide was not impaired by prior use of long-acting beta-agonist. This confirms that the effect that we have interpreted as beta-agonist tolerance is specific to beta-agonists and unlikely to be due to a non-specific change in airway smooth muscle responsiveness. The intracellular effects of both beta-agonists and cholinergic agents are now known to be far more complex than action on single second messenger systems and there are plausible mechanisms of interaction between them 1626. Muscarinic agonists appear to reduce the potency of beta-agonist bronchodilation, possibly through an effect on adenylyl cyclase 17. The converse effect of muscarinic antagonists has been more difficult to assess 27. Acetylcholine in human airways acts via muscarinic receptors to decrease cyclic AMP and reduce intracellular calcium release, thereby causing bronchoconstriction. Ipratropium blocks these actions, thereby reducing smooth muscle tone and causing bronchodilation. Cyclic AMP is also a key second-messenger in the response to beta-receptor activation. Regular exposure to beta-agonists appears to uncouple the beta-receptor from cAMP production 28. Therefore it seemed possible that beta-agonist tolerance would also have an effect on the response to ipratropium. However, this was not discernible in our study. The addition of ipratropium bromide to beta-agonist treatment in acute severe asthma improves bronchodilation 15, whereas it affords little additional benefit in stable asthma 29. It is possible that this is because the response to beta-agonist in severe asthma is impaired because of prior beta-agonist treatment, whereas the response to anticholinergic treatment is maintained. In this study the bronchodilator response to salbutamol was more rapid and greater than to ipratropium bromide, even after tolerance had developed. However, the effect of beta-agonist tolerance increases with increasing levels of bronchoconstriction 7. In severe asthma the modest response to ipratropium bromide may become more important.

These studies used formoterol as the long-acting beta-agonist. Studies in the emergency department have focussed on patients taking salmeterol 24. Salmeterol is a partial agonist at the beta-receptor compared to formoterol and theoretically it may be less likely to induce tolerance. Alternatively, salmeterol could act as a partial antagonist to salbutamol and reduce the effects of salbutamol still further. In practice, trials that have compared bronchodilator tolerance using the challenge-rescue model have not found any difference between salmeterol and formoterol 810.

We have interpreted the reduction in response to beta-agonists as tolerance or tachyphylaxis to the effects of beta-agonists. Downregulation of the beta-receptors both in terms of receptor number and intracellular response to receptor stimulation is a pharmacologically predictable effect of repeated receptor stimulation 28. An alternative explanation for the reduced response to beta-agonist is that some beta-receptors were still occupied by formoterol molecules at the time of the test and were therefore not available to bind to salbutamol, reducing its effect. We measured the bronchodilator response 36 hours after the last dose of formoterol. This is outside the normal duration of action of formoterol 30 and receptor occupancy should be minimal at this time. The 36-hour withdrawal of formoterol also minimises confounding of the results by large changes in pre-challenge FEV1 and PD20. Although one subject showed a bronchoprotective effect at this time, overall there were no significant differences in the pre-challenge FEV1 or PD20 values. However, it is also known that beta-receptors recover rapidly following downregulation 31 and the timing of challenges 36 hours after the last dose of long-acting beta-agonist may mean that the tolerance measured in these trials was actually lower than that experienced by patients who continue take their long-acting beta-agonists twice daily 12.

There are potential limitations to our study design. First, this challenge-rescue model does not accurately reflect all of the pathophysiology of acute asthma, where airway inflammation, oedema and mucus production play important roles in airway obstruction. Nevertheless, airway smooth muscle contraction is important and is the main target of emergency bronchodilator treatment. In addition, not all of the subjects in these studies were taking inhaled corticosteroids, whereas current guidelines recommend that long-acting beta-agonists are used in conjunction with inhaled corticosteroids 12. There is conflicting evidence on whether systemic corticosteroids may partly reverse tolerance 32. However, it is known that stable doses of inhaled corticosteroids do not influence the development of tolerance 5 and hence the use of inhaled corticosteroids was not a requirement in our selection of subjects.

This study is the first to demonstrate that beta-agonist bronchodilator tolerance can be demonstrated using hypertonic saline. Most previous studies using the 'challenge-rescue' technique have used methacholine as the challenge agent 567810111233. This would have been inappropriate prior to studying the response to the anticholinergic drug ipratropium. Our findings confirm that the challenge-rescue model for studying bronchodilator tolerance works with both direct and indirect challenges. The bronchial response to hypertonic saline challenge is closely correlated with the response to exercise challenge 34. A suboptimal response to salbutamol after exercise challenge has also been found when patients use regular beta-agonists 9.

Conclusion

In summary, these studies confirm that beta-agonist bronchodilator tolerance develops during long-acting beta-agonist treatment. This is not overcome by 5 mg of nebulised salbutamol. The effect is specific to beta-agonists and does not affect the response to ipratropium bromide. Patients using long-acting beta-agonists may respond less well to emergency beta-agonist treatment. Additional treatment with an alternative bronchodilator should be considered early in the course of an exacerbation.

Abbreviations

AMP – adenosine 5'monophosphate

AUC – area under the curve

FEV1 – forced expiratory volume in one second

PD20 – dose of bronchoprovocational challenge agent required to produce a fall in FEV1 of 20% from baseline

Competing interests

The author(s) declare that they have no competing interests.

Authors' contributions

SH contributed to the trial design, acquired the data, performed the statistical analysis and helped to draft the manuscript. RH conceived the study, participated in its design, interpretation of results and helped to draft the manuscript.

Acknowledgements

We would like to thank the study participants. We also thank Dr J McLachlan and the staff of the Waikato Hospital Respiratory Laboratory, Dr Graham Mills and the Waikato Respiratory Research Unit and Jan Cowan of the Respiratory Research Unit in the Dunedin School of Medicine. The study was funded by the Waikato Respiratory Research Fund.

 <p>Global strategy for asthma management and prevention</p> Bethesda Institute NIHNHLB 2002 NIH publication no 96 3659A updated 2005 <p>British guideline on the management of asthma</p> BTS Thorax 2003 58 suppl 1 1 83 <p>Subsensitivity of bronchodilator and systemic β2 adrenergic responses after regular twice daily treatment with eformeterol dry powder in asthmatic patients</p> Newnham DM Grove A McDevitt DG Lipworth BJ Thorax 1995 50 497 504 7597661 <p>Long-term effects of a long-acting β2-adrenocepter agonist, salmeterol, on airway hyperresponsiveness in patients with mild asthma</p> Cheung D Timmers MC Zwinderman AH GBel EH Dijkman JH Sterk PJ N Engl J Med 1992 327 1198 1203 1357550 <p>Tolerance to beta agonists during acute bronchoconstriction</p> Hancox RJ Aldridge RE Cowan JO Flannery EM Herbison GP McLachlan CR Town GI Taylor DR Eur Respir J 1999 14 283 287 10.1034/j.1399-3003.1999.14b08.x 10515402 <p>Reversing acute bronchoconstriction in asthma: the effect of bronchodilator tolerance</p> Jones SL Cowan JO Flannery EM Hancox RJ Herbison GP Taylor DR Eur Respir J 2001 17 368 373 10.1183/09031936.01.17303680 11405513 <p>Bronchodilator tolerance: the impact of increasing bronchoconstriction</p> Wraight JM Hancox RJ Herbison GP Cowan JO Flannery EM Taylor DR Eur Respir J 2003 21 810 815 10.1183/09031936.03.00067503 12765426 <p>Decreased bronchodilating effect of salbutamol in relieving methacholine induced moderate to severe bronchoconstriction during high dose treatment with long acting β2 agonists</p> Van der Woude HJ Winter TH Aalbers R Thorax 2001 56 529 535 10.1136/thorax.56.7.529 11413351 <p>A comparison of the effects of oral montelukast and inhaled salmeterol on response to resuce bronchodilation after challenge</p> Storms WW Chervinsky P Ghannam A Bird S Hustad CM Edelman JM Respir Med 2004 98 1051 1062 10.1016/j.rmed.2004.05.008 15526805 <p>Comparison of combination inhalers vs inhaled corticosteroids alone in moderate persistent asthma</p> Lee DKC Jackson CM Currie GP Cockburn WJ Lipworth BJ Br J Clin Pharmacol 2003 56 494 500 10.1046/j.1365-2125.2003.01887.x 14651722 <p>Rapid onset of tolerance to beta-agonist bronchodilation</p> Haney S Hancox RJ Respir Med 2005 99 566 571 10.1016/j.rmed.2004.10.014 15823453 <p>Tolerance to bronchodilation during treatment with long-acting beta-agonists, a randomised controlled trial</p> Haney S Hancox RJ Respiratory Research 2005 6 107 1266400 16168062 10.1186/1465-9921-6-107 <p>Recovery from bronchoconstriction and bronchodilator tolerance</p> Haney S Hancox RJ Clin Rev Allergy Immunol 2006 31 181 196 10.1385/CRIAI:31:2:181 17085792 <p>Past, present and future - β2-adrenoceptor agonists in asthma management</p> Sears MR Lotvall J Respir Med 2005 99 152 170 10.1016/j.rmed.2004.07.003 15715182 <p>The role of anticholinergics in acute asthma treatment</p> Rodrigo G Rodrigo C Chest 2002 121 1977 1987 10.1378/chest.121.6.1977 12065366 <p>Beyond the dogma: novel β2-adrenoceptor signalling in the airways</p> Giembycz MA Newton R Eur Respir J 2006 27 6 1286 1306 10.1183/09031936.06.00112605 16772391 <p>Muscarinic M2 receptors in acetylcholine-isoproterenol functional antagonism in human isolated bronchus</p> Sarria B Naline E Zhang Y Cortijo J Molimard M Moreau J Therond P Advernier C Morcillo EJ American Journal of Lung Cell Molecular Physiology 2002 283 L1125 L1132 <p>Regular use of inhaled albuterol and the allergen-induced late asthmatic response</p> Cockcroft DW O'Byrne PM Swystun VA Bhagat R J Allergy Clin Immunol 1995 96 44 49 10.1016/S0091-6749(95)70031-5 7622762 <p>Beta 2 agonist tolerance and exercise-induced bronchospasm</p> Hancox RJ Subbarao P Kamada D Watson R Hargreave FE Inman MD Am J Respir Crit Care Med 2002 165 1068 1070 11956046 <p>Rapid method for measurement of bronchial responsiveness</p> Yan K Salome C Woolcock AJ Thorax 1983 38 760 765 6648855 <p>Airway responsiveness. Standardized challenge testing with pharmacological, physical and sensitizing stimuli in adults</p> Sterk PJ Fabbri LM Quanjer PH Cockcroft DW O'Byrne PM Anderson SD Juniper EF Malo JL Eur Respir J 1993 6 53 83 8425595 <p>A comparison of albuterol administered by metered dose inhaler (and holding chamber) or wet nebulizer in acute asthma</p> Colacone A Afilalo M Wolkove N Kreisman H Chest 1993 104 835 841 8365298 <p>First-line therapy for adult patients with acute asthma receiving a multiple-dose protocol of ipratropium bromide plus albuterol in the emergency department</p> Rodrigo GJ Rodrigo C Am J Respir Crit Care Med 2000 161 6 1862 1868 10852758 <p>Salmeterol does not compromise the bronchodilator response to albuterol during acute episodes of asthma</p> Korosec M Novak RD Myers E Skowronski M McFadden ER Am J Med 1999 107 209 213 10.1016/S0002-9343(99)00222-3 10492312 <p>The self-administration of inhaled beta agonist drugs during severe asthma</p> Windom HH Burgess CD Crane J Pearce N Kwong T Beasley R N Z Med J 1990 103 205 207 2342689 <p>Muscarinic receptor signalling in the pathophysiology of asthma and COPD</p> Gosens R Zaagsma J Meurs H Halayko AJ Respiratory Research 2006 7 73 1479816 16684353 10.1186/1465-9921-7-73 <p>Antagonism of β-adrenoceptor-mediated relaxations of human bronchial smooth muscle by carbachol</p> Watson N Magnussen H Rabe KF Eur J Pharmacol 1995 275 307 310 10.1016/0014-2999(95)00048-P 7768300 <p>Beta-adrenergic receptors and their regulation</p> Barnes PJ Am J Respir Crit Care Med 1995 152 838 860 7663795 <p>Influence of age on response to ipratropium and salbutamol in asthma</p> Ullah MI Newman GB Saunders KB Thorax 1981 36 523 529 6458920 <p>Therapeutic Drugs: formoterol</p> Dollery C Therapeutic Drugs Churchill Livingstone Dollery C 2 1999 F155 F158 <p>Agonist-induced desensitization of β-adrenoceptor function in humans</p> Brodde OE Daul A Michel-Reher M Boosma F Man in't Veld AJ Schlieper P Michel MC Circulation 1990 81 914 921 1968366 <p>Interactions between corticosteroids and β2-agonists</p> Hancox RJ Clin Rev Allergy Immunol 2006 31 231 246 10.1385/CRIAI:31:2:231 17085796 <p>Cross tolerance to salbutamol occurs independently of β2 adrenoceptor genotype-16 in asthmatic patients receiving regular formoterol or salmeterol</p> Lee DKC Jackson CM Bates CE Lipworth BJ Thorax 2004 59 662 667 10.1136/thx.2003.019059 15282385 <p>Relation of the hypertonic saline responsiveness of the airways to exercise induced asthma symptom severity and to histamine or methacholine reactivity</p> Makker HK Holgate ST Thorax 1993 48 142 147 8493628