The Use of Inhaled Corticosteroids in the Treatment of Asthma is Children in the Emergency Room

Asthma is the most common chronic disease of childhood and the most common cause of admission of children to the hospital. Children in Saudi Arabia have a relatively high prevalence of asthma compared to many other countries for reasons that are not clear. The prevalence has increased during the past 20 years2 following, and sometimes exceeding, the same pattern noted in Western countries one decade ago. As stated earlier about 5.7% of all ER asthma visits are because of asthma exacerbation and about 8% of those children gets admitted to the hospital.

Corticosteroids (CS) can show two different effects on acute asthma patients:

1. The classic anti-inflammatory or genomic action implicates the activation or repression of multiple genes involved in the inflammatory process. Thus, CS produce their effects on cells by activating glucocorticoid receptors that alter transcription through direct DNA binding. In addition, ligand activated glucocorticoid receptor (GR) can bind pro-inflammatory transcription factors like NFkB (Nuclear Factor kappa B) or activating protein-1 leading to their inactivation. Consequently, CS increase the synthesis of anti-inflammatory proteins, or inhibit the synthesis of many inflammatory proteins through activation or suppression of the genes that encode them. Moreover, CS has been shown to block the production of several pro-inflammatory cytokines by increasing their mRNA (messenger ribonucleic acid) degradation rate. These effects occur with a time lag of about 4-24 hours. So far all the recommended uses of CS in asthma therapy are related to this mode of action, including the use of systemic CS in patients with asthma exacerbation in the emergency room.
2. The nongenomic action, which has a rapid onset (minutes), is reversible (short duration of 60-90 minutes), and is dose dependent. A protective effect was demonstrated 2 hours after a single dose of 100 mcg of fluticasone propionate inhaler using bronchial provocation with cyclic adenosine monophosphate (cAMP). Higher doses were reported to cause more significant effects. Asthmatics present a significant increase in airway mucosal blood flow in comparison with healthy subjects. Calculated as in the volume of the conducting airways from the trachea to the terminal bronchioles, mean airway blood flow values were 24-77% higher in asthmatics than in healthy controls. The inhalation of fluticasone (880 mcg) or budesonide (400 mcg) significantly decreases blood flow in both groups, but more in asthmatics. Evidence suggests that CS decrease airway blood flow by modulating sympathetic control of vascular tone. CS inhibit the extra-neuronal monoamine transporter- mediated uptake of norepinephrine by bronchial arterial smooth muscle cells, therefore, potentiating noradrenergic neurotransmission in the airway vasculature. This action is possibly mediated by binding of CS to membrane bound GR in smooth muscle cells of human airway blood vessels. This effect is a topical local one and is a feature of Inhaled CS (ICS) rather that systemic CS (SCS). Furthermore, this decrease in airway blood flow is likely to enhance the action of inhaled bronchodilators by diminishing their clearance from the airway. Thus, simultaneous administration of ICS and bronchodilators could be of clinical significance. Accordingly, ICS would have to be administered simultaneously with bronchodilators in high and repeated or sequential doses as a way to obtain and maintain the effect throughout the time. Since ICS induced vasoconstriction peaks between 30 and 60 min after drug administration, their use in intervals not more that 30 min seems adequate.

A recent meta-analysis comparing ICS with SCS; or ICS and SCS combination to placebo and SCS combination in the Emergency Room (ER), included 17 different randomized double blind placebo controlled trials with data for 1,133 subjects (470 adults and 663 children) were available for analysis. It concluded that ICS presents early beneficial effects (within 1 to 2 h) in terms of clinical and spirometric variables when used in 3 or more doses administered in time intervals ≤ 30 min over 90 to 120 min. ICS lead to a significant reduction in admission rate at 2 to 4 hours with only 10 subjects needed to be treated to prevent one admission. The nongenomic effect was suggested as a possible candidate by covering the link between molecular pathways and the clinical effects of CS. However, this issue remains controversial and the current asthma guidelines published by the National Heart, Lung, and Blood Institute (NHLBI) in the USA do not include the use of inhaled glucocorticoids in the treatment of asthma in the ER, while the Global Initiative for Asthma (GINA) guidelines suggested that it can be effective. This subject clearly needs to be studied further.

The addition of inhaled anti-cholinergics (Ipratropium Bromide (IB)) to β2-agonists in the treatment of asthma in the ER was shown to be effective, especially in severe asthma, and is now considered a standard therapy. However, very limited data exist in comparing the addition of ICS to anti-cholinergics and β2-agonists combination in adults. In one study the use of triple therapy was superior to the combination of β2-agonist with either IB or ICS. Up to our knowledge, this issue was not previously investigated in children. Moreover, the protocols used for adults may not be practical for the use in children.

Exhaled NO is a marker of airway inflammation. Its level is increased in several conditions of chronic airway inflammation. It correlates well with sputum eosinophilia and bronchial hyper-reactivity in none steroid treated subjects. It is useful as an adjunct in asthma diagnosis, monitoring asthma control, adherence to ICS, and in predicting asthma exacerbations. Its usefulness in the assessment of the severity of asthma exacerbations and response to treatment in the emergency room has not been determined yet. Few studies have shown that the measurement of Fractional Exhaled Nitric Oxide (FeNO) in the emergency room did not correlate with asthma severity or predict treatment outcomes. It also did not correlate with other measurements like symptom score or PEFR (peak expiratory flow rate). However, those studies were not in the same setting as we are proposing here. In other words, they were using standard medications only. Nevertheless, this issue needs to be studied further, especially with the evidence that ligand binding of the cytoplasmic GR leads to rapid activation of the NO synthase in endothelial cells and thereby may alter the level of FeNO. This study is a good opportunity to examine the value of measuring FeNO in the emergency especially that its measurement is easy, reliable and reproducible. The availability of new portable, valid, and reliable devices to measure FeNO (NIOX Mino) makes it even more attractive.

Up to our knowledge, the design we are proposing here has not been studied before.

Our objective is to compare the efficacy of adding repetitive sequential doses of budesonide versus placebo (normal saline (NS)) to β2-agonist and ipratropium bromide (IB) combination (standard treatment) in the management of acute asthma in children in the ER. We hypothesize that the addition of Budesonide to β2-agonist and IB in the management of moderate to severe acute asthma in the ER is superior to the addition of placebo.