Effective Bronchodilator Resuscitation of Children in the Emergency Room: Device or Interface?

Is Breath-Actuated Nebulizer Superior to SVN?

No randomized trials have demonstrated greater bronchodilator efficacy with breath-actuated nebulizer than with SVN in the emergency department. This trend continues in the study by Sabato et al, who report that the admission rate with breath-actuated nebulizer and SVN were both 40%.¹¹ The mean clinical asthma score was lower in the SVN group (3.0) than in the AeroEclipse group (5.1). The results suggest that in patients with less severe asthma the SVN was as effective as AeroEclipse, but the comparison is complicated by the relatively small number of patients who received SVN (10 patients) versus AeroEclipse (86 patients). While AeroEclipse may be more effective than SVN in patients with more severe asthma, this was not evaluated by Sabato et al.

Is Breath-Actuated Nebulizer Superior to Continuous Nebulization?

To answer this question, the first step is to analyze the devices' output. The high-flow MiniHeart nebulizer has a listed output of 20 mL/h and an MMAD of 2–3 μm, which corresponds to a respirable fraction of > 70%. In contrast, the AeroEclipse has a claimed MMAD of 2.8 μm and a 78% respirable fraction. Those characteristics are used in the following example.

With an inspiratory-expiratory ratio of 1:4 in a child with moderate to severe bronchospasm, 20% of the emitted dose of 10 mg (10 mg × 0.2 = 2 mg) is inhaled, and 70% of the respirable particles, or 1.4 mg (2 mg × 0.7 = 1.4 mg) of albuterol could reach the lung. If 35% of the breath-actuated nebulizer dose is inhaled, and the respirable fraction is 78%, a respirable dose of approximately 1.4 mg (5.0 mg × 0.35 × 0.78 = 1.4 mg) could be achieved with the 5-mg dose, and approximately 0.7 mg (2.5 mg × 0.35 × 0.78 = 0.68 mg) with the 2.5-mg dose. Although this example does not account for the residual drug remaining in the MiniHeart nebulizer at the end of nebulization (possibly 0.5–1.0 mg of albuterol), it does indicate a similar lung dose with the 5 mg breath-actuated nebulizer dose and the 10 mg/h LVN dose.

If the Inhaled Dose Is Similar Between Breath-Actuated Nebulizer and LVN, What Other Factors Apply?

Although Sabato et al identified a relationship between the admission rate and the first bronchodilator treatment administered in the emergency department, it is unclear how many aerosol treatments were required for any one patient. As a group, 69% of the AeroEclipse group required additional bronchodilator treatments, compared to 57% of the standard-therapy group. To understand the causal relationship between treatment and admission, we need to understand how many total doses were administered.

The AeroEclipse and SVN treatments were administered by respiratory therapists who remained at the bedside during the treatments, which assures that the aerosol was in fact administered and tolerated through the treatment. In contrast, after initial setup, the continuous nebulization via LVN was largely overseen by the parent, and was not supervised by the respiratory therapist, so we are not sure how much of each LVN treatment was actually administered during the LVN treatment hour. One might infer that aerosol therapy directly observed by a clinician is more reliable and effective than unobserved therapy.

Is Interface the Key?

The LVN patients were sicker than the AeroEclipse patients (clinical asthma score 5.5 vs 5.1, respectively). However, the key to the difference in hospital admission may be associated more with the interface than with the aerosol generators. Treatment tolerance was greater in the AeroEclipse group than the standard-therapy group. Blow-by was used in 23% of the standard-therapy group, and in less than 4% of the AeroEclipse group. If the therapeutic benefit of blow-by is negligible, then this difference in interface may account for much of the difference in therapeutic response.

Sabato et al report that more of the AeroEclipse patients tolerated mask, which might indicate that breath-actuation is better tolerated than continuous nebulization, which involves cold aerosol blowing onto the face between breaths.¹¹ This aspect of aerosol therapy has not been well studied and merits further investigation. Loose-fitting mask and blow-by dramatically reduce aerosol deposition.^13–21 Lung dose is less than 1% with a face mask leak of ≥ 0.2 cm²,¹³ so optimal mask/face seal is important in maximizing aerosol delivery. Blow-by decreases aerosol delivery with the distance between the face and mask,²⁰ so variability in mask/face distance during the LVN treatment hour with an untrained parent administering blow-by may have been a large factor in inhaled dose. Therefore, the trend toward better clinical asthma score and difference in admission rate may be associated with patient tolerance of the patient/device interface with AeroEclipse.

A key issue in aerosol therapy in children is intolerance of the interface. We must use an interface the patient will tolerate, so improvements that make the interface more tolerable may be more important than the type of aerosol generator. It is well known that screaming, struggling, and crying decrease aerosol delivery to children,^17,22,23 whereas tolerance is associated with greater lung deposition and better adherence to therapy. For instance, Janssens et al²⁴ compared aerosol delivery in awake and asleep children and found that lung dose was significantly higher in the sleeping children. When the interface is better tolerated, it causes less agitation and leads to better deposition and outcomes. Up to 49% of infants and children do not tolerate aerosol via mask without agitation, which decreases deposition, and with blow-by the lung delivery is negligible. This is a problem in the emergency department and at home, and is associated with low adherence to therapy.

A better-tolerated interface may be the key to more effective therapy. Recent research on aerosol delivery via high-flow nasal cannula to pediatric patients was promising.^25,26 Infants and children have preferential nasal breathing and tolerate nasal cannula better than mask, and in vitro studies suggested that delivery via nasal cannula provided a high inhaled dose and may be worthy of further evaluation.^25,26

Sabato et al address a very important research question: comparing breath-actuated nebulizer to LVN and SVN.¹¹ If breath-actuated nebulizer and LVN have similar particle-size distributions and respirable dose, then any differences in clinical response are more about the interface than about the aerosol generator. The observation that AeroEclipse with mask was better tolerated by children with severe asthma may provide an important insight into the observed difference in hospital admission. Through additional research we can determine the best aerosol delivery method for children in the emergency department and determine the effect of each device/interface in children with asthma. Therefore, future studies should concentrate not only on aerosol devices but also on patient-related factors that affect aerosol delivery in children of all ages, races, and ethnicities.