Abstract
Children with acute asthma exacerbations frequently present to an emergency department with signs of respiratory distress. The most severe episodes are potentially life-threatening. Effective treatment depends on the accurate and rapid assessment of disease severity at presentation. This statement addresses the assessment, management and disposition of paediatric patients with a known diagnosis of asthma who present with an acute asthma exacerbation, especially preschoolers at high risk for persistent asthma. Guidance includes the assessment of asthma severity, treatment considerations, proper discharge planning, follow-up, and prescription for inhaled corticosteroids to prevent exacerbation and decrease chronic morbidity.
Keywords: Asthma, Disposition, Emergency management, Paediatrics, Preschoolers
Abstract
Les enfants ayant des exacerbations aiguës de l’asthme consultent souvent à l’urgence parce qu’ils présentent des signes de détresse respiratoire. Les crises les plus graves peuvent mettre en jeu le pronostic vital. L’efficacité du traitement dépend de l’évaluation exacte et rapide de la gravité de la maladie à la présentation. Le présent document de principes porte sur l’évaluation, la prise en charge et la conduite à tenir auprès des patients pédiatriques ayant un diagnostic connu d’asthme qui consultent en raison d’une exacerbation aiguë de l’asthme, notamment les enfants d’âge préscolaire très vulnérables à un asthme persistant. Les conseils incluent l’évaluation de la gravité de l’asthme, les considérations thérapeutiques, la planification convenable du congé, le suivi et une prescription de corticoïde par aérosol pour prévenir les exacerbations et réduire la morbidité chronique.
Français en page 257
EPIDEMIOLOGY AND BACKGROUND
Asthma is a common, chronic inflammatory disorder of the airways associated with airway hyper-responsiveness. Asthma exacerbations are the leading cause of hospitalization in children (1), and the lifetime prevalence of asthma in Canadian children has been estimated at 11% to 16% (2).
For this statement, asthma exacerbation is defined as an acute or subacute deterioration of symptom control that causes distress or risks health to the extent that a visit to a health care provider or treatment with systemic corticosteroids becomes necessary (3). The most common triggers for asthma exacerbations in both younger and older children are viral respiratory tract infections; other typical factors are exposure to allergens and a suboptimal control of asthma as a baseline (4). Acute exacerbations are a frequent cause of emergency department (ED) visits (5,6). Guttmann and colleagues (5) reported that in Ontario, over 9% of children with asthma had made at least one ED visit in the past two years, and asthma exacerbations accounted for 3% to 7% of all paediatric ED visits. More than 50% of children who present to the ED with an asthma exacerbation are preschool age (<5 years) (5). Rosychuk et al (6) recently reported that in Alberta, nearly 10% of the paediatric ED visits resulted in an admission to hospital, with one death for every 25,000 ED visits.
Many health care centres across Canada and a wide range of national and international health organizations have developed their own practice guidelines for the assessment and management of acute asthma exacerbations (3,7–9). The use of evidence-based asthma guidelines can improve outcomes for children with asthma (10). This statement specifically addresses the ED management of acute asthma exacerbations in paediatric patients with a known diagnosis of asthma, particularly preschoolers with early transient wheezing whose pattern of symptoms and history of atopy suggest a high risk for persistent asthma (11).
ED management objectives for acute asthma exacerbations are:
An immediate and objective assessment of their severity.
Prompt and effective medical intervention to decrease respiratory distress and improve oxygenation.
Appropriate disposition of the patient after emergency management.
Arranging proper follow-up.
1. Assessing the child in respiratory distress from an acute asthma attack
Effective treatment depends on an accurate and rapid assessment of disease severity upon presentation (3,7–10,12). For definition of mild, moderate and severe, see Table 1.
TABLE 1.
Clinical features | Mild | Moderate | Severe | Impending respiratory failure |
---|---|---|---|---|
Mental status | Normal | Might look agitated | Usually agitated | Drowsy or confused |
Activity | Normal activity and exertional dyspnea | Decreased activity or feeding (infant) | Decreased activity, infant stops feeding | Unable to eat |
Speech | Normal | Speaks in phrases | Speaks in words | Unable to speak |
Work of breathing | Minimal intercostal retractions | Intercostal and substernal retractions | Significant respiratory distress. Usually all accessory muscles involved, and may display nasal flaring and paradoxical thoraco-abdominal movement | Marked respiratory distress at rest. All accessory muscles involved, including nasal flaring and paradoxical thoraco-abdominal movement |
Chest auscultation | Moderate wheeze | Loud pan-expiratory and inspiratory wheeze | Wheezes might be audible without stethoscope | The chest is silent (absence of wheeze) |
SpO2 on room air | >94% | 91–94% | <90% | <90% |
Peak flow versus personal best | >80% | 60–80% | best <60% | Unable to perform the task |
Definitions are not absolute and can overlap. The presence of several parameters indicates the classification of the exacerbation.
Assessment should include:
Signs and symptoms of respiratory distress and airway obstruction, including clinical documentation of vital signs. Pulse oximetry should be used in all patients. Pulsed oxygen saturation (SpO2) of 92% or less on presentation (before oxygen or bronchodilator treatment) is associated with higher morbidity and greater risk for hospitalization (13).
- A focused medical history recording previous medications and risk factors for ICU admission and death (14):
- ○ previous life-threatening events,
- ○ admissions to ICU,
- ○ intubation,
- ○ deterioration while already on systemic steroids.
A focused physical examination to estimate the functional severity of airway obstruction, documenting the use of accessory muscles, air entry in both lungs and wheezing, level of alertness, ability to speak in full sentences, and activity level (Table 1). A silent chest is an ominous sign that there is not enough gas exchange and a warning that respiratory failure is imminent. Mental agitation, drowsiness and confusion are clinical features of cerebral hypoxemia and should be considered signs of extreme severity.
When children are able to perform the task, spirometry is an objective measure of airway obstruction. Spirometry is difficult to perform in children younger than six years of age and/or during an exacerbation. Peak flow meters may be more readily available but are a less sensitive measure of airway obstruction and may be unreliable, especially in children younger than 10 years of age (15). Peak flows should be compared to readily available normal values or, if known, the child’s ‘personal best’.
- Ancillary tests are not routinely recommended.
- ○ Chest x-rays are very rarely indicated unless the clinician suspects complications (ie, pneumothorax), bacterial pneumonia, the presence of a foreign body, or in cases that fail to improve with maximized conventional treatment. In the absence of suggestive clinical features, there is a documented risk of overdiagnosis of pneumonia (16).
- ○ Blood gases are not routinely required to treat a child with asthma exacerbation unless the patient has no clinical improvement with maximal aggressive therapy. A normal capillary carbon dioxide level despite persistent respiratory distress is a sign of impending respiratory failure.
After conducting the initial assessment, a treating physician should categorize disease severity. There are different clinical tools for assessing disease severity in patients with acute asthma exacerbation (17–19). Birken et al (20) compared the performance of various assessment tools and concluded that the Clinical Assessment Score (17) and the Pediatric Respiratory Assessment Measure (PRAM) (18) both reliably assess the severity of an acute asthma exacerbation and are sensitive to changes in clinical status. Typically, clinical tools take into consideration many of the following parameters: level of alertness, ability to speak in full sentences, use of accessory muscles, air entry in both lungs, presence of wheezing and O2 saturation (Table 1).
Independent of the method of assessment, the same parameters used to estimate disease severity at baseline should be used after each treatment, on a regular basis, and at discharge.
2. Medical management steps
Treat hypoxemia,
Give short-acting ß2-agonists,
Prescribe corticosteroids,
Assess treatment response, and
Consider other modalities of treatment.
Patients who are acutely distressed, have signs of severe respiratory impairment or show signs of impending respiratory failure (eg, altered level of consciousness, silent chest, central cyanosis) should be treated immediately with oxygen and short-acting bronchodilators (3,7,12). Anaphylaxis can present with severe respiratory distress that mimics a severe asthma attack (21). If anaphylaxis is suspected, treat immediately with epinephrine.
Otherwise, treatment should be instituted as soon as the assessment is completed. Patients should then be monitored closely to assess their response to initial management and to ensure proper care and disposition after the acute episode.
The flow diagram (Figure 1) shows a pathway to assess and treat children with asthma exacerbation.
Oxygen: Hypoxemia (SpO2 <92%) must be treated urgently with oxygen delivered by face mask or nasal canulae. There is no strong evidence in support of a specific goal for SpO2. In the context of acute respiratory distress, a SpO2 ≥94% appears reasonable (8,12,13).
Short-acting ß2-agonists: Salbutamol (albuterol) is the bronchodilator of choice (3,8,12). A metered-dose inhaler (MDI) with a spacer is the preferred device for salbutamol administration because it is more efficient than a nebulizer for bronchodilator delivery (22). An MDI can be used in almost all situations except for very severe episodes with impending respiratory failure. Even in the presence of hypoxemia, oxygen can be given by nasal canulae at the same time that salbutamol is given by MDI and spacer. In children without initial oxygen requirements, ß2-agonists administered by MDI and spacer are less likely to provoke hypoxemia and tachycardia than a nebulizer (22).
The recommended doses for MDI and nebulizer ß2-agonist delivery are listed in Table 2. The dose and frequency of intermittent salbutamol therapy depend on the severity of an acute attack and the patient’s response to treatment. The first dose of salbutamol should be given as soon as possible after rapid triage and evaluation in the ED. In patients having a severe asthma attack, the continuous administration of nebulized ß2-agonists may have a better and more prolonged bronchodilator effect compared with intermittent therapy (23). Side effects of salbutamol include tachycardia, hyperglycemia and hypokalemia, which are generally well tolerated. There is no evidence in the paediatric age group of reversible arrhythmias following treatment with ß2-agonists, but this side effect has been reported in adults. Paediatric patients treated with continuous nebulized ß2-agonists should be monitored for cardiac arrhythmias.
TABLE 2.
Asthma severity | Drug and route | Dose (maximum) | Risks | Comment |
---|---|---|---|---|
Mild | Inhaled corticosteroids | See discharge plan and Table 3 | ||
Moderate* | Salbutamol, MDI with spacer | <20 kg = 5 puffs (0.1 mg/puff), >20 kg =10 puffs every 20 min during the first hour | Preferable route | |
Salbutamol, intermittent nebulization | 5 mg in 2 ml of normal saline to be given every 20 min during the first hour | Monitor potassium serum levels in patients requiring frequent doses | ||
Oral corticosteroids | Prednisone or prednisolone 1 to 2 mg/kg/day (maximum 60 mg) OR dexamethasone 0.15–0.3 mg/kg/day (maximum 10 mg) | Prolonged course or frequently repeated doses can be associated with adrenal suppression |
Start treatment early. Recommended as one single dose in the morning to decrease risk of adrenal suppression |
|
Ipratropium bromide, MDI/spacer | Puffs (100 μg) every 20 min x 3 doses <20 kg = 3 puffs, >20 kg = 6 puffs | Use with caution in children with soy allergy | ||
Severe† | Salbutamol, continuous nebulization | 0.3 mg/kg/hr 5 mg in 4 ml of normal saline | Tachycardia, hypokalemia, hyperglycemia | Monitor heart rhythm and rate, glucose and electrolytes |
Ipratropium bromide, nebulized | <20 kg = 0.25 mg, >20 kg = 0.5 mg every 20 min maximum 3 doses | Can be mixed with salbutamol aerosols | ||
IV corticosteroids | Methylprednisolone: 1–2 mg/kg/dose (maximum 60 mg q.6 h) hydrocortisone: 5–7 mg/kg (maximum 400 mg q.6 h) | |||
Severe to impending respiratory failure | IV magnesium sulfate | 25–50 mg/kg IV bolus over 20 min (maximum 2 g) | Hypotension | Consider if patient is not improving |
IV salbutamol | Load: 7.5 mcg/kg over 2–5 min, followed by 1 mcg/kg/min. Titrate upwards with increments of 1 mcg/kg/min (maximum 5 mcg/kg/min) | Tachycardia, hypokalemia, hyperglycemia | Monitor heart rhythm and rate, glucose and electrolytes |
Conventional treatment: Oral corticosteroids, nebulized salbutamol ± ipratropium;
Maximized treatment: intravenous (IV) steroids, continuous nebulized salbutamol + ipratropium. MDI metered-dose inhaler
Inhaled anticholinergics: Inhaled ipratropium bromide can be used as an add-on therapy to ß2-agonists. Some randomized control trials demonstrated reduced hospital admission rates and better lung function when ß2-agonists were used in combination with inhaled ipratropium during the first hour, compared with ß2-agonists used alone (24,25). The dose may be repeated every 20 min for the first hour, mixed with ß2-agonists. There are no clinical trials supporting ipratropium use beyond the first hour in children.
Oral/intravenous (IV) corticosteroids: Children who have a moderate to severe asthma exacerbation should receive systemic steroids as part of their initial treatment. This medication should be administered as early in the ED visit as feasible. Steroids may reduce the need for hospitalization and the risk of relapse after initial treatment and may also facilitate an earlier discharge from the hospital (26). The recommended doses of corticosteroids are listed in Table 2. Children with severe asthma or impending respiratory failure should receive IV steroids. The drugs of choice are methylprednisolone and hydrocortisone.
Magnesium sulphate: A recent meta-analysis suggested that IV magnesium sulphate may be effective in children with severe acute asthma, improving respiratory function and decreasing hospital admissions (27). IV magnesium sulphate may be considered in cases of moderate and severe asthma with incomplete response to conventional therapy during the first 1 h to 2 h (27). Patients treated with magnesium sulphate can have hypotension and bradycardia as side effects, and their vital signs should be monitored during treatment. Consultation with an intensive care unit (ICU) physician or respirologist is recommended.
IV salbutamol infusion: This delivery method should be used in patients with severe asthma who do not respond to other treatments (28). In patients with severe attacks, IV ß2-agonists have been shown to improve pulmonary function and gas exchange (28). In general, inhaled drugs may have a limited effect in patients with nearly complete airway obstruction and have practical limitations in ventilated patients. Cardiac responses, such as arrhythmia and tachycardia, are significant side effects of this medication. Patients receiving IV salbutamol should be in a setting where continuous cardiac monitoring is available.
IV aminophylline: This bronchodilator is reserved for children in the ICU setting with a severe asthma exacerbation who have failed to improve despite maximized therapy (continuous inhaled ß2-agonists, IV corticosteroids) (28,29).
Heliox: Using a helium-oxygen gas mixture is reserved for children in the ICU setting with severe asthma exacerbation who have failed to improve despite maximized therapy (30).
Endotracheal intubation and ventilation for impending respiratory failure:
Intubation and mechanical ventilation can be life-saving interventions but their use in paediatric patients with asthma have been associated with significant adverse effects. Up to 26% of children intubated due to asthma have complications, such as pneumothorax or impaired venous return, and cardiovascular collapse because of increased intrathoracic pressure (31). Mechanical ventilation during an asthma exacerbation is associated with increased risk of death and should be considered as a last resort and only in conjunction with the support of a paediatric ICU specialist.
3. Disposition
Admission should be considered if any one of the following apply:
An ongoing need for supplemental oxygen
Persistently increased work of breathing
ß2-agonists are needed more often than q4 h after 4 h to 8 h of conventional treatment
The patient deteriorates while on systemic steroids.
Other criteria may also be taken into consideration (eg, distance from home, comorbid conditions such as anaphylaxis).
ICU admission or referral to a tertiary care centre should be considered if:
The patient requires continuous nebulized salbutamol and fails to improve on this therapy. Call a tertiary care centre PICU specialist to discuss patient management and transport.
Discharge criteria from the ED include:
Needing ß2-agonists less often than q4 h after 4 h to 8 h of conventional treatment
A reading of SpO2 ≥94% on room air
Minimal or no signs of respiratory distress
Improved air entry.
4. Discharge home plan (follow-up)
Children with persistent asthma and/or who have a moderate or severe episode should be given inhaled corticosteroids (ICS) on a regular basis. If the patient is already taking ICS, the dose should be reviewed and adjusted (9,13). ICS are the cornerstone of regular preventive anti-inflammatory treatment to protect against exacerbations and chronic morbidity. The literature does not support a role for short-term intermittent therapy. ICS in appropriate doses are safe and efficacious. Long-term studies have demonstrated that ICS use does not impair growth or affect final adult height. Although there is a potential risk for adrenal suppression when high doses of ICS are used over prolonged periods, this risk can be diminished with proper monitoring and the use of newer ICS. Common ICS and doses are listed in Tables 3 and 4 (9,11).
TABLE 3.
Corticosteroid | Trade name |
Daily inhaled corticosteroid dose, μg
|
|||||
---|---|---|---|---|---|---|---|
(6 to 11 years of age)
|
(12 years of age and over)
|
||||||
Low | Medium | High | Low | Medium | High | ||
Beclomethasone dipropionate HFA | QVAR† | ≤200 | 201–400 | >400 | ≤250 | 251–500 | >500 |
Budesonide* | Pulmicort Turbuhaler‡ | ≤400 | 401–800 | >800 | ≤400 | 401–800 | >800 |
Ciclesonide* | Alvesco§ | ≤200 | 201–400 | >400 | ≤200 | 201–400 | >400 |
Fluticasone | Flovent MDI and spacer; Flovent Diskus¶ | ≤200 | 201–500 | >500 | ≤250 | 251–500 | >500 |
Dose equivalencies are approximate and are based on efficacy data. Categories are somewhat arbitrary but are based on manufacturers’ recommendations.
Licensed for once daily dosing in Canada;
Graceway Pharmaceuticals, Canada;
AstraZeneca Inc, Canada;
Nycomed Canada Inc, Canada;
GlaxoSmithKline Inc, Canada. HFA Hydrofluoroalkane; μg micrograms; MDI Metered-dose inhaler. ICS are currently approved for the following ages: Flovent 12 months and over, QVAR 5 years and over, Alvesco 6 years and over, Pulmicort (nebules) 3 months and over (products insert). This information was originally published in Can Respir J 2010 17(1): 15–24
TABLE 4.
Medication and inhaler device | Minimum age licensed for use in Canada | Low to moderate dose | High dose† |
---|---|---|---|
Beclomethasone–hydrofluoroalkane by metered-dose inhaler and spacer | 5 years | 100–150 μg twice daily | 200 μg twice daily |
Budesonide by dry powder inhaler | 6 years‡ | 200 μg twice daily | 400 μg twice daily |
Budesonide by wet nebulizer† | 3 months | 250–500 μg twice daily | 1000 μg twice daily |
Fluticasone by metered-dose inhaler and spacer or dry powder inhaler | 12 months‡ | 100–125 μg twice daily | 250 μg twice daily |
Ciclesonide by metered-dose inhaler and spacer | 6 years | 100–200 μg once daily | 400 μg once or twice daily§ |
Adapted from the Canadian asthma consensus report (1999);
It is preferable to administer high-dose inhaled corticosteroids (or budesonide by nebulizer) in consultation with an asthma expert;
The youngest children able to use a dry powder inhaler are generally 4 to 5 years of age (11);
Ciclesonide is usually used once daily except in cases of more severe disease. Reference 11 was used as a source, with permission, for this table
Complete a 3- to 5-day course of oral steroids, depending on the severity of the illness at presentation.
Continue to use a short-acting ß2-agonist such as salbutamol (200 μg [0.3 puffs/kg to a maximum of 10 puffs] every 4 h) until exacerbations resolve and then as needed, with directions to see a health care professional if therapy is needed more often than every 4 h.
Prepare a written asthma action plan.
Review techniques for using inhaled asthma medications as well as for cleaning/maintaining the inhaler device.
Encourage follow-up with the patient’s primary care physician or a local asthma clinic to review asthma control, environmental history and symptom recognition. Every effort should be made to ensure proper follow-up and to implement a long-term plan with the patient’s primary care physician within two to four weeks of discharge from the ED. If severe or frequent exacerbations lead to further treatment in the ICU, referral to an asthma specialist, such as a paediatric allergist or respirologist, is strongly recommended.
Acknowledgments
The principal authors wish to thank Drs Denis Bérubé, Patrick Daigneault, Tom Kovesi, Janet Roberts, Sheldon Spier, David Wensley, Manisha Witmans and Hirotaka Yamashiro, for their expert review and comments during manuscript development. This position statement has been reviewed by the Allergy and Respiratory Health Sections, as well as by the Community Paediatrics and Adolescent Health Committees of the Canadian Paediatric Society.
Footnotes
ACUTE CARE COMMITTEE
Members: Adam Cheng MD; Isabelle M Chevalier MD (Board Representative); Catherine A Farrell MD; Jeremy N Friedman MD; Marie Gauthier MD (Board Representative, 2008–2011); Angelo Mikrogianakis MD (Chair); Oliva Ortiz-Alvarez MD
Liaisons: Laurel Chauvin-Kimoff MD, CPS Paediatric Emergency Medicine Section; Marilyn Monk, The Hospital for Sick Children; Jennifer Walton MD, CPS Hospital Paediatrics Section
Principal authors: Oliva Ortiz-Alvarez MD; Angelo Mikrogianakis MD
The recommendations in this statement do not indicate an exclusive course of treatment or procedure to be followed. Variations, taking into account individual circumstances, may be appropriate. All Canadian Paediatric Society position statements and practice points are reviewed on a regular basis. Please consult the Position Statements section of the CPS website (www.cps.ca) for the full-text, current version.
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