Abstract
Asthma continues to be recognized as a well-known respiratory disease requiring complex management. Asthma is assessed and treated by clinicians across the continuum. The interest in evidence-based recommendations for diagnosis, treatment, and long-term management is ongoing and essential for aligning clinical practice with its changes. The purpose of this review is to provide updates from recent literature on asthma for clinicians.
- asthma self-management
- asthma phenotypes
- bronchial thermoplasty
- exhaled nitric oxide
- medication delivery devices
- disease management
- environmental remediation
Introduction
Asthma is one of the most prevalent chronic respiratory diseases recognized in the United States, affecting > 25 million people, including > 7 million children.1 Common symptoms, including shortness of breath, wheezing, coughing, and chest tightness, are caused by inflammation, hyper-reactive airways, and bronchoconstriction and continue to impact the lives of many. Asthma is a multifaceted disease with a need for growing evidence supporting key combinations of medications, techniques, and therapies to promote better health for all populations of patients.
In 2014, a PubMed search to identify updates on asthma yielded several hundred publications, which signifies a renewed focus on a need for better control and an ongoing pursuit for optimal treatment. This review on asthma was part of a series presented at the American Association for Respiratory Care Congress 2014, held in Las Vegas, Nevada, to address one of the topics of interest to the respiratory care community. In this paper, topics relevant to asthma are divided into 3 components: programs and guidelines, diagnosis and treatment, and management.
Programs and Guidelines
In 2014, the National Heart, Lung, and Blood Institute recommended that the current guidelines established in 2012 become a living document with bi-annual updates instead of every 5–7 y.2 The National Heart, Lung, and Blood Advisory Council (a 37-member expert panel) met and reviewed the document “Expert panel report-3: guidelines for the diagnosis and management of asthma.” Five priority topics were identified for literature review, and potential guideline updates were discussed. The role of medication dosing in wheezing and asthma, use of long-acting antimuscarinic agents in asthma with inhaled corticosteroids, use of bronchial thermoplasty in adult severe exacerbations, role of the fraction of exhaled nitric oxide (FENO) in diagnosis, medication selection and monitoring treatment response for asthma, and need for remediation of indoor allergens in asthma management were among the elements of proposed review and change.
The Global Initiative for Asthma updated its overall strategy of asthma management and prevention by redefining asthma to include variable limited expiratory flow as a finding, in addition to the already established classical symptoms of wheezing, coughing, and shortness of breath.2 In reference to diagnosis and management, approaches used to assess symptom control, identify risk factors, and proposed management strategies were reviewed. Asthma control was clearly defined by measuring the degree of limited activity, symptoms during sleep, daytime symptoms, need for rescue medication, lung function, and exacerbations. For patients using combination treatments such as inhaled corticosteroids and controller medications, regular follow-up was recommended at least every 6 months. To round out all aspects of care, recommendations involved reviewing asthma self-management practices, including asthma education, providing patient feedback on home treatment and monitoring, and arranging follow-ups.2
Other changes included altering the program related to management of pediatric patients below 5 y of age.2 Relevant pediatric patient-specific information and recommendations were separated into their own distinct chapter. Patients with asthma and COPD (currently known as asthma-COPD overlap syndrome) were formally recognized to identify components of specific management related to this subset of asthma patients. The peer-reviewed documents with recommendations have become a resource for caregivers at every level.
Research programs typically provide important information on risk factors, management, and treatment of different populations of asthma patients. A well-known research program encompassing clinical studies involving both adult and pediatric asthma patients was merged into a single network. The National Heart, Lung and Blood Institute Asthma Network (AsthmaNet) devised a strategy to identify similarities and differences across age groups; to verify important interventions, data exchanges, and clinical outcomes; and to overcome operational challenges between populations of patients.3 Topics reviewed in the merged network include subject recruitment and specific consent challenges, demographics and populations, pediatric and adult asthma phenotypes, interventions related to control and outcomes, and growth and development. This combined network generated an enhanced repository of evidence-based information to be shared with clinicians participating at every level of care.
Diagnosis and Treatment
Diagnosis
Evidence supporting the relationship of risk factors and the incidence of asthma continues to unfold. Pediatric patients present unique challenges for diagnosis and management of asthma. Obesity has been linked to an increased incidence of asthma in children for a number of years.4 Unlike efforts to show further correlation between obesity and incidence of asthma using body mass index alone, Chen et al4 demonstrated a relationship between poor fitness level and an increase in sedentary time, in addition to the obesity factor, and a greater incidence of asthma in children. Based on 3 y of these reproducible measurements, the findings showed that FEV1 values were decreased during pulmonary function tests in these pediatric subjects. Additional information about risk factors can be applied to individual patients for promoting early prevention and treatment interventions.
Classification by Phenotype.
Phenotypes are used to identify factors that relate to asthma diagnosis. The identification of phenotypes in children has been a focus for asthma researchers. In 2014, Depner et al5 reviewed epidemiological factors of clinical phenotypes in children using a latent class analysis classification system. Clinical phenotypes used in these studies included subject history, components of a complete diagnostic evaluation, and treatment response. Subjects under 6 y of age with wheezing were monitored using: lung function, atopy, exhaled nitric oxide, and medications. The smallest subjects used the greatest number of resources to control wheezing. Children ≤ 5 y are difficult to diagnose and treat, as there is little evidence that identifies consistency in successful control of this population.6 Attempts to identify phenotypes for preschool-age subjects have not been successfully validated; therefore, establishing treatment standards for this population has been a challenge.6
Ducharme et al6 acknowledged that additional risk factors such as environmental exposure, genetic susceptibility, and prenatal history predispose these patients to wheezing at a young age. Preschoolers presenting with wheezing and impaired lung function before starting first grade are likely to continue to have recurrent wheezing episodes throughout childhood and as young adults.
FENO.
FENO measurements are considered to be an index of airway inflammation measured as part of a diagnostic evaluation for asthma. The role FENO plays in the diagnosis of asthma continues to evolve. In adults, FENO typically decreases by ∼20% in response to bronchodilator administration.7 In 2014, further investigation into FENO responses in pediatric patients was pursued. In a study conducted by Grzelewski et al,7 bronchodilator response at certain FENO levels showed larger variances in pediatric subjects. Attempts to demonstrate alignment of FENO with other asthma diagnostic indicators are forthcoming. Grzelewski et al7 evaluated the relationship between FEV1 and FENO in pediatric asthma subjects. Although these relationships need further validation, the correlation between FEV1 and FENO demonstrated that as FENO increases, FEV1 decreases (up to FENO of 35.4 ppb). The authors showed when FENO was > 35.4 ppb, the pre-bronchodilator FEV1 increased. In subjects with moderate asthma, FEV1 and FENO became more linear. To obtain diagnostically relevant information, measuring FENO before and after a pre-bronchodilator and post-bronchodilator evaluation via spirometry in children was recommended. Using FENO values as diagnostic parameters in pediatric patients is feasible through careful attention to physiologic differences and responses to medications in both adult and pediatric patient populations.
Treatment
Early detection and management of asthma symptoms are imperative to achieve successful treatment and control. In adults, corticosteroids and leukotriene receptor antagonists in combination with short- and long-acting β2 agonists are the fundamentals of treatment. Inhaled corticosteroids are administered for the inflammatory component of asthma. Long-acting β2 agonists and leukotriene antagonists are frequently part of the asthma symptom control regime for bronchial hyper-responsiveness. For patients who present with symptoms of wheezing while being treated with corticosteroids, a long-acting β2 agonist is recommended. When added to an adult patient's treatment plan, long-acting β2 agonists resulted in a reduction of exacerbations, improved FEV1, reduced symptoms, and improved quality of life.8 However, an increase in severe exacerbations was noted; therefore, a combination of long-acting β2 agonists and inhaled corticosteroids in a single inhaler was recommended.
In pediatric patients, medications used to treat wheezing differ slightly. Bronchoconstriction in children with viral illness is often unaffected by administration of β2 agonists.6 Intermittent corticosteroid therapy is recommended in situations in which moderate wheezing is caused by viral illness.6
Medication Delivery Devices.
Aerosol delivery devices are evaluated and selected based on ease of use, treatment duration, medication delivery, and cost. Is a metered-dose inhaler used with a holding chamber equivalent to a nebulizer in terms of drug delivery, duration of time to complete technique, and stay in an acute care setting? In a Cochrane Review of 39 trials with 1,897 children and 797 adults, metered-dose inhalers with spacers were introduced in an emergency room setting to evaluate if they were as effective as nebulizer therapy.9 Pediatric subjects showed a significant reduction in adverse effects such as tachycardia, tremor, and emergency department stay, whereas adult subjects did not show a significant decrease in emergency department stay. Delivery of medications via nebulizer devices is not superior to metered-dose inhalers with spacers, and both methods are feasible.
Aerosol devices and patient technique impact medication delivery for asthma patients. Because many adult patient technique errors occur during inspiration (10–18%), it is imperative that education and follow-up on basic concepts occur regularly.9,10 Fixed-dose medication combinations appear to promote a lower incidence of technique errors with inhalers.9 Better adherence was demonstrated when technique was reviewed, repeated, and followed up with training.10
Mechanical Ventilation and Asthma.
For adults over 18 y of age, asthma exacerbations account for > 2.4 million hospital admissions in the United States.11 The number of patients admitted for asthma exacerbations is on the rise and accounts for a disturbing 60% of all admissions of patients > 50 y of age.11 About 10% of these admissions require ICU care, with an average of 3% requiring mechanical ventilator support.11 In 2014, the Healthcare Cost and Utilization Project (National Inpatient Sample) evaluated subjects who were admitted with asthma exacerbations requiring invasive mechanical ventilation and noninvasive ventilation (NIV). Invasive mechanical ventilation and NIV rates combined increased by 45% over the 8-y evaluation period (2000–2008).11 The number of subjects requiring invasive mechanical ventilation decreased by 50%, whereas those requiring NIV rose by 400% during the same time period.11 Mortality and hospital stay were unchanged despite the type of ventilation used. Although use of NIV during asthma exacerbations has increased significantly, the outcomes related to NIV practices need further investigation. The most critical asthma patients are at the highest risk, and data to support clinical practice associated with improved outcomes are forthcoming.
Novel Therapies
Bronchial Thermoplasty.
Bronchial thermoplasty, a nonpharmacologic therapy that applies radiofrequency energy in the form of heat to bronchial smooth muscle for ablation, is intended to reduce bronchospasm in cases of refractory (severe) asthma.12 Four y following its FDA clearance, bronchial thermoplasty has not been adopted as a standard, but is instead considered to be a novel therapy. Its clearance as a treatment for asthma was centered on prior studies, including the Asthma Intervention Research 2 trial, which compared bronchial thermoplasty-directed therapy with sham therapy and its effects on the Asthma Quality of Life Questionnaire.12 Although not part of the primary objective, secondary outcomes showed peak-flow changes, less need for rescue medications, and reductions in lost work days and severe asthma exacerbations. The outcomes for the sham and bronchial thermoplasty groups were not statistically different. It remains unclear whether one therapy is superior to the other. Although the criteria for bronchial thermoplasty remain stringent, including corticosteroid dependence, evidence of frequent exacerbations, in-patient admissions, history of emergency room visits, significant decrease in FEV1, and inadequate quality of life, there is a question as to whether the therapy needs additional investigation before its use.12
In search of direct evidence supporting clinical improvement from bronchial thermoplasty, Kaukel et al13 noted that these secondary outcomes revealed no significant change in FEV1 or airway hyper-responsiveness. A reduction in the number of severe exacerbations, as well as reductions in the number of missed work days and emergency room visits, was also noted. Because this intervention is not suitable for all severely affected asthma patients, identifying a phenotype that demonstrates response to bronchial thermoplasty is imperative.
Management
Disease Management Programs
Disease management programs are implemented to control asthma symptoms, improve quality of care, generate positive outcomes, and reduce cost.14 Through evidence-based guidelines, asthma education has been shown to promote self-management, including an understanding of medications, a review of drug-delivery techniques, and an organized plan that addresses different degrees of acute and chronic care and that empowers patients to control their disease.
Disease management programs have exhibited optimistic outcomes in decreasing hospitalizations, improving the number of patients who self-manage their disease, and helping patients set goals for improvement. A longitudinal population-based study carried out in Germany over a 4-y period demonstrated a 5-fold increase in participants and an increase in physician alignment with the program.14 Table 2 of this study displays the changes in the trends in prescribing medication over the 4-y period. Oral corticosteroid prescriptions decreased; inhaled corticosteroid use was not significantly changed; and long-acting β2 agonist use and monotherapy increased. The most striking changes were a 50% increase in implementation of asthma home treatment plans and a 5-fold increase in self-management education. Collectively, these components of the program had a direct effect on reducing hospitalizations by 75%. The use of disease management programs is gaining popularity. Systematic quality improvement displayed in the progress and outcomes of these programs has been demonstrated in nearly every aspect of each program. Sustainability in disease management may improve the future of asthma management.
Environmental Remediation in Asthma Management
The prevalence of an allergy-related environmental trigger component of asthma is on the rise.15 Environmental exposure to indoor allergens is believed to be a primary contributor to exacerbation, especially in children. A recent trend shows that the amount of time patients spend indoors contributes to increased exposure to household dust mites.15 Dust mites and mold are believed to be fostered in an environment of high humidity and temperature. Exposure to domestic pets, rodents, cockroaches, tobacco smoke, and air pollution may create allergy-related triggers that produce symptoms. The latest updates on environmental remediation collected from a number of studies were presented in 2014.15
The goal of sensitizing patients to allergens using a single intervention has not been shown to be successful in reducing reactions to allergens such as dust mites.15 Fifty-four studies conducted to assess dust mite interventions revealed that compared with control groups, there was no significant change in asthma symptoms despite interventions.15 Small changes in 1-y corticosteroid use in a single study could not be reproduced in similar evaluations. Documented interventions used to reduce dust mite exposure include routine cleaning; washing bedding weekly; and eliminating carpets, stuffed animals, and some furniture. A multifaceted approach to remediation is recommended.
Pet-related exposures causing asthma-related symptoms are most easily remediated by removal of a pet from the home. Corticosteroid use was not necessary when the pet was removed, but was high when the pet remained in the house.15 When pets were allowed to remain in the home, the use of high-efficiency particulate filters was not shown to be a sustained remediation measure.
Cockroach and rodent exposure in densely populated areas was found in as many as half of all homes studies.15 The National Cooperative Inner-City Asthma Study showed that allergen exposure could be reduced through a combination of pest control initiatives and patient education.15 Remediation of infestation is challenging and requires a combination of methods to be successful.
Mold and endotoxin exposure is prevalent in inner city areas, where a damp environment, inadequate ventilation, and poor air quality exist. Awareness of endotoxin exposure has become more widespread following Hurricane Katrina.15 Cleaning and, in some cases, disposal of damaged house furnishings were required to reduce symptoms. Allergens from mold exposure have been associated with an increased number of asthma-related symptoms. Aggressive interventions for mold eradication resulted in reduced emergency room visits and hospitalizations for 62 asthma subjects compared with a control group.15
Anecdotally, going back to school is believed to result in an increased incidence of asthma exacerbations. Endotoxin levels in dust in schools were higher than those at home, indicating that this viewpoint may indeed be true, at least in inner city schools.15
Other endotoxins such as nicotine and nitrogen dioxide found in air pollution have adverse effects on patients with asthma and can produce troublesome symptoms.15 Nitrogen dioxide exposure in young children has been associated with coughing and wheezing in the first few years of life.
Environmental smoke exposure is a known irritant and cause of asthma-related symptoms. However, despite interventions to reduce exposure, there is no proven effective method to eliminate its side effects.15 Although avoidance has been shown to be the most effective measure, high-efficiency particulate air filter use may provide some benefit in reducing acute symptoms from smoke exposure of any kind. Environmental exposure continues to play an important role in triggering asthma symptoms. Continued emphasis on preventing exposure and remediation strategies are integral to maintaining asthma control.
Summary
In this review, important recent literature on key topics related to asthma were presented. Diagnosis, treatment, and management were reviewed. Key concepts from updates available in 2014 were presented.
Footnotes
- Correspondence: Kathleen M Deakins MHA RRT-NPS FAARC, Women's and Children's Respiratory Care and Respiratory Diagnostic Services, University Hospitals Rainbow Babies and Children's Hospital, 11100 Euclid Avenue, Cleveland, OH 44106. E-mail: kathleen.deakins{at}uhhospitals.org.
Ms Deakins presented a version of this paper at the Year in Review 2014 of AARC Congress 2014, held December 9–12, 2014, in Las Vegas, Nevada.
Ms Deakins discloses relationships with Masimo and Hill-Rom.
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