Measuring the corticosteroid responsiveness endophenotype in asthmatic patients

Inhaled corticosteroids (ICSs) constitute the most commonly prescribed therapies for asthma. They are effective, but there are up to 24% of asthma patients who do not achieve significant improvement with them. ICSs produce treatment responses in six clinical phenotypes: lung function, bronchodilator response, airway responsiveness, symptoms, need for oral steroids, and frequency of emergency department visits or need for hospitalization. For the past 15 years and in an escalating prevalence of asthma, researchers have considered these phenotypes to be guided by separate mechanisms.

Clemmer et alpropose a move away from the focus on single phenotypes to a more holistic approach. They suggest that there is a corticosteroid responsiveness endophenotype that modulates the asthma disease process, is latent in ICS-untreated patients, and is active in ICS-treated patients. Under this hypothesis, the corticosteroid responsiveness endophenotype influences the asthma disease process to produce the treatment effect observed in all the clinical phenotypes (J Allergy Clin Immunol 2015; 136(2): 274-281).

As such, the authors present a composite phenotype responsiveness model that combines the six clinical phenotypes and measures the endophenotype. They used principal component analysis (PCA) to determine the model in a study population of both ICS-treated and non-ICS-treated patients with mild to moderately severe asthma. The model was then tested in four replication populations. Using treatment effect area under the receiver operating characteristic curve (AUC), they demonstrate that a composite phenotype measures corticosteroid responsiveness with greater accuracy and stability across populations than the individual clinical phenotypes do.


The potential applications of the composite phenotype are many. It should enable asthma pharmacogenetic studies with more power for a given sample size or that require a smaller sample to achieve a given power. Given that it collapses multiple longitudinal clinical observations into a corticosteroid response metric and that it is easily implemented in a single computer program, it could allow a clinical practitioner to more accurately estimate ICS response. Finally, the model could be used to characterize the many asthma patients who do not respond to ICS treatment with better accuracy.

Comments

Post a Comment

Popular posts from this blog

Features of the bronchial bacterial microbiome associated with atopy, asthma and responsiveness to inhaled corticosteroid treatment

It’s been known that asthmatic lungs are different from healthy lungs in many aspects, including housing different strains of bacteria.  So far, studies haven’t been able to tell whether these differences are due to asthma, associated allergies (atopy), or treatment with different drugs.  They also haven’t been able to determine how these differences affect the way asthma manifests itself and how asthma can be treated.  In this month’s issue of JACI, Durack and colleagues aim to answer these pressing questions ( J Allergy Clin Immunol 2017; 140(1): 63-75 ). Durack and other investigators looked at the bacterial communities in 84 individuals, split into three groups: (1) 42 atopic asthmatic subjects, (2) 21 atopic non-asthmatic subjects, and (3) 21 non-atopic non-asthmatic, otherwise healthy, subjects.  They also looked at inflammatory markers and changes in bronchial hyperresponsiveness after 6 weeks of treatment with fluticasone, an inhaled steroid commonly used for...
Read more

Introducing an environmental assessment and intervention program in inner-city schools

Few studies have comprehensively examined the role the school environment plays in asthma and how effectively changing the environment may reduce morbidity, when adjusting for exposures in the home. In their review, Huffaker and Phipatanakul summarize the importance and common challenges of school-based environmental assessment and intervention studies linked to health effects ( J Allergy Clin Immunol 2014; 134: 1232-1237 ). They discuss the challenges and potential benefits of comprehensive environmental assessment and health outcomes in inner-city schools. The school environment has been shown to be a significant reservoir for allergens and pollutants. Indoor allergens known to be important in urban home environments may also be important in schools, including cockroach, cat, dog, mouse, dust-mite, and molds. Studies have identified children with asthma in inner-cities have markedly higher levels of mouse allergen in their schools compared to levels in their individual bedrooms. Give...
Read more

Role of viral infections in the development and exacerbation of asthma in children

Wheezing is a common complaint among parents of infants.  About 1 in 5 children have acute wheezing illnesses in their first two years of life.  This is important because an overwhelming majority of these wheezing illnesses are related to viruses, and are linked to asthma development.  In this month’s issue of JACI, Jartti and Gern review the role of viral infections in the development of asthma in children ( J Allergy Clin Immunol 2017; 140(4): 895-906 ).  They survey the viruses -rhinoviruses, respiratory syncytial viruses, and others – and how they impact the developing set of lungs.  Genetic variation and low interferon responses are two factors that increase the risk of these types of infections.  In addition, increased eosinophil counts in blood and nasal mucus and atopic eczema all increase the risk of later asthma.  Additionally, viral infections can lead to exacerbations in children who already have asthma.  This may explain why the rates...
Read more