b t asthma case study

Case Study: Managing Severe Asthma in an Adult

—he follows his treatment plan, but this 40-year-old male athlete has asthma that is not well-controlled. what’s the next step.

By Kirstin Bass, MD, PhD Reviewed by Michael E. Wechsler, MD, MMSc

This case presents a patient with poorly controlled asthma that remains refractory to treatment despite use of standard-of-care therapeutic options. For patients such as this, one needs to embark on an extensive work-up to confirm the diagnosis, assess for comorbidities, and finally, to consider different therapeutic options.

Case presentation and patient history

Mr. T is a 40-year-old recreational athlete with a medical history significant for asthma, for which he has been using an albuterol rescue inhaler approximately 3 times per week for the past year. During this time, he has also been waking up with asthma symptoms approximately twice a month, and has had three unscheduled asthma visits for mild flares. Based on the National Asthma Education and Prevention Program guidelines , Mr. T has asthma that is not well controlled. 1

As a result of these symptoms, spirometry was performed revealing a forced expiratory volume in the first second (FEV1) of 78% predicted. Mr. T then was prescribed treatment with a low-dose corticosteroid, fluticasone 44 mcg at two puffs twice per day. However, he remained symptomatic and continued to use his rescue inhaler 3 times per week. Therefore, he was switched to a combination inhaled steroid and long-acting beta-agonist (LABA) (fluticasone propionate 250 mcg and salmeterol 50 mcg, one puff twice a day) by his primary care doctor.

Initial pulmonary assessment Even with this step up in his medication, Mr. T continued to be symptomatic and require rescue inhaler use. Therefore, he was referred to a pulmonologist, who performed the initial work-up shown here:

Spirometry, pre-albuterol: FEV1 79%, post-albuterol: 12% improvement
Methacholine challenge: PC 20 : 1.0 mg/mL
Chest X-ray: Within normal limits

Continued pulmonary assessment His dose of inhaled corticosteroid (ICS) and LABA was increased to fluticasone 500 mcg/salmeterol 50 mcg, one puff twice daily. However, he continued to have symptoms and returned to the pulmonologist for further work-up, shown here:

Chest computed tomography (CT): Normal lung parenchyma with no scarring or bronchiectasis
Sinus CT: Mild mucosal thickening
Complete blood count (CBC): Within normal limits, white blood cells (WBC) 10.0 K/mcL, 3% eosinophils
Immunoglobulin E (IgE): 25 IU/mL
Allergy-skin test: Positive for dust, trees
Exhaled NO: Fractional exhaled nitric oxide (FeNO) 53 parts per billion (pbb)

Assessment for comorbidities contributing to asthma symptoms After this work-up, tiotropium was added to his medication regimen. However, he remained symptomatic and had two more flares over the next 3 months. He was assessed for comorbid conditions that might be affecting his symptoms, and results showed:

Esophagram/barium swallow: Negative
Esophageal manometry: Negative
Esophageal impedance: Within normal limits
ECG: Within normal limits
Genetic testing: Negative for cystic fibrosis, alpha1 anti-trypsin deficiency

The ear, nose, and throat specialist to whom he was referred recommended only nasal inhaled steroids for his mild sinus disease and noted that he had a normal vocal cord evaluation.

Following this extensive work-up that transpired over the course of a year, Mr. T continued to have symptoms. He returned to the pulmonologist to discuss further treatment options for his refractory asthma.

Diagnosis Mr. T has refractory asthma. Work-up for this condition should include consideration of other causes for the symptoms, including allergies, gastroesophageal reflux disease, cardiac disease, sinus disease, vocal cord dysfunction, or genetic diseases, such as cystic fibrosis or alpha1 antitrypsin deficiency, as was performed for Mr. T by his pulmonary team.

Treatment options When a patient has refractory asthma, treatment options to consider include anticholinergics (tiotropium, aclidinium), leukotriene modifiers (montelukast, zafirlukast), theophylline, anti-immunoglobulin E (IgE) antibody therapy with omalizumab, antibiotics, bronchial thermoplasty, or enrollment in a clinical trial evaluating the use of agents that modulate the cell signaling and immunologic responses seen in asthma.

Treatment outcome Mr. T underwent bronchial thermoplasty for his asthma. One year after the procedure, he reports feeling great. He has not taken systemic steroids for the past year, and his asthma remains controlled on a moderate dose of ICS and a LABA. He has also been able to resume exercising on a regular basis.

Approximately 10% to 15% of asthma patients have severe asthma refractory to the commonly available medications. 2 One key aspect of care for this patient population is a careful workup to exclude other comorbidities that could be contributing to their symptoms. Following this, there are several treatment options to consider, as in recent years there have been several advances in the development of asthma therapeutics. 2

Treatment options for refractory asthma There are a number of currently approved therapies for severe, refractory asthma. In addition to therapy with ICS or combination therapies with ICS and LABAs, leukotriene antagonists have good efficacy in asthma, especially in patients with prominent allergic or exercise symptoms. 2 The anticholinergics, such as tiotropium, which was approved for asthma in 2015, enhance bronchodilation and are useful adjuncts to ICS. 3-5 Omalizumab is a monoclonal antibody against IgE recommended for use in severe treatment-refractory allergic asthma in patients with atopy. 2 A nonmedication therapeutic option to consider is bronchial thermoplasty, a bronchoscopic procedure that uses thermal energy to disrupt bronchial smooth muscle. 6,7

Personalizing treatment for each patient It is important to personalize treatment based on individual characteristics or phenotypes that predict the patient's likely response to treatment, as well as the patient's preferences and practical issues, such as adherence and cost. 8

In this case, tiotropium had already been added to Mr. T's medications and his symptoms continued. Although addition of a leukotriene modifier was an option for him, he did not wish to add another medication to his care regimen. Omalizumab was not added partly for this reason, and also because of his low IgE level. As his bronchoscopy was negative, it was determined that a course of antibiotics would not be an effective treatment option for this patient. While vitamin D insufficiency has been associated with adverse outcomes in asthma, T's vitamin D level was tested and found to be sufficient.

We discussed the possibility of Mr. T's enrollment in a clinical trial. However, because this did not guarantee placement within a treatment arm and thus there was the possibility of receiving placebo, he opted to undergo bronchial thermoplasty.

Bronchial thermoplasty Bronchial thermoplasty is effective for many patients with severe persistent asthma, such as Mr. T. This procedure may provide additional benefits to, but does not replace, standard asthma medications. During the procedure, thermal energy is delivered to the airways via a bronchoscope to reduce excess airway smooth muscle and limit its ability to constrict the airways. It is an outpatient procedure performed over three sessions by a trained physician. 9

The effects of bronchial thermoplasty have been studied in several trials. The first large-scale multicenter randomized controlled study was the Asthma Intervention Research (AIR) Trial , which enrolled patients with moderate to severe asthma. 10 In this trial, patients who underwent the procedure had a significant improvement in asthma symptoms as measured by symptom-free days and scores on asthma control and quality of life questionnaires, as well as reductions in mild exacerbations and increases in morning peak expiratory flow. 10 Shortly after the AIR trial, the Research in Severe Asthma (RISA) trial was conducted to evaluate bronchial thermoplasty in patients with more severe, symptomatic asthma. 11 In this population, bronchial thermoplasty resulted in a transient worsening of asthma symptoms, with a higher rate of hospitalizations during the treatment period. 11 Hospitalization rate equalized between the treatment and control groups in the posttreatment period, however, and the treatment group showed significant improvements in rescue medication use, prebronchodilator forced expiratory volume in the first second (FEV1) % predicted, and asthma control questionnaire scores. 11

The AIR-2 trial followed, which was a multicenter, randomized, double-blind, sham-controlled study of 288 patients with severe asthma. 6 Similar to the RISA trial, patients in the treatment arm of this trial experienced an increase in adverse respiratory effects during the treatment period, the most common being airway irritation (including wheezing, chest discomfort, cough, and chest pain) and upper respiratory tract infections. 6

The majority of adverse effects occurred within 1 day of the procedure and resolved within 7 days. 6 In this study, bronchial thermoplasty was found to significantly improve quality of life, as well as reduce the rate of severe exacerbations by 32%. 6 Patients who underwent the procedure also reported fewer adverse respiratory effects, fewer days lost from work, school, or other activities due to asthma, and an 84% risk reduction in emergency department visits. 6

Long-term (5-year) follow-up studies have been conducted for patients in both the AIR and the AIR-2 trials. In patients who underwent bronchial thermoplasty in either study, the rate of adverse respiratory effects remained stable in years 2 to 5 following the procedure, with no increase in hospitalizations or emergency department visits. 7,12 Additionally, FEV1 remained stable throughout the 5-year follow-up period. 7,12 This finding was maintained in patients enrolled in the AIR-2 trial despite decreased use of daily ICS. 7

Bronchial thermoplasty is an important addition to the asthma treatment armamentarium. 7 This treatment is currently approved for individuals with severe persistent asthma who remain uncontrolled despite the use of an ICS and LABA. Several clinical trials with long-term follow-up have now demonstrated its safety and ability to improve quality of life in patients with severe asthma, such as Mr. T.

Severe asthma can be a challenge to manage. Patients with this condition require an extensive workup, but there are several treatments currently available to help manage these patients, and new treatments are continuing to emerge. Managing severe asthma thus requires knowledge of the options available as well as consideration of a patient's personal situation-both in terms of disease phenotype and individual preference. In this case, the patient expressed a strong desire to not add any additional medications to his asthma regimen, which explained the rationale for choosing to treat with bronchial thermoplasty. Personalized treatment necessitates exploring which of the available or emerging options is best for each individual patient.

Published: April 16, 2018

1. National Asthma Education and Prevention Program: Asthma Care Quick Reference.
2. Olin JT, Wechsler ME. Asthma: pathogenesis and novel drugs for treatment. BMJ . 2014;349:g5517.
3. Boehringer Ingelheim. Asthma: U.S. FDA approves new indication for SPIRIVA Respimat [press release]. September 16, 2015.
4. Peters SP, Kunselman SJ, Icitovic N, et al. Tiotropium bromide step-up therapy for adults with uncontrolled asthma. N Engl J Med . 2010;363:1715-1726.
5. Kerstjens HA, Engel M, Dahl R. Tiotropium in asthma poorly controlled with standard combination therapy. N Engl J Med . 2012;367:1198-1207.
6. Castro M, Rubin AS, Laviolette M, et al. Effectiveness and safety of bronchial thermoplasty in the treatment of severe asthma: a multicenter, randomized, double-blind, sham-controlled clinical trial. Am J Respir Crit Care Med . 2010;181:116-124.
7. Wechsler ME, Laviolette M, Rubin AS, et al. Bronchial thermoplasty: long-term safety and effectiveness in patients with severe persistent asthma. J Allergy Clin Immunol . 2013;132:1295-1302.
8. Global Initiative for Asthma: Pocket Guide for Asthma Management and Prevention (for Adults and Children Older than 5 Years).
10. Cox G, Thomson NC, Rubin AS, et al. Asthma control during the year after bronchial thermoplasty. N Engl J Med . 2007;356:1327-1337.
11. Pavord ID, Cox G, Thomson NC, et al. Safety and efficacy of bronchial thermoplasty in symptomatic, severe asthma. Am J Respir Crit Care Med . 2007;176:1185-1191.
12. Thomson NC, Rubin AS, Niven RM, et al. Long-term (5 year) safety of bronchial thermoplasty: Asthma Intervention Research (AIR) trial. BMC Pulm Med . 2011;11:8.

Case of Acute Severe Asthma

Kane guthrie.

Dec 2, 2022

A 25-year-old lady Miss. Poor Compliance is rushed into your Emergency Department as a Priority 1. She is a brittle asthmatic and has been given 3x 5mg salbutamol nebs, and 0.5mg of adrenaline IM prehospital. On arrival Miss PC is sitting forward in the tripod position , using her accessory muscles to breath. She is tachypnoeic, agitated and unable to talk.

Vital signs: Pulse 143, BP 138/95, RR 42, Sp02 91% on neb, GCS 14/15.

Past Medical and Medication History

Smoker. Severe asthmatic. Intubated twice in past 2 years
Currently taking seritide 250/50mg, salbutamol MDI PRN and prednisolone 50mg PRN

Asthma Epidemiology

Over 2.2 million Australians have currently diagnosed asthma
406 deaths attributed to asthma in 2006
Highest risk of dying from asthma is in the elderly over 70
The emergency clinician’s goal in treating acute severe asthma is preventing intubation
Severe/Critical asthma is a life threatening condition

Asthma Pathophysiology

Asthma is a chronic inflammatory disorder of the airways in which many cells and cellular elements play a role, in particular, mast cells, eosinophils, T lymphocytes, macrophages, neutrophils, and epithelial cells.
Smooth muscle hypertrophy and hyperplasia
Inflammatory cell infiltration and oedema
Goblet cell and mucous gland hyperplasia with mucous hypersecretion
Protein deposition including collagen
Epithelial desquamation
Most common, responsible for 80-85% of all fatal events is characterised by eosinophilic inflammation associated with gradual deterioration over days-weeks occurring in patients with severe or poorly controlled asthma, and is slow to respond to therapy.
The second phenotype, with neutrophilic inflammation, has both rapid onset and response to therapy.

Markers of severe asthma:

Inability to speak in full sentences
Use of accessory muscles or tracheal tugging
Cyanosis and sweating
Pulsus paradoxus (>15mmHg decreased with inspiration). With severe muscle fatigue might be absent
Quiet chest on auscultation (The “Silent Chest”)
Confusion or decreased level of consciousness
Hypotension or bradycardia
FEV 1<40% predicted
PEF <40% of predicted or best (<25% in life threatening asthma)
Oxygen saturation <90-92%
PaO2 <60mmHg
PaCO2 >45mmHg

Complications of Asthma :

Pneumothorax, Pneumomediastinum, Pneumopericardium and Pneumoretroperitoneum
Cardiac Arrhythmias, Myocardial ischaemia or infarction
Electrolyte disturbances (hypokalaemia, hypomagnesaemia, hypophosphataemia)
Lactic Acidosis
Hyperglycaemia

Conditions that may mimic acute asthma:

Upper airway obstruction
Foreign-body aspiration
Vocal cord dysfunction syndrome
Pulmonary oedema
Acute exacerbations of COPD
Hysterical conversion reaction
Munchausen syndrome

Diagnostic Test:

Hyperinflation 5-10%
Infiltrate 5%
Pneumothorax <1%
Pneumomediastinum <1%
Respiratory alkalosis typical
Inaccurate predictor of outcome
Will seldom alter your treatment plan
An objective measure of lung function
Useful to assess response to treatment
Impossible to obtain in the dying patient
<25% Severe
25-50% Moderate
50-70% Mild
>70% Discharge Goal
Simple, and less painful than ABG
Provides continuous oxygenation measurements
Needs to placed on well-perfused site, difficult to obtain readings if global hypoperfusion or peripheral vasoconstriction present.
Aim to keep sp02 >92%

Management of Acute Severe Asthma

Hypoxia is the main cause of death in asthma
Oxygen should be given to keep Sp02 above 92%
A slight Pco2 rise may occur with oxygen therapy but this is of no clinical significance.

Beta-agonists:

Rapid acting inhaled beta-agonists (bronchodilators) are the first line therapy for acute asthma.
Nebulisers should generally be used in acute severe asthma, as provide easier delivery of medication to patient, multi dose inhalers have a role in mild to moderate asthma.
IV salbutamol gives you the advantage of hitting the beta 2 receptors from the back door, while continuing nebulizer treatment, and should be trialed in patients not responding to nebulisers.
Continuous nebuliser therapy appears to be more effective than intermittent nebulisers for delivering beta-agonist drugs to relieve airway spasm in acute severe asthma. (Cochrane Review, 2009)
Salbutamol toxicity can caused a lactic acidosis which is often unrecognized in asthma patients, the lactic acidosis has been hypothesized to adversely affect ventilation by increasing ventilatory demand, increasing dead space ventilation, worsening dynamic hyperinflation and intrinsic PEEP. Management is to discontinue salbutamol at the earliest opportunity.
Dose: Salbutamol Nebuliser Ampoule 5mg
Dose: Salbutamol IV 5mg in 500mL of 0.9% sodium chloride or 5% dextrose start at 30mL/hr titrating up to 120mL/hr

Anticholinergics:

Anticholinergics agents block muscarinic receptors in airway smooth muscles, inhibit vagal cholinergic tone and result in bronchodilation.
Dose: Ipratropium bromide (Atrovent) 500ug to second dose of salbutamol via neb, can be repeated every 4hours
Use of corticosteroids within 1 hour of presentation to an ED significantly reduces the need for hospital admission in patients with acute asthma. Benefits appear greatest in patients with more severe asthma, and those not currently receiving steroids
Dose: Prednisolone 50mg PO
Dose: IV Hydrocortisone 100-200mg
Note: Parenteral route is indicated in ventilated patient or patient unable to swallow, eg. Vomiting

Adrenaline:

Can be give either intravenously or via nebulizer
Bronchoconstriction is the major pathology in asthma; airway oedema might also make a significant contribution. Both the a-agonist and B-agonist effects of adrenaline might be beneficial, with the alpha effect decreasing oedema and the beta effect responsible for bronchodilation.
Dose: IV 6mg in 100mls 5% dextrose start at 1-15mLs/hour
Dose: Nebulizer 1mg in 3ml normal saline

Aminophylline:

The popularity of aminophylline in asthma exacerbations has diminished in recent years.
Systematic reviews have shown that IV aminophylline in severe acute asthma does not produce additional bronchodilation above that achieved with beta-agonist and corticosteroids.
Side effects; cardiac arrhythmia’s, vomiting, toxicity.
Dose : 5mg/kg over 20min followed by infusion of 500mg aminophyline n 500mL of 5% dextrose at 0.5mg/kg per hour

Magnesium Sulphate:

Magnesium potential role is asthma may involve a combination of smooth muscle relaxation, inhibition of histamine release and acetylcholine release from nerve endings.
Most evidence to support the use of magnesium in asthma is in the acute severe asthmatic were it has been shown to be safe and beneficial.
Dose : IV 2-4g over 30-60mins
Heliox Mixture 80% helium/20% oxygen
There is evidence that helium and oxygen mixtures (heliox) may provide additional benefits to patients with acute asthma.
Heliox mixtures have the potential to decrease airway resistance, and therefore decrease the work of breathing for the severe acute asthma patient.

Antibiotics:

Antibiotics are not indicated in the management of severe acute asthma.
Antibiotics should only be used in the setting of an underlying pneumonia, respiratory tract infection or to aid in the prevention of ventilator-associated pneumonia in ICU.

Airway Management

Non-Invasive Positive Pressure Ventilation:

Good quality evidence and trails to support the use of NPPV in asthma are lacking, however it is worth trying when intubation is not immediately indicated. Remember the goal of the emergency clinician’s in treating asthma is to prevent intubation.

Positive pressure is generally less than 15cmH2O
Benefit between CPAP vs BiPAP is unknown
Tachypnea caused by severe asthma can make it difficult for the patient to coordinate they’re breathing with machine making BiPAP uncomfortable
Need a large randomised control trial to determine the effectives properly of NIV, in acute severe asthma.

“Asthmatic on BiPAP before being Intubated”

Mechanical Ventilation:

1-3% of acute severe asthma requires intubation. Prevention of intubation and mechanical ventilation are the goals of managing acute severe asthma, this can be achieved by maximising pre-intubation therapy, however you don’t want to wait too long or let the severe asthmatic tire before trying to intubate them. Once an asthmatic is intubated and ventilated their morbidity and mortality increasing dramatically, and it can be difficult to wean from the ventilator.

Criteria for Intubation:

Cardiac or Respiratory arrest
Altered mental status
Progressive exhaustion
Severe hypoxia despite maximal oxygen delivery
Failure to reverse severe respiratory acidosis despite intensive therapy
pH <7.2, carbon dioxide pressure increasing by more than 5mmHg/hr or greater than 55 to 70mm/Hg, or oxygen pressure of less than 60mm/Hg.

Challenges:

Effective pre-oxygenation impossible
No margin for error or delay
Need to be intubated by most experienced person available
High intrathoracic pressure after RSI

Recommendations:

Fluid bolus before intubation if possible
RSI preferred
Ketamine for bronchodilator effects
Permissive hypercapnea essential

Initial Ventilator settings in paralysed patients:

FiO2 1.0, then titrate to keep SpO2 >94%
Tidal Volume 5-6ml/kg
Ventilator rate 6-8 breaths/min
Long expiratory time (I:E ratio >1:2)
Minimal PEEP < 5cmH2O
Limit peak inspiratory pressure to <40cmH2O
Target plateau pressure <20cmH2O
Ensure effective humidification
Brenner, B. Corbridge, T. & Kazzi, A. (2009). Intubation and mechanical ventilation of the asthmatic patient in respiratory failure. The Journal of Emergency Medicine. 37(2s), s23-s34.
Camargo, C. Rachelefsky, G. & Schatz, M. (2009). Managing Asthma Exacerbation in the Emergency Department: Summary of the National Asthma Education and Prevention Program Expert Panel Report 3 Guidelines for the Management of Asthma Exacerbation.The Journal of Emergency Medicine. 37 (2S), S6-S17.
Camargo, C. Spooner, C. & Rowe, B. (2009). Continuous versus intermittent beta-agonist for acute asthma (Review). http://www.thecochranelibrary.com.
Chua, F. & Lai, D. (2007). Acute severe asthma: Triage, treatment and thereafter. Current Anaesthesia & Critical Care. 18, 61-68.
Creagh-Brown, B. & Ball, J. (2007). An under-recognized complication of treatment of acute severe asthma. American Journal of Emergency Medicine. 26, 513-515.
Hodder, R. et al. (2009). Management of acute asthma in adults in the emergency department: nonventilatory management. CMAJ. 182(2), E55-E67.
Holley, A. & Boots, R.(2009). Review article: Management of acute severe and near-fatal asthma. Emergency Medicine Australasia, (21) 259-268.
Jones, L. & Goodacre, S. (2009). Magnesium sulphate in the treatment of acute asthma: evaluation of current practice in adult emergency departments. Emergency Medicine Journal. 26, 783-785.
Melnick, E. & Cottral, J. (2010). Current Guidelines for Management of Asthma in the Emergency Department. http://www.ebmedicine.net. 2(2). 1-13.
Morris, F. & Fletcher, A. (Ed). (2009). ABC of Emergency Differential Diagnosis. Oxford: Blackwell Publishing
National Asthma Council of Australia. Asthma management handbook: 2006. Accessed http://www.nationalasthma.org.au/cms/images/stories/amh2006_web_5.pdf, 12/02/2010
Nowak, R. Corbridge, T. & Brenner, B. (2009). Noninvasive Ventilation. The Journal of Emergency Medicine. 37(2S), S18-S22.
Peters, S. (2007). Continuous Bronchodilator Therapy. Chest. 131(1),1-5.
Phipps, P. & Garrard, C. (2003). The pulmonary physician in critical care. 12: Acute severe asthma in the intensive care unit. Thorax. 58, 81-88.
Ram, F. Wellington, S. Rowe, B. & Wedzicha, J. (2009). Non-invasive positive pressure ventilation for treatment of respiratory failure due to severe acute exacerbations of asthma (Review)
Rodrigo, G. Pollack, C. Rodrigo, C. Rowe, B. (2010). Heliox for non-intubated acute asthma patents (Review).
Rowe, B. Spooner, C. Ducharme, F. Bretzlaff, J. Bota, G. (2008). Early emergency department treatment of acute asthma with systemic corticosteroids (Review). http://www.thecochranelibrary.com.
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Emergency nurse with ultra-keen interest in the realms of toxicology, sepsis, eLearning and the management of critical care in the Emergency Department | LinkedIn |

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Published: 16 October 2014

A woman with asthma: a whole systems approach to supporting self-management

Hilary Pinnock 1 ,
Elisabeth Ehrlich 1 ,
Gaylor Hoskins 2 &
Ron Tomlins 3

npj Primary Care Respiratory Medicine volume 24 , Article number: 14063 ( 2014 ) Cite this article

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Health care

A 35-year-old lady attends for review of her asthma following an acute exacerbation. There is an extensive evidence base for supported self-management for people living with asthma, and international and national guidelines emphasise the importance of providing a written asthma action plan. Effective implementation of this recommendation for the lady in this case study is considered from the perspective of a patient, healthcare professional, and the organisation. The patient emphasises the importance of developing a partnership based on honesty and trust, the need for adherence to monitoring and regular treatment, and involvement of family support. The professional considers the provision of asthma self-management in the context of a structured review, with a focus on a self-management discussion which elicits the patient’s goals and preferences. The organisation has a crucial role in promoting, enabling and providing resources to support professionals to provide self-management. The patient’s asthma control was assessed and management optimised in two structured reviews. Her goal was to avoid disruption to her work and her personalised action plan focused on achieving that goal.

Barriers to implementing asthma self-management in Malaysian primary care: qualitative study exploring the perspectives of healthcare professionals

Ping Yein Lee, Ai Theng Cheong, … Ee Ming Khoo

The self-management abilities test (SMAT): a tool to identify the self-management abilities of adults with bronchiectasis

Katelyn R. Smalley, Lisa Aufegger, … Ara Darzi

Improving primary care management of asthma: do we know what really works?

Monica J. Fletcher, Ioanna Tsiligianni, … Thys van der Molen

A 35-year-old sales representative attends the practice for an asthma review. Her medical record notes that she has had asthma since childhood, and although for many months of the year her asthma is well controlled (when she often reduces or stops her inhaled steroids), she experiences one or two exacerbations a year requiring oral steroids. These are usually triggered by a viral upper respiratory infection, though last summer when the pollen count was particularly high she became tight chested and wheezy for a couple of weeks.

Her regular prescription is for fluticasone 100 mcg twice a day, and salbutamol as required. She has a young family and a busy lifestyle so does not often manage to find time to attend the asthma clinic. A few weeks previously, an asthma attack had interfered with some important work-related travel, and she has attended the clinic on this occasion to ask about how this can be managed better in the future. There is no record of her having been given an asthma action plan.

What do we know about asthma self-management? The academic perspective

Supported self-management reduces asthma morbidity.

The lady in this case study is struggling to maintain control of her asthma within the context of her busy professional and domestic life. The recent unfortunate experience which triggered this consultation offers a rare opportunity to engage with her and discuss how she can manage her asthma better. It behoves the clinician whom she is seeing (regardless of whether this is in a dedicated asthma clinic or an appointment in a routine general practice surgery) to grasp the opportunity and discuss self-management and provide her with a (written) personalised asthma action plan (PAAP).

The healthcare professional advising the lady is likely to be aware that international and national guidelines emphasise the importance of supporting self-management. 1 – 4 There is an extensive evidence base for asthma self-management: a recent synthesis identified 22 systematic reviews summarising data from 260 randomised controlled trials encompassing a broad range of demographic, clinical and healthcare contexts, which concluded that asthma self-management reduces emergency use of healthcare resources, including emergency department visits, hospital admissions and unscheduled consultations and improves markers of asthma control, including reduced symptoms and days off work, and improves quality of life. 1 , 2 , 5 – 12 Health economic analysis suggests that it is not only clinically effective, but also a cost-effective intervention. 13

Personalised asthma action plans

Key features of effective self-management approaches are:

Self-management education should be reinforced by provision of a (written) PAAP which reminds patients of their regular treatment, how to monitor and recognise that control is deteriorating and the action they should take. 14 – 16 As an adult, our patient can choose whether she wishes to monitor her control with symptoms or by recording peak flows (or a combination of both). 6 , 8 , 9 , 14 Symptom-based monitoring is generally better in children. 15 , 16

Plans should have between two and three action points including emergency doses of reliever medication; increasing low dose (or recommencing) inhaled steroids; or starting a course of oral steroids according to severity of the exacerbation. 14

Personalisation of the action plan is crucial. Focussing specifically on what actions she could take to prevent a repetition of the recent attack is likely to engage her interest. Not all patients will wish to start oral steroids without advice from a healthcare professional, though with her busy lifestyle and travel our patient is likely to be keen to have an emergency supply of prednisolone. Mobile technology has the potential to support self-management, 17 , 18 though a recent systematic review concluded that none of the currently available smart phone ‘apps’ were fit for purpose. 19

Identification and avoidance of her triggers is important. As pollen seems to be a trigger, management of allergic rhinitis needs to be discussed (and included in her action plan): she may benefit from regular use of a nasal steroid spray during the season. 20

Self-management as recommended by guidelines, 1 , 2 focuses narrowly on adherence to medication/monitoring and the early recognition/remediation of exacerbations, summarised in (written) PAAPs. Patients, however, may want to discuss how to reduce the impact of asthma on their life more generally, 21 including non-pharmacological approaches.

Supported self-management

The impact is greater if self-management education is delivered within a comprehensive programme of accessible, proactive asthma care, 22 and needs to be supported by ongoing regular review. 6 With her busy lifestyle, our patient may be reluctant to attend follow-up appointments, and once her asthma is controlled it may be possible to make convenient arrangements for professional review perhaps by telephone, 23 , 24 or e-mail. Flexible access to professional advice (e.g., utilising diverse modes of consultation) is an important component of supporting self-management. 25

The challenge of implementation

Implementation of self-management, however, remains poor in routine clinical practice. A recent Asthma UK web-survey estimated that only 24% of people with asthma in the UK currently have a PAAP, 26 with similar figures from Sweden 27 and Australia. 28 The general practitioner may feel that they do not have time to discuss self-management in a routine surgery appointment, or may not have a supply of paper-based PAAPs readily available. 29 However, as our patient rarely finds time to attend the practice, inviting her to make an appointment for a future clinic is likely to be unsuccessful and the opportunity to provide the help she needs will be missed.

The solution will need a whole systems approach

A systematic meta-review of implementing supported self-management in long-term conditions (including asthma) concluded that effective implementation was multifaceted and multidisciplinary; engaging patients, training and motivating professionals within the context of an organisation which actively supported self-management. 5 This whole systems approach considers that although patient education, professional training and organisational support are all essential components of successful support, they are rarely effective in isolation. 30 A systematic review of interventions that promote provision/use of PAAPs highlighted the importance of organisational systems (e.g., sending blank PAAPs with recall reminders). 31 A patient offers her perspective ( Box 1 ), a healthcare professional considers the clinical challenge, and the challenges are discussed from an organisational perspective.

Box 1: What self-management help should this lady expect from her general practitioner or asthma nurse? The patient’s perspective

The first priority is that the patient is reassured that her condition can be managed successfully both in the short and the long term. A good working relationship with the health professional is essential to achieve this outcome. Developing trust between patient and healthcare professional is more likely to lead to the patient following the PAAP on a long-term basis.

A review of all medication and possible alternative treatments should be discussed. The patient needs to understand why any changes are being made and when she can expect to see improvements in her condition. Be honest, as sometimes it will be necessary to adjust dosages before benefits are experienced. Be positive. ‘There are a number of things we can do to try to reduce the impact of asthma on your daily life’. ‘Preventer treatment can protect against the effect of pollen in the hay fever season’. If possible, the same healthcare professional should see the patient at all follow-up appointments as this builds trust and a feeling of working together to achieve the aim of better self-management.

Is the healthcare professional sure that the patient knows how to take her medication and that it is taken at the same time each day? The patient needs to understand the benefit of such a routine. Medication taken regularly at the same time each day is part of any self-management regime. If the patient is unused to taking medication at the same time each day then keeping a record on paper or with an electronic device could help. Possibly the patient could be encouraged to set up a system of reminders by text or smartphone.

Some people find having a peak flow meter useful. Knowing one's usual reading means that any fall can act as an early warning to put the PAAP into action. Patients need to be proactive here and take responsibility.

Ongoing support is essential for this patient to ensure that she takes her medication appropriately. Someone needs to be available to answer questions and provide encouragement. This could be a doctor or a nurse or a pharmacist. Again, this is an example of the partnership needed to achieve good asthma control.

It would also be useful at a future appointment to discuss the patient’s lifestyle and work with her to reduce her stress. Feeling better would allow her to take simple steps such as taking exercise. It would also be helpful if all members of her family understood how to help her. Even young children can do this.

From personal experience some people know how beneficial it is to feel they are in a partnership with their local practice and pharmacy. Being proactive produces dividends in asthma control.

What are the clinical challenges for the healthcare professional in providing self-management support?

Due to the variable nature of asthma, a long-standing history may mean that the frequency and severity of symptoms, as well as what triggers them, may have changed over time. 32 Exacerbations requiring oral steroids, interrupting periods of ‘stability’, indicate the need for re-assessment of the patient’s clinical as well as educational needs. The patient’s perception of stability may be at odds with the clinical definition 1 , 33 —a check on the number of short-acting bronchodilator inhalers the patient has used over a specific period of time is a good indication of control. 34 Assessment of asthma control should be carried out using objective tools such as the Asthma Control Test or the Royal College of Physicians three questions. 35 , 36 However, it is important to remember that these assessment tools are not an end in themselves but should be a springboard for further discussion on the nature and pattern of symptoms. Balancing work with family can often make it difficult to find the time to attend a review of asthma particularly when the patient feels well. The practice should consider utilising other means of communication to maintain contact with patients, encouraging them to come in when a problem is highlighted. 37 , 38 Asthma guidelines advocate a structured approach to ensure the patient is reviewed regularly and recommend a detailed assessment to enable development of an appropriate patient-centred (self)management strategy. 1 – 4

Although self-management plans have been shown to be successful for reducing the impact of asthma, 21 , 39 the complexity of managing such a fluctuating disease on a day-to-day basis is challenging. During an asthma review, there is an opportunity to work with the patient to try to identify what triggers their symptoms and any actions that may help improve or maintain control. 38 An integral part of personalised self-management education is the written PAAP, which gives the patient the knowledge to respond to the changes in symptoms and ensures they maintain control of their asthma within predetermined parameters. 9 , 40 The PAAP should include details on how to monitor asthma, recognise symptoms, how to alter medication and what to do if the symptoms do not improve. The plan should include details on the treatment to be taken when asthma is well controlled, and how to adjust it when the symptoms are mild, moderate or severe. These action plans need to be developed between the doctor, nurse or asthma educator and the patient during the review and should be frequently reviewed and updated in partnership (see Box 1). Patient preference as well as clinical features such as whether she under- or over-perceives her symptoms should be taken into account when deciding whether the action plan is peak flow or symptom-driven. Our patient has a lot to gain from having an action plan. She has poorly controlled asthma and her lifestyle means that she will probably see different doctors (depending who is available) when she needs help. Being empowered to self-manage could make a big difference to her asthma control and the impact it has on her life.

The practice should have protocols in place, underpinned by specific training to support asthma self-management. As well as ensuring that healthcare professionals have appropriate skills, this should include training for reception staff so that they know what action to take if a patient telephones to say they are having an asthma attack.

However, focusing solely on symptom management strategies (actions) to follow in the presence of deteriorating symptoms fails to incorporate the patients’ wider views of asthma, its management within the context of her/his life, and their personal asthma management strategies. 41 This may result in a failure to use plans to maximise their health potential. 21 , 42 A self-management strategy leading to improved outcomes requires a high level of patient self-efficacy, 43 a meaningful partnership between the patient and the supporting health professional, 42 , 44 and a focused self-management discussion. 14

Central to both the effectiveness and personalisation of action plans, 43 , 45 in particular the likelihood that the plan will lead to changes in patients’ day-to-day self-management behaviours, 45 is the identification of goals. Goals are more likely to be achieved when they are specific, important to patients, collaboratively set and there is a belief that these can be achieved. Success depends on motivation 44 , 46 to engage in a specific behaviour to achieve a valued outcome (goal) and the ability to translate the behavioural intention into action. 47 Action and coping planning increases the likelihood that patient behaviour will actually change. 44 , 46 , 47 Our patient has a goal: she wants to avoid having her work disrupted by her asthma. Her personalised action plan needs to explicitly focus on achieving that goal.

As providers of self-management support, health professionals must work with patients to identify goals (valued outcomes) that are important to patients, that may be achievable and with which they can engage. The identification of specific, personalised goals and associated feasible behaviours is a prerequisite for the creation of asthma self-management plans. Divergent perceptions of asthma and how to manage it, and a mismatch between what patients want/need from these plans and what is provided by professionals are barriers to success. 41 , 42

What are the challenges for the healthcare organisation in providing self-management support?

A number of studies have demonstrated the challenges for primary care physicians in providing ongoing support for people with asthma. 31 , 48 , 49 In some countries, nurses and other allied health professionals have been trained as asthma educators and monitor people with stable asthma. These resources are not always available. In addition, some primary care services are delivered in constrained systems where only a few minutes are available to the practitioner in a consultation, or where only a limited range of asthma medicines are available or affordable. 50

There is recognition that the delivery of quality care depends on the competence of the doctor (and supporting health professionals), the relationship between the care providers and care recipients, and the quality of the environment in which care is delivered. 51 This includes societal expectations, health literacy and financial drivers.

In 2001, the Australian Government adopted a programme developed by the General Practitioner Asthma Group of the National Asthma Council Australia that provided a structured approach to the implementation of asthma management guidelines in a primary care setting. 52 Patients with moderate-to-severe asthma were eligible to participate. The 3+ visit plan required confirmation of asthma diagnosis, spirometry if appropriate, assessment of trigger factors, consideration of medication and patient self-management education including provision of a written PAAP. These elements, including regular medical review, were delivered over three visits. Evaluation demonstrated that the programme was beneficial but that it was difficult to complete the third visit in the programme. 53 – 55 Accordingly, the programme, renamed the Asthma Cycle of Care, was modified to incorporate two visits. 56 Financial incentives are provided to practices for each patient who receives this service each year.

Concurrently, other programmes were implemented which support practice-based care. Since 2002, the National Asthma Council has provided best-practice asthma and respiratory management education to health professionals, 57 and this programme will be continuing to 2017. The general practitioner and allied health professional trainers travel the country to provide asthma and COPD updates to groups of doctors, nurses and community pharmacists. A number of online modules are also provided. The PACE (Physician Asthma Care Education) programme developed by Noreen Clark has also been adapted to the Australian healthcare system. 58 In addition, a pharmacy-based intervention has been trialled and implemented. 59

To support these programmes, the National Asthma Council ( www.nationalasthma.org.au ) has developed resources for use in practices. A strong emphasis has been on the availability of a range of PAAPs (including plans for using adjustable maintenance dosing with ICS/LABA combination inhalers), plans for indigenous Australians, paediatric plans and plans translated into nine languages. PAAPs embedded in practice computer systems are readily available in consultations, and there are easily accessible online paediatric PAAPs ( http://digitalmedia.sahealth.sa.gov.au/public/asthma/ ). A software package, developed in the UK, can be downloaded and used to generate a pictorial PAAP within the consultation. 60

One of the strongest drivers towards the provision of written asthma action plans in Australia has been the Asthma Friendly Schools programme. 61 , 62 Established with Australian Government funding and the co-operation of Education Departments of each state, the Asthma Friendly Schools programme engages schools to address and satisfy a set of criteria that establishes an asthma-friendly environment. As part of accreditation, the school requires that each child with asthma should have a written PAAP prepared by their doctor to assist (trained) staff in managing a child with asthma at school.

The case study continues...

The initial presentation some weeks ago was during an exacerbation of asthma, which may not be the best time to educate a patient. It is, however, a splendid time to build on their motivation to feel better. She agreed to return after her asthma had settled to look more closely at her asthma control, and an appointment was made for a routine review.

At this follow-up consultation, the patient’s diagnosis was reviewed and confirmed and her trigger factors discussed. For this lady, respiratory tract infections are the usual trigger but allergic factors during times of high pollen count may also be relevant. Assessment of her nasal airway suggested that she would benefit from better control of allergic rhinitis. Other factors were discussed, as many patients are unaware that changes in air temperature, exercise and pets can also trigger asthma exacerbations. In addition, use of the Asthma Control Test was useful as an objective assessment of control as well as helping her realise what her life could be like! Many people with long-term asthma live their life within the constraints of their illness, accepting that is all that they can do.

After assessing the level of asthma control, a discussion about management options—trigger avoidance, exercise and medicines—led to the development of a written PAAP. Asthma can affect the whole family, and ways were explored that could help her family understand why it is important that she finds time in the busy domestic schedules to take her regular medication. Family and friends can also help by understanding what triggers her asthma so that they can avoid exposing her to perfumes, pollens or pets that risk triggering her symptoms. Information from the national patient organisation was provided to reinforce the messages.

The patient agreed to return in a couple of weeks, and a recall reminder was set up. At the second consultation, the level of control since the last visit will be explored including repeat spirometry, if appropriate. Further education about the pathophysiology of asthma and how to recognise early warning signs of loss of control can be given. Device use will be reassessed and the PAAP reviewed. Our patient’s goal is to avoid disruption to her work and her PAAP will focus on achieving that goal. Finally, agreement will be reached with the patient about future routine reviews, which, now that she has a written PAAP, could be scheduled by telephone if all is well, or face-to-face if a change in her clinical condition necessitates a more comprehensive review.

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Pinnock, H., Ehrlich, E., Hoskins, G. et al. A woman with asthma: a whole systems approach to supporting self-management. npj Prim Care Resp Med 24 , 14063 (2014). https://doi.org/10.1038/npjpcrm.2014.63

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Published: 21 February 2018

Pediatric severe asthma: a case series report and perspectives on anti-IgE treatment

Virginia Mirra 1 ,
Silvia Montella 1 &
Francesca Santamaria 1

BMC Pediatrics volume 18 , Article number: 73 ( 2018 ) Cite this article

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The primary goal of asthma management is to achieve disease control for reducing the risk of future exacerbations and progressive loss of lung function. Asthma not responding to treatment may result in significant morbidity. In many children with uncontrolled symptoms, the diagnosis of asthma may be wrong or adherence to treatment may be poor. It is then crucial to distinguish these cases from the truly “severe therapy-resistant” asthmatics by a proper filtering process. Herein we report on four cases diagnosed as difficult asthma, detail the workup that resulted in the ultimate diagnosis, and provide the process that led to the prescription of omalizumab.

Case presentation

All children had been initially referred because of asthma not responding to long-term treatment with high-dose inhaled steroids, long-acting β 2 -agonists and leukotriene receptor antagonists. Definitive diagnosis was severe asthma. Three out four patients were treated with omalizumab, which improved asthma control and patients’ quality of life. We reviewed the current literature on the diagnostic approach to the disease and on the comorbidities associated with difficult asthma and presented the perspectives on omalizumab treatment in children and adolescents. Based on the evidence from the literature review, we also proposed an algorithm for the diagnosis of pediatric difficult-to-treat and severe asthma.

Conclusions

The management of asthma is becoming much more patient-specific, as more and more is learned about the biology behind the development and progression of asthma. The addition of omalizumab, the first targeted biological treatment approved for asthma, has led to renewed optimism in the management of children and adolescents with atopic severe asthma.

Peer Review reports

Children with poor asthma control have an increased risk of severe exacerbations and progressive loss of lung function, which results in the relevant use of health resources and impaired quality of life (QoL) [ 1 ]. Therefore, the primary goal of asthma management at all ages is to achieve disease control [ 2 , 3 , 4 ].

According to recent international guidelines, patients with uncontrolled asthma require a prolonged maintenance treatment with high-dose inhaled corticosteroids (ICS) in association with a long-acting β 2 -agonist (LABA) plus oral leukotriene receptor antagonist (LTRA) (Table 1 ) [ 5 ].

Nevertheless, in the presence of persistent lack of control, reversible factors such as adherence to treatment or inhalation technique should be first checked for, and diseases that can masquerade as asthma should be promptly excluded. Finally, additional strategies, in particular anti-immunoglobulin E (anti-IgE) treatment (omalizumab), are suggested for patients with moderate or severe allergic asthma that remains uncontrolled in Step 4 [ 5 ].

Herein, we reviewed the demographics, clinical presentation and treatment of four patients with uncontrolled severe asthma from our institution in order to explain why we decided to prescribe omalizumab. We also provided a review of the current literature that focuses on recent advances in the diagnosis of pediatric difficult asthma and the associated comorbidities, and summarizes the perspectives on anti-IgE treatment in children and adolescents.

Case presentations

Table 2 summarizes the clinical characteristics and the triggers/comorbidities of the cases at referral to our Institution. Unfortunately, data on psychological factors, sleep apnea, and hyperventilation syndrome were not available in any case. Clinical, lung function and airway inflammation findings at baseline and after 12 months of follow-up are reported in Table 3 . In the description of our cases, we used the terminology recommended by the ERS/ATS guidelines on severe asthma [ 6 ].

A full-term male had severe preschool wheezing and, since age 3, recurrent, severe asthma exacerbations with frequent hospital admissions. At age 11, severe asthma was diagnosed. Sensitization to multiple inhalant allergens (i.e., house dust mites, dog dander, Graminaceae pollen mix, and Parietaria judaica ) and high serum IgE levels (1548 KU/l) were found. Body mass index (BMI) was within normal range. Combined treatment with increasing doses of ICS (fluticasone, up to 1000 μg/day) in association with LABA (salmeterol, 100 μg/day) plus LTRA (montelukast, 5 mg/day) has been administered over 2 years. Nevertheless, persistent symptoms and monthly hospital admissions due to asthma exacerbations despite correct inhaler technique and good adherence were reported. Parents refused to perform any test to exclude gastroesophageal reflux (GER) as comorbidity [ 6 ]. However, an ex-juvantibus 2-month-course with omeprazole was added to asthma treatment [ 7 ], but poor control persisted. Anterior rhinoscopy revealed rhinosinusitis that was treated with nasal steroids for six months [ 8 ], but asthma symptoms were unmodified. Treatment with omalizumab was added at age 12. Reduced hospital admissions for asthma exacerbations, no further need for systemic steroids, and improved QoL score (from 2.0 up to 6.7 out of a maximum of 7 points) were documented over the following months. Unfortunately, after one year of treatment, adherence to omalizumab decreased because of family complaints, and eventually parents withdrew their informed consent and discontinued omalizumab. Currently, by age 17, treatment includes inhaled salmeterol/fluticasone (100 μg/500 μg∙day -1 , respectively) plus oral montelukast (10 mg/day). Satisfactory symptom control is reported, with no asthma exacerbations.

A full-term male, who had a recurrent severe preschool wheezing, at 6 years of age developed exercise-induced asthma. At age 10, severe asthma was diagnosed. High serum IgE levels (1300 KU/l) and skin prick tests positive to house dust mites were found. Despite a 3-year treatment with progressively increasing doses of inhaled fluticasone (up to 1000 μg/day) combined with salmeterol (100 μg/day) and oral montelukast (5 mg/day), monthly hospital admissions with systemic steroids use were reported. At age 13, a 24-h esophageal impedance/pH study demonstrated the presence of acid and non-acid GER [ 7 ]. Esomeprazole was added to asthma medications, but with an incomplete clinical benefit for respiratory symptoms. Esomeprazole was withdrawn after 3 months, and parents refused to re-test for GER. As respiratory symptoms persisted uncontrolled despite treatment, severe asthma was definitively diagnosed [ 6 ]. BMI was within the normal range and anterior rhinoscopy excluded rhinosinusitis. Inhaler technique and adherence were good; thus we considered the anti-IgE treatment option [ 9 ]. Subcutaneous omalizumab was started, with fast improvement of both symptoms and QoL score (from 3.9 up to 6.5). Seventeen months later, the dose of ICS had been gradually tapered and oral montelukast definitely discontinued. Currently, at age 14, treatment includes the combined administration of bimonthly subcutaneous omalizumab and of daily inhaled salmeterol/fluticasone (50 μg/100 μg∙day - 1 , respectively). Asthma control is satisfactory and no side effects are reported. Omalizumab has been continuously administered for 2.6 years and is still ongoing.

A full-term male had severe preschool wheezing and, since age 3, recurrent, severe asthma exacerbations with acute respiratory failure that frequently required intensive care unit (ICU) admission. At age 6, sensitization to multiple perennial inhalant (i.e., house dust mites, dog and cat danders, Alternaria alternata , Graminaceae pollen mix, Artemisia vulgaris , Parietaria judaica , and Olea europaea pollen) and food allergens (i.e., egg, milk, and peanut) was diagnosed. Serum IgE levels were 2219 KU/l. Weight and height were appropriate for age and sex. The patient has been treated over 3 years with a combined scheme of high-dose inhaled fluticasone (up to 1000 μg/day) plus salmeterol (100 μg/day) and oral montelukast (5 mg/day), with correct inhaler technique and good adherence. Despite this, monthly hospital admissions with systemic steroids use were recorded. Rhinosinusitis and GER were excluded on the basis of appropriate testing; thus treatment with omalizumab was started when the patient was 9 years old. At age 11, adherence to treatment is satisfactory, with no side effects. More importantly, reduced hospital admissions for asthma exacerbations, no further need for systemic steroids, and improved QoL score (from 6.4 to 6.8) were reported. Finally, progressive step-down of anti-asthma treatment was started, and at present (by 11.5 years) inhaled fluticasone (200 μg/day) plus bimonthly subcutaneous omalizumab provide good control of symptoms. Omalizumab has been continuously administered for 2.6 years and is still ongoing.

A full-term male had severe preschool wheezing and, since age 4, recurrent, severe asthma exacerbations with frequent hospital admissions. At age 8, multiple perennial inhalants and food sensitization (i.e., house dust mites, dog dander, Graminaceae pollen mix, Olea europaea pollen, tomatoes, beans, shrimps, and peas) and high serum IgE levels (1166 KU/l) were found. The patient has been treated over 5 years with inhaled fluticasone (up to 1000 μg/day) in association with salmeterol (100 μg/day) and oral montelukast (5 mg/day). Despite this, monthly hospital admissions with systemic steroids need were recorded. After checking the inhaler technique and adherence to treatment, comorbidities including obesity, rhinosinusitis and GER were excluded. Omalizumab was proposed, but parents refused it. By 13.6 years, despite a treatment including the association of inhaled salmeterol/fluticasone (100 μg/1000 μg∙day − 1 , respectively) plus oral montelukast (10 mg/day), monthly exacerbations requiring systemic steroids are reported.

Discussion and conclusions

Most children and adolescents with asthma respond well to inhaled short-acting beta 2 -agonists (SABA) on demand if symptoms are intermittent, or to low dose controller drugs plus as-needed SABA if the risk of exacerbations increases [ 1 ]. Nevertheless, a proportion of patients is referred to specialists because this strategy is not working and asthma is persistently uncontrolled [ 4 ]. For these children, assessment is primarily aimed at investigating the reasons for poor control. Indeed, when the child is initially referred, before the label of “severe, therapy-resistant asthma” (i.e., not responding to treatment even when factors as exposure to allergens and tobacco smoke have been considered) is assigned, three main categories need to be identified: 1) “not asthma at all”, in which response to treatment is suboptimal because the diagnosis is wrong; 2) “asthma plus ”, when asthma is mild but exacerbated by one or more comorbidities; and 3) “difficult-to-treat asthma”, when asthma is uncontrolled because of potentially reversible factors [ 10 ].

The reported cases highlight some aspects of the disease process that may expand the diagnosis and improve patients’ care. At our institution, the severe asthma program includes a multidisciplinary approach with consultations by gastroenterologists as well as ear, nose and throat experts. Recently, sleep medicine experts joined this multidisciplinary team; thus, unfortunately, sleep-disordered breathing (SDB) could not be excluded at the time of our patients’ assessment. Inhalation technique is periodically evaluated by nurses or doctors in each patient. Unfortunately, in Italy an individual prescription database is not available and thus we cannot assess patients’ use of medication. In two cases, the filtering process eventually identified GER and rhinosinusitis, but poor control of asthma persisted even after comorbidities were treated. In all subjects, inhaler skills, treatment adherence, and environmental exposure to indoor/outdoor allergens as well as to second- and third-hand smoke were excluded as cause of lack of control. Eventually, three out of four patients started anti-IgE treatment; asthma control was obtained and maintenance drugs were progressively reduced. In the case that refused omalizumab therapy, pulmonary function, clinical features and controller treatment including high-dose ICS were unchanged.

Previous studies have highlighted an association between increasing asthma severity in children and reduced QoL [ 11 , 12 , 13 ]. Uncontrolled asthma symptoms not only affect children physically, but can impair them socially, emotionally, and educationally [ 13 ]. In line with previous observations, 3 out 4 of our cases had poor QoL, assessed by a standardized questionnaire [ 14 ]. It is well known that improving QoL in difficult asthma is not an easy task, despite a variety of treatments aimed at achieving control [ 12 ], and much more remains to be done to address the problem. Nevertheless, 2 of our 3 cases showed a remarkable improvement of QoL after one year of treatment with omalizumab.

Reduction in forced expiratory volume in the first second (FEV 1 ) is often used to define childhood asthma severity in treatment guidelines and clinical studies [ 5 , 11 , 15 ]. Nevertheless, children with severe asthma often have a normal FEV 1 that does not improve after bronchodilators, indicating that spirometry may be a poor predictor of asthma severity in childhood [ 6 , 16 , 17 ]. Actually, children with a normal FEV 1 , both before and after β 2 -agonist, may show a bronchodilator response in terms of forced expiratory flow between 25% and 75% (FEF 25–75 ) [ 18 ]. However, the utility of FEF 25–75 in the assessment or treatment of severe asthma is currently unknown. Interestingly, all the reported cases showed normal or slightly reduced values of FEV 1 but severe impairment of FEF 25–75 . Two cases showed a bronchodilator response in terms of FEV 1 (subjects 3 and 4), while 3 patients had a significant increase of FEF 25–75 (cases 1, 3 and 4). Unfortunately, we could not provide the results of bronchodilator response during or after the treatment with omalizumab in any case.

Available literature on the diagnostic approach to difficult asthma in children offers a number of reviews which basically summarize the steps needed to fill the gap between a generic diagnosis of “difficult asthma” and more specific labels (i.e., “severe” asthma, “difficult-to-treat” asthma, or even different diagnoses) [ 3 , 5 , 6 , 8 , 10 , 19 , 20 , 21 ]. So far, few original articles and case reports have been published, probably due to the peculiarity of the issue, which makes retrospective discussion of cases easier than the design of a prospective clinical study [ 4 , 22 , 23 , 24 , 25 , 26 ]. Available knowledge mainly derives from the experience of specialized centers.

The evaluation of a child referred for uncontrolled asthma should start with a careful history focused on typical respiratory symptoms and on the definition of possible triggers. In the “severe asthma” process, it is crucial for clinicians to maintain a high degree of skepticism about the ultimate diagnosis, particularly in the presence of relevant discrepancies between history, physical features and lung function, as many conditions may be misdiagnosed as asthma. In order to simplify this process, herein we propose an algorithm for the diagnosis of difficult-to-treat and severe asthma (Fig. 1 ). Confirmation of the diagnosis through a detailed clinical and laboratory re-evaluation is important because in 12–50% of cases assumed to have severe asthma this might not be the correct diagnosis [ 10 ]. Several documents have indicated the main steps of the process that should be followed in children with uncontrolled asthma [ 3 , 8 , 10 ]. The translation of these procedures into real life practice may deeply change from one subject to another due to the variability of individual patients’ history and clinical features, which will often lead the diagnostic investigations towards the most likely reason for uncontrolled asthma. For children with apparently severe asthma, the first step is to confirm the diagnosis and, before proceeding to broader investigations, to verify that the poor control is not simply determined by poor adherence to treatment, inadequate inhaler skills and/or environmental exposure to triggers. A nurse-led assessment, including a home visit, despite not being applicable in all settings, may be useful for identifying potentially modifiable factors in uncontrolled pediatric asthma [ 27 ].

A practical algorithm for the diagnosis of difficult-to-treat and severe asthma. ICS, inhaled corticosteroids; OCS, oral corticosteroids

A number of comorbidities have been increasingly recognized as factors that may impact asthma clinical expression and control in childhood [ 10 , 28 ]. Children with uncontrolled disease should be investigated for GER, rhinosinusitis, dysfunctional breathing and/or vocal cord dysfunction, obstructive sleep apnea, obesity, psychological factors, smoke exposure, hormonal influences, and ongoing drugs [ 3 , 6 , 8 , 20 ]. Indeed, the exact role played by comorbidities in pediatric asthma control is still debated [ 28 ]. The most impressive example is GER. Several pediatric documents recommend assessing for GER because reflux may be a contributing factor to problematic or difficult asthma [ 7 , 29 ]. Nevertheless, GER treatment might not be effective for severe asthma [ 30 , 31 ], as confirmed by current cases 1 and 2. There is an established evidence that chronic rhinosinusitis is associated with more severe asthma in children [ 32 , 33 , 34 ]. Therefore, examination of upper airways and ad hoc treatment if rhinosinusitis is evident are recommended in children with severe asthma [ 3 , 8 , 35 ]. However, intranasal steroids for rhinitis resulted in a small reduction of asthma risk in school-aged children [ 36 ], and actual placebo-controlled studies on the effect of treatment of rhinosinusitis on asthma control in children are lacking [ 10 , 37 ].

Dysfunctional breathing, including hyperventilation and vocal cord dysfunction, is associated with poorer asthma control in children [ 8 , 10 , 38 , 39 ]. Unfortunately, there is scarce literature on the effect of its treatment on the control of severe asthma in children [ 40 ]. SDB ranging from primary snoring to obstructive sleep apnea syndrome is very common in children [ 41 ], and an increased prevalence of SDB together with increasing asthma severity has been reported [ 42 ]. Interestingly, GER may also be worsened by recurrent episodes of upper airway obstruction associated with SDB, and this may further trigger bronchial obstruction. Asthma guidelines recommend the assessment of SDB through nocturnal polysomnography in poorly controlled asthmatics, particularly if they are also obese [ 5 ]. There are no studies examining whether pediatric asthma improves after SDB has been treated, for example, with nasal steroids, adenotonsillectomy, continuous positive airway pressure or weight reduction if the child is also obese [ 43 ]. The parallel increase in obesity and asthma suggests that the two conditions are linked and that they can aggravate each other [ 44 , 45 ], even though the exact mechanisms that underlie this association remain unclear [ 46 ]. Indeed, other coexisting comorbidities such as SDB or GER may play a confounding role in the development of the interactions between obesity and the airways [ 47 , 48 ]. Obesity is associated with increased markers of inflammation in serum and adipose tissue and yet decreased airway inflammation in obese people with asthma [ 49 ]. Several interventions, including behavioral and weight reduction programs or bariatric surgery, may result in improved asthma control, quality of life and lung function in adult obese asthmatics [ 50 ]. Although reports of adolescent bariatric surgery demonstrate a significant body weight decrease, this approach is not widely available and there are no published reports on its effect on pediatric severe asthma control [ 51 ]. Finally, although it is still unclear whether food allergy is causative or shares a common pathway with difficult asthma, it might explain the loss of asthma control at least in some children and thus be considered as a comorbid condition [ 10 , 16 , 52 ].

In conclusion, establishing the impact of comorbidities on asthma control may be cumbersome, and an ex-juvantibus treatment is sometimes necessary to assess their role. Comorbid conditions can also worsen each other, and symptoms arising from some of them may mimic asthma [ 6 ]. Although the ability to improve pediatric severe asthma by treating comorbidities remains unconfirmed, they should be treated appropriately [ 9 ].

The vast majority of asthmatic children exhibit a mild or at most a moderate disease that can be fully controlled with low-to-medium dose ICS associated or not with other controllers [ 5 , 6 ]. However, a subset of asthmatics remains difficult-to-treat [ 5 , 6 ]. With the advent of biologics, these severe steroid-dependent asthmatics have alternative options for treatment, as steroid-related adverse events are common in severe asthma [ 53 ]. Omalizumab, an anti-IgE monoclonal antibody, is the only biologic therapy recommended in children with moderate-to-severe asthma by the recent guidelines [ 5 , 6 ]. In Italy, this treatment is fully covered by the National Health System. Therefore, there is no influence by any funding on treatment decisions. It was approved by the US (Food and Drug Administration) in 2003 and by the European Union (European Medicines Agency) in 2005 as an add-on treatment for patients aged > 12 years with severe persistent allergic asthma and who have a positive skin test or in-vitro reactivity to a perennial aeroallergen, FEV 1 < 80% predicted, frequent daytime symptoms or nighttime awakenings, and multiple documented severe asthma exacerbations despite daily ICS plus a LABA [ 54 , 55 ]. In 2009, it also received approval in Europe for treating patients aged 6–12 years. Figure 2 illustrates current indications for treatment with omalizumab in children and adolescents with severe asthma.

Indications for omalizumab in children and adolescents with severe asthma

IgE antibodies, Th 2 -derived cytokines and eosinophils play a major role in the development of chronic airway inflammation in asthmatic subjects [ 56 ]. Once released from plasma cells, IgE binds principally to the high-affinity IgE receptor (FcεRI) on mast cells, triggering different effector responses, including the release of mediators leading to allergic inflammatory reactions [ 56 ]. The activation of the allergic cascade by IgE, under constant allergen stimulation, leads to the establishment of chronic allergic inflammation in the airways of asthmatic patients, with IgE being a key element of the vicious circle that maintains it. Cytokines produced during the late phase and subsequent chronic inflammation stage have been directly associated with the induction of airway remodelling, indirectly implicating IgE in the process [ 56 ]. At present, omalizumab is the only commercially available recombinant humanized anti-IgE monoclonal antibody that specifically binds serum free IgE at its CH 3 domain, in the proximity of the binding site for FcεRI, thus preventing IgE from interacting with its receptor on mast cells, basophils, antigen-presenting cells and other inflammatory cells [ 57 ]. The rapid reduction of free IgE levels leads to a downregulation of the FcεRI expression on inflammatory cells and an interruption of the allergic cascade, which results in the reduction of peripheral and bronchial tissue eosinophilia and of levels of granulocyte macrophage colony stimulating factor, interleukin (IL)-2, IL-4, IL-5, and IL-13 [ 58 ]. Moreover, basophils have a relevant role in the initiation and progression of allergic inflammation, suggesting that they may represent a viable therapeutic target. Indeed, in children with severe asthma, it has been reported that omalizumab therapy is associated with a significant reduction in circulating basophil numbers, a finding that is concurrent with improved clinical outcomes [ 59 ]. This finding supports a mechanistic link between IgE levels and circulating basophil populations, and may provide new insights into one mechanism by which omalizumab improves asthma symptoms.

Several clinical controlled and real-life studies of adults with severe, inadequately controlled allergic asthma have demonstrated the efficacy and safety of omalizumab in reducing asthma-related symptoms, corticosteroid use, exacerbation rates, and healthcare resource utilization, and in improving QoL and lung function [ 60 , 61 , 62 , 63 ]. Fewer studies have been published in children. In two double-blind, randomized, placebo-controlled trials (RCTs) of children aged 6 to 12 years with moderate-to-severe allergic asthma, treatment with omalizumab reduced the requirement for ICS and protected against disease exacerbations, but there was little change in asthma symptom scores or spirometry [ 9 , 64 ]. These findings were confirmed and extended in older children [ 65 , 66 , 67 ].

The results of the ICATA study, a multicenter RCT of 419 inner-city children, adolescents and young adults with persistent allergic asthma, showed that, compared to placebo, omalizumab reduces the number of days with asthma symptoms and the proportion of participants with at least one exacerbation by approximately 25% and 19%, respectively ( p < 0.001), thus reducing the need for asthmatic symptom controllers [ 68 ]. Another multicenter RCT of inner-city children and adolescents showed that the addition of omalizumab to ongoing guidelines-based care before patients return to school reduces fall asthma exacerbations (odds ratio, 0.48), particularly in subjects with a recent exacerbation [ 69 ]. Moreover, in a real-life study of 104 children and adolescents with severe allergic refractory asthma followed over 1 year, treatment with omalizumab resulted in good asthma control in 67% of the cases ( p < 0.001), while FEV 1 improved by 4.9% ( p = 0.02) and exacerbation rates and healthcare utilisation decreased approximately by 30% ( p < 0.001) [ 70 ]. The same authors also showed that, after two years of treatment, exacerbation rate and healthcare utilisation were further decreased by 83% and 100%, respectively, while level of asthma control, steroid use and lung function remained unchanged [ 71 ].

A systematic review of pediatric RCTs pooled the data of 1381 children and adolescents with moderate-to-severe allergic asthma in order to establish the efficacy of omalizumab as an add-on therapy [ 72 ]. During the stable-steroid phase, omalizumab decreased the number of patients with at least one exacerbation (risk ratio, 0.69; p < 0.001), the mean number of asthma exacerbations per patient (risk ratio, 0.35; p < 0.001), and the asthma symptom score (mean difference, 0.12; p = 0.005) when compared to placebo. During the steroid reduction phase, omalizumab further reduced the number of patients with at least one exacerbation (risk ratio, 0.48; p < 0.001) and the mean number of asthma exacerbations per patient (mean difference, 0.12; p < 0.05).

Given the cost of omalizumab, many authors have argued for the importance of identifying specific asthma populations who will have significant benefit from it [ 68 , 73 , 74 ]. In the ICATA study, baseline predictors of good response to treatment were sensitization and exposure to cockroach allergen, sensitization to house dust mite allergens, a serum IgE level of more than 100 IU per milliliter, a BMI of 25 or more, and a history of at least one unscheduled medical visit in the previous year [ 68 ].

Several studies have assessed the long-term safety of omalizumab in children and adults. A pooled analysis of 67 RCTs conducted over 2 decades on 4254 children and adults treated with omalizumab showed no association between omalizumab treatment and risk of malignancy [ 75 ]. In an RCT evaluating 225 school-aged children, omalizumab was well tolerated, there were no serious adverse events, and the frequency and types of all adverse events were similar to the placebo group [ 9 ]. These results have been further confirmed by a recent systematic review of RCTs that concluded that treatment with omalizumab does not result in increased risk of malignancy or hypersensitivity reactions [ 72 ].

While the rationale for long-term treatment with omalizumab is supported by pharmacokinetic-pharmacodynamic models [ 76 ], the duration of treatment is still under discussion. Results from published studies suggest that omalizumab should be continued for > 1 year [ 77 , 78 ]. In a retrospective study of adults and children with uncontrolled severe asthma treated with omalizumab, the response to treatment was ‘excellent’ in 52.5% of patients, particularly in the subgroup of children aged 6 to 11 years [ 77 ]. After the discontinuation of treatment, loss of asthma control was documented in 69.2% of the patients who had received omalizumab for < 1 year, 59.1% of the subjects treated for 1–2 years, and 46.1% of the cases treated for > 2 years. Time to loss of control was shorter in younger children and longer in patients with an ‘excellent’ response compared with patients with a ‘good’ response. No early loss of control (within 6 months) was observed among patients with > 3.5 years of continuous treatment with omalizumab. Finally, 20% of patients in whom omalizumab was re-prescribed because of loss of control did not respond to the treatment anymore [ 77 ]. Despite these encouraging findings, the impact of omalizumab on the natural history of severe asthma in children deserves to be further investigated by long-term studies that will also define the criteria and timing for discontinuing the treatment.

It is well known that asthma pharmacotherapy is effective in controlling symptoms and bronchial inflammation, but cannot affect the underlying immune response, thus leading to the possibility of symptom reappearance after its discontinuation [ 79 ]. In this scenario, allergen-specific immunotherapy (AIT) has been proposed as the only therapeutic method that can modulate the underlying immune pathophysiology in allergic asthma [ 80 ].

AIT is currently indicated in children and adults with mild-moderate allergic asthma that is completely or partially controlled by pharmacotherapy and with the evidence of a clear relationship between symptoms and exposure to a specific allergen [ 81 , 82 , 83 , 84 ]. However, according to recent guidelines, the efficacy of AIT in asthmatic subjects is limited, and its potential benefits must be weighed against the risk of side effects and the inconvenience and costs of the prolonged therapy [ 5 ]. Moreover, severe or uncontrolled asthma (regardless of its severity) is a major independent risk factor for non-fatal or even fatal adverse reactions, thus representing a contraindication for AIT [ 85 , 86 , 87 ]. Finally, children with severe asthma are often sensitized to multiple allergens, thus making AIT prescription even more complicated [ 88 ].

In subjects with uncontrolled and/or severe allergic asthma, a combination of omalizumab and AIT has been proposed [ 88 ]. Surprisingly, only a few studies have addressed this issue [ 89 , 90 , 91 , 92 ]. However, pre-treatment with omalizumab seems to improve the efficacy and tolerability of subcutaneous AIT in children and adults with severe allergic asthma both during omalizumab treatment and after its discontinuation [ 89 , 91 , 92 ]. Omalizumab has also been successfully used as a supplementary treatment to AIT in order to improve asthma control in children ≥6 years with severe persistent allergic asthma [ 90 ]. Given the scarcity of studies on AIT plus omalizumab in children with severe allergic asthma, further research is warranted to assess risks and benefits of the combined treatment.

Children with severe asthma require a detailed and individualized approach including re-assessment for differential diagnoses, comorbidities and contributory factors, environmental triggers, lung function and inflammation, adherence and response to therapy, and QoL. Treatment of pediatric severe asthma still relies on the maximal optimal use of corticosteroids, bronchodilators and other controllers recommended for moderate-to-severe disease. However, the management of asthma is becoming much more patient-specific, as more and more is learned about the biology behind the development and progression of asthma.

In the current paper, we described the characteristics of four children with severe asthma in whom omalizumab was prescribed. A review of the relevant literature on the topic was also performed. Finally, we provided an algorithm for the diagnosis of difficult-to-treat and severe asthma in children and adolescents, based on the evidence from the literature review. As all algorithms, it is not meant to replace clinical judgment, but it should drive physicians to adopt a systematic approach towards difficult and severe asthma and provide a useful guide to the clinician.

The addition of omalizumab, the first targeted biological treatment approved for asthma, has led to renewed optimism of outcome improvements in patients with allergic severe asthma. As severe asthma is a heterogeneous condition consisting of different phenotypes, the future of asthma management will likely involve phenotypic and potentially even genotypic characterization in selected cases in order to determine appropriate therapy and thus to provide the highest possible benefit, especially if specific responder phenotypes can be identified and selected for this highly specific treatment.

Abbreviations

Anti-immunoglobulin E

Body mass index

IgE receptor

Forced expiratory flow between 25% and 75%

Forced expiratory volume in the first second

Gastroesophageal reflux

Inhaled corticosteroids

Intensive care unit

Interleukin

Long-acting β 2 -agonist

Oral leukotriene receptor antagonist

Quality of life

Randomized controlled trials

Short-acting β 2 -agonists

Sleep-disordered breathing

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Acknowledgements

The authors gratefully thank Dr. Marco Maglione for his contribution in the clinical assessment of the described cases. Medical writing assistance was provided by Stephen Walters on behalf of City Hills Proofreading.

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VM, SM and FS, authors of the current manuscript, declare that they have participated sufficiently in the work to take public responsibility for appropriate portions of the content. VM and SM carried out the initial investigations, drafted the initial manuscript, revised the manuscript, and approved the final manuscript as submitted. FS conceptualized and designed the study, and critically reviewed and approved the final manuscript as submitted. All authors read and approved the final manuscript.

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Correspondence to Francesca Santamaria .

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Mirra, V., Montella, S. & Santamaria, F. Pediatric severe asthma: a case series report and perspectives on anti-IgE treatment. BMC Pediatr 18 , 73 (2018). https://doi.org/10.1186/s12887-018-1019-9

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Severe asthma
Adolescents
Asthma exacerbations

BMC Pediatrics

ISSN: 1471-2431

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Long-term outcomes of combination biologic therapy in uncontrolled severe asthma: a case study

Affiliations.

1 Department of Health Sciences, Respiratory Unit, ASST Santi Paolo e Carlo, San Paolo Hospital, University of Milan, Milan, Italy.
2 Department of Internal Medicine, Asthma and Allergy, Norbert Barlicki Memorial Teaching Hospital No. 1; Medical University of Lodz, Lodz, Poland.
PMID: 35913268
DOI: 10.1080/02770903.2022.2109162

Introduction: Treatment with biologics has significantly reduced the social and economic burden of severe asthma. However, some patients may still feature a suboptimal control of their symptoms while on therapy. In this subset of asthmatic patients, a benefit from a dual biologic therapy has sporadically been reported in literature. Our aim is to add our experience to the limited body of evidence supporting combination biologic therapies.

Case study: Here we present the case of a 68-year-old nonsmoker female, with an allergic and eosinophilic corticosteroid-dependent severe asthma. She displayed well controlled comorbidities and good adherence to the inhaled therapy. Omalizumab was started in 2008 with an initial remarkable clinical improvement. After nine years of biologic therapy, she reported a gradual worsening of her symptoms and exacerbations. Mepolizumab was then added in 2019.

Results: The addition of Mepolizumab resulted in a meaningful amelioration of her quality of life, asthma control, number of exacerbations and 6-minute-walking-distance at 3-year follow-up. The average Prednisone dosage was tapered from 25 mg to 20 mg daily. No adverse events were observed since the introduction of the second biologic.

Conclusion: Our experience indicates that Mepolizumab may be beneficial and safe as an add-on biologic in a patient whose allergic and eosinophilic asthma remains uncontrolled despite treatment with an anti-IgE strategy. Further studies on a larger number of patients are required to demonstrate whether the positive outcomes published so far are replicable on a larger scale.

Keywords: Severe asthma; allergic asthma; biologic therapy; eosinophilic asthma; uncontrolled asthma.

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J Kolbe a , b ,
W Fergusson a ,
M Vamos c ,
J Garrett a
a Department of Respiratory Medicine, Green Lane Hospital, Auckland, New Zealand, b Department of Medicine, University of Auckland, Auckland, New Zealand, c Department of Psychiatry, John Hunter Hospital, Newcastle, NSW, Australia
Dr J Kolbe, Respiratory Services, Green Lane Hospital, Auckland, New Zealand jkolbe{at}ahsl.co.nz

BACKGROUND Severe life threatening asthma (SLTA) is important in its own right and as a proxy for asthma death. In order to target hospital based intervention strategies to those most likely to benefit, risk factors for SLTA among those admitted to hospital need to be identified. A case-control study was undertaken to determine whether, in comparison with patients admitted to hospital with acute asthma, those with SLTA have different sociodemographic and clinical characteristics, evidence of inadequate ongoing medical care, barriers to health care, or deficiencies in management of the acute attack.

METHODS Seventy seven patients with SLTA were admitted to an intensive care unit (pH 7.17 (0.15), Pa co 2 10.7 (5.0) kPa) and 239 matched controls (by date of index attack) with acute asthma were admitted to general medical wards. A questionnaire was administered 24–48 hours after admission.

RESULTS The risk of SLTA in comparison with other patients admitted with acute asthma increased with age (odds ratio (OR) 1.04/year, 95% CI 1.01 to 1.07) and was less for women (OR 0.36, 95% CI 0.20 to 0.68). These variables were controlled for in all subsequent analyses. There were no differences in other sociodemographic features. Cases were more likely to have experienced a previous SLTA (OR 2.04, 95% CI 1.20 to 3.45) and to have had a hospital admission in the last year (OR 1.86, 95% CI 1.09 to 3.18). There were no differences between cases and controls in terms of indicators of quality of ongoing asthma specific medical care, nor was there evidence of disproportionate barriers to health care. During the index attack cases had more severe asthma at the time of presentation, were less likely to have presented to general practitioners, and were more likely to have called an ambulance or presented to an emergency department. In terms of pharmacological management, those with SLTA were more likely to have been using oral theophylline (OR 2.14, 95% CI 1.35 to 3.68) and less likely to have been using inhaled corticosteroids in the two weeks before the index attack (OR 0.69, 95% CI 0.47 to 0.99). While there was no difference in self-management knowledge or behaviour scores, those with SLTA were more likely to have inappropriately used oral corticosteroids during the acute attack (OR 2.09, 95% CI 1.02 to 4.47).

CONCLUSIONS In comparison with those admitted to hospital with acute severe asthma, patients with SLTA were indistinguishable on sociodemographic criteria (apart from male predominance), were more likely to have had a previous SLTA or hospital admission in the previous year, had similar quality ongoing asthma care, had no evidence of increased physical, economic or other barriers to health care, but had demonstrable deficiencies in the management of the acute index attack. Educational interventions, while not losing sight of the need for good quality ongoing care, should focus on providing individual patients with better advice on self-management of acute exacerbations.

life threatening asthma
socioeconomics
health care
acute attack

https://doi.org/10.1136/thorax.55.12.1007

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Severe life threatening asthma (SLTA) is an important entity in its own right. 1 While still numerically rather small, SLTA greatly outnumbers asthma deaths. 1-3 Patients with SLTA are a disproportionate source of subsequent asthma morbidity 2 , 4-6 and health care costs. 7 Previous SLTA clearly defines a population at increased risk of death or SLTA. 2 , 4-6 Because patients who present with SLTA share demographic and other characteristics with those dying of asthma, 1 and also because death would almost certainly ensue in those presenting with SLTA in the absence of prompt medical intervention, SLTA may be regarded as a “proxy for asthma death”. 1 , 8 However, study of SLTA has some practical advantages. The more complete, detailed, and unbiased information available should facilitate the precise definition of specific risk factors for SLTA (and asthma death), as distinct from the risk factors for simple hospital admission for acute severe asthma. In turn, defining risk factors for SLTA within the population of those admitted to hospital with acute asthma should allow the development of specific interventional strategies to reduce the incidence of serious adverse events.

Poor quality, fragmented medical care, or both, has been cited as a cause of asthma death and near fatal asthma in New Zealand 6 , 9-12 and elsewhere. 13-17 Although in previous studies we have shown evidence of good quality ongoing asthma management in patients admitted to hospital with acute asthma, 18 we have also demonstrated that serious self-management errors occur in a high proportion of patients with acute severe asthma requiring hospitalisation. 19 , 20 If such errors were a risk factor for SLTA (and asthma death), then educational and other initiatives which specifically focus on management of the acute severe attack may be the most effective means of reducing asthma mortality and severe morbidity.

The aims of this study were therefore to determine whether or not, in comparison with those admitted to hospital with acute asthma, patients experiencing SLTA had (1) different demographic characteristics, (2) inferior health care, (3) barriers to health, and/or (4) demonstrably inferior self-management of the acute attack.

A case-control study was undertaken because of its efficiency. 21

Cases comprised consecutive patients aged 15–49 years normally resident in the Auckland region who were admitted to one of the two intensive care units (ICUs) in the region with SLTA. 1 For the purposes of this study, SLTA was defined as admission to ICU for acute severe asthma plus at least one of the following: (1) cardiorespiratory arrest, (2) requirement for mechanical ventilation, (3) impaired level of consciousness at presentation, (4) pH <7.2, and (5) arterial carbon dioxide tension (Pa co 2 ) ⩾6.0 kPa.

Exclusion criteria were: (1) age ⩾50 years to avoid major inaccuracies in the diagnosis of asthma in older patients; (2) age <15 years as this is the lower age limit for entry into “adult” clinics and patients aged 15 years and older are generally considered to be of sufficient maturity to assume responsibility for their own health, thus avoiding the need to study the behavioural attitudes and psychosocial features of both parent and child and the parent-child interaction as would be necessary for younger age groups; (3) asthmatics in whom the primary reason for admission to the ICU was not asthma or in whom admission to the ICU was primarily for asthma complications such as pneumothorax rather than SLTA; (4) patients with persisting sequelae of hypoxic encephalopathy preventing completion of questionnaire; and (5) patients whose proficiency in English impaired their ability to complete the questionnaire (lack of proficiency in English was defined as requiring an interpreter when attending a routine doctor's appointment).

Matched hospital control group

This group comprised patients aged 15–49 years normally resident in the Auckland region admitted with acute asthma to a general medical ward of the same hospital as the case, on the same day as the case, on the day before, or within the subsequent two weeks of admission of the case—that is, day –1 to day 14. No other matching was undertaken as it was considered that features traditionally matched for such as age and sex may be important risk factors for SLTA. Up to four matched controls were selected for each case in order to maximise efficiency. 21

Exclusion criteria were: (1) age ⩾50 years; (2) age <15 years; (3) asthmatics for whom the primary reason for admission was not acute asthma; and (4) poor proficiency in English

Both cases and controls satisfied the criteria for reversible airflow obstruction—that is, improvement of ⩾20% in forced expiratory volume in one second (FEV 1 ) or peak expiratory flow (PEF) in response to treatment.

Community comparison group

A random sample of community based asthmatic patients were recruited to provide normative data for asthmatics, to provide a three way comparison for some parameters, and to distinguish between risk factors for hospitalisation and risk factors for SLTA. Potential subjects had been identified in a previous study of the prevalence of adult asthma. 22

QUESTIONNAIRE

A detailed questionnaire was administered to cases and hospital controls within 24–72 hours of admission to general medical wards by the same research associate (WF). Members of the community comparison group were interviewed at home.

Data collected included: (1) Patient demographics. (2) Indicators of quality of health care including: (a) quality of ongoing asthma specific management (acquisition of PEF meter and written action plan, availability of supply of oral steroids, checking of metered dose inhaler (MDI) technique); (b) accessibility of health care: availability of primary health care for routine appointments and during exacerbations, physical accessibility, cost of health care, financial and other barriers to health care; (c) doctor-patient relationship: this is an individual item obtained by factor analysis of the modified Attitudes and Beliefs About Asthma questionnaire. 23 This modification has been described elsewhere 24 and has proved to be feasible, reliable, and acceptable in different patient groups. 19 , 20 , 24 , 25 (3) Asthma severity using a modification of the severity classification of asthma based primarily on drug management by Blanc. 26 (4) Indices of severity of the acute (index) attack. (5) Medication use in the two weeks before admission. (6) Assessment of self-management knowledge using scenarios describing two hypothetical attacks. 25 One described an attack of increasing severity over seven days (slow onset) while the second described an attack which developed over one hour (rapid onset). Both scenarios ended with the subject “experiencing” a severe attack such that he/she was so wheezy and short of breath as to be unable to speak or rise from a chair. At three stages during each of the scenarios subjects were asked to describe what action they would normally undertake if they were actually experiencing such symptoms. The scoring system, in which scores were weighted for strategies considered most important in aborting an attack or to be potentially lifesaving, was based on consensus statements on the management of asthma published by the Thoracic Society of Australia and New Zealand (TSANZ) 27 and the British Thoracic Society (BTS). 28 , 29 (7) Patient self-management behaviour: this methodology has been described elsewhere. 19 Behaviour was assessed by a very detailed history of symptoms and self-management strategies undertaken before admission to hospital. Particular attention was paid to symptoms which defined “stages” in the hypothetical scenarios and the self-management strategies undertaken in relation to those stages in the actual attack. The index attack was then classified as rapid (<6 hours) or slow (⩾6 hours). Because of the relative infrequency of rapid onset attacks (8% based on previous findings 30 ), only those experiencing a slow onset attack were analysed. The subjects' “behaviour” during the index attack was scored using the same system as for the scenarios.

The total possible score for the measures described in (6) and (7) is 25; a score of <15 was considered to represent clinically significant inadequate self-management knowledge/behaviour. Serious errors in management were defined using predefined criteria. 14 Additional information relating to the management of the acute attack was separately obtained—for example, the use of PEF meters, action plans, oral corticosteroids and nebulised bronchodilators, and difficulties experienced during the attack.

The instruments used in (6) and (7) have previously been tested and found to be feasible, acceptable, and reliable in patients attending an asthma clinic, 25 in inpatients, 19 and in different ethnic groups. 24

A detailed assessment of psychological factors will be presented elsewhere. 31

All subjects gave written informed consent to participate in the study which was approved by the Auckland Healthcare ethics committee.

STATISTICAL ANALYSIS

Normally distributed data were expressed as mean (SD). For the matched case and controls, conditional logistic regression was performed to identify factors related to SLTA compared with the matched hospital control group. Initially, basic demographic variables were analysed and any statistically significant variables were included in all further analyses. Variables considered to be the best measures of individual parameters were grouped and analysed in conjunction with the significant demographic variables. Differences between cases and the community comparison group were analysed using unpaired t tests and the Wilcoxon signed rank test on parametric and non-parametric data, respectively. The χ 2 test was used to test the differences in proportions between the groups. A p value of ⩽0.05 was regarded as statistically significant.

Seventy seven patients fulfilled the criteria of cases. Three were excluded because they normally lived outside the Auckland region and two because they were unable to complete the interviewer administered questionnaire, one because of severe mental retardation and one because of severe schizophrenia. One was excluded because of poor English proficiency. Three potential cases were not interviewed; all left hospital after less than 48 hours and two discharged themselves. There were no refusals.

Two hundred and thirty nine matched hospital controls were recruited, representing 1–4 controls per case. Two were excluded because they normally lived outside the Auckland regions, six were excluded because of poor English proficiency, three because of mental retardation, and there was one refusal. Twelve potential controls were not interviewed because of rapid discharge from hospital, three of whom discharged themselves. One hundred subjects were recruited in the community comparison group; a further 45 declined to participate but did not differ from the total group in terms of basic demographic characteristics.

The sociodemographic data of the patients are presented in table 1 . Analysis of SLTA cases and matched hospital controls showed that both age and sex were risk factors for SLTA. The risk of SLTA increased with age (odds ratio (OR) 1.04 per year, 95% confidence interval (CI) 1.01 to 1.07) and was less for women (OR 0.36, 95% CI 0.20 to 0.68). These variables were therefore controlled for in all further analyses. There were no differences in ethnicity or socioeconomic indicators between cases and hospital matched controls. However, the community comparison group were more likely to be European (p<0.01) and less socioeconomically disadvantaged (p<0.05) than the cases and matched hospital controls.

View inline

Demographic data and previous asthma morbidity of cases (SLTA), matched hospital controls and community comparison group

Asthma morbidity is also shown in table 1 . Cases with SLTA were more likely than matched hospital controls ever to have had previous SLTA (OR 2.04, 95% CI 1.20 to 3.45) and to have been admitted to hospital for acute asthma in the last year (OR 1.86, 95% CI 1.09 to 3.18). The community comparison group had markedly lower morbidity indices than either cases or controls (p<0.001 for all).

The community comparison group was assessed to have less severe asthma than cases or hospital controls (table 2 ) but there were no differences between cases, hospital controls, or the community comparison group in terms of chronic prescribed drug management of asthma except for the use of oral theophylline (table 2 ). There were no differences between cases and hospital controls for indicators of quality of ongoing asthma specific medical care (table 2 ). Data on barriers to health care are shown in table 3 . There were no differences between cases and hospital controls in terms of: (1) physical accessibility of health care, (2) financial barriers to health care (both general and asthma specific), and (3) quality of the doctor-patient relationship (either in terms of total factor score (data not shown) or for the individual items). (“Doctor” was defined as the medical professional whom patients considered most important in the management of their asthma.) The community comparison group had fewer financial barriers to health care but less favourable attitudes to their doctor (not statistically significant) (table 3 ).

Severity and asthma management

Barriers to health care

Data pertaining to presentation and management of the index attack for cases and matched hospital controls are presented in table 4 . As expected, cases had evidence of more severe asthma at presentation. Cases were less likely to present initially to general practitioners and were more likely to present to emergency departments or to call an ambulance (p<0.01). Difficulties encountered by the patient in the management of the index attack are shown in table 4 . Cases were more likely to have perceived panic during the attack but were less likely to be concerned about time off work. Otherwise there were no differences in these parameters.

Management of the acute attack

Use of oral theophylline (ongoing and in the two weeks before the index attack) was associated with a higher risk of SLTA (OR 2.14, 95% CI 1.35 to 3.68) while use of inhaled corticosteroids in the two weeks before the index attack (as opposed to prescribed inhaled corticosteroids) was associated with a reduced risk of SLTA (OR 0.69, 95% CI 0.47 to 0.99) compared with hospital controls. However, cases were less likely to have previously run out of their usual medications (48% vs 28%, p<0.01). There were no differences between cases and controls with regard to access to urgent after hours care nor in their previous management of a nocturnal attack (table 5 ).

Asthma self-management

There were no differences in self-management knowledge scores or self-management behaviour scores between cases and hospital controls. Cases were less likely to use standard self-management strategies, but only the lower rate of use of a peak flow meter reached statistical significance (table 5 ). Self-management error in terms of delayed use or non-use of oral steroids during the index attack was associated with an increased risk of SLTA (OR 2.09, 95% CI 1.02 to 4.47). Delayed or non-summoning of an ambulance was not associated with an increased risk of SLTA.

In comparison with those admitted with acute asthma, patients with SLTA are relatively more likely to be men. However, women predominate in most statistics of asthma morbidity and mortality, making up about 60% of deaths and SLTA 1 , 32-37 and a greater proportion of hospital admissions (up to 75% 18 ), although not all series of asthma death 6 and of near fatal asthma 38 , 39 have shown a predominance of women. We have recently reported a predominance of men in those presenting with rapid onset asthma and who are more likely to have SLTA. 29 This may be a partial explanation for the relative predominance of men in the SLTA cases. However, sex is not a particularly useful clinical criteria for identifying patients at increased risk of SLTA. Similarly, although there is a statistically significant increased risk of SLTA with increasing age, even within the limited age range studied, an odds ratio of 1.04 per year age is not likely to represent a useful discriminator for identifying patients at increased risk of SLTA or death. These factors were controlled for in all further analyses.

Previous SLTA and recent admission to hospital were risk factors for SLTA whether the comparison was made with matched hospital controls or the community comparison group. This is consistent with previous results from our group 4-6 and the case-control study of Turner et al , 39 which was smaller but of similar design to the current study. Risk stratification, even within the group admitted to hospital with acute severe asthma, can therefore be undertaken on the basis of previous SLTA and recent admission to hospital. This is of considerable relevance to all doctors managing patients with acute exacerbations of asthma.

Poor quality and/or fragmented ongoing health care is a potential remediable factor in asthma death 6 , 9 , 10 , 13-17 and life threatening asthma. 18 , 32 , 38 One of the postulated reasons for the dramatic decline in asthma morbidity and mortality in New Zealand over the last decade is an improvement in the quality of, and access to, primary health care—both ongoing and emergency care. 11 , 12 In a previous cross sectional study of patients admitted to hospital with acute asthma we found evidence of generally good quality, ongoing, asthma specific medical care 18 but we hypothesised that poor quality care might still be a risk factor for SLTA. However, our results showed that, compared with matched hospital controls, cases with SLTA did not differ in any of the indices of quality of ongoing medical care. Data on quality of health care were not available for the community group and the possibility still exists that deficiencies in health care may operate to increase the risk of an acute attack and admission to hospital, although not increasing the risk of SLTA per se.

Barriers to health care may take a variety of forms—for example, physical inaccessibility, financial barriers, and attitudinal factors. Inaccessibility to health care is one of the reasons why asthma deaths and SLTA are more likely to occur outside usual working hours. 1 Jones and Bentham 40 showed that geographical barriers to acute hospital services were an independent risk factor for asthma death, although this association was based on population statistics rather than on data of individuals with asthma. In the current study none of the geographical or organisational factors differed significantly between SLTA cases and hospital controls. Indeed, the data in table 3 argue against an important role for physical barriers in both groups. Analysis of the reasons for difficulty in managing the index attack (table 4 ) suggests that non-availability of a telephone or a car was not an issue for >90% of patients in both groups. However, the current study was undertaken in an urban region, albeit a sprawling one, and thus the results may not be applicable to other regions, particularly if they contain a substantial rural population.

The results of this study do not support the contention that financial barriers to health care are a risk factor for SLTA when comparison is made with hospital controls. This does not imply that financial barriers are not important and operational in patients with asthma, merely that they influence both of these groups in a similar fashion. This is shown in table 3 by the considerable differences between the community group and both cases and hospital controls in terms of general and asthma specific financial factors. We have recently demonstrated a very close relationship between hospital admissions, SLTA and asthma death and an index of socioeconomic deprivation (SED) in the Auckland region. 41 There was a stronger influence of SED on the more severe undesirable adverse outcomes. Although there are no differences between cases (SLTA) and hospital controls in any of the indicators of socioeconomic status, both groups had evidence of significant socioeconomic disadvantage (consistent with results of a previous cross sectional study of patients admitted with acute asthma 18 ).

Successful management of a chronic illness such as asthma requires the establishment of a therapeutic alliance and partnership between the patient and doctor. Deficiencies in this relationship have adverse effects on the acquisition of self-management knowledge and patient self-management behaviour during an acute attack. 19 , 20 The doctor's level of sensitivity to the emotional needs of the asthmatic patient may influence clinical decisions; doctors too much in tune with the patient's psychological distress tended to overtreat while doctors who paid inadequate attention to such issues discharged inappropriately early. 42 In this study all indications were that there was generally an excellent relationship between the patient and the doctor regarded as most important in the management of their asthma, and no evidence that the quality of the doctor-patient relationship was an identifiable risk factor for SLTA.

Factors related to patient self-management strategies shortly before and during the index attack were significantly associated with the risk of SLTA, those with SLTA being (1) less likely to have used inhaled corticosteroids in the two weeks before the index attack, (2) more likely to have used oral theophylline, (3) less likely to have monitored peak flow, and (4) less likely to have appropriately used oral corticosteroids during the acute attack. In part, these results are consistent with our previous results which showed a high rate of errors in the management of severe attacks of asthma, the errors being generally made by the patient rather than the doctor and more likely to occur in relation to strategies that may abort the attack or be potentially life saving. 20 We have also shown considerable disparity between the patients' knowledge of what to do in the event of an acute attack and what is acutely done—that is, their behaviour. 19 The patients' self-management knowledge, their behaviour during an acute attack, and self-management errors are all influenced by a variety of socioeconomic and health care factors. 19 , 20 , 25 Thus, while deficiencies in quality of ongoing asthma care have been cited as a cause of SLTA/asthma death, 1-10 efforts directed towards improving patient self-management of acute exacerbations of asthma may be more likely to produce improved outcomes in terms of reductions in asthma mortality and severe morbidity, and should be the focus of intervention strategies and be an essential component of asthma education. 43

The results of this study raise issues about the perceived role of the general practitioner in the management of acute severe asthma. Cases with SLTA were more likely to present directly to an emergency department or to call an ambulance; only 29% presented initially to the general practitioner compared with 51% of hospital controls. Similar reliance on emergency departments was noted in the study by Turner et al . 39 This behaviour would seem entirely appropriate in the context of a more severe attack of asthma. However, few attacks leading to hospital are rapid (<6 hours) 30 and the behaviour during the index attack is reflected in the responses to questions on the previous management of nocturnal exacerbations of asthma; only 4% of those who presented with SLTA and 7% of hospital controls had telephoned their general practitioner during previous acute episodes. Perhaps most disturbing is the fact that, on previous occasions, over 80% had not summoned any form of help nor sought any advice. Previous studies have shown that, in the event of an acute attack of asthma, there were delays in summoning emergency services 20 and also delays in attendance at the emergency department; the latter was indicated by more severe asthma on presentation in Auckland than in Toronto. 44 This underuse of primary health care, particularly after hours when there may be organisational and other barriers to community care, was one of the factors thought to contribute to asthma morbidity and mortality in New Zealand. 1 , 9-12 These data seem to reflect a perception by the patient of a lack of role for the general practitioner in the management of acute asthma. This may be appropriate in the event of a rapid onset or very severe attack (along with the lower rate of use of a peak flow meter), but may also be influenced by the perceived availability of general practitioners after hours and of other barriers to acute health care (including financial, as primary health care is delivered on a fee-for-service basis in New Zealand). Such patient behaviour needs to be considered when providing advice to individual patients and when devising acute asthma management guidelines. Unfortunately, a similar situation seems to exist for patients admitted to hospital with chronic obstructive pulmonary disease (COPD) as only 25% had sought medical help from their general practitioner in the two weeks before admission. 45

One of the major aims of asthma education is to increase patients' self-management knowledge and skills, 19 , 25 although this does not necessarily translate into improved self-management behaviour. 19 , 20 In this study there were no differences between cases and controls in the total scores for self-management knowledge (table 5 ) although scores for both groups were higher than those obtained from a community based comparison group (data not presented). This suggests that educational strategies directed solely at increasing patient knowledge are unlikely to reduce the risk of SLTA. A critical component of self-management educational initiatives is instruction on action to be undertaken in the event of an acute attack, specifically the indications for use of oral corticosteroids. Delay or non-use of oral corticosteroids was a risk factor for SLTA, thus reinforcing the importance of that single piece of advice in attempts to reduce serious asthma morbidity.

Inhaled corticosteroids are the linchpin of preventive therapy in adult asthma; these agents modulate the inflammatory response in airways, 46-49 reduce the level of airway responsiveness, 50-52 improve various parameters of asthma control, 52-54 and reduce asthma morbidity. 55 Although we have previously shown that the use of all forms of asthma drugs was associated with increased risk of death or SLTA, and that confounding by severity was present, it was only for higher doses of inhaled steroids that the risk ratio (RR) for SLTA or death fell below 1 after adjustment for multiple severity indicators. 5 Other pharmacoepidemiological studies have reported similar findings of a reduced risk of adverse outcomes in association with the use of inhaled corticosteroids. 56 , 57 Although the rate of use of inhaled corticosteroids was much higher than in the Canadian study of Turner et al , 39 this study showed that it was recent use (within two weeks) and not prescribed use that was associated with the reduced risk of a serious adverse event. In view of the similarities in most other respects between the cases and matched hospital controls, these data suggest that recent use of inhaled corticosteroids may prevent SLTA. The importance of the distinction between prescribed and actual use of medications is also highlighted.

In pharmacoepidemiological studies theophylline has been consistently associated with an increased OR for serious adverse events 5 , 56 , 57 and, even after adjusting for multiple severity markers, the OR remained significantly raised. 5 While this may be due to residual confounding (with theophylline use being a marker of poorly controlled asthma for whatever reason or inappropriate medical management), direct or indirect effects of the drug are not excluded. Whatever the mechanism and whatever the indication for administration, the results of this study support the contention that the use of oral theophylline does indicate a patient at increased risk of a serious adverse event.

The lack of information in the literature regarding the possible impact of panic by the patient during the acute attack reflects the general paucity of research in the area of patient behaviour, especially at times when self-management decisions are most crucial. High rates of anxiety, not necessarily related to acute exacerbations, are well documented in those with severe asthma 19 , 43 and have been shown to be associated with higher rates of hospitalisation and greater use of “as required” medication and oral steroids. 58 It has been suggested that symptoms of panic/fear occurring during an attack of asthma may lead to more inappropriate action by the patient. 59 , 60 While heightened awareness may help to focus the patient on making correct self-management decisions, a high level of anxiety/fear may incapacitate the patient and lead to no action rather than incorrect but deliberate action, precisely what was found to occur in this study and in previous studies. 19 , 20

In this study patients admitted to hospital with an acute attack of asthma were used as controls, thus allowing interview of both cases and controls using the same procedure and controlling to a large extent for the impact of the acute exacerbation, drug treatment, and the effect of hospitalisation. Matching, apart from date of attack and hospital of presentation, was not undertaken as it was argued that some of the features traditionally matched for may be significant risk factors. As it turned out, this was entirely appropriate as both age and sex were statistically significant risk factors and were controlled for in all subsequent analyses. While the use of patients admitted acutely to hospital to a large extent controls for severity of asthma 4 , 5 and the effects of acute treatment, the use of hospital controls may represent “over-matching”—that is, the cases and controls were both derived from the same subgroup of asthmatic patients and hence were unlikely to differ in measurable ways. However, the major consideration in the choice of controls was the highly relevant clinical aim to distinguish those at highest risk of SLTA (and death) from the larger group of patients admitted acutely to hospital, rather than distinction from the much larger population of community based asthmatics. In other words, we aimed to distinguish between risk factors for SLTA and risk factors for hospitalisation for acute asthma. Most patients who die of asthma or experience SLTA have had contact with hospital services in the previous year and thus present an opportunity for intervention. 4-6 Furthermore, any intervention strategies to reduce morbidity and mortality would be likely be hospital based, at least initially.

It has been argued that patients with SLTA to some extent represent a population of survivors and are thus a highly biased sample. 8 However, during the conduct of this study there were only four asthma deaths in this age range in the region and thus the cases in this study are a reasonably unbiased population of all patients having very severe attacks in the region.

Suitable controls in a case-control study should accurately reflect that population from which the cases were derived. However, obtaining a random sample of patients having an acute exacerbation of asthma in the community presented insurmountable logistical difficulties, not only because of the range of sources of acute health care in New Zealand but also because a substantial proportion of patients do not obtain medical help for an acute attack which occurs outside usual working hours (table 5 ). The conduct of an epidemiological study of asthma prevalence 22 provided the opportunity to obtain a random sample of community based asthmatic subjects to provide normative data for some of the instruments used and for comparison with the cases and controls. This comparison reinforced the fact that community based asthmatic subjects differ markedly from those who are admitted to hospital with acute asthma.

Although not a primary aim, this study provides data on risk factors for admission to hospital for acute asthma; these included non-European ethnicity, socioeconomic deprivation (either general or directly related to asthma, confirming our previous results 18 , 40 ), more severe asthma, previous SLTA, and recent admission to hospitals or presentation at the emergency department. This highlights the fact that risk factors for death (and SLTA) may differ according to the control subgroup studied, an important consideration in discussions relating to controlling for severity in the debate about the relationship between fenoterol and asthma deaths. 4-6

Thus, in comparison with patients admitted to hospital with acute severe asthma, those with SLTA are (1) indistinguishable on sociodemographic criteria (apart from relative male predominance), (2) are more likely to have had previous SLTA or hospital admission in the last year, (3) have similar quality ongoing asthma care, (4) have no evidence of physical, economic, or other barriers to health care, and (5) have demonstrable deficiencies in management shortly before and during the index attack in terms of being more likely to have been using oral theophylline, less prior use of inhaled corticosteroids, less likely to have monitored PEF and to have appropriately used oral steroids during the attack.

These findings have major implications for asthma education and management. Following an acute attack, particularly one of sufficient severity to necessitate admission to hospital, it is important to review carefully the patients' self-management strategies, to identify errors particularly of omission or delays in undertaking appropriate action, and to institute corrective advice. Educational strategies, while not losing sight of the need for good quality ongoing care, need to focus more on providing individual patients with rational, relevant, and realistic advice on self-management of acute exacerbations and this advice needs to be repeatedly reinforced and refined—the “5 Rs” of asthma education.

Acknowledgments

The authors wish to thank the medical nursing and other staff of the general medical wards and intensive care units of the Auckland hospitals for their assistance and cooperation during the conduct of this study. We also thank Mrs Josephine Ratnasabapathy for her patience and diligence in preparing the manuscript. We are extremely grateful to Joanna Stewart for her assistance in performing the statistical analyses and to Dr Julian Crane for assistance in the recruitment of the community comparison group.

Richards GN ,
Fenwick J ,
Marquette CH ,
Sauliner F ,
Spitzer WO ,
Garrett JE ,
Jackson R ,
Barnes PJ ,
Jansson B ,
Beasley R ,
Beaglehole R ,
Beaglehole R
Garrett J ,
Richards G ,
Westerman DE ,
Benatar SR ,
Potgieter PD ,
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MacDonald JB ,
Williams DA
Miller BD ,
Fergusson W
Fergusson W ,
Sibbald B ,
Collier J ,
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Rubinfeld AR ,
↵ Kolbe J, Fergusson W, Vamos M, et al . Case-control study of severe life-threatening asthma (SLTA) in adults: psychological factors. Thorax 2000; 55 :(in review).
Benator SR ,
Cochrane GM ,
Ormerod LP ,
Stableforth DE
Wasserfallen JB ,
Schaller MD ,
Wareham NJ ,
Harrison BDW ,
Jenkins PF ,
Campbell DA ,
McLennan G ,
Turner MO ,
Noertjojo K ,
↵ Garrett JE, Poyser M, Kolbe J. The relationship between social and economic deprivation and asthma morbidity/mortality in New Zealand. Eur Respir J 1999; 12 (abstract).
Horton DJ ,
Kinsman RA ,
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Manolitsais ND ,
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Haaktela T ,
Jarvinen M ,
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Livingstone JM ,
Burgess C ,
Thiruchelvan R ,
Staudenmeyer H ,

Funding: This study was supported by grants from Lottery Health Research and New Zealand Health Research Council.

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StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2024 Jan-.

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Case study: 33-year-old female presents with chronic sob and cough.

Sandeep Sharma ; Muhammad F. Hashmi ; Deepa Rawat .

Affiliations

Last Update: February 20, 2023 .

Case Presentation

History of Present Illness: A 33-year-old white female presents after admission to the general medical/surgical hospital ward with a chief complaint of shortness of breath on exertion. She reports that she was seen for similar symptoms previously at her primary care physician’s office six months ago. At that time, she was diagnosed with acute bronchitis and treated with bronchodilators, empiric antibiotics, and a short course oral steroid taper. This management did not improve her symptoms, and she has gradually worsened over six months. She reports a 20-pound (9 kg) intentional weight loss over the past year. She denies camping, spelunking, or hunting activities. She denies any sick contacts. A brief review of systems is negative for fever, night sweats, palpitations, chest pain, nausea, vomiting, diarrhea, constipation, abdominal pain, neural sensation changes, muscular changes, and increased bruising or bleeding. She admits a cough, shortness of breath, and shortness of breath on exertion.

Social History: Her tobacco use is 33 pack-years; however, she quit smoking shortly prior to the onset of symptoms, six months ago. She denies alcohol and illicit drug use. She is in a married, monogamous relationship and has three children aged 15 months to 5 years. She is employed in a cookie bakery. She has two pet doves. She traveled to Mexico for a one-week vacation one year ago.

Allergies: No known medicine, food, or environmental allergies.

Past Medical History: Hypertension

Past Surgical History: Cholecystectomy

Medications: Lisinopril 10 mg by mouth every day

Physical Exam:

Vitals: Temperature, 97.8 F; heart rate 88; respiratory rate, 22; blood pressure 130/86; body mass index, 28

General: She is well appearing but anxious, a pleasant female lying on a hospital stretcher. She is conversing freely, with respiratory distress causing her to stop mid-sentence.

Respiratory: She has diffuse rales and mild wheezing; tachypneic.

Cardiovascular: She has a regular rate and rhythm with no murmurs, rubs, or gallops.

Gastrointestinal: Bowel sounds X4. No bruits or pulsatile mass.

Initial Evaluation

Laboratory Studies: Initial work-up from the emergency department revealed pancytopenia with a platelet count of 74,000 per mm3; hemoglobin, 8.3 g per and mild transaminase elevation, AST 90 and ALT 112. Blood cultures were drawn and currently negative for bacterial growth or Gram staining.

Chest X-ray

Impression: Mild interstitial pneumonitis

Differential Diagnosis
Aspiration pneumonitis and pneumonia
Bacterial pneumonia
Immunodeficiency state and Pneumocystis jiroveci pneumonia
Carcinoid lung tumors
Tuberculosis
Viral pneumonia
Chlamydial pneumonia
Coccidioidomycosis and valley fever
Recurrent Legionella pneumonia
Mediastinal cysts
Mediastinal lymphoma
Recurrent mycoplasma infection
Pancoast syndrome
Pneumococcal infection
Sarcoidosis
Small cell lung cancer
Aspergillosis
Blastomycosis
Histoplasmosis
Actinomycosis
Confirmatory Evaluation

CT of the chest was performed to further the pulmonary diagnosis; it showed a diffuse centrilobular micronodular pattern without focal consolidation.

On finding pulmonary consolidation on the CT of the chest, a pulmonary consultation was obtained. Further history was taken, which revealed that she has two pet doves. As this was her third day of broad-spectrum antibiotics for a bacterial infection and she was not getting better, it was decided to perform diagnostic bronchoscopy of the lungs with bronchoalveolar lavage to look for any atypical or rare infections and to rule out malignancy (Image 1).

Bronchoalveolar lavage returned with a fluid that was cloudy and muddy in appearance. There was no bleeding. Cytology showed Histoplasma capsulatum .

Based on the bronchoscopic findings, a diagnosis of acute pulmonary histoplasmosis in an immunocompetent patient was made.

Pulmonary histoplasmosis in asymptomatic patients is self-resolving and requires no treatment. However, once symptoms develop, such as in our above patient, a decision to treat needs to be made. In mild, tolerable cases, no treatment other than close monitoring is necessary. However, once symptoms progress to moderate or severe, or if they are prolonged for greater than four weeks, treatment with itraconazole is indicated. The anticipated duration is 6 to 12 weeks total. The response should be monitored with a chest x-ray. Furthermore, observation for recurrence is necessary for several years following the diagnosis. If the illness is determined to be severe or does not respond to itraconazole, amphotericin B should be initiated for a minimum of 2 weeks, but up to 1 year. Cotreatment with methylprednisolone is indicated to improve pulmonary compliance and reduce inflammation, thus improving work of respiration. [1] [2] [3]

Histoplasmosis, also known as Darling disease, Ohio valley disease, reticuloendotheliosis, caver's disease, and spelunker's lung, is a disease caused by the dimorphic fungi Histoplasma capsulatum native to the Ohio, Missouri, and Mississippi River valleys of the United States. The two phases of Histoplasma are the mycelial phase and the yeast phase.

Etiology/Pathophysiology

Histoplasmosis is caused by inhaling the microconidia of Histoplasma spp. fungus into the lungs. The mycelial phase is present at ambient temperature in the environment, and upon exposure to 37 C, such as in a host’s lungs, it changes into budding yeast cells. This transition is an important determinant in the establishment of infection. Inhalation from soil is a major route of transmission leading to infection. Human-to-human transmission has not been reported. Infected individuals may harbor many yeast-forming colonies chronically, which remain viable for years after initial inoculation. The finding that individuals who have moved or traveled from endemic to non-endemic areas may exhibit a reactivated infection after many months to years supports this long-term viability. However, the precise mechanism of reactivation in chronic carriers remains unknown.

Infection ranges from an asymptomatic illness to a life-threatening disease, depending on the host’s immunological status, fungal inoculum size, and other factors. Histoplasma spp. have grown particularly well in organic matter enriched with bird or bat excrement, leading to the association that spelunking in bat-feces-rich caves increases the risk of infection. Likewise, ownership of pet birds increases the rate of inoculation. In our case, the patient did travel outside of Nebraska within the last year and owned two birds; these are her primary increased risk factors. [4]

Non-immunocompromised patients present with a self-limited respiratory infection. However, the infection in immunocompromised hosts disseminated histoplasmosis progresses very aggressively. Within a few days, histoplasmosis can reach a fatality rate of 100% if not treated aggressively and appropriately. Pulmonary histoplasmosis may progress to a systemic infection. Like its pulmonary counterpart, the disseminated infection is related to exposure to soil containing infectious yeast. The disseminated disease progresses more slowly in immunocompetent hosts compared to immunocompromised hosts. However, if the infection is not treated, fatality rates are similar. The pathophysiology for disseminated disease is that once inhaled, Histoplasma yeast are ingested by macrophages. The macrophages travel into the lymphatic system where the disease, if not contained, spreads to different organs in a linear fashion following the lymphatic system and ultimately into the systemic circulation. Once this occurs, a full spectrum of disease is possible. Inside the macrophage, this fungus is contained in a phagosome. It requires thiamine for continued development and growth and will consume systemic thiamine. In immunocompetent hosts, strong cellular immunity, including macrophages, epithelial, and lymphocytes, surround the yeast buds to keep infection localized. Eventually, it will become calcified as granulomatous tissue. In immunocompromised hosts, the organisms disseminate to the reticuloendothelial system, leading to progressive disseminated histoplasmosis. [5] [6]

Symptoms of infection typically begin to show within three to17 days. Immunocompetent individuals often have clinically silent manifestations with no apparent ill effects. The acute phase of infection presents as nonspecific respiratory symptoms, including cough and flu. A chest x-ray is read as normal in 40% to 70% of cases. Chronic infection can resemble tuberculosis with granulomatous changes or cavitation. The disseminated illness can lead to hepatosplenomegaly, adrenal enlargement, and lymphadenopathy. The infected sites usually calcify as they heal. Histoplasmosis is one of the most common causes of mediastinitis. Presentation of the disease may vary as any other organ in the body may be affected by the disseminated infection. [7]

The clinical presentation of the disease has a wide-spectrum presentation which makes diagnosis difficult. The mild pulmonary illness may appear as a flu-like illness. The severe form includes chronic pulmonary manifestation, which may occur in the presence of underlying lung disease. The disseminated form is characterized by the spread of the organism to extrapulmonary sites with proportional findings on imaging or laboratory studies. The Gold standard for establishing the diagnosis of histoplasmosis is through culturing the organism. However, diagnosis can be established by histological analysis of samples containing the organism taken from infected organs. It can be diagnosed by antigen detection in blood or urine, PCR, or enzyme-linked immunosorbent assay. The diagnosis also can be made by testing for antibodies again the fungus. [8]

Pulmonary histoplasmosis in asymptomatic patients is self-resolving and requires no treatment. However, once symptoms develop, such as in our above patient, a decision to treat needs to be made. In mild, tolerable cases, no treatment other than close monitoring is necessary. However, once symptoms progress to moderate or severe or if they are prolonged for greater than four weeks, treatment with itraconazole is indicated. The anticipated duration is 6 to 12 weeks. The patient's response should be monitored with a chest x-ray. Furthermore, observation for recurrence is necessary for several years following the diagnosis. If the illness is determined to be severe or does not respond to itraconazole, amphotericin B should be initiated for a minimum of 2 weeks, but up to 1 year. Cotreatment with methylprednisolone is indicated to improve pulmonary compliance and reduce inflammation, thus improving the work of respiration.

The disseminated disease requires similar systemic antifungal therapy to pulmonary infection. Additionally, procedural intervention may be necessary, depending on the site of dissemination, to include thoracentesis, pericardiocentesis, or abdominocentesis. Ocular involvement requires steroid treatment additions and necessitates ophthalmology consultation. In pericarditis patients, antifungals are contraindicated because the subsequent inflammatory reaction from therapy would worsen pericarditis.

Patients may necessitate intensive care unit placement dependent on their respiratory status, as they may pose a risk for rapid decompensation. Should this occur, respiratory support is necessary, including non-invasive BiPAP or invasive mechanical intubation. Surgical interventions are rarely warranted; however, bronchoscopy is useful as both a diagnostic measure to collect sputum samples from the lung and therapeutic to clear excess secretions from the alveoli. Patients are at risk for developing a coexistent bacterial infection, and appropriate antibiotics should be considered after 2 to 4 months of known infection if symptoms are still present. [9]

Prognosis

If not treated appropriately and in a timely fashion, the disease can be fatal, and complications will arise, such as recurrent pneumonia leading to respiratory failure, superior vena cava syndrome, fibrosing mediastinitis, pulmonary vessel obstruction leading to pulmonary hypertension and right-sided heart failure, and progressive fibrosis of lymph nodes. Acute pulmonary histoplasmosis usually has a good outcome on symptomatic therapy alone, with 90% of patients being asymptomatic. Disseminated histoplasmosis, if untreated, results in death within 2 to 24 months. Overall, there is a relapse rate of 50% in acute disseminated histoplasmosis. In chronic treatment, however, this relapse rate decreases to 10% to 20%. Death is imminent without treatment.

Pearls of Wisdom

While illnesses such as pneumonia are more prevalent, it is important to keep in mind that more rare diseases are always possible. Keeping in mind that every infiltrates on a chest X-ray or chest CT is not guaranteed to be simple pneumonia. Key information to remember is that if the patient is not improving under optimal therapy for a condition, the working diagnosis is either wrong or the treatment modality chosen by the physician is wrong and should be adjusted. When this occurs, it is essential to collect a more detailed history and refer the patient for appropriate consultation with a pulmonologist or infectious disease specialist. Doing so, in this case, yielded workup with bronchoalveolar lavage and microscopic evaluation. Microscopy is invaluable for definitively diagnosing a pulmonary consolidation as exemplified here where the results showed small, budding, intracellular yeast in tissue sized 2 to 5 microns that were readily apparent on hematoxylin and eosin staining and minimal, normal flora bacterial growth.

Enhancing Healthcare Team Outcomes

This case demonstrates how all interprofessional healthcare team members need to be involved in arriving at a correct diagnosis. Clinicians, specialists, nurses, pharmacists, laboratory technicians all bear responsibility for carrying out the duties pertaining to their particular discipline and sharing any findings with all team members. An incorrect diagnosis will almost inevitably lead to incorrect treatment, so coordinated activity, open communication, and empowerment to voice concerns are all part of the dynamic that needs to drive such cases so patients will attain the best possible outcomes.

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Histoplasma Contributed by Sandeep Sharma, MD

Disclosure: Sandeep Sharma declares no relevant financial relationships with ineligible companies.

Disclosure: Muhammad Hashmi declares no relevant financial relationships with ineligible companies.

Disclosure: Deepa Rawat declares no relevant financial relationships with ineligible companies.

This book is distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0) ( http://creativecommons.org/licenses/by-nc-nd/4.0/ ), which permits others to distribute the work, provided that the article is not altered or used commercially. You are not required to obtain permission to distribute this article, provided that you credit the author and journal.

Cite this Page Sharma S, Hashmi MF, Rawat D. Case Study: 33-Year-Old Female Presents with Chronic SOB and Cough. [Updated 2023 Feb 20]. In: StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2024 Jan-.

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