Asthma and Chronic Obstructive Pulmonary Disease (COPD) in Medical Emergency :

 

Asthma is a common chronic affliction with wide clinical variability. Though most patients have mild disease, asthma can be rapidly fatal. Patients with COPD often present in distress, expending tremendous effort to combat hypoxia. Uncomplicated medical or surgical disease will become more serious or life-threatening as the impact of COPD is unmasked.

Clinical Features:

Asthma is defined as reversible airway obstruction, associated with hyper-responsiveness of the tracheobronchial tree. An early component of an asthmatic attack is the bronchial smooth-muscle contraction. Bronchial inflammation, edema, and mucus hypersecretion become more prominent as the attack progresses. Increased airway resistance leads to air trapping, increased airway pressures, ventilation-perfusion imbalance, increased work of breathing, hypoxemia and, in severe cases, hypercapnia. Although bronchospasm can be reversed within minutes, mucus plugging and inflammatory changes do not resolve for days, steroid-dependent patients, and those with prior attacks requiring intubation are at higher risk for respiratory failure.

The most common aetiology of COPD is cigarette smoking. Other causes include environmental toxins, genetic aberrations, and sustained bronchospastic airflow obstruction. There are two dominant clinical forms of COPD:

1.       Pulmonary emphysema, characterized by abnormal, permanent enlargement and destruction of the air spaces distal to the terminal bronchioles.

2.       Chronic bronchitis, a condition of excess mucus secretion in the bronchial tree, occurring on most days for at least 3 months in the year for at least 2 consecutive years. Elements of both forms are often present, though one predominates. Airway resistance, especially to expiration is the fundamental feature of either condition. Hypoxemia and hypercapnia result from ventilation-perfusion mismatches and alveolar hypoventilation. As COPD progresses, neuro-chemical and proprioceptive ventilatory responses become aberrant. Pulmonary arterial hypertension develops leading to right ventricular hypertrophy and cor pulmonale. Clinically, compensated patients present with exertional dyspnea, chronic productive coughs (frequently with minor hemoptysis) and expiratory wheezing. Coarse crackles are heard in patients with primary bronchitic disease. An expanded thorax, impeded diaphragmatic motion, and diminished breath sounds are noted in those with emphysema.

A  Acute exacerbation of asthma / COPD are usually due to increased bronchospasm, smoking an d exposure to other noxious stimuli, adverse response to medication such as antihistamines decongestants, beta-blockers, and hypnotic tranquilizers; allergic reactions, and noncompliance with prescribed therapies. Respiratory infection, pneumothorax, myocardial infarction, dysrhythmias, pulmonary edema, chest trauma, metabolic disorders, and abdominal processes are triggers and complication s of asthma / COPD. Patients with exacerbations of asthma / COPD present complaining of dyspnea, chest tightness, wheezing, and coughs. Physical examination reveals wheezing with prolonged expiration. Wheezing does not correlate with degree of airflow obstruction. A ‘quite chest’ indicates severe airflow restriction. Patients and physicians often underestimate the severity of attacks. Patients with severe attacks may demonstrate sitting-up-and-forward posturing, pursed -lip exhalation, accessory muscle use, paradoxical respirations, and diaphoresis. Pulsus paradoxicus of 20 mmHg or more may be noted. Hypoxia is characterized by tachypnea, cyanosis, agitation, apprehension, tachycardia, and hypertension. Signs of hypercapnia include confusion, tremor, plethora, stupor, hypernea, and apnea.

Diagnosis and Differential

ED diagnosis of asthma / COPD usually is made clinically. The clinician should attempt to determine the severity of the attack and the presence of complications. Objective measurements of airflow obstruction, such as peak expiratory flow rate, have been shown to be more accurate than clinical judgement in determining the severity of the attack, and the response to therapy. Laboratory examinations should be used selectively, chest w-ray is used to diagnose complications such as pneumonia and pneumothorax, arterial blood gases should not be obtained routinely. Arterial blood gases (ABGs) serve primarily to evaluate hypercapnia in moderate-to-severe attacks.  Hypoxia can usually be evaluated by pulse oximetry. ABG results should be interpreted in light of the total clinical picture. Compensated hypercapnia and hypoxia is common in COPD patients, therefore, comparison with previous ABG’s is helpful. Normocarbia in the setting of an acute asthmatic attack is an ominous finding if the patient is doing poorly. An arterial pH below that consistent with renal compensation implies either acute hypercarbia that consistent with renal compensation implies either acute hypercarbia or metabolic acidosis. ECG are useful to identify arrhythmias or ischemic injury. Measurement s of methylxanthine levels should be obtained.

The differential diagnosis of decompensated asthma / COPD includes many of the disorders  listed above as complications. In addition, interstitial lung diseases, pulmonary neoplasia, aspirated foreign bodies, pleural effusions, and exposure to asphyxiants must be considered.

 

Managenment and Emergency Care:

Although patients with COPD often have more than underlying illnesses than asthmatic, therapy for acute bronchospasm and inflammation is similar. Treatment should precede history-taking in acute dyspneic patients, as the patient may decompensate rapidly.  These patients should be placed on a cardiac monitor, noninvasive BP device, and have continuous pulse oximetry. An intravenous line should be started in patients moderate and severe attacks. The primary goal of therapy is to correct tissue oxygenation.

1.       Hypoxemia is nearly universal during asthmatic attacks. Therefore, empiric supplemental oxygen should be administered. The need for supplemental oxygen with COPD must be balanced against the suppression of hypoxic ventilatory drive. Arterial saturation should be corrected above 90 %.

2.       Beta-adrenergic agonists produce prompt effects and are the drugs of choice to treat bronchospasm. Aerosolized or parental forms should be used in critical settings. Aerosol therapy minimize systemic toxicity and is preferred. Albuterol sulphate, 1.25 to 5 mg. and metaproterenol, 10 to 15 mg are the most beta2 -specific agents. Iso-etharine, 2.5 to 5 mg or bitolterol mesylate, 0.5 to 1.5 mg can also be delivered by nebulizer. Delivering doses in rapid succession maximizes results. Frequency of dosing depends on clinical response and signs of drug toxicity =. Metered dose inhalers with space devices may be reasonable to use in ill patients. Subcutaneous terbutaline sulphate (0.25 – 0.5 ml) or adrenaline 1:1000 (0.1 – 0.3 mL) may also be administered. Adrenalin should be avoided in the first trimester of pregnancy and possibly in patients with underlying cardiovascular disorder. Beta -adrenergic agonists may inhibit uterine contraction when used near term of pregnancy.

3.       Systematic glucocorticoids elicit bronchodilator response, facilitate the actions of concurrently given beta-agonists and methylxanthines, and have anti-inflammatory effects. As the onset of action may take hours, they should be given early in the course of treatment.

 

See my experience using reflexology on a young Malay girl with status asthmaticus during the course of my work in an isolated village here:

 

https://scientificlogic.blogspot.com/search?q=a+miracle+before+my+eyes

 

Once you get to this site, scroll right down to the paragraph on:

 

“Another Medical Emergency”

 

where I found natural therapy by merely massaging the soles of her feet worked much faster and more efficiently in a medical emergency than using any bronchodilators, e,g.  beta 2-agonists, anticholinergics and theophylline or other drugs described here.

 

Steroids should be given immediately to patients with severe attacks, as well as patients who are currently taking, or have recently taken, these drugs. The optimal daily dose is the equivalent of 60 to 180 mg of Prednisone day, with an initial dose being equivalent of 60 to 80 mg prednisone. The choice of steroid is not critical. If the patient is unable to take oral medication, use methylprednisolone 125 mg IV. Hydrocortisone should be avoided, however because of excess mineralocorticoid effect. Inhaled steroids are extremely useful in the treatment of chronic asthma / COPD, but should not be used in the treatment of acute symptoms.

 

4.       Anticholinergics are useful adjuvants when given with other therapies. Ipratropium bromide has recently replaced nebulized atropine sulphate (1 – 3.5 mg) and glycopyrrolate (0.2 – 1 mg) as the agent of choice. Nebulized iprotropium (500 mg = 2.5 ml) may be administered either alone or mixed with albuterol. Iprotroprium is available as a metered dose inhaler. The effects of iprotroprium peak in 1 in 2 hours and last for 3 to 4 hours.  Dosages may be repeated every 1 to 4 hours When used with beta-agonist agents, effects may be additive. The use of nebulized anticholinergics has been reported to cause attacks of narrow angle glaucoma due to tropical ophthalmic absorption.

5.       The role of methylxanthines in the treatment of acute asthma has been seriously challenged. Theophylline produces less bronchodilation than beta-adrenergic agents. In addition, studies have shown that when used in combination with inhaled beta-adrenergic agents, theophylline increases toxicity but not efficac7y of the therapy. Although methylxanthines are no longer the first-line drugs, some patients not responding to beta-agonists and steroids may benefit from the addition of theophylline. Methylxanthines seem to have more of a role of theophylline in the treatment of chronic, stable asthma. The efficacy of methylxanthines in COPD is still controversial. The loading dose of theophylline is 5 to 6 mg / kg ideal body weight. In patients previously medicated, a mini load should be given. The mini-load is calculated as (target concentration – measured concentration ) x (0.5 x ideal body weight in litres). The maintenance dose is 0.2 to 0.8 mg / kg ideal body weight. These dosages should be used as guidelines.  Metabolism of methylxanthines is highly variable. Increased serum levels are associated with liver disease, CHF , cor pulmonale, viral respiratory infections, advanced age, cimetidine, erythromycin, oral contraceptives, and allopurinol. Decreased levels are seen with cigarette smoking, phenobarbital, phenytoin, large consumption of charcoaled beef, and factors that promote the hepatic P450 enzyme system. Toxicity can be severe and can occur at drug level that fall within normal range. Serum levels should be measured to guide appropriate therapy.

6.       Broad spectrum antibiotics such as TMP / SMX DS bd, or doxycycline 100 mg bid, or others are indicated for the treatment of bacterial respiratory infections. Preventive polyvalent pneumococcal and trivalent influenza vaccination may be administered to stabile COPD patients.

7.       Although some authors have reported that 1 to 2 gm of intravenous magnesium sulphate reduces bronchospasm, no consistent clinical benefit has been demonstrated.

8.       Sedatives, hypnotics, and other medication which depresses respiratory drive are generally contraindicated. Beta-blockers may exacerbate bronchospasms. Antihistamines and decongestants should also be avoided as they diminish the ability to clear respiratory secretions. Mucolytics may provoke further bronchospasm. The benefit of iodides and glyceryl guaicolates in asthma and doxapram in COPD are unproven. Many asthmatics respond poorly to ultrasonic nebulization and IPPB.

If all these standard Treatment fails, what should we do?

Assisted mechanical ventilation is indicated for inability to maintain oxygen saturation above 90 %, or severe hypercarbia associated with stupor, narcosis, or acidosis. In selected patients, non-invasive, positive-pressure ventilation (Bi-PAP) may avert artificial  ventilation. Oral intubation is preferred as large endotracheal tubes can be used. Large tubes facilitate suctioning, fibreoptic bronchoscopy, and ventilator weaning. Initially, high inspired oxygen concentration may be used. A volume -cycled ventilator should always be used. Excessive tidal volume of over 15 mL / kg ideal body weight  and air trapping due to bronchospasm can cause barotrauma and hypotension. Utilizing high flow rates at a reduced respiratory frequency allow adequate expiration. The goal of this approach, referred to as controlled mechanical hypoventilation, is to maintain adequate oxygenation with little regard to hypercarbia.

 

Therapy should be guided by pulse oximetry and ABG results. Sedation and continued therapy for bronchospasm should continue after the patient has been placed on artificial ventilation.

Source by Frantz R. Melio. For further reading and other references:

1.     PH Feng, KM Fock. Philip Eng: Handbook of Acute Medicine

2.     David M. Cline, O. John Ma, Judith E. Tintinalli, Ernest Ruiz, Ronald L. Krome: Emergency Medicine: Companion Handbook. 

3.     Richard Robinson & Robin Stott: Medical Emergencies: Diagnosis and Management

4.     Sonke Mulle: Memorix Emergency Medicine