A leading cause of chronic illness in childhood.
Asthma is the most frequent admitting diagnosis in children's hospitals
10-15% of boys and 7-10% of girls may have asthma at some time during childhood.
Asthma can lead to severe psychosocial disturbances in the family.
With proper treatment, however, satisfactory control of symptoms is usually possible.
It may be regarded as a diffuse, obstructive lung disease with
(1) Hyper reactivity of the airways to a variety of stimuli and
(2) reversibility of the obstructive process occurs either spontaneously or because
of treatment.
Other names -reactive airway disease, wheezy bronchitis, viral-associated wheezing, and
atopic-related asthma.
Bronchoconstriction and inflammation are the pathophysiologic factors. Mast cells,
eosinophils, activated T lymphocytes, macrophages, and neutrophils have key roles in the
inflammation of asthma.
Both large (>2 mm) and small (<2 mm) airways may be involved
Hyper reactivity of the airways, appears to be an intrinsic part of the disease and is
present in almost all asthmatic individuals.
This hyperresponsiveness manifests
As bronchoconstriction following exercise;
On natural exposures to strong odors or irritant fumes such as sulfur dioxide,
tobacco smoke, or cold air
On intentional exposures in the laboratory to inhalations of histamine or
parasympathomimetic agents
Airway hyperreactivity relates to the severity of the disease.
increased reactivity occurs
i. during viral respiratory infections,
ii. following exposure to air pollutants and allergens
iii. to occupational chemicals in sensitized individuals,
iv. following administration of b-receptor antagonists.
An acute decrease in airway irritability follows administration of b-receptor agonists,
theophylline, and anticholinergics, and decreased irritability follows chronic
administration of cromolyn, nedocromil, or systemic or inhaled corticosteroids.
A child with one affected parent has about a 25% risk of having asthma;
the risk increases to about 50% if both parents are asthmatic.
genetic predisposition combined with environmental factors may explain most cases of
childhood asthma.
EPIDEMIOLOGY.
onset at any age;
30% of patients are symptomatic by 1 yr of age,
80-90% of asthmatic children have their first symptoms before 4-5 yr of age.
Occasional attacks of slight to moderate severity,
Some experience severe, intractable asthma, -interferes with school attendance, play
activity, and day-to-day functioning.
most severely affected children have an onset of wheezing during the first yr of life and a
family history of asthma and other allergic diseases (particularly atopic dermatitis).
These children may have
1. growth retardation unrelated to corticosteroid administration (although ultimate
height attainment usually is normal),
2. chest deformity secondary to chronic hyperinflation,
3. persistent abnormalities on pulmonary function testing.
The prognosis for young asthmatic children is good.
remission depends on growth in the cross-sectional diameter of the airways.
Risk factors for asthma
1. poverty,
2. maternal age less than 20 yr at the time of birth,
3. birthweight less than 2,500 g,
4. smoking by adult member
5. small home size and over crowding
PATHOPHYSIOLOGY.
1. bronchoconstriction,
2. hypersecretion of mucus,
3. mucosal edema,
4. cellular infiltration,
5. desquamation of epithelial and inflammatory cells.
inhaled allergens (dust mites, pollens, molds, cockroach, cat or dog allergens), vegetable
proteins, viral infection, cigarette smoke, air pollutants, odors, drugs (nonsteroidal anti-
inflammatory agents, b-receptor antagonists, metabisulfite), cold air, and exercise.
The pathology of severe asthma
1. bronchoconstriction,
2. bronchial smooth muscle hypertrophy,
3. mucous gland hypertrophy,
4. mucosal edema,
5. infiltration of inflammatory cells (eosinophils, neutrophils, basophils,
macrophages),
6. desquamation.
7. Pathognomonic findings include Charcot-Leyden crystals (lysophospholipase
from eosinophil membranes), Curschmann spirals (bronchial mucous casts), and
Creola bodies (desquamated epithelial cells).
Mediators of inflammation are released from local mucosal mast cells following
stimulation by allergens -.
Mediators such as histamine, leukotrienes C4 , D4 , and E4 , and platelet-activating factor
initiate bronchoconstriction, mucosal edema, and the immune responses (see Chapter
141).
The early immune response results in bronchoconstriction, is treatable with b2 -receptor
agonists, and may be prevented by mast cell-stabilizing agents (cromolyn or nedocromil).
The late-phase reaction occurs 6-8 hr later, produces a continued state of airway
hyperresponsiveness with eosinophilic and neutrophilic infiltration, can be treated and
prevented by steroids, and can be prevented by cromolyn or nedocromil.
Obstruction is most severe during expiration because the intrathoracic airways normally
become smaller during expiration.
airway obstruction is diffuse but not uniform throughout the lungs.
Segmental or subsegmental atelectasis may occur, aggravating mismatching of
ventilation and perfusion
Hyperinflation causes decreased compliance, with consequent increased work of
breathing.
Increased transpulmonary pressures, necessary for expiration through obstructed airways,
may cause further narrowing or complete premature closure of some airways during
expiration, thus increasing the risk of pneumothorax.
Increased intrathoracic pressure may interfere with venous return and reduce cardiac
output, which may be manifested as a pulsus paradoxus.
Mismatching of ventilation with perfusion, alveolar hypoventilation, and increased work
of breathing cause changes in blood gases
Hyperventilation of some regions of the lung compensates for the higher carbon dioxide
tension in blood that perfuses poorly ventilated regions.
it cannot compensate for hypoxemia while breathing room air because of the patient's
inability to increase the partial pressure of oxygen and oxyhemoglobulin saturation.
Further progression of airway obstruction causes more alveolar hypoventilation, and
hypercapnia
Hypoxia interferes with conversion of lactic acid to carbon dioxide and water, causing
metabolic acidosis.
Hypercapnia increases carbonic acid, which dissociates into hydrogen ions and
bicarbonate ions, causing respiratory acidosis.
Hypoxia and acidosis can cause pulmonary vasoconstriction,
cor pulmonale resulting from sustained pulmonary hypertension is not a common
complication of asthma.
Hypoxia and vasoconstriction may damage type II alveolar cells, diminishing production
of surfactant, which normally stabilizes alveoli. Thus, this process may aggravate the
tendency toward atelectasis.
ETIOLOGY.
Asthma involves - autonomic, immunologic, infectious, endocrine, and psychologic
factors
Neural bronchoconstrictor activity is mediated through the cholinergic portion of the
autonomic nervous system.
Vagal sensory endings - termed cough or irritant receptors, depending on their location,
initiate the afferent limb of a reflex arc, which at the efferent end stimulates bronchial
smooth muscle contraction.
Vasoactive intestinal peptide neurotransmission initiates bronchial smooth muscle
relaxation. Vasoactive intestinal peptide may be a dominant neuropeptide involved in
maintaining airway patency.
Humoral factors favoring bronchodilation include the endogenous catecholamines that
act on b-adrenergic receptors to produce relaxation in bronchial smooth muscle.
Locally produced adenosine, may contribute to bronchoconstriction.
Methylxanthines - deriphylline- are antagonists of adenosine.
Asthma may be due to abnormal beta-adrenergic receptor-adenylate cyclase function,
with decreased adrenergic responsiveness.
decreased numbers of beta-adrenergic receptors on leukocytes - may provide a structural
basis for hyporesponsiveness to b-agonists.
Immunologic Factors.
extrinsic or allergic asthma, exacerbations follow exposure to -dust, pollens, and danders.
such patients have increased concentrations of both total IgE
intrinsic --- no evidence of IgE involvement;
skin test results are negative
IgE concentrations low.
in the first 2 yr of life and in older adults (late-onset asthma
increased IgE levels may be due to atopy,
Viral agents - respiratory syncytial virus (RSV) and parainfluenza virus are most often
involved; in older children rhinoviruses. Influenza virus - with increasing age.
Viral agents -- stimulation of afferent vagal receptors of the cholinergic system in the
airways. An IgE response to RSV can occur in infants and children with RSV-associated
wheezing - Wheezing with RSV infection may unmask a predisposition to asthma.
Endocrine Factors.
Asthma may worsen in relation to pregnancy and menses, especially premenstrually,
may have its onset in women at menopause.
improves in some children at puberty.
Thyrotoxicosis increases the severity of asthma; the mechanism is unknown.
Psychologic Factors.
Emotional factors can trigger symptoms
effects of severe chronic illness such as asthma on children's views of themselves, their
parents' views of them, or their lives in general can be devastating.
Emotional or behavioral disturbances are related to poor control of asthma
CLINICAL MANIFESTATIONS.
acute or insidious.
Acute episodes - exposure to irritants such as cold air and noxious fumes (smoke, wet
paint) or exposure to allergens or simple chemicals,
Exacerbations precipitated by viral respiratory infections are slower in onset, with
gradual increases in severity of cough and wheezing over a few days.
Because airway patency decreases at night, many children have acute asthma at night.
The signs and symptoms
cough, which sounds tight and is nonproductive early in the course of an attack;
wheezing,
tachypnea,
dyspnea with prolonged expiration and use of accessory muscles of respiration;
cyanosis;
hyperinflation of the chest;
tachycardia and pulsus paradoxus,
Cough may be present without wheezing,
wheezing may be present without cough;
tachypnea also may be present without wheezing.
in extreme respiratory distress, wheezing—may be absent
child has difficulty walking , talking.
hunched-over, tripod-like sitting position that makes it easier to breathe.
Expiration is typically more difficult
children complain of inspiratory difficulty also
Abdominal pain is common, due to the use of abdominal muscles and the diaphragm.
The liver and spleen may be palpable because of hyperinflation of the lungs.
Vomiting is common - followed by slight relief of symptoms.
sweat profusely;
low-grade fever
fatigue may be severe.
barrel chest deformity is a sign of chronic, airway obstruction
Harrison sulci, = anterolateral depression of the thorax at the insertion of the diaphragm, -
in children with recurrent severe retractions.
Clubbing of the fingers is rare
Clubbing suggests other causes of chronic obstructive lung disease such as cystic fibrosis.
DIFFERENTIAL DIAGNOSIS.
1. congenital malformations (of the respiratory, cardiovascular, or gastrointestinal
systems),
2. foreign bodies in the airway or esophagus,
3. infectious bronchiolitis,
4. cystic fibrosis,
5. immunologic deficiency diseases,
6. hypersensitivity pneumonitis,
7. allergic bronchopulmonary aspergillosis,
8. a variety of rarer conditions that compromise the airway, including endobronchial
tuberculosis, fungal diseases, and bronchial adenoma ,
9. alpha-1 antitrypsin deficiency
10. tropical eosinophilia and other parasitic infections
ASTHMA IN EARLY LIFE.
Wheezing in the infant -
anatomic and physiologic peculiarities
(1) a decreased amount of smooth muscle in the peripheral airways compared with adults
may result in less support;
(2) mucous gland hyperplasia in the major bronchi compared with adults favors increased
intraluminal mucus production;
(3) disproportionately narrow peripheral airways up to 5 yr of age result in decreased
conductance relative to adults and render the infant and young child vulnerable to disease
affecting the small airways;
(4) decreased static elastic recoil of the young lung prediposes to early airway closure
during tidal breathing and results in mismatching of ventilation and perfusion and
hypoxemia;
(5) highly compliant rib cage and mechanically disadvantageous angle of insertion of
diaphragm to rib cage (horizontal vs. oblique in the adult) increase diaphragmatic work of
breathing;
(6) decreased number of fatigue-resistant skeletal muscle fibers in the diaphragm leave
the diaphragm poorly equipped to maintain high work output;
(7) deficient collateral ventilation with the pores of Kohn and the Lambert canals
deficient in number and size.
development of atelectasis distal to obstructed airwaysis easier in child
The clinical, roentgenographic, and blood gas findings in asthma and bronchiolitis are
similar.
bronchiolitis caused by RSV peaks during the first 6 mo of life,
during the cold weather months,
second and third attacks are uncommon.
Previously well infants or young children develop -cough, tachypnea, and wheezing
require hospitalization.
recurrent episodes of coughing and wheezing with bacterial infections should be
investigated for cystic fibrosis or immunologic deficiency.
Chronic aspiration caused by swallowing dysfunction (usually in developmentally
delayed children) or gastroesophageal reflux also may cause recurrent cough and
wheezing in early life. Symptoms of respiratory distress often occur with or shortly after
feeding, and a chest roentgenogram is commonly abnormal.
obliterative bronchiolitis (usually a sequela of a severe viral insult, most often
adenovirus) and bronchopulmonary dysplasia
food allergy - during early life is controversial.
Positive skin test to foods are unusual in asthmatic infants, - usually milk, wheat, or egg
Eczema is associated with the subsequent appearance of asthma.
Eosinophilia greater than 400 cells/mm3 (and especially greater than 700 cells/mm3 ) and
high serum IgE concentrations predict continuing respiratory tract problems.
TREATMENT.
avoiding allergens,
improving bronchodilation,
reducing mediator-induced inflammation.
Systemic or topical inhaled medications are used,
minimizing exposure to irritants such as tobacco smoke, smoke from wood-burning
stoves, and fumes from kerosene , wet paint and disinfectants,
avoiding ice-cold drinks and rapid changes in temperature and humidity.
Pharmacologic therapy
Oxygen by mask or nasal prongs at 2-3 L/min
epinephrine = 0.01 mL/kg of the 1:1,000 (1.0 mg/mL)
repeat the same dose once or twice at intervals of 20 min
side effects of epinephrine (pallor, tremor, anxiety, palpitations, and headache)
Terbutaline, a more selective b2 -agonist, is available in an injectable form and is an
alternative to epinephrine.
The dose of 0.01 mL/kg of the 1:1,000 (1 mg/mL) - longer duration of activity, up to 4 hr.
The maximal dose of terbutaline by subcutaneous injection is 0.25 mL; this dose may be
repeated once, if necessary, after 20 min.
Inhalation of bronchodilator aerosols
less drug is given than would be required by the subcutaneous route;
side effects of injected drugs such as epinephrine are avoided.
aerosol therapy is more effective than epinephrine in reversing bronchoconstriction.
Salbutamol solution is safe and effective at a dose of 0.15 mg/kg (maximum 5 mg)
followed by 0.05-0.15 mg/kg at intervals of 20-30 min until response is adequate.
available as a 0.5% solution (5 mg/mL) to be diluted with 2-3 mL normal saline
Nebulization with oxygen at 6 L/min prevents hypoxemia
metered-dose inhaler, 3 to 10 puffs per dose, with a spacer
doses of 6 to 10 puffs
nebulized ipratropium bromide, 250-500 mg,
Both can be administered safely at intervals of 20 min for three doses and subsequently at
intervals of 2 to 4 hr if necessary.
Theophylline
aminophylline = 5 mg/kg for 5-15 min
intravenous dose should be held until the theophylline level is known.
Steroid therapy reduces the relapse and hospitalization rates.
Source:DR.NS.MANI.MD Associate Professor in Pediatrics
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