 |
PULMONARY PROBLEMS (RESUSCITATION PHASE 0 - 48
hours) Continued
II_c. chemical burn to upper & lower airways
Pathophysiology:
This aspect of inhalation injury is often an
extension of the upper airways injury just
described but is generally much more serious
than that produced by heat alone. Toxic gases
contained in smoke as well as carbon particles
coated with irritating aldehydes and organic
acids can result in injury to both upper and
lower airways. The location of injury will
depend on the duration of exposure, the size of
the particles, and the solubility of the gases.
Components in Smoke:
The components in smoke causing injury are
defined as follows:
a)
Heat injury from the hot gas is usually confined
to the area above the cords, as heat is rapidly
neutralized in the oro and nasopharynx.
b)
The gas phase contains a host of toxins,
including carbon monoxide, cyanide gas, acids,
and aldehydes.8-13,25-28 Oxidants
are also clearly present in the gas phase.
These agents produce both a systemic response
and local airway injury. The vapors, in large
part, are mucous membrane irritants leading to
intense bronchorrhea, bronchoconstriction, and
airway edema. The process often peaks hours
after injury, although patients with
pre-existing airway reactivity disease can
develop very early intense bronchoconstriction.4,8,27-28
c)
The particulate phase injury of smoke
produces a severe injury. The degree of
exposure to the lung is dependent on particle
size and breathing pattern.29-31 The
particle deposition willl depend on particle
size. Particles range from 0.1 to 15 ųm in
size, depending on the heat of the smoke and
what is burning. Particles of 3 to 5 ųm appear
to predominate in many of the smoke inhalation
studies. In general, particles >5 ųm are
cleared by the nasopharynx if the patient is a
nasal breather. With mouth breathing, most of
the larger particles will deposit in the larynx,
trachea, and large airways. Particles <5 ųm
will deposit in both large and small airways,
and alveoli. The degree of deposition in distal
lung is accentuated by deeper breaths, as would
be evident in an attenuated hypox patient or in
a patient attempting to actively escape the
insult. As opposed to the gas phase, which is
short lived, the particulates can adhere to the
mucosa and perpetuate the local tissue injury.
Particulate clearance, in turn, will be impeded
byu the impaired mucociliary action perpetuating
the injury.32
Of major importance is the fact that smoke from
different environments varies dramatically in
toxicity. Examples of extremely toxic smoke
includes smoke from burning automobile
interiors, upholstery, and chemical plants in
which hydrocarbons are a major component.11,12
|
Table 3: CHEMICAL COMPONENTS OF
SMOKE |
|
COMPOUNDS |
SOURCE |
EFFECT |
TIMING |
|
Ammonia
SULFUR DIOXIDE
CHLORINE |
CLOTHING, FURNITURE,
WOOL, SILK |
Mucous membrane irritation, bronchospasm,
bronchorrhea |
Early onset (first several hours) |
|
HYDROGEN CHLORIDE
PHOSGENE |
PLYVINYL CHLORIDE,
FURNITURE, (WALL, FLOOR COVERINGS) |
Severe mucosal damage; ulcers, mucous
plugging, mucosal slough, pulmonary edema |
Delayed often 1-2 days |
|
ACETALDEHYDE
FORMALDEHYDE
ACROLEIN |
WALL PAPER
LACQUERED WOOD
COTTON, ACRYLIC |
|
|
CYANIDE
CARBON MONOXIDE |
POLYURETHANE UPHOLSTERY
NYLON (ANY
COMBUSTIBLE SUBSTANCE) |
Tissue hypoxia |
immediate |
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