-
Gas Laws
-
Boyle's Law
-
Law
- "If the temperature remains constant,
the volume of a given mass of gas is
inversely proportional to the
absolute pressure."
-
Formula
-
P₁ × V₁ = P₂ × V₂
- V₁ = The initial volume
V₂ = The final volume
P₁ = The initial pressure
P₂ = The final pressure
-
Significance
-
As we ascend, the air in an enclosed space will expand.
- The enclosed space could be a pneumothorax.
- This would rapidly turn into a tension pneumothorax on ascent.
-
Dalton's Law
-
Law
- "The total pressure of a gas mixture
is the sum of the partial pressures
of each individual gas in the mixture."
-
Formula
-
P₁ = F₁ × P
- P₁ = The partial pressure of gas 1
F₁ = The fractional concentration of gas 1
P = The total pressure of the gas mixture
-
Significance
- Barometric Pressure × Gas concentration = Gas partial pressure
760 mm Hg × 21% O₂ = 159.6 mm Hg PO₂ @ Sea Level
-
Oxygen remains @ 21%, regardless of altitude.
- Oxygen availability decreases with altitude
because the oxygen molecules are farther apart.
- This can result in hypoxia!!!
-
Charles' Law
-
Law
- "The volume of a gas is very nearly
proportional to its absolute temperature
when the pressure is kept constant."
-
Formula
-
V₁ ÷ T₁ = V₂ ÷ T₂
- V₁ = The initial volume
V₂ = The final volume
T₁ = The initial absolute temperature
T₂ = The final absolute temperature
- Significance
-
Gay-Lussac's Law
-
Law
- "The density of an ideal gas at
constant pressure varies inversely with
the absolute temperature of the gas."
-
Formula
-
P₁ ÷ T₁ = P₂ ÷ T₂
- P₁ = The initial pressure
P₂ = The final pressure
T₁ = The initial absolute temperature
T₂ = The final absolute temperature
- Significance
-
Henry's Law
-
Law
- "The quantity of gas dissolved in a
liquid is proportional to its partial
pressure in contact with that liquid."
- Formula
-
Significance
- If the gas is N and the liquid is blood...
...and we decrease the pressure rapidly...
...we get acute decompression illness!
-
What happens if we fly this patient?
We decrease the pressure more...
...making the decompression illness worse!
- Don’t fly high with divers!!!
-
Graham's Law
-
Law
- "The rate of diffusion of a gas through
a liquid medium is directly proportional
to the solubility of the gas and inversely
proportional to the square of its density"
- Formula
-
Significance
-
This means that gases will go from a
higher pressure or concentration to a
region of lower pressure or concentration.
- This is the basis for gas exchange at the cellular level.
-
Stresses of Transport
-
Decreased Partial Pressure of Oxygen
-
Terminology
-
Hypoxia
- A state of low tissue oxygenation.
-
Hypoxemia
- A state of low arterial blood oxygen tension.
-
Hypercapnia
- A state of increased amount of carbon dioxide in the blood.
-
The four stages of hypoxia
-
Indifferent stage
- The physiologic zone for this stage starts
at sea level and extends to FL100.
[10,000 ft :: 3,000 m]
- Body reacts to hypoxia at this stage
with a slight increase in RR & HR.
- Night vision loss occurs at FL50.
[5,000 ft :: 1,500 m]
-
Compensatory stage
- The physiologic zone for this stage is FL100-150.
[10,000-15,000 ft :: 3,000-4,500 m]
- At this stage the body attempts
to protect itself from hypoxia.
- BR, RR, and HR increase.
Quality of respirations becomes deeper.
- Efficiency and performance of mental
tasks requiring alertness become impaired.
-
Disturbance stage
- The physiologic zone for this stage is FL150-200.
[15,000-20,000 ft :: 4,500-5,000 m]
- This stage is characterized by
dizziness, sleepiness, tunnel vision, and cyanosis.
- Thinking becomes slow and muscle coordination decreases.
-
Critical stage
- The physiologic zone for this stage is FL200-300.
[20,000-30,000 ft :: 6,000-9,000 m]
- This stage is characterized marked
mental confusion and incapacitation.
- Unconsciousness usually follows
within a few minutes.
- Death is imminent!
-
The four types of hypoxia
-
Hypoxic hypoxia
- Interferes with gas exchange in two phases
of respiration, ventilation and diffusion.
- Manifests as a deficiency of alveolar oxygen exchange.
- Caused by a reduction in PO₂ in inspired air,
or a reduction in the effective gas exchange area of the lung.
- Often referred to a altitude hypoxia.
- During the ventilation phase, a reduction in PaO₂ may occur.
Specific causes include reduced barometric pressure,
respiratory arrest, severe asthma, hypoventilation, breathing
gas mixtures with insufficient PO₂,
and malfunctioning oxygen equipment at altitude.
- Causes of reduction in the gas exchange area include
pneumonia, drowning, atelectasis, emphysema,
pneumothorax, pulmonary embolism, congenital defects,
and physiologic shunting.
-
Hypemic hypoxia
- Interferes in the transportation phase of respiration,
caused by a reduction in oxygen-carrying capacity of the blood.
- Mainly caused by anemia, hemorrhage,
or intake of chemicals (CO, cyanide).
- Can be a risk to air-medical crews
since they are around exhaust fumes.
-
Stagnant hypoxia
- Interferes in the transportation phase of respiration,
caused by a reduction in systemic blood flow.
- Specific causes include heart failure, shock,
G-forces, and pulmonary embolism.
- A reduction in regional or local blood flow
can be caused by blood clots, tourniquets,
and extremes of environmental temperatures.
-
Histotoxic hypoxia
- Interferes with the utilization phase of respiration,
caused by metabolic disorders or poisoning of
cytochrome oxidase enzyme system resulting
in a cell’s inability to use molecular oxygen.
- Common causes include CO,
cyanide, and alcohol poisoning.
- Also caused by respiratory enzyme
poisoning or degradation.
- Barometric Pressure
- Thermal Changes
- Decreased Humidity
- Noise
- Vibration
- Fatigue
- Gravitational Forces
- Cabin Pressurization
- Additional Stresses of Transport