Diving Physiology

A Bonus from the 422 Staff!

Not in your Textbook!

Pressures:

Depth P (atm) P (mm Hg) Vol

0’ 1 760 1 L

33’ 2 1520 0.5

67’ 3 2280 0.33

100’ 4 3040 0.25

200’ 7 5320 0.14

300’ 10 7600 0.10

Partial Pressures of Gases in Air

Gas 0 33’ 100’ 200’

Air 760 1520 2280 5320

O₂ 160 320 640 1120

N₂ 600 1200 2400 4200

Free Dive Limitations

Alveolar pressures are not isolated from atmosphere!

As depth increases, DP across chest wall increases

Depths below 100’ result in the "BIG SQUEEZE"

SCUBA

Function of Regulator

Deliver same volume of gas per minute as at sea level

However 1L of gas now occupies less volume depending upon depth

Must purge breathing tubes

As depth increases, air supply lasts less time

SCUBA

P_gas dissolved in plasma and body fluids depends upon DP of that gas

As depth and P increases, so does gas dissolved in blood

Suddenly decrease P, gas comes out of solution!

the Bends

Decompression

To combat the bends, decompression is required

Slow release of gases from body fluids due to stepwise decrease of pressure

Decompression tables

Time and depth

Decompression after 1 hour at 200’

10 min @ 50’

17 min @ 40’

19 min @ 30’

50 min @ 20’

84 min @ 10’

Total Time = 3 hours

Gases at High Pressure

Nitrogen Narcosis or Rapture of the Deep

CO₂ narcosis

O₂ toxicity due to free radicals at P_O2 > 1520 mm Hg

nausea, twitching, disturbed vision, disorientation, dizziness --> coma

Solutions

Replace N₂ with inert gas, Helium

Remove CO₂ with increased air flow as depth increases

Increased depth decreases air supply time

e.g., 1 hour tank lasts 1/4 hr at 100’

Diving Mammals

How can a Whale dive for 1 hour, a Weddell seal for 15 minutes, and a Peking duck for > 5 minutes?

How long can you hold your breath?

Physiological Adaptations:

Hematocrit --> No D

Hemoglobin (1.5X increase)

Myoglobin (7X increase)

Tidal volume

>80% of lung volume

exhale before a dive!!

prevents the bends

Physiological Adaptations:

O₂ consumption decreases during a dive

Cardiac Output decreases to 20% of that at rest on surface

Vasoconstriction of major arteries

Blood flow to skeletal muscles reduced to almost 0

Physiological Adaptations:

Reflex bradycardia

temperature dependent

all mammals

can be ‘learned’

Sphincter on posterior vena cava

decrease CO

Delivers blood to critical

Summary

Selective delivery of blood

O₂ to CNS & heart

Prevent CO₂ from reaching CNS

Decreased O₂ consumption

Increased O₂ stores in blood and muscle