barotrauma related to diving
Last reviewed 01/2018
barotrauma in diving
- many tissues in the body may contain natural or unnatural collections of
free gas
- extremely rigid containers e.g. blocked paranasal sinuses
- very compliant containers of free gas e.g. unobstructed lungs or patent sinuses.
- intermediately compliant containers of free gas e.g. the gastrointestinal tract and the cavity of the middle ear
- the unobstructed lung has a time constant of emptying of less than 1
second and so it normally vents and fills with gas without difficulty
during ascent and descent
- if the lung is obstructed, as for example during descent on a breath-hold
dive, it compresses according to Boyle's Law
- the air in the lungs taken in by a breath-holding diver at
the surface will shrink to one-half the original volume at a depth
of 10 m, to one-third at a depth of 20 m and so on
- scuba divers breathe gas at the ambient pressure of the
surrounding water and this enables the diver to breathe with
ease
- however, as the diver goes deeper, the supplied gas
will become denser, and the work of breathing will become
harder
- in the condition where the volume of gas diminishes and further gas cannot be drawn in to occupy this space, it will either be filled by body tissues or by clothing - this situation is termed a "squeeze"
- further descent causes blood to be drawn into the chest from the limbs and abdomen to compensate for further diminution of lung volume
- however, as the diver goes deeper, the supplied gas
will become denser, and the work of breathing will become
harder
- scuba divers breathe gas at the ambient pressure of the
surrounding water and this enables the diver to breathe with
ease
- the air in the lungs taken in by a breath-holding diver at
the surface will shrink to one-half the original volume at a depth
of 10 m, to one-third at a depth of 20 m and so on
- if the lung is obstructed on ascent, e.g. by a diver unwisely holding
his/her breath, the gas in the lung expands until the lung reaches
its bursting pressure which is roughly 70 mmHg at about 115% of voluntary
total lung capacity when it ruptures
- gas may escape from the lungs into other tissues in four ways:
- 1. pneumothorax - into the virtual space between the visceral and parietal pleura to give a pneumothorax - tension pneumothorax might occur
- 2. into the pulmonary venous blood from where the gas passes into the arterial circulation (arterial gas embolism, AGE) giving rise to the manifestations of DCI
- 3. pneumomediastinum - into the mediastinum (pneumomediastinum) and thence into the soft tissues of the neck - causes surgical emphysema.
- 4. pneumoperitoneaum - into the peritoneum
- for unknown reasons (but may be to do with posture whilst working), aviators and tunnel workers experience pneumothoraces more commonly than AGE, while the situation is reversed in divers
- gas may escape from the lungs into other tissues in four ways:
- if the lung is obstructed, as for example during descent on a breath-hold
dive, it compresses according to Boyle's Law
- obstruction of the Eustachian tube
- if the Eustachian tube is obstructed
- when the diver descends a painful bowing of the tympanic membrane into the middle ear occurs
- if the diver descends further then will cause rupture of the
tympanic membrane with entry of potentially infected water into
the middle ear cavity
- can result in vertigo underwater which may cause the diver to panic and ascend rapidly to the surface
- if the Eustachian tube is obstructed
- obstruction of the external meatus
- obstructing the external meatus (which most commonly occurs by means of a tightly fitting hood) causes an outward bowing of the tympanic membrane, known as "reversed ear"
- odontocharexis
- gas may become trapped in a tooth cavity at depth, commonly as a
result of poor dental hygiene
- when the diver ascends, the expanding gas can cause severe pain in the tooth (odontalgia); in some cases the tooth has been known to shatter (odontocharexis)
- gas may become trapped in a tooth cavity at depth, commonly as a
result of poor dental hygiene
- mask barotrauma is described in the linked item
Notes:
- Boyle's Law
- at constant temperature the pressure and the volume of the gas are
inversely related:
- PV=k, where P is the total pressure of the gas and V is the volume of the gas. k is a constant for a given gas or mixture of gases o cavities in the body that contain gas will be affected by pressure as indicated by Boyle's Law
- at constant temperature the pressure and the volume of the gas are
inversely related:
Reference:
- 1) Edge CJ. Recreational diving medicine.Current Anaesthesia Critical Care 2008; 19 (4): 235-246.
- 2) Knauth, M. et al. Cohort study of multiple brain lesions in sport divers: role of a patent foramen ovale. BMJ 1997; 314: 701-5.