When the force of a blast
shoots a round out of a large-caliber rifle, howitzer or M1 Abrams tank gun,
the teams of people operating these weapons are exposed to low-level blasts that can cause traumatic brain injuries.
Low-level blasts do not
cause visible trauma, such as bleeding from ruptured eardrums, and they don’t
cause injury through violent head motion, such as a concussion. Yet, these
blasts can cause physical changes in the brain that lead
to a host of neuropsychiatric symptoms.
The link between the force
of a blast and the resulting changes in the brain is not completely understood.
So our team of engineers and scientists in the PANTHER
program, funded by the Department of Defense, is using physics to
elucidate how blasts cause traumatic brain injury.
What is a blast?
When a weapon like a
rifle is fired, the round is initially in its
barrel. Pulling the trigger engages a primer that produces a flame, igniting
the propellant. This chemical reaction releases stored energy and creates
high-pressure, rapidly expanding gas. This is the blast.
The rate and magnitude of gas expansion are often
so extreme that they create a shock wave, where high-pressure air molecules travel outward faster
than the speed of sound. This invisible pulse of high pressure carries a
tremendous amount of energy. It’s the same force that can propel a 24-pound
warhead out of the muzzle of a howitzer to hit a target 19 miles (30.6
kilometers) away.
After the blast leaves the
gun’s muzzle, it dissipates quickly because it is free to expand in the open
air. This is when the high pressure washes over the bodies of nearby people.
The blast from the muzzle
of a large gun like the M777
howitzer does not pulverize rocks or knock someone off their
feet. But some of the blast pressure enters the body, passing through the skin
and rigid skull bone and into the soft tissue of the brain.
Linking blast to brain injury
As blast pressure enters
the brain, it is initially compressive, meaning it squeezes the tissue equally
from all sides. Because brain tissue is largely
composed of water molecules, which are difficult to compress, this
type of pressure tends to cause little known harm to
cells.
An initially compressive
wave, or positive pressure wave, that squeezes brain tissue changes when it
bounces off the inside of the skull. It is reflected as a tensile wave, or
negative pressure wave, which tends to pull brain tissue apart. With low enough
pressures, micron-sized bubbles can form in a
process called cavitation. These bubbles can grow 10 to 50 times their initial
size over the course of less than a tenth of a millisecond, rapidly stretching
the adjacent brain tissue.
Experiments from our lab
have shown that the deformation caused by cavitation bubbles happens so rapidly
– like the speed of a bullet – that cells tend to get torn apart. The extreme speed of
stretching and squeezing causes nearby brain cells to die immediately.
Afterward, we see only fragments where healthy cells used to be.
Cell death is the physical root cause of
brain injury. In the lab, when the cells that make up brain tissue are deformed
at a magnitude and rate beyond what they can withstand, they die – either
immediately, as in the case of blast-induced cavitation, or slowly over six to
24 hours, as in most brain injuries from blunt impacts such as concussions.
In low-level blast exposure, the cavitation bubbles are very
small, and the trauma is contained to the small area around them. However,
repeated exposure to blasts can lead to an accumulation of these microtraumas,
eventually reaching a volume large enough to cause significant and irreversible
neurological symptoms.
Although evidence is mounting, it has yet to be fully
proven that cavitation directly causes blast-induced traumatic brain injury.
The hypothesis fits with post-mortem analyses of
the brains of service members with a history of blast exposure. It also fits
with the physics that link blast exposure to injury from tissue deformation.
Understanding the connection between blasts and cellular damage in the brain will help researchers develop better ways to protect against repetitive blast-induced traumatic brain injury.
-The Conversation
- Alice Lux Fawzi
PANTHER Engineering Project Manager and Associate Director of the Center for Traumatic Brain Injury, University of Wisconsin-Madison
Bjorn Borgen Professor of Mechanical Engineering and Director of the Center for Traumatic Brain Injury, University of Wisconsin-Madison, University of Wisconsin-Madison
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