This is a neat trick and
certainly can provide emergency oxygen when the lung itself has failed such as
happens when drowning has taken place.
There been able to keep the heart working is critical to prevent more serious
damage.
It certainly applies across the field
and will become standard for first responder.
If the heart itself has stopped, a responder must keep compressing the
heart as much as possible in order to provide a cyclic pressure wave that
continues to jostle the blood throughout the body. This has so far been proven to save lives up
to two and one half hours after a stoppage.
It is also cheap and easy enough
to make readily available whereas a CPR machine is way more difficult .
Oxygen microcapsules could save lives when patients can't breathe
By Ben
Coxworth
10:39 June 29, 2012
A syringe containing the oxygen microparticle solution
Six years ago, Dr. John Khier of Boston
Children’s Hospital began investigating the idea of using injectable oxygen
on patients whose lungs were incapacitated or whose airways were blocked. He
was prompted to do so after a young girl that he was caring for passed away –
she succumbed to a brain injury, which resulted when severe pneumonia caused
her lungs to stop working properly, which in turn caused her blood oxygen
levels to drop too low. Now, Khier is reporting that his team has injected
gas-filled microparticles into the bloodstreams of oxygen-deprived lab animals,
successfully raising their oxygen levels back to normal levels within seconds.
The microparticles are created using a device called a sonicator, which
uses high-frequency sound waves to mix lipids (fatty molecules) and oxygen gas
together. This results in the mixture forming into particles about two to
four micrometers in diameter, each of which consists of an oxygen core
surrounded by a lipid outer shell. Because the particles are so small and
flexible, they are able to squeeze through capillaries – by contrast, if
straight oxygen gas were injected, bubbles of it could block the blood flow and
cause embolisms.
The microparticles are combined with a liquid carrier, so they can then
be injected into the bloodstream. That suspension contains three to four times
the amount of oxygen as regular red blood cells, so relatively small amounts of
it are required, depending on how much of an oxygen level boost is required.
When the microparticle solution was tested on lab animals with blocked
tracheas, it was able to keep them alive for up to 15 minutes without their
taking a single breath, plus it also reduced low-oxygen-related cardiac arrests
and organ injuries.
It is intended that the treatment would be used mainly in emergency
response scenarios, to hold non-breathing patients over for 15 to 30 minutes –
the carrier liquid would overload the bloodstream if used for longer. Khier and
his team envision paramedics, emergency clinicians or intensive care personnel
keeping supplies of the microparticle solution close at hand and ready to go,
should it be needed.
“This is a short-term oxygen substitute—a way to safely inject
oxygen gas to support patients during a critical few minutes,” he said.
“Eventually, this could be stored in syringes on every code cart in a hospital,
ambulance or transport helicopter to help stabilize patients who are having
difficulty breathing.”
Although already-available blood substitutes are capable of carrying oxygen,
they still first need to be oxygenated by functioning lungs.
A paper on the research was published this Wednesday in the journal Science
Translational Medicine.
Living Without Breathing: Scientists Keep Rabbits Alive With Oxygen
Injections
Rabbits with completely blocked windpipes were able to stay alive for
up to 15 minutes without a single breath after researchers injected tiny
oxygen-filled microparticles into the animals' blood stream, in a
"potential breakthrough" that may help save many lives in the
emergency room.
BY CHRISTINE HSU | JUNE 27, 2012
Rabbits with completely blocked windpipes were able to stay alive for
up to 15 minutes without a single breath after researchers injected tiny
oxygen-filled microparticles into the animals' blood stream, in a
"potential breakthrough" that may help save many lives in the
emergency room.
###
Photo: Children's Hospital Boston
An injected gas-filled microparticle (yellow) can transfer oxygen molecules directly to red blood cells (red), bypassing the lungs to carry throughout the body.
Researchers at Boston
Children's Hospital have come up with a way to bypass the lungs and deliver
oxygen to the bloodstream of patients who cannot or have stopped breathing by
using injectable oxygen.
Patients who stop breathing, may it be from an obstruction in their
airway or acute lung failure, need another way to get oxygen to their blood
fast or risk going into cardiac arrest or serious brain injury. Scientists
believe that the new technique has the potential to hold off injuries like
cardiac arrest, brain injury and cerebral palsy induced by oxygen deprivation.
Previous attempts to treat hypoxaemia or low oxygen levels in the blood
and other related conditions like cyanosis with oxygen injections have had
varying degrees of success, mainly because these past methods of injection free
oxygen gas directly into the bloodstream can be dangerous because free oxygen
gas can accumulate into larger bubbles and form potentially lethal blockages in
the body called pulmonary embolisms.
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However a new study, published in the Science Translational Medicine,
has found a way around the danger by injecting the body with oxygen in liquid
form.
Lead author Dr. John Kheir, of the Department of Cardiology at Boston
Children's Hospital, and colleagues designed a lipid foam infusion of
microparticles that consists of a single layer of lipids or fatty molecules
that surround a tiny pocket of oxygen gas.
Researchers explain that once the solution is injected, the gaseous
oxygen will still be contained and suspended in a liquid mixture to prevent it
from getting to other oxygen particles to form larger bubbles.
Kheir said that the particles are injected directly into the
bloodstream where they will mix with circulating red blood cells, allowing the
oxygen to diffuse into the cells within seconds of contact, according to
Nature.
"By the time the microparticles get to the lungs, the vast
majority of the oxygen has been transferred to the red blood cells," Kheir
said, according to Nature.
Researchers say that oxygen-filled microparticle solution is different
from the other various types of artificial blood currently used in medicine
because while they can carry oxygen around the body, they still need to receive
oxygen from the lungs.
Kheir said that the lipid foam solution is safe because as the oxygen
leaves the bubbles, the shells buckle and fold and the fatty molecules break
off and are reabsorbed by the body.
Kheir and his team had injected rabbits with the liquid solution and
found that the animals were able to be kept alive for up to 15 minutes without
breathing. The animals also had normal blood pressure and heart rate,
and showed no indication of heart, lung or liver damage that is usually caused
by oxygen deprivation or pulmonary embolisms, which can happen if free oxygen
gas is injected into the bloodstream.
"Essentially as soon as we started injecting it, clinically we
started to see an effect," Kheir said, according to Science. However, he
noted that when the injection stopped, the levels fell just as quickly, meaning
that the microparticle-solution must be continuously administered.
Researchers said that the microparticle solutions are cheap to make,
portable, could stabilize patients in emergency situations, and make time for
doctors to perform other urgent life-saving therapies.
"This is a short-term oxygen substitute—a way to safely inject
oxygen gas to support patients during a critical few minutes," Kheir said
in a statement. "Eventually, this could be stored in syringes on every
code cart in a hospital, ambulance or transport helicopter to help stabilize
patients who are having difficulty breathing."
However he noted that the microparticles should only be administered
for a maximum of 15 to 30 minutes, because they are carried in a solution that
is mostly comprised of liquid, and the fluid would overload the blood if used
for longer periods.
"If we could increase the ratio of microparticles to fluid, we
might be able to use this for even longer, and even more indications,"
Kheir said, according to Science.
"This is a potential breakthrough," says cardiac intensive
care doctor Peter Laussen of Boston
Children's Hospital, who was not involved in the work. "You can apply this
across healthcare, from the battlefield to the emergency room, intensive care
unit, or operating room."
How do you help save people dying from oxygen depravation .
ReplyDeleteGive them o2 ..duhh simple right ... well if they can't breath you need to get it in the blood stream . Ok makes sense . What if you had a way . The chemical was proven safe . Approved by the FDA to be administered to humans , not for this cause but for others . You had prof that it oxygenates the blood could save lives including heart attack victims but just needed some more testing to prove conclusively .
But there is one catch .. one really big catch . One that stops all research and shuts down the whole project and production that will cost the lives and pain a 100's of thousands .
What should you do ?
Simple fix the catch .
But you can't it's impossible .
What is the catch you ask ?
You might ask what is the substance that can do this miraculous feat .
h2o2 ... You have it in the house Hydrogen Peroxide , given intravenously .
( and yes it is done and it is safe with pharmaceutical grade h2o2 .
I have had it done for other ailments .)
You see you can't Patent something what occurs in nature .
The catch is a Patent .
So what do you do to help people ?
Why develop a new different Patentable delivery system .
If you read the article you will see that they keep rabbits alive for 15min . without breathing ... funny they already did the test with h2o2 in the
1960's yes the 60's
Oh and the rabbits lived 2 .... HOURS !!
From the book :
HYDROGEN PEROXIDE–MEDICAL MIRACLE
In their first experiment, the Baylor doctors cross- clamped the trachea of some New Zealand rabbits. In other words, they strangled them. If you can't breathe, you can't get oxygen into your blood and, thus, to the heart muscle. Within 12 minutes the rabbit will develop cardiac arrest or ventricular fibrillation and die.
Then they took another group of New Zealand rab- bits (these devils are big—they weigh seven pounds) and gave them the same treatment. But this group was given H2O2 directly into the arteries of the heart. The animals were observed for two hours without cardiac arrest devel- oping.
Incredible, unbelievable. Someone must repeat this experiment. If the results are the same (and I am confi- dent they will be), then this technique, or a modification of it, should be instituted all over the nation for heart at-
tacks.
That won't be easy. There will be three very powerful forces fighting the general acceptance of this simple therapy. First, the drug industry. H2O2 is not patentable. The drug industry would lose billions in lost drug sales.
Second, the FDA works in collusion with the drug in- dustry. They can be counted on to pull every dirty trick imaginable to stop this therapy, including declaring H2O2 an "investigational new drug.'' But right now, they seem to be going in both directions. Page 26 -27
Duncan Adams