The
science of resurrection continues to advance and we are now to the
point is which serious decisions need to be made to improve
outcomes. Read this item carefully. I survived a twenty minute
interruption of heart activity because the right things were done and
I should have survived. Yet in the time and place I won the lottery.
Since my event and because of similar survivals, it is now standard
to start and maintain CPR. The rest described here needs to also
become standard.
In my
ward, my sense is that a number left in body bags who should also
have survived. The habit of excusing medical abandonment has become
ingrained and dangerous.
Beyond
that he also reaches the same startling conjecture that I arrived at
from a completely different direction. It is that memory itself is
not neuronic. I got there by applying the law of conservation of
biological effort. It made no sense to operate a read write storage
device alongside a connection protocol when merely connecting to the
memory in time and space was amply sufficient. Thus is is merely
enough to recognize the memory as having value to reinforce
connectivity to secure the memory. Your processor has to help you
here.
Thinking
about what and how you are learning may be most important.
Sam Parnia – the
man who could bring you back from the dead
This British doctor specialises in resurrection and insists
outdated resuscitation techniques are squandering lives that could be
saved
Saturday 6 April 2013
Sam Parnia MD has a
highly sought after medical speciality: resurrection. His patients
can be dead for several hours before they are restored to their
former selves, with decades of life ahead of them.
Parnia is head
of intensive care at the Stony Brook University Hospital in New
York. If you'd had a cardiac arrest at Parnia's hospital last year
and undergone resuscitation, you would have had a 33% chance of
being brought back from death. In an average American hospital, that
figure would have fallen to 16% and (though the data is patchy)
roughly the same, or less, if your heart were to have stopped
beating in a British hospital.
By a conservative
extrapolation, Parnia believes the relatively cheap and
straightforward methods he uses to restore vital processes could
save up to 40,000 American lives a year and maybe 10,000 British
ones. Not surprisingly Parnia, who was trained in the UK and moved
to the US in 2005, is frustrated that the medical establishment
seems slow and reluctant to listen to these figures. He has written
a book in the hope of spreading the word.
The Lazarus Effect is
nothing short of an attempt to recast our understanding of death,
based on Parnia's intimate knowledge of the newly porous nature of
the previously "undiscovered country from which no traveller
returns". His work in resuscitation has led him logically to
wider questions of what constitutes being and not being. In
particular, he asks what exactly happens, if you are lying dead
before resuscitation, to your individual self and all its attendant
character and memories – your "soul", as he is not shy
to call it – before it is eventually restored to you a few hours
later?
When I meet Parnia,
he is not long off the plane from New York after a night flight with
his wife and baby daughter, and the particular revival he is craving
is the miracle of strong coffee. He is both forthright and softly
spoken, full of careful zeal for his findings. As I sit across the
table from him, he can make even the most extraordinary claim seem
calmly rational. "It is my belief," he says, "that
anyone who dies of a cause that is reversible should not really die
any more. That is: every heart attack victim should no longer die. I
have to be careful when I state that because people will say, 'My
husband has died recently and you are saying that need not have
happened'. But the fact is heart attacks themselves are quite easily
managed. If you can manage the process of death properly then you go
in, take out the clot, put a stent in, the heart will function in
most cases. And the same with infections, pneumonia or whatever.
People who don't respond to antibiotics in time, we could keep them
there for a while longer [after they had died] until they did
respond."
Parnia's belief is
backed up by his experience at the margin of life and death in
intensive care units for the past two decades – he did his
training at Guy's and St Thomas' in London – and particularly in
the past five years or so when most of the advances in resuscitation
have occurred. Those advances – most notably the drastic
cooling of the corpse to slow neuronal deterioration and the
monitoring and maintenance of oxygen levels to the brain – have
not yet become accepted possibilities in the medical profession.
Parnia is on a mission to change that.
The one thing that is
certain about all of our lives, he says, is that we will all
eventually experience a cardiac arrest. All our hearts will stop
beating. What happens in the minutes and hours after that will
potentially be the most significant moments of our biography. At
present, the likelihood is, however, that in those crucial moments
we will find ourselves in the medical environment of the 1960s or
1970s.
The kind of CPR
(cardiopulmonary resuscitation) that we are familiar with from
medical dramas – the frenzied pumping of the chest – remains
rooted, Parnia claims, in its serendipitous discovery in 1960. It
remains a haphazard kind of procedure, often performed more in hope
than anticipation. Partly, this is a question of personnel. Parnia
is quietly maddened by the worldwide hospital habit, in the event of
death, to send the most junior of doctors along "to have a go
at CPR". It is as if hospital staff have given up before they
have started.
"Most doctors
will do CPR for 20 minutes and then stop," he says. "The
decision to stop is completely arbitrary but it is based on an
instinct that after that time brain damage is very likely and you
don't want to bring people back into a persistent vegetative state.
But if you understand all the things that are going on in the
brain in those minutes – as we now can – then you can minimise
that possibility. There are numerous studies that show that if
you implement all the various resuscitation steps together you not
only get a doubling of your survival rates but the people who
come back are not brain damaged."
In Parnia's ideal
world, the way that people are resuscitated would first take in the
knowledge that machines are much better at CPR than doctors. After
that, he suggests, the next step is "to understand that you
need to elevate the level of care". The first thing is to cool
down the body to best preserve the brain cells, which are by then in
the process of apoptosis, or suicide.
At the same time, it
is necessary to keep up the level of oxygen in the blood. In Japan,
this is already standard practice in emergency rooms. Using a
technique called an ECMO, the blood of the deceased is siphoned out
of the body, put through a membrane oxygenator and pumped round
again. This buys the time needed to fix the underlying problem
that caused the person to die in the first place. If the level of
oxygen to the brain falls below 45% of normal the heart will not
restart, Parnia's research shows. Anything above that and there is a
good chance.
Potentially, by this
means, dead time can be extended to hours and there are still
positive outcomes. "The longest I know of is a Japanese girl I
mention in the book," Parnia says. "She had been dead
for more than three hours. And she was resuscitated for six hours.
Afterwards, she returned to life perfectly fine and has, I have been
told, recently had a baby."
It was a truncated
version of this process, at the London Chest Hospital, that allowed
the Bolton footballer Fabrice Muamba to be restored to life after he
collapsed on the pitch at White Hart Lane last year. Parnia watched
the events unfold on TV and subsequently kept on reading that Muamba
had been, for up to an hour, "dead" – but always in
quotation marks. He laughs. "Journalists have invented a new
term, 'clinically dead'. I don't know what that term means. But the
fact is Muamba was dead. And it was not by a miracle he was brought
back to life, it was by science."
One of the stranger
things you realise in reading Parnia's book is the idea that we
might be in thrall to historical perceptions of life and death and
that these ultimate constants have lately become vaguer than most of
us would allow. The other strand of Parnia's research, in which he
leads a team at Southampton University, is into what most people
tend to call "near-death experiences" and what he calls
"actual death experiences". Parnia has talked to many
people about what they recall experiencing while they were dead in
his intensive care unit. About half claim to have clear
recollections, many of which involve looking down on the surgical
team at work on their body or the familiar image of a bright
threshold or tunnel of light into which they were being drawn.
Parnia has been collecting detailed accounts of these experiences
for four years. I ask what conclusions he has drawn.
He suggests he is
agnostic about the source of these subjective memories, as he is
about questions of mind and matter. "When I first got
interested in these mind/body questions, I was astonished to find
that no one had even begun to put forward a theory about exactly how
neurons in the brain can generate thoughts," he says. "We
always assume that all scientists believe the brain produces the
mind, but in fact there are plenty who are not certain of that. Even
prominent neuroscientists, such as Sir John Eccles, a Nobel
prizewinner, believe that we are never going to understand mind
through neuronal activity. All I can say is what I have observed
from my work. It seems that when consciousness shuts down in death,
psyche, or soul – by which I don't mean ghosts, I mean your
individual self – persists for a least those hours before you are
resuscitated. From which we might justifiably begin to conclude that
the brain is acting as an intermediary to manifest your idea of soul
or self but it may not be the source or originator of it… I
think that the evidence is beginning to suggest that we should keep
open our minds to the possibility that memory, while obviously a
scientific entity of some kind – I'm not saying it is magic or
anything like that – is not neuronal."
Does he have a
religious faith?
"No," he
says, "and I don't have any religious way into this. But what I
do know is that every area of inquiry that used to be tackled by
religion or philosophy is now tackled and explained by science. One
of the last things to be looked at in this way is the question of
what happens when we die. This science of resuscitation allows us to
look at that for the first time."
While those more
esoteric studies go on, Parnia wants to ensure that more and more
people are successfully returned from death to tell whatever tales
they can. "I still have colleagues in ICU who say, 'I don't
know why we are doing all this stuff'," he says. "Not long
ago, I went for a job interview in New York at a teaching hospital
and I was told if a patient comes in and has a cardiac arrest and
they end up in the cardiac care unit they will be cooled, but if
they end up in the intensive care unit the doctor in charge doesn't
believe in it. He thinks it blocks his beds so he won't do it. I
don't see this as negligence exactly because there is, as yet, no
authority telling us this is the standard we should use. But surely
there should be." All of this, I say, must have had a powerful
bearing on Parnia's own sense of mortality. Is he comforted or made
paranoid by his work?
He suggests that the
experience of talking to people who have returned from dying serves
only to enhance his curiosity about the process they have undergone,
and which he has sometimes helped to reverse. Other than that, he
says: "In ICU, I see people dying every day and each time it
happens a part of you thinks, one day this will be me. There will be
people huddling round my bed deciding whether or not to resuscitate
and I know one thing for sure: I don't want it just down to pot luck
whether I end up brain damaged or even alive."
Staying alive: The
'miracle' machine
WHAT IS ECMO?
During cardiac arrest, blood cannot carry oxygen to the brain, causing brain cells to decay irreparably, making recovery uncertain. CPR, in which circulation is manually stimulated to delay brain damage, has long been considered the last chance for patients. With ECMO, however, those same patients can be brought back from the brink and kept alive while doctors work towards diagnosis and treatment, making CPR seem primitive by comparison. This hi-tech method of resuscitation is known as ECPR and could mark a revolution in medical practice if adopted by hospitals worldwide.
HOW DOES IT WORK?
An extracorporeal membrane oxygenation machine (ECMO) is an advanced life-support apparatus. Two catheter needles are inserted, one into a major vein and one into a major artery, allowing a synthetic pump to begin drawing blood out of the body, circulating it through the apparatus, before returning it to the bloodstream. The blood passes through a membrane oxygenator, in which oxygen is introduced and carbon dioxide removed, much like the exchange of gases that takes place in the lungs. Some ECMO machines also include a heat exchanger, which can cool or warm the blood according to the patient's condition.
A dedicated team is
required to place a patient on ECMO but, once that patient is
stabilised, the machine can be supervised by specially trained nurses
and can maintain stability for sustained periods. This allows the
patient to live without a functioning cardiopulmonary system for days
or even weeks, giving diseased organs a valuable holiday in which to
recover.
WHEN IS IT USED?
Until recently, it has been used largely for severe lung failure in babies. In the UK, it is principally thought of as an intensive care treatment used in the ward, but more and more US hospitals are adding ECPR to their emergency treatment options. In an emergency, when a patient has shown no return of spontaneous circulation after conventional CPR, a doctor would decide whether the patient merits being attached to an ECMO machine, which must be carried out in a matter of minutes. Emergency ECMO is therefore administered as a last resort to patients who stand a good chance of full recovery.
In these conditions,
it can be very effective and patients who have been medically dead
for hours have been resuscitated successfully through ECMO, which can
restart the heartbeat through steady pressure and blood flow. Even
after full cardiac arrest, in situations where cell decay and brain
damage have been avoided, ECMO has proved a lifesaver. There are four
ECMO centres in the UK. Europe's largest centre and the only one in
the UK that treats adults is the Glenfield hospital in Leicester.
Kit Buchan
Kit Buchan
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