重症救急救命士7：左室補助装置(LVAD) (Critical Care Paramedic 7: Left Ventricular Assist Devices (LVADs))

字幕表動画を再生する

Hi.
I'm Kathleen Schultz.
I'm a clinical engineer at Aurora Saint Luke's Medical
Center.
I've been working there for 10 years with the ventricular
assist device program.
And I'm here today to tell you a little bit about our devices
and how you may interact with them out in our community.
When we talk about a left ventricular assist device,
we're talking about a device that
is going to take over some of the function
of their left ventricle.
It works in parallel with their native heart.
So we don't remove their heart.
We basically core a little piece of their left ventricle
out and put in one of our devices.
Then the blood that goes into their left ventricle
is then pumped through our device back into the aorta,
and pumped back into the rest of their body.
It does take over the majority of the function
of their left ventricle, but not all of it.
They still will get some blood going from their left ventricle
into the aorta through the aortic valve itself.
At Saint Luke's, we currently use two different types
of non-pulsatile LVADs.
We use the HeartMate II and the HeartWare device.
Both of these devices are able to have the patient go home
on them.
When we talk about devices and why we use them,
there's a couple reasons.
There's one called the Bridge-to-Transplant.
With a Bridge-to-Transplant patient,
these patients ultimately will be transplanted
at the end of their device life.
We are basically putting in a device
to make them healthy for when they
go into transplant because we want them to be like you and I.
We want them to be able to walk as much as they can.
We want them to be able to exercise.
So it's basically to build their endurance back up.
We also use Bridge-to-Transplant devices
in our very large type "O" patients.
Type "O" blood type patients are a little harder to transplant.
So they're on that transplant list a little longer.
Unfortunately, the length of the list
also causes them to often become sick or in their heart failure.
So we're able to put these devices in,
and we're able to give them a better life
until their transplant comes.
Now, kind of the way the whole bad world and transplant
world is going is that most patients who
will get a transplant will be on a LVAD before transplant.
It's just how it's going.
We've noticed that the healthier we can take them
into the transplant, the better off they
are with their transplant, and their transplant surgeries
go a little better.
So at Saint Luke's, probably about 75%
of our patients who go to transplant
have an LVAD prior to it.
And again, they can be discharged home.
The other indication that we're starting to use now,
and it's been approved in the last probably about 10 years,
is destination therapy.
Destination therapy patients are not transplant candidates.
There's many reasons why they may not
be transplant candidates.
It could be their age.
At Saint Luke's, we have a soft cut-off of 70.
We do do some patients over 70 if they are very physically
active patients, but most of the time our cut-off for transplant
is 70.
We also-- if they have a lot of health conditions--
we may not be able to transplant them
right now whether they have renal failure, whether they
have cancer, other things that may cause them to not currently
be able to be on the transplant list.
Well, we don't want to promise those type of patients
a transplant if we can't give it to them.
So what we do them is we say-- oh, we can still put this pump
and is destination therapy, but we're
asking them to bear with us and see
if we can fix their health condition.
And then when their health condition
is fixed or becomes at a point where they can be transplanted,
then we move them back over to the bridge to transplant list.
Compliance is another huge issue.
We are advocates for the donor family.
We are not advocates for our patients.
So we want to make sure that our patients are a hundred percent
compliant, and that they're going
to treat their new organ with the respect that it deserves.
So if we have any sort of judgmental issues
with our patients on their ability
to be compliant with medications, alcohol, or drug
use, things like that, we may actually
say-- you know what, you have to prove to us
you're going to be compliant, and then
we will give you a heart.
So we basically do a social contract with them
and say these are the things that you have to do,
and when you fulfill that social contract we then will move you
back over to Bridge-to-Transplant.
The other reason that we may put it in for destination therapy
is obesity.
If somebody is over a BMI of 40, which is basically
a ratio between their height and their weight, if it's over 40
we can't transplant them.
It's too hard to find them a healthy organ.
So then we say to them-- you know
what, we will put this device in you,
and we will give you the ability to go out and exercise,
we'll educate you on what you need to eat,
and you need to come back to us and show us
that you're going to lose the weight you need in order
to get that transplant.
We also are one of the only programs in the nation who
actually also has a good relationship
with gastric bypass.
So a lot of our patients, if they're really obese
and they're showing us that they're
doing what they need to do, we actually
will refer them to our bariatric program
to get a lap band, or usually only a lap band
because it causes issues later with transplant
if they have a full gastric bypass,
but we do have a program with that.
All of the patients who are destination therapy,
they're at high risk of intervention,
high risk of death if we don't intervene soon.
Usually the protocol is if we don't do something and put
a device in them, their life expectancy
is about six months is what we're looking at.
These patients will live on this device.
They are never promised a transplant.
They're given basically contracts
and say-- if you follow these, we will go ahead and possibly
move you over to that transplant list,
but you really have to prove it to us.
So when they're put in, we do give them a palliative care
consult, because we know that they could
die on this device that might be there end-all.
They could eventually again move to that transplant list
if things get fixed, and then they
can be discharged home on these devices to live on them.
Currently, at Saint Luke's we are
about a 50/50 in our Bridge-to-Transplant
and our destination therapy list.
Now when we talk about these new types of devices,
before we get into them I want to just talk
about what non-pulsatile devices are.
When I first started at Saint Luke's, our devices
were about the size of a paint can lid,
and they were about two inches thick.
So imagine putting that in a patient.
That was pretty big.
It was all motorized and it would
break in about a year and a half.
So the companies and the health care world
said-- you guys have to do something about this.
So in order to make them smaller,
we had to make them what we call non-pulsatile.
So basically when we talk about non-pulsatile,
our devices have no valves in them.
So they have no ability to close and shut.
It's just one opening that goes through.
With that the easiest way to picture
it is like water coming out of a garden hose.
We call it continuous flow.
So whatever the device gets the device is going to spit out.
When it comes out of the end of our device,
or what we call our outlet, it is also
going to have no pulsatility to it.
It is, seriously, like water out of a garden hose.
So with that in mind, our patients
will have very, very low blood pressures,
and their difference between their systolic
and their diastolic pressure is pretty small.
We're looking at about a 5 to 15 millimeter of mercury due.
And that difference, and that-- what we call pulse pressure,
the difference between the systolic and diastolic--
is literally just on their own heart and their contracting.
So that's what causes that difference, but again
we minimize it.
So there is no usually blood pressure of 120 over 80.
We're looking at 90 over 70, 80 over 60, sometimes.
We're looking at much lower blood pressures.
They're typically not palpable at the extremities.
So even though it may have a little bit of pulse pressure
when it leaves our device and hits the aorta, by the time
it gets out to their arms and their legs,
if you try to feel pulses they're
often diminished, or gone.
So it does cause a little bit of problem
for people who meet them in the community
because they're used to feeling a pulse,
and our patients often don't have that.
The patients still do need their native heart.
We did not take it out.
We attach these devices to their native heart,
and for our devices to work and work effectively,
we really that need that native heart to still pump.
So we're really dependent on still that contractility
that that native heart has always had.
And we will try to correct the heart if it's not functioning
right because our device will see
and have problems with that.
Similarities among all of our LVADs that we use,
even the ones that I'm not going to show you today-- we do
have some at the hospital that maybe don't go home
or are a different kind that we rarely use,
but all of our devices will have what we call a driveline.
And this is basically a line that exits their body usually
on the right side, and this is what
delivers all the power to the device
and actually allows the device to communicate back with us.
This driveline is very, very important
that we keep and maintain it.
We don't want any cuts in it.
We don't want any breaks it because if we break things
we break the wires, we break the communication,
or we break the ability to provide power to it.
All of our devices will have a controller, basically
the brains of the system.
It's like a little mini computer.
It's all programmed.
It's what provides-- tells the pump what to do,
and it also is what reads what the pump is doing and gives you
visual and audible alarms if anything is wrong.
It has two batteries.
They will all have a battery charger,
and they will all have some sort of AC power unit for sleeping.
Basically all that is is a unit that plugs up into the wall
and provides the patient continuous power so
that when they're sleeping they don't
have to worry about running out of battery power.
What we do at Saint Luke's, though,
is we encourage our patients only
to use that wall unit when they are sleeping.
We did not have them go through this big surgery that
requires a full chest opening for them to sit on a power unit
and not get out and exercise.
So we tell them when you get up in the morning,
you need to get on batteries, and you
need to stay on batteries all day
so that you can go ahead and be living life,
and going to the store, and going out to eat,
and going to be with your family and friends.
Again, the types of LVADs that we're going to talk about today
are our two most common types.
It's the HeartMate II device and the HeartWare device.
When it comes to which one we choose,
it really comes down to a couple things.
Usually the physician will choose
based on the patient's size, their heart failure,
sometimes it depends on if it's in a clinical study or not.
If it is in a clinical study, sometimes a patient
may not qualify so they may be forced to the other one.
If the physician really has no reason
to choose one device over the other device,
we actually show both to the patient.
We show them what they're going to take
home, how they're going to have to live,
give them a small synopsis of how it functions,
and we let the patient choose what
they feel will fit into their lifestyle the best.
When we talk about the HeartMateII,
this is currently the most common LVAD
that we do use at Aurora St. Lukes.
There is a picture on the screen with it,
but here is the LVAD also.
What happens is it does take over pumping
for the left side of the heart.
This is what we call an inflow right here.
So when I talked earlier about coring out that left ventricle,
basically it's almost like an apple core.
We just go in there and we take out
a small piece of the ventricle in which this inlet can fit in.
We basically then pop this into the inlet.
All of this pump stays down just below their ribcage inside
of them.
And this is our outflow in which we go ahead
and we sew right back to the aorta.
So we're taking the blood from the left ventricle
that it normally would have used.
We spin it through our pump, which
is this gray portion right here, and we put it
right back where it should have gone, the aorta.
Again, this is the driveline.
We've talked about this a couple times, this white cord.
So basically this is going to tunnel underneath them,
come out on the right side of their body.
And this is what you will see, basically,
is just this cording piece of material from here to here.
It's going to come out so this patient only
has this much distance in order to move.
This pump itself is projected to last about five to ten years.
There is truly no contacting parts inside of here.
So there really should be nothing that wears
or tears inside of it and breaks,
but just in the time of being on.
And what we have to do is we have
to do something called anticoagulate these patients
because we put a foreign body inside of their body.
Their body likes to reject it a little bit.
So what we have to do is these patients will
be on coumadin and aspirin in most cases,
and usually that fluctuation in coumadin and aspirin
at some point in time may cause this pump to clot off.
So that's where we get that projected five to ten years is
more how easy they are to what we call anticoagulate.
When they're on coumadin, there is a level
that we can watch to see what their level is at.
And that's called an INR.
We look for an INR of 1 1/2 to 2 1/2 for the HeartMate II.
With that in mind, that is not any higher
than a patient who is out there on atrial fib,
or has a valve, arm surgery or replacement.
So we're really not asking for a hugely increased INR
than other common heart surgeries out there.
With the HeartMate II, some patients
can be off of anti-coagulation if they
have a history of a GI bleed.
What happens with the devices is sometimes
they will have an increased risk of GI bleeding.
So the HeartMate II does allow our patients
to take it off of them, off of coumadin
for that history of GI bleeds.
We already talked about where it exits the body.
So, again just above the waistline.
With this driveline, this white piece that will come out
of here, will then attach to something called a controller.
This is the controller.
Off of the controller is two other lead.
So this driveline right here will go into the controller
right here, and then off of there comes two power
leads in which they would have to have batteries or a power
unit attached at all times.
This is our older controllers.
So we actually have two different controllers
currently out in the community and on our HeartMate II
patients.
The older controller looks like this.
It provides power to the LVADs still
like before, still controls everything.
It does provide visual and audible alarms
through this panel on the front here.
And when the patient leaves they will always
have an extra controller with them.
So in this case, if they have this controller,
the driveline is actually going to attach right here.
So this white line would come in right here and attach,
and then their batteries are coming off on one on each side.
The controller actually has been upgraded
to a new controller which is the first one I had out here.
The nice thing about this controller
is it not only gives you symbols,
but it actually gives you words.
So it'll tell you how to fix it or what's going on.
So there's not a lot of guess work with this newer
controller.
The batteries-- the patient will wear two batteries
at all times.
So this controller right here is actually
attached to a driveline and running
so it has two batteries attached to it at all times.
For a battery to interface with the controller,
it does require a clip.
So you just put these two together, and go on
and put it on to the pump.
It does require that two power sources
be attached to it at all times.
So it either has to have two batteries,
or it'll have the power module cable which
has two ends to it that are attached.
Once a patient on HeartMate II goes on to a set of batteries,
a set of batteries is going to last them about 12 to 15 hours.
So they will actually get the majority
of their day out of one set of batteries.
Unless they sleep two hours a night,
they really are going to get all day on one set of batteries.
You'll see on this slide there's also
a picture of a power module.
That's what they would use to provide AC power.
The thing with the HeartMate II is
this box is about a foot by a foot.
It has to sit in one room.
It's about 10 to 15 pounds.
So the patients don't like to move it around.
So it's often going to be found in their bedroom.
So if you do ever go to their house
and you're looking for their power module,
we tell them to put it where they're
going to sleep because that's where they're going to need it.
So it is often found in a bedroom.
The next slide shows the Universal Battery Charger.
So again, obviously these batteries
need to be recharged at some point in time.
So the patient goes home with eight batteries.
Their battery charger charges four at a time.
So they are taught to rotate through all eight
of their batteries at any given time.
When the batteries are not hooked up into the charge,
if they're just sitting there not being used,
they will hold a charge for well over a month.
So they should be able to rotate through them pretty easily.
If the patient has the older controller,
the manila-colored controller, they
will also on top of their power module have a display module.
That is what gives them all of their numbers.
It gives them all of their alarms
in verbal or in written form.
So they have that portion to it with that display module.
With the newer controller that's all available right there
for you at that time because the display module only
works when you hook up to the power module.
So it wasn't quite as convenient as the new controller.
The Heartware devices, the other one that we commonly use.
So this is the Heartware device.
This device is currently approved
for just Bridge-to-Transplant.
It is in a study for destination therapy.
It's not a study based on how effective the pump is.
It is more based on a study on what blood pressure
you need to maintain to make this pump not clot off
for long periods of time.
Because again, remember, that destination therapy patients
are going to live on this device.
So they really are looking at what is that blood pressure?
Again, it works very similar to before.
We still have an inflow.
It sits at the top of this pump, still
requires a full chest opening.
The nice thing about this one is it does sit right
at the apex of their heart.
So not below their ribcage, but rather behind their ribcage.
So if we have a shorter, smaller person,
this device sometimes fits in a little better
because it doesn't have to go down into their abdomen at all.
I do not have the graph material on this pump,
but it has the same kind of grafting material
that comes off of here and goes right back to the aorta.
Again, this pump is projected to last about five to 10 years,
just like the other pump.
The only thing is this one does require a tiny bit higher INR.
We're looking at two to three for this device.
And they're pretty strict on that two to three.
They don't like us to take people off of anti-coagulation
if they're bleeding with this device.
At times we have no choice but to do that,
but we try to leave it on.
Again, the picture here shows how it fits in there.
It shows the pump right at the base of the heart.
It shows the driveline-- mine's a little twisted--
coming out on the right hand side.
And then this driveline, again, attaches to a controller box.
And then this controller box has to attach
to some sort of power source.
When we talk about accessories, again, this
is their controller.
The big selling point on this one
used to be that it had the LCD screen,
but now HeartMate II has come to the new century
and has also given them an LCD screen.
It still does the same thing the HeartMateII does.
It still provides all the power to the pump.
It also takes information for the pump
and gives it back to the user.
So this is what is going to provide them
any of their visual or audible alarms, based
on if something is wrong with the pump.
There is a picture of how it is carried
in a bag down below on the PowerPoint.
And they still are required to carry an extra one of these
around when they leave the house.
So basically, any patient who leaves their house
should always have an extra controller with them,
no matter which device they're on,
and they should have extra batteries with them.
A battery for this device is the small gray box right here.
I'm going to pick up this whole thing.
And it plugs into the controller just like this.
These are a little nicer.
They're just a turn and a push to get them in.
It can operate, or it does operate
on just one battery at a time.
So even though you are required to have two power
sources attached to your controller at all times,
it is only draining one of them at a time.
So with that in mind, the batteries
do only last about four to six hours,
and then the patient will get a little beep that tells them
that they need to put a new battery on that side.
Once they replace the battery, then the beep goes away.
The controller will automatically
switch to the other power source that's
attached to it so the patient doesn't
have to run out of power.
It just is notified every four to six hours
that they have a volt battery.
The nice thing about this, which I didn't bring here,
is this device does have an AC-- what they call power cord.
It's a lot like a laptop brick so that core
that runs to your laptop, that's what their AC cord is.
So rather than that one by one foot box,
it's really a portable cord with them.
So these patients, even though their batteries may not
last as long, [INAUDIBLE] is very portable.
So we actually do encourage these patients,
if they're just sitting around watching TV,
why run on your batteries?
Just plug into the wall because the cord
is really easy and portable to move around.
We also encourage them if they're
going out of their house to take one of their AC cords
with them.
They do go home with two to have it with them so that they
can hook up when they're just sitting around doing nothing.
They also are provided with a DC adapter, which is something
that the HeartMate II does not have.
So these patients, if they're one of those
that's going to travel-- we actually
have a patient that is currently on his way
to Wyoming in a car-- and he is using his DC adapter.
It plugs into its power cord in his car,
and he can hook up and run off of his car battery
while he's driving to Wyoming.
And he doesn't have to worry about-- worrying
about his batteries changing because this patient physically
himself is driving to Wyoming.
He is the one driving.
So we don't want him to have to worry about running out
of power as he's driving.
About probably 50% of our patients drive.
We do allow them to drive.
There's nothing currently in the state of Wisconsin
that stops them from driving.
So they are restricted to about 12 weeks
after surgery before we allow them to drive.
This device also has a battery charger just
like the other device.
It charges four batteries at a time.
It allows them to-- so if they have four to six hours out
of their battery, it's going to take them about four hours
to recharge that battery.
This device does go home with only six batteries,
but, remember they do have that AC cord that they're
allowed to use during the day a little more freely.
So they don't eat through quite as many batteries.
When we talk about complications-- so now
we put this in, we say they're OK to leave the hospital
and we send them out to the community.
What complications are you guys maybe going
to see with these patients?
One of the main complications that we have are arrhythmias.
On There's right heart failure.
There's low volume.
Device malfunction.
Bleeding.
Infection.
And thrombus and stroke.
When it comes to arrhythmias, remember
before I told you that our pump is really
dependent on that heart functioning as it's intended.
Because that's what fills our pump.
When your heart contracts, it pushes blood
through our pump a little faster.
So we need that heart to work.
Remember too, earlier, I told you
that this only supports the left side of their heart.
Well, there's a whole other side of the heart
called the right side.
And the right side is what feeds all the blood to the lungs,
oxygenates that blood, and then that blood comes from the lungs
into your left side.
And then that's that oxygenated blood
that your tissue in your body get
when your left side pumps it out.
Well if we leave these patients in arrhythmias
for long periods of time, we're going
to put out that right side of the heart
and it's not going to function as it was intended.
And then our device isn't going to function as well.
And then guess what happens?
Your end organs, your livers, your kidneys,
all of those type of things, they don't get profusion.
They don't get oxygenated blood.
So we can't leave our patients in arrhythmias
for long periods of time.
With that in tow, our patients will tolerate an arrhythmia.
So you may walk up upon one of our patients
and they may be in v-tach or v-fib.
Well, guess what?
They'll be talking to you.
So it's a little strange because that's not normally
what you see out there.
When people especially are in v-fib,
they're down on the ground.
You're doing CPR usually.
And our patients, sometimes will talk to you.
They may tell you they don't feel the best,
but they're likely not going to hit the ground
and pass out in most cases.
They'll be talking.
We still want you to get them out of them.
So if their AICD hasn't gone off on its own,
we want you to externally defibrillate these patients.
Again, if the right size is not working
and it can't get blood through the lungs
and it can't get it to our left side,
then our pump can't function.
So we really have to work on that right heart failure.
With that in mind, out in the community,
do not underestimate the amount of patients
that we may have on some sort of Viagra in some way, shape,
or form may come in different names, Revatio or Magellan.
But ask even our female patients--
are you on some sort of Viagra before you treat these patients
because they often are.
That is one of the medications that we commonly
use to help that right heart function.
It helps lower those pressures and the lungs for us
so that right side doesn't have to work quite as hard.
So low volume, that is another thing
that we're going to deal with here.
We did not cure their heart failure.
Again, there's no cure truly for heart failure.
All we're doing is finding a way to assist their heart failure
so it's not quite as overcoming to them.
So with low volume, what happens sometimes
is we sold these patients on diuretics.
And we're limiting their intake, and we're
giving them diuretics such as Lasix, furosemide, things
like that.
So we always are bouncing back and forth
on that low volume issue.
So you may run across a patient who has low volume.
The other thing that comes with low volume,
and we're going to jump ahead a little bit, is that bleeding.
So if that patient is doing some GI bleeding,
or bleeding somewhere else or they've
been bleeding profusely out of their nose which
happens sometimes, they may become a low volume state.
And we have to supplement that low volume state.
Because what happens if we don't stop that low volume
state-- remember, I told you all of these inflows
are sitting in their left ventricle--
if we don't have enough volume in that left ventricle,
our ventricle sucks down around that inflow.
And if our inflow taps that ventricle wall at all,
it often will cause that patient to go into v-tach or v-fib.
So we really are juggling that low volume state.
Device malfunctions.
I know it sounds horrible, but they actually are pretty rare.
The devices are actually pretty reliable.
They may get a battery here or there that goes wrong,
but when we're looking at device malfunctions
they often are just a change of a controller.
In most of the time, the patient can come to us
and we can change their controller.
It's still functioning, just something
maybe isn't working a hundred percent right with it.
So often they're not even changing their controllers
at home.
They're coming to us.
When we talk about device malfunction,
the big one really is, jumping ahead again a little bit,
is that thrombus and stroke issue.
Because if we start building any sort of issue
up inside our pump, it can't spin like it wants to.
And it starts to cause some heart failure
issues with these patients.
So when we're thinking that there
may be some sort of thrombus in our pump,
we start looking for things like Coca-Cola color urine.
So if you come across our patients
and they have really dark urine, when we get them
to the hospital we start looking at things like their labs.
There's a value called LDH that we check.
There's a value called plasma for hemoglobin.
If all of those are elevated, along with that Coca-Cola
colored urine, plus there's a number on the device called
power that we watch, if that's also increased
those are all really indicated that the patient may
have some sort of thrombus building up inside of them.
They also always risk that stroke.
Just because we put a foreign body inside of them
they always will have a risk of stroke,
and that ability to build up some sort of clot
and basically spit it out of our pump,
and then it goes to their head or to some sort of arm or limb.
With that in mind, there is also infection.
I know I talked about it last, but this is probably
the number one problem our patients have.
Remember I told you earlier, we have that exit site
that's coming out of the right side.
Well, that's basically a foreign body coming out of their thing.
If they tug or pull on that exit site, it's going to open it up.
Well, as soon as you open it up, guess what?
Those little bugs like to get in there.
Once our patients are infected, if they
have a full-blown infection and they don't call us early,
it will often remain infected for the duration of their pump
life.
They often will end up on antibiotics
for the duration of their pump life
which often becomes a miserable life for them.
So we really encourage our patients
to be mindful of that exit site.
We actually have them wear a device
a little further down from their exit site.
So if they drop their bag or something
like that, which is going to happen at times,
it pulls on that device and not the actual exit
site itself to avoid infections.
When we talk about the EMS ED role, or just
the community role in general, we
do want you guys calling us and asking us
if you have any questions.
So anytime you come across a patient who
may be having a problem out in the community,
we do ask that you guys use the numbers that
are on the controllers.
On the HeartWare controller, the numbers
are going to be on the back of the controller.
And on the HeartMate II, the numbers
will also be on the back of the controller for you.
Those numbers will give you the EMS,
or it will give you all the pager
numbers for the engineers.
It also gives you the surgeons and the transplant clinics'
numbers.
So you have full access to us at all times.
When the patient does go home, we
do notify their immediate community
that they are out there.
So if the patient lives in Milwaukee,
we notify the Milwaukee EMS.
If the patient lives in Racine, we notify the Racine EMS.
So if the patient lives in Waukesha,
we'll notify Waukesha's EMS.
But remember these patients aren't homebound.
They don't have to stay home.
Remember earlier, I said we have a patient going
to Wyoming right now.
So we then also notified Wyoming.
So if they travel, we ask that they
let us know that they're traveling so we can set them up
with the safest way to travel in centers out and about.
But again, a patient from Waukesha
could very easily go to Pleasant Prairie to go shopping,
and a Racine person could run across them out
in the communities.
So again, it is important to remember that if you need them
at all that those numbers are on the back of the controller.
So if the patient can't communicate with you,
you need to look for those numbers
and communicate with us so that we can help you out
in the community about getting them back to us.
Again, the patients and the families
are completely trained on these devices.
When they leave our hospital, they
know exactly how to run them, how to troubleshoot them,
how to change controllers, how to notice
if things are going wrong.
It is not the community's responsibility
to know how to troubleshoot them.
What we like to do is come out and educate you guys
so you guys can see what they are,
what a battery is, what a controller is.
So when you get out there, if the patient is stumbling
through things, you've seen it already.
We do ask, though, that if you do come across them
and they need to be put in an ambulance
and taken to a facility that you do allow
a device-trained individual to go with them, especially
if the patient is in some sort of distress,
because they may not be able to one hundred
percent operate their own device at that point in time.
We also ask that you try to get a hold of the engineers
and let us know that you're coming in so that we can meet
you in the ER because if it's the weekends or nights,
we're not at the hospital.
So we're coming from home.
We also ask that you really help us make sure
that the patient leaves the house with the back-up
controller and extra batteries.
I know sometimes that's the hardest
thing to do when the patient's in distress,
you just want to get them in the rig and get them out,
but we really need that extra controller
when they hit our hospital.
So they may need assistance carrying that equipment.
We do encourage our patients to try
to keep their extra controller and an extra set of batteries
in a bag ready to go at all times.
So often if you just ask them-- where's your emergency bag,
where's your back-up controller.
They'll know right away like- oh, it's right by the door,
or, it's right here.
Sometimes it's just a little bit of communicating with them
because they're often forgetful when
they're in that distressed state.
If the patient is medically stable,
we do asks that you try to take them to St. Luke's.
We do understand if they're not within the Milwaukee area
sometimes that's a little hard to do.
So you can take them to a local hospital.
That local hospital then would hopefully
communicate with us, or if you can remind them to communicate
with us with the numbers on the back of the controller
that they're out there, and then we
will communicate with them on what
is the best course of action for that patient.
It's becoming more common that LVADs are out there.
So now you're seeing that a lot of times
our patients will go to outlying and ERs,
and they'll actually get treated and get discharged home
from those outlying ERs.
It's not always necessary that they come to St. Luke's as much
as it used to be.
If the patient is clinically unstable,
though, we really need them to go to the closest hospital
because we don't want anybody to miss a treatment because you
took a three hour drive from Green Bay down to Milwaukee.
So at that point in time, we have no choice
but to take them to the local hospital
and get them stabilized, and then
get them transported down to us.
Now what is the EMS ED role when it comes to LVAD-- so if you're
not a LVAD trained person, what are you
supposed to do with these patients?
Well, we do understand that assessing these patients
is very hard because remember, again, this
is a non-pulsatile left ventricular assist device.
So we took away every measurement
that you guys are used to using.
We took away their blood pressure in most cases.
We took away their pulse in most cases.
So you really have to go back to things that are clinical signs.
You need to look-- are they breathing?
Are they warm?
Do they have capillary refill?
Push their finger down and see how fast
it takes their fingernail to fill back up.
If they're talking to you, even if they don't have a pulse,
please don't do anything crazy with them.
Just call us, and we'll help you through it.
So with that in mind, with blood pressures,
that's always the big question for us.
What do we do with that blood pressure?
Because, guess what?
It's not always going to be picked up
by an automated cuff which people are used to using.
You can try it.
We do run our devices a little slower
than we used to to help with that GI bleed problem,
just to keep a little more pulsatility in these patients.
So sometimes that automatic blood pressure cuff will work.
If you do get it to work, fine, you can take that number.
But again, remember, that number may not
be what you're used to looking at.
When it comes through that automated cuff,
it may only be 80 over 60.
I don't want you pumping a bunch of volume into my patient
because that's normally what people
would do at that point in time.
If you have an 80 over 60, we are
looking for a mean pressure between 60 and 90
for these devices.
So we don't treat a systolic and diastolic with these patients.
We treat a mean.
So again, you may have some patients
out there with lower blood pressures.
If you put too much volume in these patients,
you're going to push them into congestive heart failure.
So again, we walk that really thin line.
If you cannot get that automated blood pressure cuff to work,
sometimes it requires that you use a Doppler.
And what you would do is you would put a normal manual cuff
on their arm.
You're going to blow it up.
You're going to put the Doppler where you would listen.
And when you hear that first swoosh sound, guess what?
That's the number you're going to take.
You will not hear a second number.
You're just going to hear that first swoosh number.
And we want that number somewhere to be 60 and 90.
We consider that kind of like their systolic mean.
So again, if you can't get it to automatically read,
then you will have to find a Doppler
and use a Doppler pressure.
Now what happens if your patient application comes in
and they're not stable?
They're not able to talk to you.
They come in.
They're basically full-blown coating.
Well, guess what?
We made it easy for you.
Follow all your ACLS protocol.
You still want to attach EKG rhythms to these patients.
That's one of the biggest things we see out in the community is
patients who have LVADs, people don't want to do the normal.
Guess what?
You're AICDs will work.
Your AEDs will work.
You want to get ECG cables on there.
Make sure that they're not an arrhythmia,
that that's not what's causing their problems.
If they do you have an arrhythmia,
we want you to shock them out of it.
Again, remember though, that a lot of them
will be awake and alert and oriented.
So if you're going to shock them externally,
please sedate them first because they
won't be very happy with you.
If you have to do chest compressions
on these patients-- let's say that they have no pulse.
You can't find it.
They're not talking to you.
They're starting to turn gray.
They're starting to turn cold.
Guess what?
You have no choice.
Do chest compressions.
To us at St Luke's, we have the little saying-- dead is dead.
So please, try to save them and do the chest compressions.
If you do nothing, they're going to die.
So we can't stress more than anything, look at that rhythm.
If you only have an AED-- if they go down at church,
and you have an AED, pop it on them.
It'll work.
We want to keep them out of those arrhythmias.
And again, follow all the ACLS protocol.
The only thing I caution again is make sure
that the patient's not on some sort of Viagra.
In general, LVAD troubleshooting.
So again, we don't train you, but everybody
wants to know-- what do we do?
How do we do this?
What do we do if we come across this patient
and their controller's alarming?
Well, guess what?
In general, if the controller is not alarming and you come
across one of our patients, they have at least 2 1/2 liters
of flow going through them.
Our devices, both devices, alarm if their flow is less than 2
1/2 liters.
So with that in mind, you're not going
to get much more with that with doing chest compressions.
So unless that patient is truly turning gray and cold,
I wouldn't jump into them if the controller's not alarming.
If the controller is alarming, we
do ask that you verify that the power source is attached.
So if this is the hardware, you want
to make sure the batteries are attached to it.
And then the HeartMate II, you want
to make sure the batteries are attached to the power leads.
In both cases, these pumps will not
run if batteries are not attached.
So you may come across a patient that has just accidentally
disconnected both of his powers.
So if there is not power attached, please attach power.
If there is still good power attached,
and the thing is still alarming, we
want you to verify that the controller's detached
to the driveline.
So in this case, on the heartware,
it's making sure that the silver connection is
in the actual controller and hasn't come out.
The HeartMate II, depending on which controller you have,
it's either going to go into the top here,
or if you run across some of our older patients that are out,
it's going to be on the side here.
So it's just making sure that that controller has not
come out at all from the driveline.
Because if the controller's not attached,
there's no way to provide power to the pump.
So the pump will stop again.
If it's still alarming, at that point and time
you need to page one of the engineers
at the 414-222-7434 number, and we'll
help you do any additional troubleshooting
that you would need to do out in the field.
With that in mind, I will remind you there
has been times where the EMS or the ED has had to call us
and they've had to put a battery on,
or they've had to find equipment for us.
And this is why we do these talks,
so that when I'm on the phone with you
and I say-- can you find a battery?
You know what a battery looks like.
I'd like to thank you now for assisting us
in helping us get these patients back out to the community
and living their lives again.
For us., it's huge in their recovery process.