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Case: Cardiac Ultrasound - Parasternal Short Axis

Read more about Case: Cardiac Ultrasound - Parasternal Short Axis

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This video details the use of bedside ultrasound imaging, specifically the parasternal short-axis view, with a phased array probe to evaluate cardiac health and anatomy, especially when looking at a patient's left ventricular contractility.

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Cardiology

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Case Study Videos

Subtitles

- Hello, my name is Phil Perera and I'm
the Emergency Ultrasound Coordinator
at the New York Presbyterian Hospital in New York
City, and welcome to SoundBytes Cases!
In this module, we'll continue our journey looking
specifically at the cardiac echo views of the heart.
In this module, we're going to focus entirely
on the parasternal short axis view of the heart.
Now we've covered the parasternal long axis
view of the heart previously in SoundBytes module
and recall that the probe will be positioned
for the parasternal views in Position A as shown
here in the pictorial to the right.
In upcoming segments, we'll cover the subxiphoid view
as shown in probe Position B, and finally the apical
view of the heart as shown here in probe Position C.
Now the parasternal short axis view of the heart
can be very helpful in emergency care as it gives
a great deal of information about the contractility
of our patient's heart.
So let's look now further into how
to perform this examination.
The probe will be placed just left of the sternum
at about intercostal space 3 or 4
as shown in the pictorial here to the right.
Now in variance to the parasternal long axis
view of the heart where the probe marker was
positioned down towards the patient's left elbow
we'll swivel the probe 90 degrees clockwise so now
the marker is down towards the patient's right hip.
That's with the caveat that the ultrasound screen
indicator is positioned towards the left of the screen.
Now moving the patient into left lateral
decubitus position may help imaging
from the parasternal short axis plane.
Here's what the views from the parasternal
short axis plane of the heart will look like.
We see a pictorial here to the left showing
the left ventricle cut in cross section as a cylinder
and the right ventricle as a little sliver
just to the left of the left ventricle.
We see an ultrasound image corresponding to the right
and note the left ventricle again, that cylinder
cut in cross-section and the right ventricle
above the left ventricle more anteriorally
and to the left.
In this way we get a good sense of the overall
cylinder of the left ventricle
and can gauge its contractility.
Here's a video clip showing extra contractility
of the left ventricle as taken from the parasternal
short axis plane and note the muscular contractions
of the left ventricle as a cylinder squeezing in
dramatically during systole.
We also note the mitral valve flipping up
and down within the left ventricle and the right
ventricle as seen up and above the left ventricle.
Now let's contrast this video clip showing
excellent contractility with another patient
who had an advanced cardiomyopathy.
Note again the left ventricle and note here
the poor percentage change from diastole through
systole, indicating an advanced cardiomyopathy
with low ejection fraction.
We can also see the right ventricle anterior
to the left ventricle.
For learning purposes, we'll identify the walls
of the LV, the septum in between the ventricles,
the anterior wall to the top of the screen,
posterior wall to the back, and the lateral wall
as shown here towards the right portion of the screen.
Now while I show the walls of the left ventricle here,
it's important to realize that the goal of emergency
echo at the bedside is to determine overall left
ventricular contractility rather than looking
for segmental wall motion abnormalities.
So in conclusion, the parasternal short axis view
of the heart gives a great deal of information
about the contractility of the left ventricle.
This will allow you to identify patients who may
have a cardiogenic cause for their presentation.
So I hope to see you back as SoundBytes continues
and we move on to discuss the subxiphoid views
and apical views of the heart.

Brightcove ID

5752151759001

https://youtube.com/watch?v=B731sgCuZU4

Case: Parasternal Long Axis Pt. 2

Read more about Case: Parasternal Long Axis Pt. 2

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This video details the use of bedside ultrasound imaging and a phased array probe to evaluate cardiac health and structure, especially when evaluating the left heart chambers and valves, or investigating for paracardial effusion.

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Cardiology

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Case Study Videos

Subtitles

- Hello, my name is Philips Perera
and I'm the emergency ultrasound coordinator
at the New York Presbyterian Hospital
in New York City.
Welcome to SoundBytes Cases.
In this module, entitled Cardiac Echocardiography,
Parasternal Long Axis View Part Two,
we're going to look further into
the uses of the parasternal long axis view
at the patient's bedside.
Recall that the parasternal long axis view
of the heart is going to be obtained
by placing the probe into position A as shown here.
That will configure the probe
just left of the sternum at about intercostal space three
with the marker dot down towards
the patient's left elbow.
Now, the first two goals from the parasternal long axis view
of the heart are going to be first of all,
to look for left ventricular
contractility.
The second goal is going to be
to investigate for a pericardial effusion.
Let's begin by looking at some clips,
going over left ventricular contractility.
Here's a video clip, showing excellent contractility
of the left ventricle as taken
from a medical student triathlete.
Recall the chambers of the heart,
as taken from the parasternal long axis plane,
the left atrium, as seen in the posterior location;
the mitral valve, just to the left of the left atrium;
and the left ventricle,
as seen with it's hypertrophic walls.
Notice the strong contractility
of this left ventricle as the endocardial walls
almost meet during ossicle.
We see the aortic valve to the right
of the left ventricle
and the right ventricle in a superficial location
above the left ventricle.
Recall the descending aorta,
the cylinder cut and cross section,
just posterior to the left atrium.
Note the posterior pericardial reflection
coming off just anterior to the descending aorta
and posterior to the left ventricle.
With the small indicator arrow,
I'll trace out the posterior
pericardial reflection.
Note here the absence of any dark
or anechoic fluid collections.
Now let's contrast that last video clip
with this one taken from a patient
with an advanced cardiomyopathy.
We recall the left ventricle
and the right ventricle in a superficial location
above the LV.
Notice the very poor percentage change
of the endocardio walls
of the left ventricle during ossicle,
indicating a very decreased
ejection fraction.
Here's a clip taken from a patient
who presented with a transplanted heart
and acute shortness of breath.
We'll begin by identifying the descending aorta
as shown here to the bottom part of the picture.
Note the posterior pericardial reflection,
that white line coming off just anterior
to the descending aorta.
But what we see here is the presence
on a dark, fluid collection,
a pericardial effusion that layers out posteriorly
above the posterior pericardial reflection
and comes anteriorly to surround the heart.
With a small indicator arrow,
I'll point to the anterior portion
of the pericardial effusion and note the chaotic movement
of the right ventricle
as shown here.
This is indicative of early tamponade or high pressures
within the pericardial sac.
Here's a video clip
showing a potential mimic of a pericardial effusion.
Let's being by identifying the descending aorta
as a cylinder cut and cross section
posterior to the left atrium.
We identify the posterior pericardium, as shown here,
coming off just anterior to the descending aorta.
Note the presence here of a large,
dark or anechoic fluid collection,
but note that it layers our posteriorly there
to the pericardium.
Thus, this fluid is within the pleural cavity
and not within the pericardial cavity.
With a small indicator arrow I'm again reinforcing
the pericardial reflection
and the presence of the fluid
within the thoracic cavity,
a pleural effusion.
Next we'll look at a video clip
from a patient who present with acute
shortness of breath requiring intubation.
First, we'll begin by identifying the descending aorta,
then the posterior pericardial reflection.
Note here, the presence of fluid,
both within the pericadial sac, as shown here,
layering anterior to the pericardium
and posteriorly within the pleural cavity
layering out just below the pericardial reflection.
Why, you might ask, does the patient have all this fluid?
Well, let's look closely at the mitral valve
and on the posterior mitral valve leaflet,
we see a calcified vegetation.
This patient, in fact,
had an infected dialysis catheter
with mitral valve endocarditis
and had developed wide-open mitral valve regurgitation
resulting in heart failure
and all the fluid layering out
within the pericardium and
the thoracic cavity.
In conclusion, the parasternal long axis view
of the heart gives a great deal of information
about our patient's condition
and can be instrumental in emergency care.
Through this module,
I hope now that you'll have a better idea
on how to grade left ventricular contractility
as good through poor.
Also, to be able to identify the presence
of a pericardial effusion.
I hope to see you back as SoundBytes continues
and we look further at the
cardiac echocardiography examinations.

Brightcove ID

5794989698001

https://youtube.com/watch?v=uciGL4TaoaA

Case: Cardiac Ultrasound - Apical View

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Using the apical view and a phased array probe during bedside cardiac ultrasound examinations can enable clinicians to evaluate cardiac health, structures, & ventricular contractility. This view is ideal for identifying cardiomyopathy, pericardial effusion, and cardiac tamponade.

Applications

Cardiology

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Case Study Videos

Subtitles

- Hello, my name is Phil Perera
and I'm the emergency ultrasound coordinator
at the New York Presbyterian Hospital in New York City
and welcome to Soundbytes Cases.
In this module we'll continue our journey
down the path of the four cardiac examination views.
Specifically in this module
we're going to look at probe position C,
known as the apical view of the heart.
I hope you've been able to join me prior
looking at probe position A, the parasternal views,
and probe position B the subxiphoid views of the heart.
So the apical view of the heart is an excellent view
and gives a great deal of information
about our patient's heart
as it shows all four chambers of the heart
in relation to one another.
Therefore, the apical view of the heart
is preferred by cardiologists as it shows the synergy
of all of the chambers of the heart to one another.
Now let's take a look at a pictorial
showing how to perform the apical view of the heart.
Preferably, you're going to be using a small footprint
phased array type probe
that can easily get in between the ribs.
Position the probe directly underneath the left nipple
at about the point of maximal impulse of the heart
with the probe indicator
over towards the patient's right side.
Now that's with the caveat
that the ultrasound's screen indicator is positioned
toward the left of the screen.
Now moving the patient
into the left lateral decubitus position
can improve imaging from the apical view of the heart
as it moves the heart closer to the probe
and moves the lung out of the way.
Thus, it's important to consider moving the patient
into this position
when performing the apical view of the heart.
Now let's learn how to interpret the images
that we'll obtain.
We see here a pictorial to the left
and an ultrasound image to the right.
As we're imaging from the apical view of the heart,
we're closest to the ventricles
and in this image we see the left ventricle
to the right of the screen and the right ventricle adjacent.
The atria from the apical view of the heart
will be further away, thus posterior to the ventricles
and we see here the left atrium
just below the left ventricle
and the right atrium below the right ventricle.
We also see the valves, the tricuspid valve to the left
and the mitral valve to the right
in between the left atrium and the left ventricle.
We can also appreciate the white lines
surrounding the heart, which is the pericardium.
Now let's take a look at a video clip
showing the apical view of the heart in action.
This is taken from a medical student triathlete,
so let's take a look at that left ventricle.
We see the left ventricle in its more superficial location
to the right of the screen.
Notice the percentage change from diastole to systole.
Note the walls almost touch with each heartbeat,
indicating a good contractility.
We see the right ventricle to the side of the left ventricle
and the two atria posterior to the ventricles.
Notice the mitral valve in between the left atrium
and left ventricle and the tricuspid valve
to the right side.
Notice here the absence
of any significant pericardial effusion.
Let's contrast that last clip from this patient
who has a dilated cardiomyopathy,
and as we look at that left ventricle
from the apical view of the heart
we see a very poor percentage change
from diastole through systole.
This is indicative of a very poor contractility
of this heart.
We see the right ventricle to the side of the left ventricle
and the two atria posterior.
Notice the sluggish movement of both the mitral value
and the tricuspid valve.
We see a little bit of pericardial effusion,
that little black rim around the heart,
also going together
with this patient's cardiomyopathy status.
Here's an interesting video clip
of a patient who presented with acute shortness of breath.
What we notice here is the right ventricle
and the left ventricle closest to the screen,
but we see here a very large pericardial effusion
circumferentially surrounding the heart.
And notice the heart swinging back and forth
in all the pericardial effusion.
This gives rise to the phenomenon
known as electrical alternans
or different sizes QRSs on the EKG.
Here's a patient who was in bad shape
and presented with acute shortness of breath.
We see a very large pericardial effusion
and let's look specifically at the right ventricle.
Notice that it caves in from diastole
due to the high pressure in the pericardial sac.
Thus this is indicative of advanced cardiac tamponade.
This patient will need a stat pericardiocentesis procedure.
So in conclusion I'm glad I could share with you
this Soundbytes module
going over the apical views of the heart.
This is an often neglected view
but one that gives a great deal of information
about your patients heart
and really should be routinely integrated
into the cardiac echo examination.
It's best to move the patient
into the left lateral decutibus position
to optimize imaging from the apical view of the heart
to see all four chambers of the heart
in relation to one another.
So I hope to see you back as Soundbytes continues.

Brightcove ID

5752159405001

https://youtube.com/watch?v=4vBJoWP-zBM

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Case: RUSH Exam Part 4

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Series 4 of 4, This video represents a comprehensive algorithym for the intergration of bedside ultrasound for patients in shock. By focusing on "Pump, Tank, and the Pipes," clinicians will gain crucial anatomic and physiologic data to better care for these patients.

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Cardiology

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Case Study Videos

Subtitles

- [Voiceover] Welcome back to Soundbytes Ultrasound
teaching videos.
My name is Dr Phil Perera, and this video sequence
entitled The RUSH Exam Video Part 4,
we're gonna go further on to our exploration
of the Rapid Ultrasound in Shock
in the Critically Ill Patient, ultrasound algorithm.
In this video we'll focus on Part three,
evaluation of the pipes.
I'm also going to include evaluation for right ventricular
dilatation, really part of step one,
evaluation of the pump, that we did not go over earlier
in the video sequence.
Here in table one we see the four classic types
of shock, and the ultrasound findings associated
with each of these conditions.
We've covered step one, evaluation of the pump,
specifically looking for cardiac contractility,
and the presence of a pericardial effusion.
Now looking under the column of obstructive shock,
we see two conditions that we haven't covered prior,
and that we'll go over in this video.
Specifically, looking for, right ventricular strain
or cardiac thrombis, that may signal a massive pulmonary
emobolis, as the etiology for the patient's shock.
Now let's skip down to part three, evaluation of the pipes,
which will really be the main focus of this sequences.
And here, under hypovolemic shock, we're going to asses
both the thoracic and abdominal aorta for pathology,
specifically, dissection or aneurysm with rupture.
Under obstructive shock, if we do see
right ventricular thrombis, or right ventricular strain,
we may wanna switch probes and look for the presence
of a deep veious thrombosis, to correlate or corroborate
obstructive shock as the etiology
for the patient's condition.
Now let's learn how to analyze the relative cardiac
chamber sizes as a means of determining right ventricular
dilatation, and the possibility of a thrombo-embolic cause
for the patient's shock condition.
The normal left ventricular to right ventricular size
ratio should be one to zero point six,
meaning that the left ventricle should generally
be twice the size of the right ventricle.
In cases of acute pulmonary strain,
such as a massive pulmonary embolis,
as seen in the small image to the upper left,
the right ventricle will suddenly dilate,
and may be larger than the left ventricle,
as seen in the image.
In conditions of sudden right ventricular dilatation,
the RV wall will generally be thin,
measuring less than five millimeters,
and this needs to be differentiated from cases of
chronic pulmonary artery hypertension or strain,
where the right ventricle will have time to dilate,
as well as hypertrophy, and the wall will generally
be thicker than five millimeters.
Let's take a look at this video clip taken from
a patient who presented to the ED,
with a blood pressure of 70 over pul,
and a history of a recent hip replacement one week prior.
With a small indicator arrow,
I'm tracing the confines of the left ventricle.
Notice that the LV is relatively small in relation
to the gigantic RV, and there I'm showing the confines
of the RV with the indicator arrow.
This would indicate a massive pulmonary embolism
as a cause of the patient's shock,
and the need for acute therapy to correct this condition.
To put that last video clip into reference,
let's take a look at a normal parasternal long axis view
of the heart.
Here we see that the left ventricle is about twice
the size of the right ventricle,
which would be the normal relation between the two chambers.
Notice in the last video, the relation was almost reversed.
Here's another video clip taken from a hypotensive patient,
who had just gotten off a long plane flight,
and what we see here, is that the LV is very small
in relation to the RV, and notice the deflection
of the septum away from the RV with each heartbeat,
indicating relatively high pressures
within the right ventricle.
So this was an acute pulmonary embolis,
and the treatment here was going to be fibrinolysis.
We can now examine the heart in the parasternal short
axis view, by moving the probe 90 degrees clockwise.
Now we see the heart in cross section,
and notice that the chambers appear as cylinders end on.
We can see the gigantic right ventricle to the top
of the screen, and the much smaller left ventricle
is traced by the small indicator arrow.
Notice here that the septum is flattened,
and bows away from the right ventricle,
due to the relatively high pressures within the RV.
The LV almost takes on the appearance of a D-shaped
chamber, due to the flattening of the septum,
and the high pressures within the right ventricle.
A classic finding in a massive pulmonary embolis.
As we had mentioned earlier, we need to differentiate
right ventricular dilatation in acute causes such
as an acute pulmonary embolis, from a more chronic cause
such as primary pulmonary hypertension.
This was taken from a patient who had long standing
primary pulmonary hypertension,
and with the small indicator arrow,
I'm tracing the confines of the relatively large RV
in relation to the LV, and we can also see the thickening
of the RV wall greater than five millimeters.
This indicates a time for hypertrophy,
that would indicate more of a chronic condition.
We can also see a compensatory hypertrophy
of the papillary muscles within the right ventricle,
tethering the valve that is often seen with
primary pulmonary hypertension.
Now, swiveling the probe to a parasternal short axis view
in the same patient, we also see the findings
of the small LV in relation to the RV,
and the D-shaped chamber finding,
but notice that looking closer at the right ventricle,
we can again see the hypertrophic wall,
greater than five millimeters,
and again, the compensatory thickening of the papillary
muscles within the right ventricle,
often seen with primary pulmonary hypertension.
This video clip was taken from a patient
who presented to the emergency department with
unexplained tachycardia,
associated with periodic chest pain,
and shortness of breath.
This is a subxiphoid view of the heart,
and looking within the right atrium,
it looks like there's jellybeans bouncing around
within the chamber.
In actuality, this is thrombis, moving around
within the right atrium, very very concerning,
that this may pass out through the right ventricle
into the pulmonary system and cause
a massive pulmonary embolism.
While this is an unusual finding
to see a clot within the heart,
we may be able to see this as we look closer and closer
at the heart in patients presenting with unexplained
tachycardia and shock.
This is an apical view from the same patient.
Notice here we see the thrombis bouncing around
in the right atrium.
Notice that it actually passes out through the
right ventricle, into the right ventricle,
through the tricuspid valve, and then is pushed back
into the right atrium, and this was a very interesting case
and that this patient had relatively high pulmonary
arterial pressures, and a large amount of tricuspid
regurgitation, that pushed the thrombis back into
the right atrium.
Let's now move on to specifically look further at
step three of the rapid ultrasound in shock exam,
the evaluation of the pipes.
While in this illustration it looks like there's
many probes on the patient's body,
let's sequentially break this down.
Let's look first at probes positions A and B.
Probe position A is a suprasternal notch view,
in which we may be able to get a look at the
thoracic aorta, and the actual arch of the aorta,
looking specifically for aneurysm or dissection.
Position B is the classic parasternal view,
in which we can also get a glimpse of the thoracic aorta,
looking for dissection or aneurysm.
Probes positions C and D are the classic probe positions
for placement, to look for evaluation of abdominal
aortic aneurysm.
We can also see an intimal flap at times that may signal
a thoracic aortic dissection extending down
into the abdomen.
Now probes position E and F are the classic positions
for the DVT exam, and should be performed
if the patient has right ventricular dilatation
on bedside echo, and one has a high suspicion
for a thrombo-embolic cause of the patient's shock.
In this video clip we see a parasternal long axis view
of the heart.
Recall that we see the three chambers of the heart
from this view, the left atrium, the left ventricle,
and the right ventricle.
We see the aortic valve,
and the left ventricular outflow tract to the right
of the aortic valve.
Notice in this video clip that this aortic root
is relatively widened, and I'm tracing that
with a small indicator arrow.
Now a normal aortic root should measure no greater
than three point eight centimeters,
and a widened aortic root is suspicious for thoracic
aortic dissection, or aneurysm.
Here we're actually measuring the aortic root,
notice that it measures 4.74 centimeters.
And we can see there that this patient
has a thoracic aortic aneurysm.
Now we may be able to see an intimal flap here
within this region, which would indicate
a dissection as the etiology for the patient's shock.
In this video clip, taken from a patient with
Marfan Syndrome, and chest pain radiating to the back,
we see a very widened aortic root taken from the
parasternal long axis view.
This would indicate the possibility of a Stanford Class A
aortic dissection as a cause of the patient's shock.
Notice here, the very very widened aortic root,
and what looks like the possibility of an intimal flap.
Now an intimal flap may not always be seen
on transthoracic echo, but if one is very suspicious,
one can pursue a transesophageal echo or a CT scan
to further confirm this condition.
This patient actually was confirmed to have a
Stanford Class A aortic dissection requiring a stent.
This image of the aortic arch was taken from the
suprasternal notch view.
In this view the probe is placed directly into
the suprasternal notch, with the probe marker
oriented towards the patent's right side.
In relatively thin patients, it can be possible
to move the head to the side and to aim the probe
down into the chest to get a view of the aortic arch.
And here we can see the ascending aorta to the left,
the descending aorta to the right,
and the aortic arch right in the middle.
Notice we also see some of the branching vessels
coming off of the aortic arch, and this would be
normal anatomy, not consistent with dissection.
But occasionally we may be able to pick up an aortic
dissection or aneurysm, from the suprasternal notch view.
This video clip represents the suprasternal notch view
taken from the patient with Marfan syndrome
discussed earlier in the video sequence.
The first thing we notice right away is that this aortic
arch is much more dilated than the normal anatomy
shown prior, and with the small indicator arrow,
I'm showing the confines of the aortic arch.
Let's look closer within the aortic arch,
and right away we can see what looks like an intimal flap
moving around with each heartbeat.
So this patient was diagnosed with a Stanford Class A
aortic dissection, extending from the root,
through the arch, and down into the descending aorta.
The next step in the evaluation of the pipes
is performed through looking at the abdominal aorta.
The probe should be placed in positions C and D
as shown on the patient's abdomen,
with the probe in a short axis configuration.
Generally we'll begin with the probe high,
at position C, and move all the way down to D
to fully examine the aorta.
We're looking for an abdominal aortic aneurysm,
as signaled by a abdominal aorta greater than three
centimeters in diameter.
Now most AAAs will be fusiform in nature,
and also infrarenal.
Some may extend down into the iliac artery.
A minority of triple As will be saccular as shown
in the image over to the right, where we have
a small protrusion of the wall, out from the normal aorta.
This video clip demonstrates an abdominal aortic aneurysm,
in a patient who presented to the emergency department
with a hypotensive state and tachycardium.
Here we see a very large abdominal aortic aneurysm
in the short axis view.
Notice here we see a large amount of thrombis
along the walls of the aorta,
and recall that when measuring for an abdominal aortic
aneurysm, we need to measure the thrombis in addition
to the lumin.
That means we're going to measure from outer wall
to outer wall, not just the inner walls of the lumin.
And we can see the swirls of clot or pre-clot
within the lumin of the triple A.
Now to confirm that this is a triple A,
we can further go ahead and put a color power doppler,
or color flow doppler, onto this area,
just to confirm that there's flow within the lumin,
and that this is indeed a vascular structure.
We'll perform that in the next step here,
and by putting color power doppler there,
we can see that this is indeed a turbulent movement
of blood within the large abdominal aortic aneurysm.
So right away we have an etiology for the patient's shock,
and this is a patient who needs to go directly
to the operating room, and bypass the CT scan
in order to live.
This video clip was taken from a patient who presented
to the ED with hypotension accompanied by
chest, back, and abdominal pain.
Here we see a short axis view of the abdominal aorta.
First with the indicator arrow, I'll trace out the spine,
a landmark for the posterior aspect of the abdominal cavity.
Anterior to that, we'll notice the abdominal aorta,
and while it's not terribly large in size,
we see a positive finding in the lumin,
the presence of an intimal flap.
To the right there is the true lumin,
and to the left is the false lumin,
so what we see here is a thoracic dissection
that's extending down into the abdomen.
This actually turned out to be a class A dissection
that was extending from the root all the way down
into the abdominal cavity.
So occasionally we can actually pick up,
in the aortic dissection, on evaluation of the aorta,
on bedside ultrasound.
Here's a long axis view of the same patient,
notice we have the probe marker,
so that superior is to the left, inferior to the right.
Again we see the abdominal aorta stretch out
as a tubular structure across the screen,
and in the middle we see the presence of an intimal flap,
moving around with each heartbeat, again,
pathonomic for an aortic dissection.
The next step in part three, evaluation of the pipes,
once one has evaluated the major arterial circuit,
IE the thoracic and abdominal aorta for pathology,
is to examine the major venous circuit,
IE probes position E and F, looking for a pathology
within the venous circuit such as a massive DVT,
that could be the cause of a thrombo-embolic etiology
for shock.
And now while not every patient will need this examination,
I will go ahead and perform this exam in a patient
with a high pre-test probability for a thrombo-embolic
cause of shock, or right ventricular dilatation
seen on bedside echo.
This illustration shows the lower extremity venous anatomy.
Recall that the common femoral vein bifurcates into
the deep and superficial femoral veins.
Now the superficial femoral vein is the one
that continues on down the thigh,
and into the leg, and in fact has been renamed
the femoral vein of the thigh.
It will continue on into the back of the knee to
become the popliteal vein.
Now we can perform a two point compression examination,
looking for a DVT, by placing the probe into the area
of the small indicator arrow,
scanning from the common femoral vein down
to bifurcation, into the femoral vein of the thigh,
and the deep femoral vein.
We can then proceed all the way down to the popliteal vein,
placing the probe posteriorly, and compressing sequentially
from high within the popliteal fascia,
down to the area of trifurcation into the three calf veins.
Failure to compress would be indicative of a positive DVT.
This video clip illustrates normal compression of the
femoral vein.
At this level, we see the common femoral vein and artery.
We have the high frequency linear array probe
placed on a side to side configuration,
with the probe marker laterally oriented,
or towards the left.
Notice that the femoral vein towards the right or medial,
completely compresses with probe pressure,
indicating the absence of a DVT.
So this would be considered
a completely normal DVT examination, and in fact
we can see a little bit of the saphenous vein coming
off the top of the femoral vein.
Now we can use doppler to help us in identification
of the femoral vessels.
This would be a positive examination,
we can see the femoral artery with pulsations,
laterally or towards the left,
and towards the right or medial,
we actually see the femoral vein,
and notice the swirls of fresh clot
present within the vessel.
Now recall that we must go ahead and compress the vessel
to confirm a DVT, so that will be our next step,
but here again we see absence of flow within the
femoral vein, which is completely clotted off by a DVT.
Next we'll apply gentle probe pressure downwards,
with a high frequency linear array probe.
Notice we see failure of compression of the femoral vein,
and with the small indicator arrow I'm tracing the confines
of the femoral vein, again we can see the
echogenic debris of the DVT,
that's actually the saphenous coming off the top,
also involved with this DVT.
So a failure of compression of the femoral vein,
indicative of a positive DVT,
and in the right clinical scenario,
this could suggest a thrombo-embolic cause
for the patient's shock, especially if the patient
has right ventricular dilatation on bedside echo.
Continuing downwards, we'll look at the popliteal vein.
Now remember that the probe is placed posteriorly
into the popliteal fascia for this exam,
and gentle probe pressure is applied.
We can see that the artery is anterior to the vein,
and that the vein, which is posteriorly located,
completely compresses.
This would be a normal examination,
and we can see that the walls completely come together
with probe pressure.
This video clip illustrates a positive exam
for a popliteal vein thrombosis.
Recall again that the popliteal artery is located
anterior to the vein, and we can see here
that the popliteal vein with what looks like swirls
of echogenic material.
With a small indicator arrow, I'll show the confines
of the popliteal vein, and notice that with probe pressure,
that the vessel does not compress.
And in fact, with the small indicator arrow there
I can see a calf vein that's coming off the popliteal vein,
that's also filled with debris or DVT.
And we know that most DVTs occur within the calf,
and propagate upwards into the popliteal vein.
Now let's put all the information we've learned
in the various RUSH segments, into one unified
RUSH protocol, to help us in determining the etiology
for the patient's shock.
Let's begin by looking at hypovolemic shock.
In step one, evaluation of the pump, often heart will
be small in size and hypercontracting,
with the endocardial walls almost coming together
during sistole.
On evaluation of the tank, the inferior vena cava
may be small in size, with a large percentage change
during inspiration.
The internal jugular veins may also be small in size,
with a low closing column within the neck.
We may see the presence of peritoneal fluid,
or pleural fluid, indicating a hole within the tank.
In step three, evaluation of the pipes, one may see
an abdominal aortic aneurysm, which may be the cause
of hemorrhagic shock, causing the shock etiology
in this patient.
One may also see an intimal flap
indicating aortal dissection,
another cause of hemorrhagic shock within our patient.
Moving on to the next category, cardiogenic shock,
generally the heart will be dilated in size.
With systolic dysfunction,
the heart will be hypocontracting,
with a small percentage change from diastole through
to sistole.
On evaluation of the tank, the inferior vena cava
will often be large in size, greater than two centimeters,
with a small percentage change during inspiration.
The internal jugular vein will be distended as well,
with a high closing column within the neck.
One may see, on evaluation of the lung,
the positive lung rockets that we talked about,
or ultrasonic beelines indicating pulmonary edema.
Pleural effusion and ascites may also be seen
as a sign of tank overload.
On evaluation of the pipes, often this will be normal,
although occasionally a DVT may be seen in this
low flow state.
In obstructive shock, of which the first is,
pericardial effusion with cardiac tamponade,
we'll be looking specifically for a circumferential
pericardial effusion, with diastolic collapse
of the right atrium and or right ventricle,
indicative of cardiac tamponade.
In the other two types of obstructive shock,
a massive PE or a tension pneumothorax,
generally we will see a hypercontracting heart,
and recall that in cases of a massive PE,
we may see right ventricular dilatation,
and we may at times actually see thrombis within
the right atrium, and or right ventricle.
Moving on to the tank, the inferior vena cava
is usually distended in obstructive shock,
with a low percentage change from expiration
through to inspiration.
The internal jugular vein will also be distended,
with a high closing column within the neck.
Now if the patient has a tension pneumothorax,
we may be able to see absent lung sliding and
the absence of vertical comet tails.
Moving on to the evaluation of the pipes
in obstructive shock, we may be able to pick up
a positive DVT within the femoral or popliteal regions,
indicative of a thrombo-embolic etiology of the shock,
and a DVT that may have moved on into the heart
and into the lungs to cause a massive PE.
Last but not least, in distributive shock,
of which sepsis will be the most common,
in early septic shock, the heart is
generally hypercontracting, with the endocardial walls
almost touching during sistole.
Later in sepsis, the heart may fail,
and one can see a hypocontracting heart with
a small percentage change from diastole through to sistole.
On evaluation of the tank, in distributive shock,
generally the IVC will be normal or small,
less than two centimeters, with a high percentage change
during inspiration.
The internal jugular vein may also be normal or small,
with a low closing column within the neck.
In cases of sepsis due to empyema,
we may be able to pick up the presence of a septage
or a complicated pleural effusion.
And in cases of peritonitis, usually due to
spontaneous bacterial peritonitis in a liver patient,
we may see the presence of peritoneal fluid or ascites.
On the evaluation of the pipes in distributive shock,
generally this part can be omitted,
as this usually will be normal.
So in conclusion, the RUSH ultrasound protocol
can quickly help us at the bedside,
stratify a patient into one of the four categories
of shock, and immediately start the correct therapy
for the patient's shock state.
Now continuing on, we can use the RUSH exam
to monitor the patient's response to treatment
over time, and this is very important in cases
of hypovolemic shock or distributive shock,
where one can look at fluid loading at the response
of the inferior vena cava and internal jugular veins.
Hopefully they should become more plump,
and less distensible, with respirations,
as volume resuscitation continues.
This means that the RUSH exam can first identify
the patient's shock state, allowing for appropriate therapy,
and also very importantly can allow us to evaluate
the patient's response to therapy,
by looking at the response to fluid loading,
as we want to push up the central venous pressure
in cases of hypovolemic and distributive shock states.
So, I'm glad you could join me for the Soundbytes Videos,
and I look forward to seeing you in the future,
as Soundbytes continues.

Brightcove ID

5754400770001

https://youtube.com/watch?v=9UyVHqvGgHE

Case: RUSH Exam Part 3

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Series 3 of 4, This video represents a comprehensive algorithym for the intergration of bedside ultrasound for patients in shock. By focusing on "Pump, Tank, and the Pipes," clinicians will gain crucial anatomic and physiologic data to better care for these patients.

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Subtitles

- [Voiceover] Hello and welcome back
to Soundbytes ultrasound teaching videos.
My name is Dr. Phil Perera and in this video segment
termed RUSH Part 3, we're going to look specifically further
at the rapid ultrasound in shock
in the critically ill patient or the RUSH exam
focusing on evaluation of the tank or step two.
Now the RUSH exam is a three part examination
that begins with evaluation of the pump or cardiac status;
continues with part two, evaluation of the tank;
and finishes with part three, evaluation of the pipes.
In this video segment we're specifically gonna focus on
part two, evaluation of the tank.
Now this is a three part evaluation
beginning with part one, evaluation of tank volume;
continuing on to part two, evaluation of tank leakiness;
and concluding with part three, which is evaluation
for tank compromise.
So in this three-part evaluation
the first part, the evaluation of tank fullness
really means evaluation
of the patient's core vascular circuit for volume status
or central venous pressure.
This can be performed
through examination of the inferior vena cava
and alternatively with assessment
of the internal jugular veins.
Part two, evaluation for tank leakiness and overload
is performed through examination of the extended FAST exam
looking for free fluid in the abdominal and pelvic cavities
as well as in the thoracic cavity.
We can also employ lung ultrasound techniques
looking for pulmonary edema or ultrasound B-lines,
which can signify tank overload in the appropriate patient.
Last we'll conclude with evaluation for tank compromise
in which we'll again employ lung ultrasound techniques
to look for the presence of pneumothorax.
In a hypotensive patient with a positive pneumothorax,
this may signify a tension pneumothorax
requiring immediate decompression.
Here's a slide showing the probe positions
for evaluation of the tank.
Let's begin by looking at position A.
This is the best position
to evaluate the inferior vena cava
and we can look at the inferior vena cava
from the subxiphoid position
in both short and long axis views.
Probe positions B, C, and D
represent the appropriate positioning
of the ultrasound probe for investigation
of the extended FAST exam,
in which we can look for free fluid
within the abdominal and pelvic cavities
as well as within the thoracic cavities.
Finally, probe position E is the positioning of the probe
to look anteriorly on the chest for pulmonary edema
or ultrasonic B-lines.
Now let's learn how to evaluate the inferior vena cava
for assessment of central venous pressure.
First I place the probe
in the subxiphoid four chamber position
looking at the heart,
then I rotate the probe more posteriorly
down towards the spine to look at the IVC
as it runs from the right atrium down through the liver.
In this view the IVC will be seen as a cylinder
allowing us to get the full dimensions of the chamber.
The probe can be moved
slightly towards the patient's right side
to best image the IVC as it runs through the liver.
And one would like to follow the IVC
all the way down through the liver
towards the confluence of the hepatic veins
as the IVC should be measured just distal to this position
where the IVC and the hepatic veins join each other.
The next step is to visualize the IVC
in the long axis configuration
to corroborate the findings found on short axis view.
To do this the probe is swiveled with the IVC in sight
from a short axis view with the marker dot
oriented towards the patient's right to the long axis plane
with the probe in an up-and-down configuration
and the marker oriented upwards towards the ceiling.
In this way, the IVC will appear as a tubular structure
running up and down the screen with the superior aspect
towards the left and the inferior aspect
towards the right of the screen.
In this illustration we see a long axis configuration
of the IVC.
To determine the volume of the core vascular circuit
or the central venous pressure,
the IVC needs to be looked at
with regards to two specific variables.
The first is the absolute size of the IVC
and the second is the percentage change
from expiration to inspiration.
The IVC is measured at a point about two centimeters
distal to the confluence of the right atrium
at a point just inferior to the confluence
of the hepatic veins.
A small IVC that measures less than two centimeters
and that collapses greater than 50% with inspiration
or a sniff maneuver generally correlates
to a lower CVP less than 10 centimeters of water.
Conversely, a larger IVC greater than two centimeters
that collapses less than 50%
with inspiration or sniff maneuver
correlates to an elevated CVP above 10 centimeters of water.
In this way we can use analysis of the IVC
to get valuable information
about the patient's central venous pressure.
In this video clip we'll take a look at the IVC
in a short axis configuration
first aiming the probe
to a subxiphoid chamber view right there.
We see a positive pericardial effusion.
Now let's watch the IVC as it moves inferiorly
away from the right atrium through the liver
and we can see there the confluence of the hepatic veins.
Remember we wanna measure the absolute size
and the inspiratory collapse of the IVC
just distal to the hepatic veins.
And we can see there that the IVC is relatively small
and that it has a high percentage change
from expiration to inspiration.
We can use M-Mode ultrasound to graphically show
the changes in the IVC over time.
Here we notice that the IVC is 2.74 centimeters
at its widest diameter during expiration
but that it closes to 0.44 centimeters during inspiration.
And while we talked about the absolute size of the IVC
as being a predictor of CVP,
I actually think the percentage change
during respiratory variation is more important
as a predictor of CVP.
And in this patient we notice a greater than 50% change
indicating a relatively low CVP
less than 10 centimeters of water.
Now we'll swivel the probe to a long axis configuration
with the probe marker up towards the ceiling
and the probe aligned in an up-and-down configuration
across the patient's abdomen.
Superior to the left, inferior to the right
we see the IVC as a tubular structure.
Now noting the inspiratory changes of the IVC
we can see that the walls almost completely collapse
during inspiration
and with a small indicator arrow
I'll show the area where we should generally measure the IVC
that's two centimeters distal to the confluence of the IVC
to the right atrium just inferior
to the confluence of the hepatic veins with the IVC.
So a CVP less than 10 centimeters of water
with inspiratory collapse of the IVC.
We can again put M-Mode ultrasound over the IVC
to further graphically determine the general size
and respiratory dynamics of the IVC
and we can see that this is a smaller IVC
that measures 0.98 at expiration
and that almost completely closes,
in fact does close during inspiration
demonstrating a low CVP less than 10 centimeters of water.
Let's contrast those last video clips with this one.
Beginning with the heart in a subxiphoid four-chamber view
we see that this heart is not beating well.
As we aim the probe more inferiorly
down to image the IVC
as it moves inferiorly down through the liver
from the right atrium we can see that this IVC is very large
and that it has little inspiratory collapse.
In fact, we also see the three hepatic veins
are very engorged.
Notice we can also see little speckles of prethrombus
within the IVC indicating a low flow state.
Now we'll put M-Mode ultrasound directly over the IVC
in the short axis configuration.
Notice this IVC is relatively large at 2.52 centimeters
and then has very little change during inspiration.
We can also see the speckles of prethrombus
within the lumen of the IVC indicating a low flow state.
So this patient has a CVP
that's greater than 10 centimeters of water.
In fact, this tank is pretty full.
Now we'll swivel the probe to the long axis configuration
with the probe marker up towards the ceiling
and the probe aligned up and down on the patient's abdomen.
Superior here is towards the left of the screen
and inferior to the right.
With a small indicator arrow
I was just showing the engorged hepatic vein
entering into the IVC.
Recall that we wanna measure the IVC
just inferior to that point
where the hepatic vein enters into the vessel.
Here we see very little inspiratory collapse of the IVC
as well as a plethoric or dilated IVC
that indicates a high CVP
greater than 10 centimeters of water.
We can put that M-Mode cursor right along the IVC
just inferior to the confluence of the hepatic vein.
Again we see the IVC is dilated
greater than 2.46 centimeters but more importantly
notice here the small respiratory variation of the IVC
from expiration to inspiration
indicating an elevated CVP
greater than 10 centimeters of water.
Let's put all that information into play
in a real clinical case of a hypotensive patient.
This is a four-chamber subxiphoid view.
That's the right atrium, right ventricle, left ventricle,
and left atrium.
Here we see a large circumferential
dark anechoic pericardial effusion surrounding the heart.
So what we'll do is we'll duck the probe inferiorly
down towards the spine looking at the IVC
as it moves away from the right atrium into the liver.
Here we see the IVC as it emerges from the right atrium.
Notice here that this IVC has little respiratory collapse
and that it's relatively large in size
and we can see the dilated hepatic veins
joining into the IVC.
In the presence of a significant pericardial effusion,
this is concerning for potential early tamponade physiology
as one sees an elevation of the CVP as tamponade progresses.
We'll confirm those findings by swiveling the probe
to the long axis configuration superior to the left,
inferior to the right.
Again, we see the heart with a large pericardial effusion.
Notice here we see the IVC that's relatively distended
or plethoric greater than two centimeters
just distal to that hepatic vein
and notice the little respiratory collapse
of the IVC with inspiration
indicating a relatively high CVP
and the potential for early tamponade physiology
in this patient.
There may be times where visualization
of the inferior vena cava can be limited by gas
or fluid-filled intestine or stomach.
In these cases, visualization of the internal jugular veins
can act as an alternate measure
for assessing central venous pressure.
In this examination,
the head of the bed is placed upwards 30 degrees
and a high-frequency linear array probe is placed
tangentially or in a short axis view
across the internal jugular vein.
Here we see a plethoric or distended internal jugular vein
that has little inspiratory collapse
indicating a relatively high CVP.
This ultrasonic assessment of jugular venous distension
or CVP can be confirmed by using the probe
in a long axis configuration with the probe up and down
along the neck in the plane of the internal jugular vein.
I like to have the probe marker upwards
towards the patient's head
and here we can see the internal jugular vein is distended
all the way from low just above the clavicle to high,
all the way just below the mandible
indicating jugular venous distension on ultrasound
or a relatively high central venous pressure.
Now let's take a look at the jugular vein
in a patient who presented
with hypovolemic hypotensive shock.
We see here the probe is in a short axis configuration
across the internal jugular vein
and we notice a very small IJ vein
that almost completely collapses during inspiration
indicating a relatively low CVP
and the need for immediate resuscitation with IV fluids.
We can corroborate those findings
by moving the probe to a long axis configuration
with the probe marker up towards the patient's head.
We see the carotid artery deep to the internal jugular vein
and we see the closing level of the IJ vein
low within the neck.
Again corroborating a low CVP
less than 10 centimeters of water
and the need for immediate resuscitation
with intravenous fluids in this hypovolemic patient.
Step two in the assessment of the tank
is to look for tank leakiness or overload.
This is performed by using the extended FAST exam
putting the probe into positions two, three, and four,
the right upper quadrant, left upper quadrant,
and suprapubic views.
This will determine the presence of free fluid
within the abdominal, pelvic, and thoracic cavities.
While the RUSH exam is not specifically designed
for the evaluation of the trauma patient,
occasionally a patient may present
as a delayed presentation of trauma
or after occult trauma with this positive finding.
In this situation, a surgical consultation
and operative repair for an injury to an internal ogran
may be indicated.
In this view we have a positive right upper quadrant exam
with free fluid in Morison's pouch.
Now in the non-trauma patient, this could indicate
failure of the heart, liver, or kidneys
as contributing pathology
to the patient's physiological state.
Now the patient with a fever on this finding,
this would indicate the possibility
of spontaneous bacterial peritonitis
and the need for paracentesis
to obtain cultures of the fluid.
By angling the ultrasound probe
above the right upper quadrant and left upper quadrant views
we can actually look above the diaphragm
to look for the presence of positive free fluid
within the thoracic cavities.
Here we have a positive examination
from left upper quadrant view,
the small arrow indicating the presence of free fluid
within the left thoracic cavity.
We can see the spleen to the right or inferior
and we can see the lung waiving around superior
or towards the left.
In the non-trauma patient
this could show the possibility
of lung, kidney, or heart failure
as an exacerbating condition to the patient's pathology
and the patient with a presentation of occult trauma
or delayed presentation of trauma,
this could indicate a hemithorax needing urgent treatment.
Lung ultrasound applications
have become increasingly important in the assessment
of the hypotensive patient or the patient with dyspnea.
In this examination, which is still part of part two,
assessment of the tank looking for tank leakiness
or tank overload, we use the three megahertz probe
to examine the pleura by placing the probe
both anteriorly and laterally on the chest.
This would be a normal examination
and we can see the pleural line moving back and forth
towards the top of the screen.
We note here the presence of multiple A-lines,
those horizontal reverberating lines
coming off of the pleura at regular intervals
that are indicative of normal lung.
In contrast, let's take a look at this video clip
taken from a patient
who presented with acute pulmonary edema.
Here we see the pleural line
as taken with a three megahertz lower frequency probe
and instead of those repeating horizontal lines
the A-lines that we saw in normal lung
now we see the development of these vertical lines
known as lung rockets.
And here we see the lung rockets
emanating all the way to the back of the screen
using the three megahertz probe.
Lung rockets are also known as ultrasonic B-lines
and these indicate fluid within the alveoli.
Now, if the B-lines are seen
in multiple areas of the lung bilaterally,
this is more consistent with acute pulmonary edema.
As pulmonary edema progresses,
we can see the development
of more and more ultrasonic B-lines or vertical lung rockets
showing a worsening of the pulmonary edema.
In this situation we almost see a complete lung whiteout
with multiple rays coming off of the pleural line
showing the development of multiple lung rockets
within one ultrasound field.
Now while the presence of ultrasonic B-lines
are indicative of a syndrome
known as alveolar interstitial syndrome or AIS,
which just shows the presence of positive fluid
within the alveoli,
if this is diffuse on both sides of the chest
this is more indicative of pulmonary edema
and the presence of tank overload.
The final step in evaluation of the tank
is to look for tank compromise
or the presence of a tension pneumothorax
requiring emergent decompression.
We see the positive lung findings on the right
with a 10 megahertz probe, we see the lung sliding
as the patient breathes the lung moves back and forth.
We can see the opposed parietal and visceral pleura
with positive vertical comet tails and sliding.
To the left we see a positive pneumothorax
and notice here we see the stationary parietal pleura,
which shows no sliding back and forth.
We also see the absence
of the vertical comet tail artifacts.
In the hypotensive patient
these findings may necessitate emergent decompression
with the needle or chest tube.
So in conclusion, thank you for joining me
for part two, Assessment of the Tank of the RUSH Protocol.
As we described, this is a three-part evaluation
beginning with part one, evaluation of tank fullness,
which as we described is an examination
of the inferior vena cava and internal jugular veins
to assess central venous pressure.
Part two, evaluation for tank leakiness
and overload is performed by the extended FAST exam
to look for free fluid within the abdomen and pelvis
as well as to look for the presence of ultrasonic B-lines
indicative of pulmonary edema.
The last part of the tank assessment
is to look for tank compromise
or the presence of a tension pneumothorax
indicated by the lack of lung sliding
and the lack of positive comet tail artifacts.
Now we can begin to use the RUSH protocol
to assist in the evaluation of the hypotensive patient
to allow us to figure out which type of shock
the patient is suffering from.
Let's take a look at this table
with regard to beginning with hypovolemic shock to the left.
On assessment of the pump,
the heart may be small in size and hypercontracting.
On evaluation of the tank, the inferior vena cava
and internal jugular veins may be small in size
with a large percentage change
from expiration through to inspiration.
In a patient who has an occult trauma
or delayed presentation of trauma
we may actually see positive free fluid
in the peritoneal cavity or within the pleural cavity
indicative of blood.
In the second type of shock, cardiogenic,
we may see a dilated heart which is hypocontracting.
The IVC and internal jugular veins may be distended
with a small percentage change from expiration
through to inspiration.
Also, we may see pulmonary edema
as evidenced by the presence of multiple lung rockets
and it's not uncommon for us to visualize
a pleural effusion or ascites in these patients.
In the presence of obstructive shock
of which we think of the three main categories
being one, cardiac tamponade;
two, massive pulmonary embolus;
and three, tension pneumothorax,
generally on assessment of the pump
we're gonna see a hypercontracting heart.
In the presence of cardiac tamponade
we're gonna look for the presence of pericardial effusion
and diastolic collapse of the right ventricle
and or right atrium.
Now we'll discuss the findings of a large pulmonary embolus
in an upcoming video,
but generally we're looking for dilatation
of the right side of the heart
and we may be able to visualize a cardiac thrombus.
On assessment of the tank
and the different types of obstructive shock
we generally will see a distended
and large inferior vena cava and internal jugular veins
with little respiratory collapse.
In the presence of a tension pneumothorax
we can see absent lung sliding
and absent vertical comet tail artifacts
requiring emergent decompression.
In the last category of shock,
distributive, of which sepsis will be the main cause,
on evaluation of the pump in early sepsis
we'll generally see a hypercontracting heart.
As sepsis continues we may see a component
of cardiac failure and hypocontraction.
On evaluation of the tank,
the IVC and internal jugular veins
will generally be small in size
with the large comparative change
during the respiratory phases.
We may be able to see the presence of peritoneal fluid
indicating a spontaneous bacterial peritonitis,
especially in liver patients,
and we may also be able to see pleural fluid
indicated in empyema
and the appropriate patients requiring drainage.
So, now we can see how we can use
all of the assessment that we've learned
in the evaluation of the pump and the tank
to stratify the different types of shock accordingly
with the ultrasound findings.
So I look forward to seeing you back in the future
as the RUSH series continues with part three
Evaluation of the Pipes.

Brightcove ID

5754395503001

https://youtube.com/watch?v=oXiIU4mx-H8

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