CCP 216 Cardiovascular Emergencies ❤️ Flashcards

Question 1

Q

preload equation (Laplace’s law)

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Preload = (Ventricular pressure x Ventricular chamber radius) / 2x ventricular wall thickness (i.e. P⋅R/2h)

Question 2

Q

afterload definition

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

“load” that the heart must eject blood against
a result of stress (or “tension”) that the cardiac wall (LV) experiences during systolic ejection
the amount of pressure that the heart needs to exert to eject the blood out if it during the contraction

Question 3

Q

preload definition

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Myocardial sarcomere length just prior to contraction, for which the best approximation is end-diastolic volume
Tension on the myocardial sarcomeres just prior to contraction, for which the best approximation is end-diastolic pressure

cardiac preload is about the length-tension relationship. this is the core principle of the frank-starling mechanism

Question 4

Q

factors leading to increased cardiac afterload

Answer

A

Afterload is increased when aortic pressure and systemic vascular resistance are increased.
aortic valve stenosis and ventricular dilation will both increase afterload

Question 5

Q

cardiac afterload equation

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

[(LV Pressure x LV Radius) / LV wall thickness] or [(P x r)/h]
LV Wall Tension = [(SVR - Pleural Pressure) x LV Radius] / LV wall thickness

Afterload reduction can be achieved through:

Decreasing SVR (arterial dilation)
Increasing pleural pressure (PPV/PEEP)

Question 6

Q

hydralazine MOA

Answer

A

direct acting arterial vasodilator

stimulates the formation of nitric oxide by the vascular endothelium
inhibits release of calcium from the smooth muscle sarcoplasmic reticulum
causes smooth muscle hyper-polarization through the opening of K+ channels

Question 7

Q

mechanisms to reduce cardiac afterload

Answer

A

Decreasing SVR (arterial dilation)

2. Increasing pleural pressure (PPV/PEEP)

Question 8

Q

primary determinants of cardiac preload

Answer

A

Pressure filling the ventricle

2. Compliance of the ventricle

Question 9

Q

primary determinants of “pressure filling the ventricle” (cardiac preload)

Answer

A

Intrathoracic pressure (pleural pressure aka esophageal pressure)
Left atrial pressure
Right atrial pressure
Mean systemic filling pressure
Cardiac output

Question 10

Q

primary determinants of “Compliance of the ventricle” (cardiac preload)

Answer

A

Pericardial compliance

2. Ventricular wall compliance

Question 11

Q

primary determinants of “myocardial wall stress” (cardiac afterload)

Answer

A

[(LV Pressure x LV Radius) / LV wall thickness] or [(P x r)/h]
LV Wall Tension = [(SVR - Pleural Pressure) x LV Radius] / LV wall thickness

P: ventricular transmural pressure (difference between intrathoracic pressure and ventricular pressure)

r: radius of the ventricle (Increased LV diameter increases wall stress at any LV pressure)
h: thickness of ventricular wall (thicker wall decreases wall stress by distributing it among larger number of sarcomeres)

Question 12

Q

primary determinants of “input impedance” (cardiac afterload)

Answer

A

Arterial compliance (Aortic compliance, Peripheral compliance)
Inertia of the blood column
Ventricular outflow tract resistance (HOCM, AS)
Arterial resistance (Length of arterial tree, Blood viscosity, Vessel radius)

Question 13

Q

input impedance definition (cardiac afterload)

Answer

A

describes ventricular cavity pressure during systole

Question 14

Q

contractility definition

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

“Contractility describes the factors other than heart rate, preload, and afterload that are responsible for changes in myocardial performance.”

change in peak isometric force (isovolumic pressure) at a given initial fibre length (end diastolic volume)
length-independent activation

Question 15

Q

Type 1 MI

Answer

A

caused by acute atherothrombotic CAD
usually precipitated by atherosclerotic plaque disruption (rupture or erosion)

“Vaso-occlusive”

Question 16

Q

Type 2 MI

Answer

A

MI caused by oxygen supply/demand mismatch

“Demand”

Question 17

Q

Type 3 MI

Answer

A

Patients with a typical presentation of myocardial ischemia/infarction with unexpected death before blood samples for biomarkers could be drawn

“Sudden cardiac death”

Question 18

Q

Type 4 MI

Answer

A

MI as a complication of PCI

Question 19

Q

Type 5 MI

Answer

A

MI as a complication of CABG

Question 20

Q

typical value for right atrial pressure (RAP) in an adult

Answer

A

RA 5 mmHg

“nickel”

Question 21

Q

typical value for right ventricular pressure (RVP) in an adult

Answer

A

RV 25/5 mmHg (systolic/diastolic)

“quarter”

Question 22

Q

typical value for left atrial pressure (LAP) in an adult

Answer

A

LA 10 mmHg

“dime”

Question 23

Q

typical value for left ventricular pressure (LVP) in an adult

Answer

A

LV 100/10 mmHg (systolic/diastolic)

“dollar”

Question 24

Q

tachyphylaxis definition

Answer

A

very rapid development of tolerance or immunity to the effects of a drug
sudden decrease in response to a drug after its administration

Question 25

Q

Virchow’s triangle (venous thrombosis)

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Hyper coagulability
Stasis
Endothelial injury

Question 26

Q

Five causes of hypoxemia

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Low partial pressure of inspired oxygen
VQ mismatch
Diffusion impairment
Hypoventilation
Shunt (venous admixture)

Question 27

Q

differentials for sinus bradycardia

Answer

A

“EPI-ID” (a reichertism)

Electrolytes
Parasympathetic response
Infarction
ICP elevation
Drugs/Pharmacologic

Question 28

Q

Stanford type “A” aortic dissection

Answer

A

Affects ascending aorta
Accounts for 60% of aortic dissections
Initially managed surgically

Question 29

Q

Stanford type “B” aortic dissection

Answer

A

Affects descending aorta
“B begins beyond brachiocephalic vessels”
Accounts for 40% of aortic dissections
Initially managed medically

Question 30

Q

primary risk factors for aortic dissection

Answer

A

advancing age
male sex
systemic hypertension
preexisting aortic aneurysm
atherosclerosis
connective tissue disorders
sympathomimetic drug abuse

Question 31

Q

cardiac steal syndrome

Answer

A

The heart’s vessels naturally auto regulate to facilitate even flow to all areas
In the presence of a coronary lesion, the vessel will dilate to accommodate improved flow distal to the plaque
If you have two vessels branching off a main vessel, and one branch vessel contains a plaque, the flow to each vessel will still be 50/50 via auto regulation
If the person becomes vasodilated, the vessel containing the plaque is already maximally dilated d/t auto regulation. Now, the second branch vessel will dilate, causing what was previously 50/50 flow distribution to shift to a disproportional distribution, such as 80/20, which means the tissue distal to the site of the plaque will get reduced flow.
The good vessel is “stealing” flow from the occluded vessel d/t vasodilation beyond what the shitty vessel is capable of

Question 32

Q

primary determinants of cardiac contractility

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Preload
Afterload (the Anrep effect)
Heart rate (the Bowditch effect)
Myocyte intracellular calcium concentration
Temperature

Question 33

Q

Biochemical and cellular factors which affect cardiac contractility

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Catecholamines and the autonomic nervous system (Calcium concentration)
ATP availability (eg. ischaemia)
Extracellular calcium (Calcium concentration)
Temperature

this shit is super important and you gotta know how it impacts the heart in a range of disease. everything from your bread and butter HFrEF all the way to your septic-induced cardiomyopathy and your post-cardiac-arrest myocardial stunning

Question 34

Q

Key clinical findings for diagnosing cardiac tamponade

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Beck’s Triad (JVD, muffled heart sounds, hypotension)
Compressed RA (ultrasound)
Non-collapsible IVC (ultrasound)
pulsus paradoxus (arterial waveform)

remember kids, tamponade is a clinical diagnosis. just because the guy has a big old pericardial effusion on ultrasound it does NOT mean he is in tamponade.

tamponade is a clinical SYNDROME characterized by shock which can be interpreted through your clinical exam as seen in the above points

Question 35

Q

define pulsus paradoxus

Answer

A

During normal spontaneous breathing, negative pleural pressure against the heart during inspiration produces a slight increase in transmural pressure and cardiac afterload
During normal spontaneous breathing, inspiration causes blood to fill the RA from the vena cava, and causes increased RV filling with a slight bulge of ventricular septum into the LV
This causes a small decrease in LV ejection with systole (increased afterload, decreased LVEDV). In normal breathing, SBP can normally fall on inspiration by 10 mmHg
Pulsus paradoxus is an exaggeration of this normal blood pressure variation with breathing. It is defined as a fall in systolic pressure by more than 15 mmHg during spontaneous inspiration
In a mechanically ventilated patient, a reversal of this pressure variation occurs. PPV displaces the LV wall inward during systole to assist in LV emptying. This causes a slight rise in the systolic pressure during mechanical inspiration.
Reversed Pulsus Paradoxus (PPV) is defined as an exaggeration of the rise in systolic BP during mechanical inspiration. A rise in peak systolic pressure on mechanical inspiration by more than 15 mmHg is considered significant.

you can measure this with Korotkoff sounds but really the best/easiest way to see it is in A-line Δ pulse pressure variation

Question 36

Q

delta (Δ) pulse pressure variation definition

Answer

A

the difference between the maximal and minimal pulse pressure during one breathing cycle, divided by their mean

you can measure this with korotkoff sounds but really the easiest way is to watch the ΔPP variation on A line. there will be a drop in BP during negative pressure spontaneous breathing, and a rise in BP during positive pressure MV

Question 37

Q

systolic blood pressure definition

Answer

A

the maximum pressure experienced in the aorta when the heart contracts and ejects blood into the aorta from the left ventricle

this can be seen on the cardiac cycle PV loop at the point where the AV closes

Question 38

Q

diastolic blood pressure definition

Answer

A

the minimum pressure experienced in the aorta when the heart is relaxing before ejecting blood into the aorta from the left ventricle

this can be seen on the cardiac PV loop as the point where the AV opens at the end of systolic iso-volumetric contraction

this is because the valve is just opening but the aorta hasn’t actually “seen” any of the pressure yet, so it is actually at the lowest pressure state it will be in in the pressure-volume cycle

Question 39

Q

mechanism behind naturally occurring hypertension as people age

this slide is legit don’t just write it off cause you think old people are boring

Answer

A

With aging, there is a decrease in the compliance of the large elastic arteries.
This change is due to structural molecular changes in the arterial wall, including decreased elastin content, increased collagen I deposition, and calcification, which increases the stiffness of the wall
This process is often described as “hardening of the arteries.”
As the LV contracts against stiffer, less compliant arteries, SBP and DBP increase
In response, the LV tends to hypertrophy

this is legit to know cause it factors into our cardiac afterload equation nicely. factors that increase cardiac afterload include intra cardiac factors or extra cardiac factors. extra cardiac factors are things the impede LV outflow of blood. part of this is the “compliance” of the arterial system. meaning, as people age and get shitty calcified vessels they will have significantly elevated cardiac afterload d/t worsening arterial compliance

Question 40

Q

Differentials for a narrowed pulse pressure in shock

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

heart failure (decreased pumping)
hypovolemia (decreased blood volume)
aortic stenosis (reduced stroke volume)
cardiac tamponade (decreased filling time)

Question 41

Q

Normal amount of pericardial fluid

Answer

A

10–50 mL

Question 42

Q

TnK vs alteplase in the fibrinolysis of AMI

Answer

A

TnK is associated with a lower rate of non-cerebral bleeding complications (ASSENT-2 trial)

Question 43

Q

summarize the benefits of beta blockers in AMI

Answer

A

1) Decreased MvO2
2) Decreased risk of VF/dysrhythmias
3) Decreased automaticity
4) Prolonged diastole & increased coronary perfusion
5) Reduction in cardiac remodelling
6) Slows progression of atherosclerosis
7) Inhibits platelet aggregation and thromboxane synthesis
8) Reduction in reperfusion injury

Question 44

Q

At what phase in the cardiac cycle does the majority of ventricular filling occur?

Answer

A

early diastole

2. a large initial pressure gradient leads to rapid ventricular filling

Question 45

Q

How can a paralytic drug affect hemodynamics?

Answer

A

Loss of skeletal muscle tone leads to a relative vasodilation, reducing venous return to RA

Question 46

Q

A 0.6mg/hr (600mcg per hr) transdermal NTG patch has the equi-pharmaceutical potency of what IV NTG infusion rate?

Answer

A

10mcg/min

Question 47

Q

Describe the approach to staged dosing for labetalol

Answer

A

Labetalol is designed to be given in bolus-dose pushes q10min

5mg (wait 10)
10mg (wait 10)
20mg (wait 10)
40mg (wait 10)
80mg (wait 10)

Stop at total of 300mg and consider another vasodilator like hydralazine, phentalomine, nitroprusside or nifedipine

Question 48

Q

cardiac index definition

Answer

A

a measure of cardiac function that can be normalized for the patient’s body habitus
a haemodynamic parameter that relates the cardiac output (CO) from left ventricle in one minute to body surface area (BSA)
Calculated as CI (L/min/m2) = CO (L/min) / TBSA (m2)

Question 49

Q

Clinical findings associated with pericarditis

Answer

A

Positional “pleuritic” chest pain (improved with sitting up and leaning forward)
Pericardial “Friction rub” on auscultation of left lower sternal border
Diffuse, concave ST-E on ECG with P-R depression
low-grade fever

Question 50

Q

What patient cohort requires “emergent rescue PCI” in the setting of STEMI (post thrombolysis)

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

1) Persistent ST-E that hasn’t decreased by at least 50% following thrombolysis
2) Persistent ischemic C/P post thrombolysis

Question 51

Q

What is the target time-frame for achieving rescue PCI in the setting of STEMI failed thrombolysis

Answer

A

Ideal time frame is within 2 hours

2. Necessary within 24 hours

Question 52

Q

What is the preferred P2Y-12 inhibitor agent for patients who will be receiving primary PCI?

Answer

A

Ticagrelor (Brilinta) 180mg is the preferred P2Y-12 inhibitor agent for patients who will be receiving primary PCI
If using clopidogrel (Plavix) for PCI, double the usual age-based dose that would be administered in the setting of fibrinolysis

Question 53

Q

What is the preferred P2Y12 inhibitor agent for patients who will be receiving primary fibrinolysis?

Answer

A

Clopidogrel (Plavix) is the preferred P2Y12 inhibitor agent for patients who will be receiving primary fibrinolysis
Age ≤75 Clopidogrel 300 mg
> 75 Clopidogrel 75 mg

Question 54

Q

P2Y12 inhibitors MOA (platelet activation)

Answer

A

Inhibition of platelet aggregation impairs formation and progression of thrombotic processes
A core part in the platelet activation process is the interaction of adenosine diphosphate (ADP) with the platelet P2Y12 receptor
P2Y12 inhibitors provide irreversible blockade of the P2Y12 component of the ADP receptor on platelet surface
Results in reduced platelet adhesion, activation and aggregation

Question 55

Q

aspirin MOA (platelet aggregation)

Answer

A

Inhibition of platelet aggregation impairs formation and progression of thrombotic processes
A core part in the platelet activation process is the activation of thromboxane A2 (an important lipid responsible for platelet aggregation)
aspirin use irreversibly blocks the formation of thromboxane A2 in platelets, producing an inhibitory effect on platelet aggregation

Question 56

Q

Transfer to PCI-capable centre is preferable compared to primary fibrinolysis if PCI can be achieved within ___ minutes of first medical contact

Answer

A

120 minutes

Question 57

Q

The gold standard timeline for PCI in STEMI is within ___ minutes of first medical contact

Answer

A

90 minutes

Question 58

Q

indications for emergent PCI in NSTEMI

💵💵💵💵 MONEY SLIDE 💵💵💵💵

Answer

A

Hemodynamic instability
Electrical instability
Persistent C/P

Question 59

Q

Time-target for fibrinolysis (TnK) administration once a diagnosis of STEMI has been made, and the decision has been made to thrombolyze

Answer

A

30 minutes

Question 60

Q

Contraindications for PCI

Answer

A

1) Risk of bleeding during procedure.
2) Inability to take dual anti-platelet therapy (DAPT) for 1yr
3) Severe renal failure
4) Triple vessel disease (ie. needs CABG)
5) Palliative status

Question 61

Q

Anticoagulant of choice for an NSTEMI patient who is to be catheterized within 24 hours

Answer

A

unfractionated heparin (UFH)

Question 62

Q

Anticoagulant of choice for an NSTEMI patient who is to be catheterized in a timeframe beyond 24 hours

Answer

A

LMWH or Fondaparinux

Single dose LMWH or fondaparinux provides 24 hours of coverage

Question 63

Q

Amiodarone dosing for ventricular irritability/acute tachyarrhythmias (bolus and infusion)

Answer

A

Initial bolus: 150mg over 10 minutes
First 6 hours: 1mg/min
Next 18 hours: 0.5mg/min
total dose over 24 hours should not exceed 2.4 grams

Question 64

Q

What is the percentage of cardiac output used up during heavy diaphragmatic breathing/tachypnea

Answer

A

Up to 30% of CO can be used up during periods of tachypnea/heavy breathing
This is why sometimes it is necessary to intubate a patient in shock, as a mechanism for reducing their total oxygen demand, reducing myocardial workload, improving systemic oxygen delivery

Answer 65

A

trick question sonn

all patients with acute myocardial infarction (MI) should be treated with beta blocker therapy, unless there are gross contraindications

Answer 66

A

Thorax Pain (95.5% of individuals with AD report pain, with 84.8% of all individuals with AD describing an abrupt onset of pain; 90.6% of the individuals studied reported their pain as “severe or worst ever.”)
Abnormal CXR (Widening of the mediastinum 61.6% of cases, Widening of the aortic knob or abnormal contour 49.6% of cases
New aortic murmur (Approximately 40% of patients with a dissection demonstrate an aortic insufficiency/regurgitant murmur, reflecting unseating of the aortic valve by an ascending AD)
New onset peripheral pulse deficit (30% of patients with a Stanford Type A dissection and 15% with a Type B dissection demonstrate a pulse deficit.)

Answer 67

A

trick question buddy

Intensive statin therapy should be initiated as early as possible in ALL patients with STEMI

Answer 68

A

large dagger-like “septal Q waves” in the lateral — and sometimes inferior — leads
due to the abnormally hypertrophied interventricular septum

Answer 69

A

1) Nitrates (hydralazine is also an option, but it is less titratable and less predictable)
2) PEEP/NIPPV
3) Diuretics (IV Lasix)
4) Beta blocker (if HR > 150)
5) Transition to long-term antihypertensive (ie. labetalol and hydralazine)

Answer 70

A

Clonidine

2. dexmedetomidine

Answer 71

A

1) Atropine
2) Pacing (Transcutaneous or TVP)
3) Chronotropy (epinephrine, dopamine, isoproterenol)
4) Calcium (if secondary to hyper-kalemia)
5) Insulin (for beta blocker/CCB overdose)

Answer 72

A

Mechanical RV problem

Tamponade
tension PTX
dynamic hyperinflation
PE
Acute MI with rupture

Answer 73

A

Metabolic LV problem

Hyperkalemia
Sodium channel blockade
Agonal (terminal) rhythm
Acute MI with pump failure (severe myocardial dyskinesis)

Answer 74

A

QTc shortening

Answer 75

A

QTc lengthening

Answer 76

A

Left-sided heart failure

Answer 77

A

Left-sided HF (most common cause)
Pulmonary embolism (common)
Other causes of PH
RV outflow tract obstruction

Answer 78

A

Tricuspid regurgitation
Pulmonary regurgitation
Atrial septal defect

Answer 79

A

RV myocardial infarction

2. Ischemia may contribute to RV dysfunction in RV overload states (especially pressure overload)

Answer 80

A

Cardiomyopathy and heart failure
Arrhythmogenic RV dysplasia
Sepsis

Answer 81

A

Positive pressure ventilation
Acidosis
Hypercapnia
Hypoxia
High dose vasopressors

Answer 82

A

with LV failure the LV preload needs to be on the lower side, because high LV preload tends to lead to pulmonary oedema (all the extra preload just backs up into the lungs…)
with RV failure the preload needs to be highish, aka, RV failure is “preload dependent” (the RV requires a higher filling pressure) because the RV is essentially a passive conduit into the pulmonary circulation (RV lacks the same sort of intrinsic structural contractile force that the LV has so it’s more dependent on length-tension starling relationship provided by preload.

In RV failure you gotta force that shit into the lungs, cause if there’s no forward flow, the LV isn’t gonna receive any volume, which means there won’t be any forward flow and you’ll just go into shock and die..

Answer 83

A

fixed cardiac output
With beta blockade, the ICU patient is unable to reflexively increase their contractility or heart rate in response to stress

for example if you have a patient who is in severe sepsis and has a rapid AF with a ventricular rate of 130 and you knock them down with some metoprolol you could kill them by taking away their compensatory tachycardia and tanking their pressure

Answer 84

A

the relaxation of the myocardium

Answer 85

A

Maintain SpO2 >92% (Hypoxic pulmonary vasoconstriction is to be avoided)
Avoid excessive PEEP. PPV/PEEP is transmitted to the pulmonary circulation, adds to afterload. Unless patient is refractory hypoxemia d/t ARDS and needs to be oxygenated
Avoidance of hypercapnea. CO2 increases pulmonary arterial pressure and RV afterload
Pulmonary vasodilators (nitric oxide, prostacycline, bosentan, sildenafil, milrinone, levosimendan)

Answer 86

A

patients who have an LVEF less than 35% and a LBBB with a QRS duration of greater than 150 msec

Answer 87

A

ASD or VSD in the presence of high right sided pressures (pulmonary HTN)

Answer 88

A

all of these things will fuck up the contractility component of your CO equation

Acidosis (pH <7.20)
Hypoxia (PaO2 < 60mmHg)
Hyperkalemia (K+ > 5.5)
Hypomagnesaemia (Mg++ <0.9)
Hypocalcaemia (iCa++ <1.0)
Hypophosphataemia (PO4- <0.8)
Thiamine deficiency
Cortisol deficiency
Thyroxine deficiency
Alkalosis

Answer 89

A

Isovolumic relaxation
Ventricular filling
Isovolumetric contraction
Ventricular ejection

Answer 90

A

change in pressure per change in unit volume
relates best to the stiffness of a mechanical system
tendency to recoil back into its original dimensions in response to a distending force

Answer 91

A

change in ventricular volume per change in ventricular unit pressure

represents the compliance (distensibility) of the ventricular wall

Answer 92

A

the maximal pressure that can be developed by the ventricle at any given LV volume
one of the ways of measuring and describing cardiac contractility

Answer 93

A

iCa+ > 1.0 mmol/L (Low serum calcium is independently correlated with LV systolic dysfunction in CAD patients with and without AMI)
K+ 3.5-4.5 mmol/L (in setting of ACS, hypokalemia defined as potassium levels <3.5 is associated with ventricular arrhythmias)
Mg+ >1.0 mmol/L (low serum Mg levels may be associated with cardiac arrhythmias and sudden death. Magnesium has antiarrhythmic effects)

Answer 94

A

“Dual anti platelet therapy” (ASA + P2Y12 inhibitors)
Statin therapy (atorvastatin)
Beta blockade (metoprolol)
Nitrates (NTG)
Systemic anticoagulation (heparin/LMWH)
Maintain normoxia (SpO2 >90%)
Optimize electrolytes (target normal range)

Answer 95

A

Troponins
BNP
Lactate
SvO2
Extended lytes
BUN:Cr
CBC

Answer 96

A

The intubation procedure will most likely lead to some degree of Hypoxia/hypercapnia
Hypoxia/hypercapnia lead to pulmonary vasoconstriction, which causes increased right sided afterload
BMV/PPV will lead to high pulmonary pressures, again causing increased RV afterload, drop their CO
All this elevated RV afterload will put more stress/strain on the RV, eventually causing the person to arrest
induction will lead to decreased RV preload d/t vasodilation
Just try not to intubate or BMV RV failure patients.

Answer 97

A

Optimize preload with a fluid bolus (remember that tamponade is OBSTRUCTIVE and not cardiogenic shock. obstructive shock patients are preload dependent d/t elevated RV afterload
Augment rate: Allow tachycardia (in your CO equation your preload/afterload/contractility are all fucked so if you want to maintain MAP you’ll have to keep the HR a little bit higher)
Improve Forward flow: Levophed (if they are in shock you’ll have to support their hemodynamics with vasopressors. levy is 1st line)
Remove effusion: pericardiocentesis

Answer 98

A

CVP is measured at the SVC
The RA is more compliant than the SVC/IVC
The RA is also dynamic (ie. respiration variability)
there is rarely a point in time where RAP is able to truly equalize with CVP (as represented in the SVC)
there is a very poor relationship between CVP and blood volume and CVP/DeltaCVP is a poor predictor of the hemodynamic response to a fluid challenge
interpretation of CVP should be in association with information relating to other haemodynamic variables

Answer 99

A

Acidosis (pH <7.20)
Hypoxia (PaO2 < 60mmHg)
Hyperkalemia (K+ > 5.5)
Hypomagnesaemia (Mg++ <0.9)
Hypocalcaemia (iCa++ <1.0)
Hypophosphataemia (PO4- <0.8)
Thiamine deficiency
Cortisol deficiency
Thyroxine deficiency
Alkalosis

Answer 100

A

BNP (brain natriuretic peptide)
CK-MB (creatine kinase)
Cardiac Troponin
ANP (Arial Natriuretic Peptide)

Answer 101

A

Location (A, P, T, M)
Intensity (scale 1-6)
Pitch (eg harsh vs rumbling)
“Shape” (eg crescendo vs decrescendo)
Timing (eg early systole vs late systole)
Radiation (carotids, subclavians)

Answer 102

A

Acute vs chronic
Right vs Left
Systolic vs diastolic
High output vs low output

Answer 103

A

Systolic 25mmHg
Diastolic 10mmHg

25/10

Answer 104

A

Systolic 125mmHg
Diastolic 75mmHg

125/75

Answer 105

A

preload high (force blood through the tiny little hole)
afterload normal
HR low (prevent pulmonary edema/back flow)
contractility high (force blood out)

Answer 106

A

HR high (P1 → P2 relationship. Keep flow moving forward. Don’t allow time for backflow). these patients will be in a compensatory tachycardia in an attempt to maintain forward flow. if you slow their HR down you could put them into worsening AR, profound cardiogenic shock, and kill them.
afterload low (Improve your P1 → P2 relationship). you have to target afterload reduction in these patients. the afterload reduction is going to keep volume moving forward via P1 → P2. oftentimes these patients are d/t aortic dissection. typically we would want to use labetalol in dissection but if you use labetalol in these cats you’re gonna knock out their HR and fucking kill them. going to hydralazine or NTG would probably be a better option
contractility high (force blood out. Don’t allow time for backflow). you might have to start a concurrent dobutamine infusion in these guys to keep their contractility high to keep volume moving forward otherwise they’re just gonna keep backing up and fucking die.
put them on BiPAP or tube them and put them on PPV. It will decrease their MvO2 and improve their pulmonary edema and help with preload and afterload reduction

Answer 107

A

preload normal (Phenylephrine or vasopressin)
afterload normal
HR low (prevent pulmonary edema/back flow) [Esmolol or amiodarone]
contractility normal

Answer 108

A

HR high (P1 → P2 relationship. Keep flow moving forward. Don’t allow time for backflow). these patients will be in a compensatory tachycardia in an attempt to maintain forward flow. if you slow their HR down you could put them into worsening AR, profound cardiogenic shock, and kill them.
afterload low (Improve your P1 → P2 relationship). you have to target afterload reduction in these patients. the afterload reduction is going to keep volume moving forward via P1 → P2. oftentimes these patients are d/t aortic dissection. typically we would want to use labetalol in dissection but if you use labetalol in these cats you’re gonna knock out their HR and fucking kill them. going to hydralazine or NTG would probably be a better option
contractility high (force blood out. Don’t allow time for backflow). you might have to start a concurrent dobutamine infusion in these guys to keep their contractility high to keep volume moving forward otherwise they’re just gonna keep backing up and fucking die.
put them on BiPAP or tube them and put them on PPV. It will decrease their MvO2 and improve their pulmonary edema and help with preload and afterload reduction

Answer 109

A

pulmonary edema

2. cariogenic shock

Answer 110

A

Acute or subacute myocardial ischemia

Answer 111

A

Aortic dissection (widening of the valvular lumen d/t the dissection)
Endocarditis (vegetation causing leaflet destruction or periaortic valvular abscess rupture)

Answer 112

A

POCUS with colour doppler

2. Stethoscope is pretty useless tbh (only 50% of patients will have a new murmur on auscultation)

Answer 113

A

crescendo-decrescendo systolic ejection murmur

2. best heard at the right upper sternal border and radiates to the neck

Answer 114

A

PRELOAD DEPENDENT

give fluids/Avoid preload-decreasing drugs
Vasopressors for cardiogenic shock (Phenylephrine or vasopressin)
sensitive to both bradyarrhythmia and tachydysrhythmias (Treat both aggressively)

Answer 115

A

regurgitation volume fills the LV → increased LV diastolic pressure → decrease in forward flow + increased LA + pulmonary venous pressure
Decreased forward flow → hypotension and cardiogenic shock
Increased LA + pulmonary venous pressure → pulmonary edema

Answer 116

A

“to-and-fro” murmur
The combination of a soft systolic and low-pitched diastolic murmur produces a “to-and-fro” murmur at the cardiac apex

Answer 117

A

Ischemic MR (Papillary muscle rupture due to AMI)
Nonischemic MR (Ruptured chordae tendineae due to other cause [myxomatous disease, infective endocarditis, trauma, rheumatic heart disease])

Answer 118

A

regurgitation volume fills the LA → increased LA pressure → increased pulmonary venous pressure and pulmonary edema
LV volume is decreased due to the regurgitant volume → a decrease in forward flow → hypotension and cardiogenic shock

Answer 119

A

30 minutes door-to-needle for thrombolysis (if PCI unavailable)

Answer 120

A

Normal
Hyperacute t-waves (minutes to hours)
ST-elevation (minutes to hours)
Q-wave develops (hours)
ST-elevation resolves, residual t-wave inversion (hours to days)
T-wave recovery (days)

Answer 121

A

new ST elevation measured at the J-point relative to the PQ junction, in two contiguous leads
V2-V3: ≥2 mm in men ≥40 y old
V2-V3: ≥2.5 mm in men <40 y old
V2-V3: ≥1.5 mm in women regardless of age
Other leads: ≥1 mm

Answer 122

A

STEMI diagnosis-to-balloon time (at another facility) should not exceed 90 min (urban transfers)
The first medical contact-to-balloon time in transfer patients should not exceed 90-120 min (urban transfers)
If the total time from the first medical contact to PCI is estimated to exceed 90-120 min, fibrinolytics are recommended for symptom duration <12 h or 12-24 h if “a large area of the myocardium is at risk or hemodynamic instability is present.”
After thrombolytics, the patient should be transferred immediately to a PCI facility, if available and feasible.

Answer 123

A

Prior known coronary artery disease (CAD) (2.0)
A change in the pattern of symptoms over the previous 24 h (2.0)
Pain similar to prior ischemia (2.2)
Pain radiating to both arms (2.6)
History of peripheral arterial disease (PAD) (2.7)
Abnormal previous recent stress test (3.1)
High risk overall of clinical gestalt (4.0)
High-risk HEART score 7-10 (13.0)

Answer 124

A

ACS that does not have:

at least one troponin greater than the 99th percentile
an increase and/or decrease in troponin (defined for each assay)

and:
3. Is characterized clinically by angina that is new in onset, occurs at rest, occurs with minimal exertion, or is otherwise worsening from a previously stable pattern

Answer 125

A

requires both:

The detection of an increase and/or decrease of cardiac troponin values with at least 1 value greater than the 99th percentile upper reference limit
Clinical evidence of acute myocardial ischemia

Answer 126

A

Immediate PCI recommended for ischemic symptoms <12 h after onset, or 12-24 h if there is “ongoing ischemia”
NSTEMI with electrical/hemodynamic instability (acute pulmonary edema, shock, recurrent/refractory ventricular dysrhythmias, etc.)
NSTEMI with refractory ischemia (symptoms of angina or ECG findings of ischemia) despite maximum medical management

consider reperfusion therapy in:

“STEMI equivalents” (aka STEMI(-) occlusion MI patterns) - this is like your wellens, avR STEMI and shit like that

Answer 127

A

It will be >90-120 min total time from the first medical contact to PCI, or >90 min from STEMI diagnosis to PCI

and

Symptoms <12 h, or between 12-24 h if “a large area of the myocardium is at risk or hemodynamic instability is present”, or ECG shows high “acuteness” (large upright T waves, persistent R waves, persistent ST elevation)

Answer 128

A

Transfer to a PCI-capable facility should be carried out after the administration of thrombolytics
Immediate PCI is indicated if there is no ECG evidence of reperfusion after thrombolytics (“rescue PCI”)
ECG evidence of reperfusion is at least a >50% reduction in ST segments

Answer 129

A

Dual antiplatelet therapy (Aspirin + P2Y12 inhibitor)
Anticoagulant (UFH/enoxaparin/fondaparinux)
Oxygen (sats >94%)
Rate control (Metoprolol)
Analgesia (NTG, opioids)
Statin therapy
Reperfusion (TnK or PCI)
Angiotensin-converting enzyme inhibitors
Optimize electrolytes (target normal range)

Answer 130

A

opioids should be reserved for patients who are committed to immediate reperfusion therapy (PCI or thrombolysis)
Goal is to reduce ischemic pain during the time between the decision to perform definitive reperfusion and actual reperfusion

Answer 131

A

ACS refers to a spectrum of coronary diseases involving atherosclerotic plaque rupture and platelet-rich thrombus formation, causing stenosis or occlusion of the coronary artery with acutely diminished blood flow and resulting in hypoperfusion and ischemia, with or without infarction of the myocardium

Answer 132

A

the myocardial territory at risk
collateral circulation present
degree of coronary obstruction
showering of downstream platelet-fibrin aggregates into smaller vessels
myocardial oxygen demand (which is dependent on the heart rate and wall stress)

Answer 133

A

The spectrum of ACS currently includes:

unstable angina
NSTEMI
STEMI
sudden cardiac death (type 3 MI)

Answer 134

A

posterior STEMI (V1-V2 depression)
hyperacute T waves
de Winter’s T waves
modified Sgarbossa criteria
ST elevation in aVR associated with widespread ST depression

Answer 135

A

right ventricle
inferior wall of the LV
the AV and SA nodes
some or most of the posterior

Answer 136

A

LAD

2. Left circumflex

Answer 137

A

blocks adenosine diphosphate (ADP) production in platelets
ADP is one of the principal platelet activators

Answer 138

A

aspirin plus a P2Y12 inhibitor

2. could also refer to aspirin + a glycoprotein IIb-IIIa inhibitor, if no P2Y12 inhibitor is given

Answer 139

A

It is essential to achieve maximum platelet inhibition at the time of PCI, since this is a highly thrombogenic procedure.
the rapid onset of platelet inhibition with a P2Y12 inhibitor is especially important for immediate PCI
Higher doses act more rapidly than lower dose; this is especially useful for clopidogrel: 600 mg achieves earlier platelet inhibition than 300 mg

Answer 140

A

anticoagulation is a short-acting, temporizing therapy
anticoagulation treatment should be given to all patients with confirmed, active ACS without contraindications
anticoagulant administration is supported by the transient protection from MI granted by anticoagulation as a bridge to PCI for patients with unstable plaques

Answer 141

A

signs of CHF (Killip class III or IV)
low cardiac output (SBP <120, sinus rhythm heart rate <60 or >110 bpm)
high risk of cardiogenic shock
elderly (>70 y old)
heart block
any signs of acute SA or AV node dysfunction (most commonly seen in RCA occlusions).

Answer 142

A

If there are no contraindications (no heart failure, SBP at least 120, no tachycardia, no AV block) metoprolol IV offers benefit prior to PCI in anterior MI
Anterior MI patients treated with PCI (not fibrinolytics) without contraindications to beta blockers, who are anticipated to undergo PCI within 6 h of symptom onset and who have an SBP >120, have benefit from IV metoprolol given prior to PCI
All patients without contraindications benefit from oral metoprolol after PCI
Oral beta blockers are recommended for all ACS within the first 24 h without contraindications
it is reasonable to administer IV beta blockers at the time of presentation to patients with STEMI and no contraindications to their use who are hypertensive or have ongoing ischemia

Answer 143

A

CCB’s given with the intent of decreasing MvO2 have very little role in the early treatment of ACS in normal sinus rhythm
CCB’s role in ACS occurs in downstream scenarios as a substitute for beta blockers that have proven ineffective or are contraindicated, or in the chronic management of coronary artery spasm
there is no effect on the risk of death or initial/recurrent infarction when given routinely for AMI or unstable angina
CCB’s may be used to lower HR, and thus MvO2, in patients who are experiencing AF/Af w/ RvR or SVT in the setting of ACS
CCB’s are relatively contraindicated in patients with reduced systolic LV function for fear of acutely worsened CO and hypotension (put the echo probe on)

Answer 144

A

The early initiation of angiotensin-converting enzyme (ACE) inhibitors has been shown to reduce short- and long-term mortality in patients with AMI
ACE inhibitors should be used with caution within the first 24 h, since they may result in hypotension and/or renal dysfunction

Answer 145

A

statins convey long-term preventive mechanisms in ACS
statins offer benefits in the acute setting of ACS attributed to the “pleiotropic” effects of statins, including the inhibition of inflammatory and coagulation cascades and thrombus formation
reduced rates of periprocedural MI and other short-term clinical outcomes for ACS patients who received statins prior to PCI
it is reasonable to give the first dose of statin ASAP in any patient with ongoing ACS

Answer 146

A

pump failure (LV and/or right ventricle)
mechanical complications (papillary rupture, free wall rupture, etc.)
class I, level B recommendation for emergency PCI of STEMI in cardiogenic shock, regardless of the time since onset
class I, level B recommendation for emergency fibrinolysis for STEMI patients with cardiogenic shock who are unsuitable candidates for either PCI or CABG
Optimize the preload with fluids/blood as necessary based on fluid responsiveness and tolerance
Consider intubation, MV, and paralysis to reduce the demand for CO during the delay to definitive management
Norepinephrine is first-line pressor, then consider adding dobutamine for persistent low CO after norepinephrine

Answer 147

A

IV/O2/Monitor
Differentiating the shock (pump failure vs mechanical complications)
optimize the MAP (Norepinephrine +/-
Inotropic agent)
“fix the lungs” (CPAP/NIPPV/Intubation)
differentiate + optimize volume status (fluid bolus vs lasix)
consider inotrope for HFrEF/shitty contractility (dobutamine/epi)
treat underlying etiology
mechanical circulatory support

Answer 148

A

broad term that encompasses the pathophysiological end result of a multitude of disease processes
HF develops when any structural or functional cardiac disorder causes impaired ventricular filling or ejection of blood at a rate commensurate with the requirements of the metabolizing tissues while maintaining normal filling pressures

Answer 149

A

Impaired ejection, left ventricular ejection fraction (LVEF) ≤40%

Answer 150

A

Abnormal filling, LVEF ≥50%

Answer 151

A

Acute HF occurs when an acute event causes the heart to suddenly become unable to generate an adequate stroke volume
may be caused by, AMI, acute valve rupture, dysrhythmia, myocarditis, tamponade, or infection
May present as sudden “flash” pulmonary edema and/or shock.
Heart size may be normal as it has not had time to change in size

Answer 152

A

develops over time, often months to years.
Usually caused by ischemia, chronic HTN, or chronic valvular disease.
In ischemic heart disease, chronic valvular disease, and chronic uncontrolled HTN, the heart’s growth and remodelling process is an attempt to compensate for its decreasing function
An acute exacerbation of chronic HF can be triggered by infection, anemia, dietary or medication non-compliance, or coronary artery disease (CAD)

Answer 153

A

failure of the LV to pump blood forward → hypotension and hypoperfusion and the resulting backup of blood into the lungs (pulmonary edema)

Answer 154

A

failure of the RV to pump blood forward → failure of the RV to “feed” the LV its preload and a right sided backup of blood (causing JVD, hepatomegaly, and peripheral edema)
most common cause of right-sided failure is left-sided failure, and patients often present with manifestations of both
Isolated right-sided failure can occur acutely (eg, in PE, hypoxia, or acidemia) or chronically (eg, in COPD)

Answer 155

A

Abnormal filling, preserved ejection

2. LVEF ≥50%

Answer 156

A

Impaired ejection

2. LVEF ≤40%

Answer 157

A

Impaired ejection; LVEF ≤40%.
characterized by abnormalities in systolic function, usually with progressive chamber dilation and eccentric remodeling

Answer 158

A

Abnormal filling; LVEF ≥50%.

2. characterized by a normal LVEF, normal LV end-diastolic volume, and abnormal diastolic function

Answer 159

A

Hemodynamic abnormalities and circulatory failure from HF → neurohormonal activation and autonomic imbalance → increase in sympathetic activity and withdrawal of vagal activity
compensatory mechanisms exists to counteract circulatory failure from HF (eg, increase blood volume and filling pressures, increase HR and muscle mass)
Chronic wall stress → myocyte hypertrophy, death, and regeneration → eccentric remodeling that progressively impairs contractility, increases O2 demand/ischemia, and promotes arrhythmogenesis
Altered relaxation and increased stiffness of the ventricle (delayed Ca2+ uptake and efflux from myocytes) occur in response to an increased afterload (pressure overload)
Impaired relaxation → impaired diastolic filling of the LV
These processes occur slowly over time
when a trigger (eg, illness, dietary changes, medication non-compliance) temporarily worsens the cardiac output or increases the body’s demand, it overwhelms the compensatory mechanisms → acute decompensated HF

Answer 160

A

Severe subset of acute HF presentations characterized by rapidly progressing pulmonary edema (minutes to hours) and sympathetic overdrive
Decreased systemic perfusion and worsening oxygenation → sympathetic surge
sympathetic surge → further increases the afterload, resulting in worsening pulmonary edema, further sympathetic activity, and a rapidly decompensating patient
These patients are often overall fluid-depleted, even though they have significant pulmonary edema
SCAPE patients may not have signs or symptoms associated with chronic HF, such as cardiomegaly or lower extremity edema, because the condition develops over a very short period

Answer 161

A

AMI (12-lead + trops)
Acute valvular rupture (auscultation/bedside echo)
Pericardial tamponade (bedside echo)
Alcohol withdrawal (History and physical)
Arrhythmia (ECG)
Missed dialysis
Physiologic stress (eg septic cardiomyopathy or CO)
Thyrotoxicosis (history and physical, labs)
Medication non-compliance

Answer 162

A

treatment should be targeted to afterload and preload reduction
Afterload can be reduced with a number of medicines, including nitrates and ACE inhibitors
Nitrates are first line, with NTG being the most common
loop Diuretics can be used in intravascularly volume-overloaded patients for preload reduction (Lasix)
Check and replenish electrolytes, particularly magnesium and potassium (arrhythmias)

Answer 163

A

Address the underlying cause of shock
If shock is from pump failure, patients are frequently extravascularly fluid-overloaded but intravascularly volume-depleted
Fluid challenges in 250-mL isotonic crystalloid boluses with frequent re-assessment of intravascular volume status
if patient is still hypotensive post fluids, start an adrenergic agonist (norepinephrine)
Dobutamine is a good option for inotropy when the primary mechanism of shock is poor cardiac contractility. Patients may still require levo for hemodynamic support

Answer 164

A

🔥 PERFUSION: warm extremities, normal capillary refill, preserved renal function, good urine output, and adequate mentation.

💩 PERFUSION: cool extremities, poor capillary refill, acute kidney injury, oliguria, poor mentation, and elevated transaminases (“shock liver”)

Answer 165

A

High wedge pressure is suggested by pulmonary edema (dyspnea, rales on lung auscultation, edema on chest X-ray, and B-lines on lung ultrasound).
Low wedge pressure is suggested by dry lungs (no dyspnea, clear lungs on auscultation and chest X-ray, A-lines on lung ultrasound)
The best test to determine wedge pressure is lung ultrasonography.
Bilateral diffuse B-lines imply elevated wedge pressure, whereas bilateral A-lines suggest a low or normal wedge pressure.
Ultrasonography is more sensitive than chest X-ray or exam to detect mild cardiogenic pulmonary edema.

Answer 166

A

it’s possible for patients to have an elevated PCWP without total body volume overload (e.g. euvolemia plus an acutely deteriorating left ventricle).
Clinical history can be very useful here: is there a history of volume loss (e.g. gastroenteritis, over-diuresis) or volume gain (e.g. diuretic nonadherence, iatrogenic fluid administration)? Weight gain or loss?
Echocardiographic assessment of the IVC and jugular veins may allow estimation of the CVP
Peripheral pitting edema suggests systemic congestion

Answer 167

A

warm and dry

Answer 168

A

warm and wet

Answer 169

A

cold and dry

Answer 170

A

cold and wet

Answer 171

A

Fix lungs (CPAP/BIPAP)
Fix perfusion (Norepinephrine +/- inotrope)
Determine volume status and address

Answer 172

A

cardiogenic shock may trigger a SIRS response with elevated cytokine levels and ↓ SVR. This may occur later in the course of cardiogenic shock, possibly d/t ischemic tissue damage. This condition will mimic septic shock 🤯
some patients w/ septic shock will develop a sepsis-induced cardiomyopathy. So, advanced-stage septic shock and advanced-stage cardiogenic shock can look clinically quite similar (e.g., shock, vasodilation, reduced systolic heart failure, systemic inflammation)

Answer 173

A

CBC, Electrolytes including Ca/Mg/Phos (if hypocalcemia suspected check iCa)
Troponin (HF 2nd to MI?)
Lactate level (how sick is this dude)
LFT’s (marked transaminase elevation suggests shock liver with poor cardiac output)
TSH if thyroid disease suspected. (cardiac manifestations of myxoedema or thyrotoxicosis)
Digoxin level for patients on digoxin
BNP levels are unhelpful (cardiopulmonary ultrasonography is a superior test).

Answer 174

A

fix the lungs (O2 vs NIPPV vs Tube them)
optimize perfusion (Levo support?)
optimize volume status (fill the tank vs diurese)
optimize contractility (inotrope? electrolytes?)
treat underlying etiology (cath lab?)
consider mechanical circulatory support (does this dude need IABP/ECMO/LVAD)

Answer 175

A

Inotropes will cause a short-term improvement in hemodynamics
avoid catecholamine inotropes when possible
In hypotensive cardiogenic shock patients in whom nitroglycerine or diuresis is contraindicated inotropes may be used with a goal of reducing the PCWP and decongesting the lungs (cold and wet, hypotensive). Resuscitate with norepi FIRST!! Or else they could crash when you start the dob from the afterload reduction

Inotropes should be used only if necessary, for the following indications:

Hypoperfusion with low-normal blood pressure
Refractory cardiogenic pulmonary edema eg failed BiPAP, nitroglycerine (if blood pressure is adequate), and diuresis (if there is evidence of volume overload)

Answer 176

A

Normotensive patient with evidence of end organ hypo perfusion (shitty pump)
Refractory cardiogenic pulmonary edema in the hypotensive patient (mega shitty pump. resuscitate with NOREPI first)

Answer 177

A

HTN or normotension you’re gonna target preload/afterload reduction (NTG)
hypotension you’re gonna resuscitate with norepi (or epi if they’re mega fucked) then maybe consider adding in some dobutamine

Answer 178

A

thrombolytic facilitated PCI is using thrombolysis as a mechanism to facilitate a “better” PCI. (Ie giving a dose of lytics’ before PCI even when the person would be within the window timeframe for primary PCI)
Don’t do it
Facilitated PCI is bullshit

Answer 179

A

Passive leg raise
Decrease in HR when you give a fluid bolus
Use ultrasound to assess IVC collapsibility (patient must be sedated/paralyzed/on VCV
CVP assessment
JVP height measurement
Arterial waveform pulse pressure variation (SBP delta P variation of 16%)

Answer 180

A

Extremities colour, temperature, cap refill, mottling

Answer 181

A

The DeBakey classification, is used to separate aortic dissections into those that need surgical repair, and those that usually require only medical management

type I: involves ascending and descending aorta (Stanford A)
type II: involves ascending aorta only (Stanford A)
type III: involves descending aorta only, commencing after the origin of the left subclavian artery (Stanford B)

Answer 182

A

PA 25/10 (systolic/diastolic)

Answer 183

A

125/75 (systolic/diastolic)

Answer 184

A

Heparin – Binds to and potentiates the actions of antithrombin (AT) to inactivate factor Xa and prevent the conversion of prothrombin to thrombin, as well as prevent the conversion of fibrinogen to fibrin.
LMWHs – Also bind and accelerate the activity of AT, but with a preferential, and longer lasting effect on factor Xa. When compared to heparin, LMWHs are less able to inhibit the production of thrombin and bind to plasma proteins and endothelial cells less due to their decreased sized. This accounts for an 85-99% bioavailability when administered SC, more predictable anticoagulant response, less inter-patient variability, and longer duration of action than heparin
Fondaparinux - Binds and enhances the anti-Xa activity of AT by 300-fold. AT specificity does not allow binding to other plasma proteins. It has no direct effect on thrombin, has excellent bioavailability after SC administration and a long half-life

Answer 185

A

HR <60
SPB <120 mm Hg
art line for accurate titration of antihypertensives
If BP differs between arms on NIBP use the extremity/value with the higher BP
Labetalol IV 10-20 mg bolus over 2 min, then 20-80 mg bolus q10-15 min to a max of 300 mg, or initiate labetalol infusion at 0.5-2 mg/min, titrate up by 0.5 mg/min every 10 min to a max of 10 mg/min.

might have to stack hydralazine on top of your labetalol to hit the alpha reduction

Answer 186

A

1-2% increase in mortality per hour for each hour delay to definitive care (SURGERY)

Answer 187

A

aortic wall is composed of tunica intima, media, adventitia (inside → out)
AD is a failure of the aortic intima → propagation of dissection between intima/media d/t the patient’s pulse pressure
The passage of blood into this space can extend the tear and create a false lumen, → impaired perfusion at branch vessels or causing rupture
occurs when the integrity of the tunica intima is disrupted, allowing pulsatile blood to dissect through the tunica media
The pulsatile aortic flow propagates the dissection, typically in an antegrade fashion, from the intimal tear
Fenestrations between the true lumen and false lumen can occur downstream from the initial intimal defect, typically near the ostia of vessels branching off the aorta, maintaining false lumen patency
Areas of repeated mechanical stress associated with the cardiac cycle as well as higher hydrodynamic forces, such as the ascending aorta and first portion of the descending thoracic aorta, are at increased risk of AD

Answer 188

A

CCP treatment consists of reducing the pulse pressure-related shear force (Δp/Δt) through pharmacologic rate control followed by blood pressure control

Treat the pain. The most common presenting symptom of AD is pain. Pain is classically described as sudden in onset and severe. Ongoing pain leads to sympathetic stimulation causing tachycardia and worsening shear stress. Use IV opioids to treat the pain
Following adequate analgesia, a Class I recommendation based on expert consensus is to initiate intravenous β-blockade and titrate to an HR of 60 beats per minute or less. Use labetalol or esmolol if available. Start an a-line
If the SBP remains >120 mm Hg following the initiation of β-blockade, an intravenous vasodilatory agent should be initiated to reduce the SBP to <120 mm Hg while maintaining adequate end-organ perfusion. Use hydralazine

don’t forget ongoing analgesia. start an a-line and watch your BP closely

Answer 189

A

pump dysfunction
insufficient vascular tone
hypovolemia

PUMP, PIPES, FLUID

Answer 190

A

heart rate
cardiac loading conditions (ADCHF)
contractility

Answer 191

A

intravascular volume

2. vessel tone

Answer 192

A

Tachycardia
Right axis deviation
RBBB
S1Q3T3 (insensitive and non-specific)
T-wave inversion anterior leads

Answer 193

A

ventricular dysfunction where the RV is deformed
used to denote the presence of RV dysfunction usually in the absence of an underlying cardiomyopathy
can be caused by PHTN, PE, RV infarction, chronic lung disease (pulmonary fibrosis or COPD), pulmonic stenosis, bronchospasm, and pneumothorax

Answer 194

A

dilatation of the RV (ideally measured in the RV focused apical 4 chamber view)
interventricular septal flattening (commonly referred to as “D sign”. look for the presence of septal flattening in LV via parasternal short axis)
paradoxical septal motion
right atrial enlargement
right ventricular hypertrophy
right ventricular systolic dysfunction (RV free wall hypokinesis with apical sparing “McConnell’s sign”)
RV hypokinesia
fat IVC (diameter >2.1cm with loss of phasic variation throughout the respiratory cycle)
tricuspid regurgitation

Answer 195

A

Persistent hypotension (systolic blood pressure <90 mm Hg) lasting >15 min or a baseline systolic pressure decrease of >40 mm Hg

Answer 196

A

Normotensive or intermittent hypotension with both radiographic and biomarker findings of heart strain

Answer 197

A

Hemodynamically stable with either right ventricular strain on CT pulmonary angiography/echo OR abnormal biomarkers, but not both abnormalities.

Answer 198

A

Hemodynamically stable with NO right ventricular strain on CT pulmonary angiography or echo with normal biomarkers

Answer 199

A

Quantifies severity of heart failure in ACS and predicts 30-day mortality.

Class I: No signs of congestion/CHF
Class II: S3 and basal rales on auscultation and/or JVD
Class III: Acute pulmonary edema
Class IV: Cardiogenic shock

Brainscape's Knowledge GenomeTM

CCP 216 Cardiovascular Emergencies ❤️ Flashcards

Brainscape's Knowledge Genome^TM