Rapibloc Training - Cardiology Basics PDF

Summary

This document is a training guide on cardiology basics. It covers the cardiovascular system, including heart anatomy and function, cardiac cycle, and blood pressure regulation. It also details arrhythmias, septic shock mechanisms, and management. The guide discusses various conditions affecting heart function and perfusion.

Full Transcript

RAPIBLOC TRAINING

CARDIOLOGY
BASICS

© AOP Health 1
Agenda

PART 1
 CARDIOVASCULAR SYSTEM

PART 2
 ARRHYTHMIA

PART 3
 SEPTIC SHOCK

© AOP Health 2
CARDIOVASCULAR SYSTEM

 Anatomy of the heart and vascular system

 Cardiac cycle

 Cardiac output

 Blood pressure

 Hemodynamic regulation

© AOP Health 3
ARRHYTHMIA

 Conduction of the heart

 Arrhythmia mechanism

 Different type of arrhythmia

 Physiopathology of AF

 AF in Critical Care

© AOP Health 4
SEPTIC SHOCK

 Definition of Septic Shock

 Physiopathology of Shock

 Organ dysfonction

 Septic shock management

 Vasopressors in septic shock

© AOP Health 5
CARDIOVASCULAR SYSTEM

 Anatomy of the heart and vascular system

 Cardiac cycle

 Cardiac output

 Blood pressure

 Hemodynamic regulation

© AOP Health 6
Chambers of the heart: right and left heart
 The heart is composed of four chambers – two atria and two ventricles

Aorta
Superior vena cava

Pulmonary artery

Left atrium

Mitral valve

Aortic valve
Right atrium
Left ventricle

Pulmonary valve

Interior vena cava Tricuspid valve
Right Descending aorta The right heart is thinner as
ventricle compared to left heart

© AOP Health 7
Blood flow through the
systemic and pulmonary circulations
Pulmonary Pulmonary
arteries Pulmonary veins
circuit

Lung Lung
O2 O2

Pulmonary circulation
Systemic circulation
CO2 CO2

Right atrium Left atrium
Systemic
circuit
Right ventricle Left ventricle

Venae cava Aorta

In systemic capillary
beds O2 leaves the
blood and CO2 enters

COO22 O22
CO

Oxygenated blood Cells in tissues
throughout the body
Deoxygenated blood

© AOP Health 8
 Arteries*: vessels that come out from heart

 Aorta carotid

 The largest artery in the body
Arch of the aorta
 Carries oxygenated blood out of the
left ventricle of the heart Ascending aorta

 Arteries Thoracic aorta
 Carry blood at high pressure from
the heart to the tissues
 Arterioles Abdominal aorta

 Smaller arteries
 Major function is to control blood
Mesenteric arteries
pressure by constricting or dilating

© AOP Health
*notes: arteries usually carries oxygenated blood except pulmonary artery that goes to the lungs.
9
 Veins*: vessels that come back to the heart
Venules
Thinnest veins in the body
Internal
Receive blood from capillaries and pass it on to veins jugular
Veins vein
Move blood towards the venae cavae and right atrium
Subclavian
of the heart Superior
vein
vena cava
Carry blood at lower pressure than arteries
Most contain semi-lunar valves to prevent back-flow of Right
atrium
blood
Contraction of skeletal muscle aids the flow of blood
Venae cavae Renal
The superior and inferior venae cavae return blood to Inferior vena
vena cava
the heart Gonadal
vena

*notes: large veins (e.g. subclavian, femoral) can be
used to insert central catheters and infuse drugs

© AOP Health 10
 Arteries and Veins: main differences

Arteries Veins
Carry blood away from Carry blood toward the
the heart heart
Thicker walls Thinner walls
Smaller lumen Larger lumen
Higher blood pressure Lower blood pressure
No valves Valves

© AOP Health 11
 Capillaries
 Capillaries are present in all tissues
 Oxygen, carbon dioxide, nutrients (e.g. glucose) and
waste products diffuse across their thin walls
 Gas exchange occurs in the capillary beds within the
tissues:
 Release of oxygen
 Uptake of carbon dioxide
 The reverse exchange occurs in the pulmonary
capillaries of the lungs
 Release of carbon dioxide
 Uptake of oxygen

© AOP Health 12
 Lung - alveolar circulation and gaz exchange

The pulmonary circulation carries blood to and from the lungs

Left pulmonary vein
Right pulmonary
vein

13

Right pulmonary
artery

Pulmonary trunk
Left pulmonary artery

Circulation pulmonaire

© AOP Health 13
Heart - Vessels of coronary circulation

 The heart is supplied with oxygen and nutrients by the coronary arteries

Right main Left main
coronary artery coronary artery

Left circumflex artery

Left anterior descending artery
Capillary density of heart is enormous!

Heart: 3000 capil/mm2 ( Ø 18µm)
Skeletal muscle: 400 capil/mm2 (Ø 50µm)

© AOP Health 14
 Heart and Coronary perfusion
Cardiac cycle and coronary flow: O2 supply to the myocardium

In healthy subject, volume myocardium perfusion
remains stable (and may be increased) even though
diastolic perfusion time is reduced (tachycardia)
thanks to an increase in diameter of coronaries
associated with tachycardia. (relaxation due to beta2)
15

In coronary or hypertensive or cardiac insufficient
patients, , volume myocardium perfusion decreases
due to reduction of diastolic perfusion time
(tachycardia), poor relaxation of ventricle during
diastole or spam and/or obstruction of coronaries,
during tachycardia

Note: coronary flow occurs during
diastole (Left Ventricle)

© AOP Health 15
 Heart and Coronary perfusion
Mechanism of Acute Coronary Syndrome Myocardial Infarction

Occlusion : ST Elevated (ECG ) Non Occlusive: ST NON- Elevated (ECG )

ACS and Myocardial infarction are explored by
angiography and mechanical reperfusion is
frequently performed
© AOP Health Thygesen et aL; Circulation. 2018;138:e618–e651. DOI: 10.1161/CIR.0000000000000617 16
Innervation of the heart
 The heart is innervated by the autonomic nervous system (ANS)
Aorta
Superior vena cava

Pulmonary artery

Left atrium

Purkinje fibres
Impulse conduction:
 Sinoatrial (SA) node Right Left ventricle
atrium
 Internodal pathway
Right
Interventricular septum
 Atrioventricular (AV) node ventricle

 AV bundle (bundle of His)
 Bundle branches Descending aorta
Interior vena cava
 Purkinje fibers

© AOP Health 17
 Cardiac Cycle and Electric Stimulation
The cardiac conduction system
Atrioventricular
Atria node

Bundle of
Sinoatrial node His fibres
(pacemaker)
Bundle
branches

Purkinje
fibres
Ventricles

Heart at rest

AtrioVentrocular node, AV bundle and Sinus Atrium node fires
Purkinje fibers fire ATRIUM CONTRACT
VENTRICULE CONTRACT
© AOP Health 19
 Cardiac cycle : Diastole and Systole

During (a) cardiac diastole, the heart muscle is relaxed and blood flows into the heart = Early phase of heart filling = Passing filling
During (b) atrial systole, the atria contract, pushing blood into the ventricles. = late phase of heart filling = completion of heart
filling = “atrial kick” # 25% of end-diastolic left ventricle volume
During (c) atrial diastole, the ventricles contract (ventricular systole), forcing blood out of the heart.
=Blood volume ejected = STROKE VOLUME
© AOP Health 20
 Cardiac stimulation and Electrocardiogram
Lead (II) corresponds to
ECG “standard” usually represented

Electrical Cardiac stimulation can be registered with a six leads
EKG , with applying leads on the body such as:
V1 : 4th intercostal space (between ribs 4 and 5) just to the right
of the sternum
V2 : 4th intercostal space just to the left of the sternum
V3 : Between leads V2 and V4
V4 : 5th intercostal space, (between ribs 5 and 6) in the mid-
clavicular line.
V5 : Horizontally even with V4, in the left anterior axillary line.
V6 : Horizontally even with V4 and V5 in the mid-axillary line.

Leads can also be positioned on the limbs to obtain a 12 lead ECG.

© AOP Health 21
 Cardiac cycle in relation with ECG

P wave= atrial depolarization

22 QRS segment = fast impulse from
His fibers to Purkinje fibers

T wave corresponds to ventricle
repolarization

Note: atrial repolarisaton is masked by QRS

© AOP Health 22
 https://www.youtube.com/watch?v=IS9TD9fHFv0

© AOP Health 23
 Cardiac cycle and pulse pressure

Normal electrocardiogram (ECG) reflect regular beats (beat per minutes= bpm)
producing cardiac output (liter of blood per minutes) resulting in pulsatile blood flow

Systole is shorter than diastole
 when heart rate increases, diastole time will be reduced
Diastole

Systole

Diastole

Systole

Diastole

Systole

Diastole

Systole
R R R R
T T T T
P P P P
ECG
Q Q Q Q
S S S S

Blood flow is ejected at systole and blood pressure increases
Blood
pressure Volume of blood ejected at each contraction is STROKE VOLUME

During diastole, heart is filled and pressure goes down
« Lub » « Dub »
( S1 ) ( S2 )
First heart sound (S1) represents closure of the atrioventricular (mitral and tricuspid)
valves as the ventricular pressures exceed atrial pressures at the beginning of systole

© AOP Health The second heart sound (S2) represents closure of the semilunar (aortic and pulmonary) valves 24
 Regulation of cardiac output
Factors effecting Cardiac Output (CO)

As seen on previous slide, the only way to fast increase cardiac output is to eject stroke volume more frequently.
Due their own limitation, volume (preload) and contractility cannot be enhanced much and have a small
contribution in CO increasing vs increase of HR.
© AOP Health 25
 Cardiac Ouput and Heart Rate

Cardiac output – the volume of blood pumped from each ventricle per minute:

CO = SV x HR
cardiac output = stroke volume X heart rate
(ml/minute) (ml/beat) (beats/min)

a. Average heart rate = 70 bpm
b.Average stroke volume = 70−80 ml/beat
c. Average cardiac output = 5,5 l/minute

TIP: 70 (b/min) X70 (ml) = 4900 (ml) # 5 L/min
© AOP Health 26
 Cardiac Ouput and Heart Rate

Caridiac output is increasing as heart rate Decreasing Heart Rate
increase until a certain point and then drop as is able to
ventricule cannot no longer fill properly increase cardiac output

What’s more, contraction strength that increase
with heart rate (Bodwitch effect) with calcium
accumulation, decreases beyond this point,
by failing of relaxation.

https://www.intechopen.com/chapters/53797
© AOP Health 27
 Cardiac output and hemodynamic
What makes the flow with a pump (heart)?

Volume of blood being returned to the heart Pressure the heart (left ventricle) has
(ventricles) at the end of diastole. The stretching to overcome to eject blood out of
of the muscle fibers just before contraction the heart.
28

Tubes must be not too
narrow and/or
Circuit must be pressure already too
high = « traffic jam »
« well filled »

and Pump must be in
« reservoir» good shape to
compliant…. « push »
© AOP Health 28
 Cardiac Ouput and Heart Rate
Why beta-blocker usually fail to maintain Cardiac Output
while decreasing Heart rate?

*CO = SV × HR
Decrease with
Beta-blockers
SV maintained
EDV Increase with HR
Negative chronotropic effect decrease
(Amount to eject)
HR SV
Inotropism Usually
Decrease with
(contractility) Beta-blockers

CO
DC
BP = Blood pressure
BP
PA CO = Cardiac Output
SVR = Systemic Vascular Resistance
SVR
RVS HR= Heart Rate
SV = Stroke Volume
© AOP Health * Calculated with normal Preload and constant SVR EDV = End Diastolic Volume 30
 Cardiac Ouput and Heart Rate
How could a beta-blocker succeed to maintain Cardiac Output
while decreasing Heart rate?

*CO = SV × HR
Decrease with Increase with HR
Beta-blockers
decrease EDV Increase with HR
Negative chronotropic effect decrease
(Amount to eject)
HR SV
Inotropism No impact contraction
no negative inotropism
(contractility
CO
DC
BP = Blood pressure
BP
PA CO = Cardiac Output
SVR SVR = Systemic Vascular Resistance
RVS HR= Heart Rate
SV = Stroke Volume
© AOP Health * Calculated with normal Preload and constant SVR EDV = End Diastolic Volume 31
 Cardiac Ouput and Ejection Fraction
ALTERED contraction
HEALTHY NORMAL
HEALTHY Ejected Volume = reduced Contraction

REDUCED PRESERVED
Ejection fraction Ejection fraction

40%

Amount of
Blood ejected from
ventricule (ml)
X 100 Ejection Fraction (%) ALTERED relaxation
Total voilume of blood Filling Volume = reduced
in ventricle (ml) Fraction éjectée HEALTHY NORMAL
© AOP Health =50-60% 32
 Cardiac Ouput and Ejection Fraction
Ejection Fraction REDUCED
Ejection fraction PRESERVED
HEALTHY
Ejection fraction
=50-60% 40%

TIP: CI (cardiac Index)
REDUCED appears in RAPIBLOC SPC
NORMAL REDUCED
CARDIAC OUTPUT CARDIAC OUTPUT for cardiac dysfunction
CARDIAC OUTPUT
definition)

Cardiac Index (CI)
= Cardiac Output/ body surface CARDIOGENIC
CI < 3 à 2,5 CI < 3 à 2,5 SHOCK
normal # 3,5 L / min /m2. L/min/m2 L/min/m2 CI < 2,2 L/min/m2

© AOP Health 33
 Cardiac Ouput and Blood Pressure

BP
34

Higher systemic vascular resistance
(< caliber or stiffer wall)

Lower systemic vascular resistance
(> caliber or relaxed wall)
BP

© AOP Health 34
 Blood Pressure in Vascular System

Pulmonary aretries

Pulmonary veins
Large veins
Small veins
Capillaries

Capillaries
Vena Cava
Pressue in the lungs is
much lower than in
systemic circulation
Large aretries

Small aretries

Lungs are COMPLIANT
Aorta

Right heart is weaker than
left heart because LUNG
Systemic Pulmonary AFTERLOAD is lower

As blood flows further in vessels, blood pressure drops until reaching # « 0 »
The normal value of Central venous pressure in healthy persons is very low, not exceeding 5 mm Hg

© AOP Health 35
35
 Blood Pressure and capillary flow
MAP CVP
(Mean Arterial Pressure) (Central Venous Pressure)

microcirculation in capillaries can be monitored by different techniques

Organ Perfusion
Pressure
# (MAP – CVP) Mottling Score
↓ density of capillaries
↑ heterogenicity of perfusion
© AOP Health 36
 Measuring the pumping action of the heart: Summary
Parameter Equation Measurement Typical value
method

Pulse detection, 70
Heart rate –
ascultation beats/minute

Cardiac output CO = SV × HR Various methods 5 litres/minute

2.6-4.2
CO – cardiac output Cardiac index CI = CO / BSA –
SV – stroke volume litres/minute
HR – heart rate
CI – cardiac index Angiogram,
BSA – body surface area Stroke volume SV = EDV – ESV 70ml
EDV – end diastolic volume
echocardiogram
ESV – end systolic volume

© AOP Health 37
Measuring the pumping action of the heart:
Summary continued
Parameter Equation Measurement Typical value
method
Ejection fraction EF = SV / EDV Angiogram, 55-70%
echocardiogram, MRI,
CTscan

Mean arterial MAP = CO × SVR 70-110mmHg
pressure
Pulse pressure PP = SBP – DBP Sphygmo 40mmHg
manometer
EF – ejection fraction
SV – stroke volume
EDV – end diastolic volume MRI – magnetic resonance imaging
MAP – mean arterial pressure CT – computed tomography
CO – cardiac output RNA – radionuclide angiocardiography
SVR – systemic vascular resistance
PP – pulse pressure
© AOP Health SBP – systolic blood pressure 38

DBP – diastolic blood pressure
 How hemodynamic is regulated?
3 main systems interplays to maintain hemodynamic homeostasis
Hypotension
Hypovolemia

Baroreceptors Voloreceptors
Aorte/ Carotides ventricles

catecholamines 39

(adrenaline, Antidiuretic hormone
noradrenaline) Vasopressin
posthypophyse
VASOCONSTRICTION VASOCONSTRICTION
WATER REABSORPTION

Autonomus Renin-angiotensine Baroreceptors
Sympathic Adrenal gland Renal Afferent Arteriola
Nervous system Aldosterone system
VASOCONSTRICTION renin
SODIUM REABSORPTION

aldosterone angiotensine

© AOP Health 39
 How hemodynamic is regulated?
The Autonomus Sympathic Nervous system

The cardiovascular system is
“equiped” with sensitive nerves
which are connected to sensors
which detect blood pression
variation and send signal to
brain stem where centres of
cardiac control are located.

Then the cardiac center sent back
an appropriate response to
Cardiovascular system via the
Autonomic Nervous System

© AOP Health 40
 Autonomic innervation of vascular system
Arteries and Veins have different type and density of receptors
Vascular system is innervated by Beta and alpha adrenergic receptors are located on
sympathetic nerves arteries while only alpha adrenergic receptors are
The lower the artery caliber, the higher present on veins.
nerves density. Note; beta2 receptors density is higher than alpha1 in coronary arteries to ensure
relaxation during stress (effort)
Blood No beta1 receptors
Flow
on vessels !!!
Sympathetic ganglion
Pressure
flow

(diameter)
Caliber

Elastic arteries

alpha1 stimulation Adrenal
gland
triggers
Innervation

vasoconstriction Adrenalin
Mucle arteries noradrenalin noradrenalin
and arterioles
beta2 stimulation
triggers
vasorelaxation
capillaries No nerves !!!
© AOP Health 41
Cardiac Output, organ perfusion and
autonomic regulation

Cardiac output is adapted to organ perfusion needs
© AOP Health driven by physical activity and stress Autonomic nervous system 42
Autonomic nervous system: Sympathetic nervous system
Catecholamines and stress

Heart is principally equipped with bêta-1
receptors which contribute to heart
contraction and cardiac stimulation

Lungs have bêta-2 receptors involved in
bronchial relaxation

Coronary arteries have principally bêta-2
receptors and are relaxed in response to
sympathetic stimulation to allow adapted
myocardium perfusion

β1 contracte
β2 relaxe

Stress (catecholamines) increase cardiac output
and increase Oxygen supply same stress message, different organ response
© AOP Health 43
Regulating autonomic nervous system with drugs
Beta-blockers acts by inhibiting catecholamine effect on beta-adrenergic receptors

Noradrenaline Sympathic Noradrenaline Sympathic
nerve nerve
Bêta
Blocker

Bêta1 receptor Bêta2 récepteur Bêta1 receptor Bêta2 receptor

When not inhibited, catecholamines (noradrenaline)
Non selective beta-blockers bind to both to beta-1
released by sympathetic nerves bind to beta-1 and beta-2
and beta-2 receptors of target cells, competing and
receptors of target cells.
inhibiting with noradrenaline, leading to decrease
With same stress message, different response depending of
of heart rate and contraction, but also
organs needs and contribution to hemodynamic and
bronchoconstriction of bronchioles.
oxuygen supply, leads to increase in heart rate and
© AOP Health
contractility, and bronchodilation of bronchioles in lungs 44
Regulating autonomic nervous system with drugs
Selective Beta-blockers acts by inhibiting catecholamine effect on
beta1-adrenergic receptors

Noradrenaline Sympathic Noradrenaline Sympathic
nerve nerve
Bêta Bêta
blocker Blocker

Bêta1 receptor Bêta2 receptor Bêta1 receptor Bêta2 receptor

Coronary
Arteries :

Arteries
remain relaxed

Selective beta-blockers bind ONLY to beta-1 receptors of target cells, competing and
inhibiting with noradrenaline, leading to decrease of heart arte and contraction, without
© AOP Health
bronchoconstriction of bronchioles and also with maintaing coronary perfusion 45
Regulating autonomic nervous system with drugs
Excessive continuous stimulation by catecholamine triggers
desensitization of beta-adrenergic receptors

Lower density on surface membrane and/or
Small dose of beta-blocker can restore sensitivity uncoupling with Gs protein
© AOP Health De Lucia et al. Front. Pharmacol., 10 August 2018 Sec. Cardiovascular and Smooth Muscle Pharmacology 46
Volume 9 - 2018 | https://doi.org/10.3389/fphar.2018.00904
Interaction between the renal and cardiovascular
systems: the renin-angiotensin-aldosterone system
Angiotensinogen
Renin
Angiotensin I
Angiotensin-
converting
enzyme (ACE)
Angiotensin II

Arteriole constriction

Aldosterone BP increases

Increased sodium and
water reabsorption
Renin release is stimulated by internal baroreceptors in renin-secreting cells of
the juxtaglomerular apparatus due to a reduction in the afferent arteriole pressure.
© AOP Health
Catecholamine additional stimulates renin secretion by juxtaglomerular apparatus 47
Vasopressin: osmoregulation blood pressure regulation
In addition to Sympathetic System and Renin-Angiotensin-Aldosterone System,
vasopressin plays an important role in maintaining blood pressure.

Relations between plasma osmolality and blood volume
© AOP Health and AVP concentration in blood 48
Vasopressin: multiple roles in blood pressure and organ homeostasis

ACTH release => Cortisol :
stimulation of V1b receptor +
Insuline release : stimulation
stimulation of V1b receptor +

Platelet agregation :
stimulation of V1a receptor +

Release of coagulation factors
stimulation of V2 receptor +
in endothelium

Vasoconstriction: stimulation Water reabsorption:
of V1a receptor + stimulation of V2 receptor +
=> aquaporine
© AOP Health 49
Demiselle et al. Ann Intensive Care 2020 Jan 22;10(1):9. doi: 10.1186/s13613-020-0628-2.
CARDIOVASCULAR SYSTEM: Summary

 Heart is a pump that provide cardiac output and blood flow to warrant organ
perfusion and oxygenation.

 Heart, vessels, lungs have different receptors to provide adapted response to
same stress message (e.g. catecholamine stress)

 Heart Rate, Cardiac Output and Blood pressure are related.

 Cardiovascular system is regulated by several system including autonomic
nervous system, renin-angiotensin-aldosterone and vasopressin
© AOP Health 50
ARRHYTHMIA

 Conduction of the heart

 Arrhythmia mechanism

 Different type of arrhythmia

 Physiopathology of AF

 AF in Critical Care

© AOP Health 51
 Heart conduction
Sinus node is « naturally » unstable
and depolarise spontaneously
It is the pacemaker responsible for
automaticity of the heart

AV node role is to naturally « slow
down conduction » to allow for
ventricle filling completion and
optimize preload before ventricular
rapid stimulation triggering contraction
and blood ejection.

Normal electrical heart conduction : Sinus Node SN (cardiac pacemaker) trigger action potential → signal propagate
through atrium and triggers its contraction → signal reach AV node and is slowed down→ AV node conduct signal
towards bundle of His along interventricular septum towards Purkinje fibres in myocardium → convey signal
throughout ventricles → ventricles contract ( electromechanical coupling).
© AOP Health 52
 Diastolic Depolarisation and Heart Rate
The cells of SINUS NODE are naturally “unstable” and depolarize REGULARLY and SPONTANEAOUSLY
Thanks to FUNNY CHANNELS that is regulated by autonomous system.
These cells are called : pacemaker cells

HCN Hyperpolarisation-activated Cyclic-Nucleotid = FUNNY CHANNELS if
https://link.springer.com/chapter/10.1007/978-3-030-75326-9_1 http://www.vnsanalyse.de/files/userdata/bilder/hf_modulation_1_650.png
© AOP Health 53 53
 Diastolic Depolarisation and Heart Rate
Impact of autonomic nervous system on heart rate at sinus node (pacemaker cells)
Sympathetic nervous system: positively chronotropic Parasympathetic nervous system: negatively chronotropic
(beta1-Gs-cAMP – Funny channels open) (m2-Gi-cAMP decreases – Funny channels closed)
Heart Rate is increased Heart Rate is reduced
Potential [mV]
Sympathetic nervous system: positively
Activation of
chronotropic
Activation of
Rest
Sympathetic Vagus Nerve
Nervous System

0.5 Time [s]

© AOP Health 54 54
 Systolic Depolarisation and Heart contraction
Cardiac action potential (contractile cells)

55

Contractile Myocardium cells are
depolarizing quickly thanks to
Na entry, then Ca entry and K
going out of the cell

Calcium entry is key to trigger internal cell Ca reserve movement out of
sarcoplasmic reticulum to participate to the contraction.
Antiarrhythmic drugs can interfere with this Ca turn over and/or alter
refractory period, this is why AA often decrease cardiac contraction
© AOP Health Mechanisms of Cardiac Arrhythmias L. Gaztan˜aga et al. / Rev Esp Cardiol. 2012;65(2):174–185 55
Heart Conduction:
different speed of
depolarisation

Contractile Myocardium cells are able to
propagate electric signals
They depolarize quickly

Contractile Myocardium cells are also transforming
the electrical signal into mechanical contraction
© AOP Health = ElectroMechanical Coupling 56
From heart conduction to heart contraction
Effects and roles of catecholamines on heart function
Excitation, conduction, contraction, relaxation
Catecholamines role is to facilitate increase heart function in order to increase cardiac output.
With accelerating heart rate
By increasing automaticity * = positive chronotropic effect
By lowering excitability threshold = positive bathmotropic effect
By increasing speed of conduction** = positive dromotropic effect
57

and also easing « pumping efficacy »
By increasing strength of contraction = positive inotropic effect
By increasing speed of relaxation*** = positive lusitropic effect

However, Some of the effects on heart conduction system, when in excess and/or prolonged period can contribute to
trigger arrhythmia, especially in patients at risk or in combination with other triggers.

* At sinus node level ***Sequential phenomenum following contraction: Catecholamines ease calcium
**increase speed of conductuion of AV node recapture by sarcoplasmic reticulum, which increase relaxation of myocardium and
Reduce refractory time period allow for optimizing ventricle filling before the next contraction

© AOP Health Gillies M, Bellomo R, Doolan L, et al. Bench-to-bedside review: Inotropic drug therapy after adult cardiac surgery -- a systematic literature review. Crit Care. 2005;9(3):266-79. 57
 Heart Conduction: mechanism of drugs
Rate control agents (BB and CCB) acts on
nodes tissues (slow depolarizing cells)

Antiarrhytmic agents act
on high speed depolarizing
cells (bundle of His Purkinje
fibres and contractile
myocardium) by blocking
Na channels or K channels
 Note: historically, beta-blockers and calcium blockers are listed in Vaugham-Williams classification of antiarrhythmic agents
while there are rather rate control agents not interfering with Na or K channels
© AOP Health 58
Heart Conduction: mechanism of arrhythmia

Disorder Mechanism Types of arrhythmias
Disorders of impulse generation
Abnormal automaticity Suppression or acceleration of Phase 4 of Sinus tachycardia
the action potential Sinus bradycardia
Triggered activity Torsades de pointes
Early afterdepolarizations (EADs) Possibly idiopathic and acquired long
QT syndromes and associated
ventricular arrhythmias
Delayed afterdepolarizations (DADs) Digitalis-induced arrhythmias
Reperfusion VT
Disorders of impulse conduction
Unidirectional block with reentry Reentry Atrial fibrillation
Atrial flutter
Other SVTs
Ventricular tachycardia
Unidirectional block or bidirectional Blocked impulse conduction Bradyarrhythmias
block without reentry

Abnormal automaticity can be caused by altered rate of spontaneous depolarization
Its can also be caused by autonomic nervous activity, hypokalemia, ischemia
© AOP Health 59
Electrocardiogram abnormalities
Examples of ECG abnormalities related to pathologies that may involve beta-blockers or antiarrhythmic
agents
ECG ECG features in acute coronary syndrome

Myocardial
Inéfarction
Acute Coronary
Syndrome

Normal ST Segment ACS with ST elevated segment ACS WITHOUT ST elevated segment

Long QT Class I or III antiarrhytrhmic agents are
syndrome contra-indicated in case of prolonged QT
Congenital Septic shock cardioac damage or injury
or can be associated with long QT and worst
Acquired prolonged QT prognosis
Normal QT Intervalle

© AOP Health 60
ECG abnormalities: STEMI and Non-STEMI
In STEMI, Electric impulse is stopped by large heart wall (transmural) necrosed o
stunned myocardium while in non-STEMI, electric impulse can still continue in par
the heart, with ischemia principally affecting small extremities of coronary vessels at
endocardium level, which are the first to suffer from lower coronary pressure or flo

© AOP Health 61
Heart Conduction: mechanism of arrhythmia

63

Heart rate ≥ 100 bpm originating from sinus node Atrial fibrillation (AF) is the most frequent type of supraventricular
and associated with regular rhythm. Frequency of tachyarrhythmia observed in critical care or emergency settings.
beating (rate of beating) alone is affected and AF is characterized by disorganized atrial activation and irregular impulse
accelerated.
© AOP Health triggering irregular response. 63
Heart Conduction: mechanism of arrhythmia
Different type of supraventricular tachycardia
Junctionnal tachycardia

There are other existing type of supraventricular tachyarrhythmia which ca,n be also observed in critical care or emergency settings, but
are much less frequent. (5 to 10% of SVT)
They can be encountered and diagnosed early in paediatrics as some of their mechanism stems from heart conduction malformation and
abnormalities.
Vagal manoeuver or adenosine injection are first line management, rate control agents are usually second or 3rd line treatment option.
© AOP Health 64
 Atrial Flutter
A supraventricular tachyarrhythmia usually caused by a single macroreentrant rhythm within the atria that is classically
characterized on ECG by the sawtooth appearance of P waves, also known as “flutter waves”, with narrow QRS
complexes. The risk factors for atrial flutter are similar to those of Afib. In atrial flutter, the atrial rate is slower than
in Afib and the ventricular rhythm is usually regular. Treatment is similar to that of Afib, consisting of anticoagulation
and strategies to control heart rate and rhythm. Atrial flutter frequently degenerates into atrial fibrillation.

Type of tachyarrhythmia Causes and mechanisms Main ECG findings

Flutter atrial Macroreentrant rhythms Regular rhythm
within the atria Rate: atrial 250–350 ventricular < 200
66

P waves
ECG Flutter atrial Occur before every QRS
complex
Sawtooth appearance of regular P waves (flutter
waves) especially in leads II, III and aVF
Narrow QRS complex
Normal ECG

1. The rhythm may be regularly irregular if atrial flutter occurs with a variable AV block occurring in a fixed pattern (2:1 or 4:1), and irregularly
2. irregular with a variable block occurring in a non-fixed pattern.
3.  The exact ventricular rate depends on the ratio of atrioventricular conduction (e.g., 1:1 or 2:1 conduction).

https://www.mayoclinic.org/diseases-conditions/atrial-flutter/symptoms-causes/syc-20352586
© AOP Health 66
 Atrial Fibrillation
Atrial fibrillation (Afib) is a commonly seen type of supraventricular tachyarrhythmia that is characterized
by uncoordinated atrial activation resulting in an irregular ventricular response.
Individuals with Afib are typically asymptomatic. However, when symptoms do occur, these usually include palpitations, lightheadedness,
and shortness of breath.
Physical examination typically reveals an irregularly irregular pulse. Ineffective atrial emptying as a result of Afib can lead to stagnation of
blood and clot formation in the atria, which in turn increases the risk of stroke and other thromboembolic complications. The diagnosis is
confirmed by an ECG showing indiscernible P waves and a narrow QRS complex with irregular QRS intervals..

Causes and
Type of tachyarrhythmia 67
Main ECG findings
mechanisms
Atrial Fibrillation Multiple mechanisms Rhythm: irregularly irregular
atrial Fibrillation ECG which are not completely Rate: atrial 350–450 bpm;
understood ventricular < 200 bpm
(valvular cardiopathy, coronary P-waves are indiscernible
disease, hyperthyroïdism, Narrow QRS complex
Normal ECG electrolyte disorders)

© AOP Health 67
 Physiopathology of Atrial Fibrillation
Hemodynamic and cardiovascular impacts

Structural ou electro-physiologic abnormalities of atrial tissues are associated with :

Excessive Heart Rate
Loss of effective atrial contraction (atrial kick)
Irregular and reduced ventricle filling time
Reduction of cardiac output from 15t to 20%.
Blood stagnation in atrium and risk of clotting
and thrombosis *

* Stagnation time is directly related to the risk of thrombus formation :  generally >48h
Recovery of sinusal rhythm and recovery of atrial contraction allows for thrombus to be expelled into
circulation :  CNS embolism (stroke) or in other arteries vessels (rarely pulmonary embolism as thrombus mainly
forms in left atrium)
© AOP Health 68
 Physiopathology of Atrial Fibrillation
Hemodynamic and cardiovascular impacts
Heart Rate(bpm) Mean Arterial Pressure
(mmHg) Rythme sinusal
Before AF
AF
160 100

140
132
80 77
75
120 73

105 66
99
60

80

40

40

20

0 0
Seeman, 2015 Klein, 2016 Seeman, 2015 Klein, 2016

Introduction or need to increase
vasopressors: 41%

© AOP Health
Seeman et al AIC, 2015 & Klein et al AJRCCM 2017 69
 Atrial Fibrillation: risk factors

© AOP Health 70
 Risk factors and triggers for AF in critical care

Bedford et al. https://doi.org/10.1016/j.iccn.2021.103114
© AOP Health 71
 Types of Atrial Fibrillation

Most common after surgery (especially cardiac
surgery) due to sympathetic overstimulation
and inflammation (80% of AF cases in ICU)

Kirchhof et al. Europace (2007) 9, 1006–1023
© AOP Health 72
Time course and management of of Atrial Fibrillation

© AOP Health 73
Time course and management of of Atrial Fibrillation

© AOP Health 74
 Atrial Fibrillation Incidence in Intensive Care
ICU Population Subset settings
Incidence of new-onset Reference
atrial fibrillation
Surgical ICU General non-thoracic Surgery 5-10%
Pulmonary surgery Rozencwajg 2016
10-23% Imperatori 2012
Esophagectomy 16-22% Schizas 2019

Cardiac surgery 10-65%

Medical ICU General ICU 5-21% Carrera et al. 2016
Gupta et al.
Septic shock 11 – 46% Meierhenrich 2010
Liu 2016
Cardiac ICU, Coronary Care Myocardial infaction 4- 10% Almendro-Delia 2013
Unit 6-21% Braga 2013
Schmitt et al. 2009
Acute Heart Failure 16% Arrigo 2017
Percutaneous Valve 17,5% [6 - 20%] Sanino 2016
replacement Chopard 2015,
© AOP Health
Maan 2015 75
 Risk factors and triggers for Postoperative
Atrial fibrillation
* Increase of Hypothermia *
surgery Pain sympathetic hypoglycemia
stimulation
Anemia*
Hypoxia
hypovolemia
Thoracicic non-Thoracic Beta-blockers
Hypotension * surgery surgery withdrawal *
76
*Identify and treat causes
of sympathetic stimulation
et de
myocardium Local Systemic correct factors that can
damage Inflammation Inflammation contribute to trigger
arrhythmia directly

Postoperative Hypokaliemia *
Atrial Fibrillation Hypomagnesemia

*
Hypervolemia

Chelazzi C, Villa G, De Gaudio AR. Postoperative atrial fibrillation. ISRN (International Scholarly Research Notices)
Cardiol. 2011;2011:203179. doi: 10.5402/2011/203179.
Boriani G, et al. Europace. 2019 Jan 1;21(1):7-8. doi: 10.1093/europace/euy110.
© AOP Health 76
 Impact of Postoperative
Atrial fibrillation on patient outcome

Mortalité toute cause pour les cohortes de pontage seul, avec FAPO (POAF) versus sans FAPO (No-POAF).
Un taux de mortalité hospitalière plus élevé chez les patients souffrant de FA de novo en postopératoire comparé
aux patients ne présentant pas de FA a été observé dans 8 études, dont sept démontrant une différence significative.
POAF (Post Operative Atrial Fibrillation) = FAPO

Postoperative Atrial fibrillation after cardiac surgery is associated with higher hospital mortality

Alex Chau Y-L. et al. The impact of post-operative atrial fibrillation on outcomes in coronary artery bypass graft and combined procedures. J Geriatr Cardiol 2021; 18(5): 319–326
© AOP Health 77
77
 Impact of Postoperative
Atrial fibrillation on patient outcome
8,0%

7,0%

6,0%

5,0%

4,0%

3,0%

2,0%

1,0%

0,0%
Ahlsson 2010 Attaran 2009 Bramer 2010 Girerd 2012 Mariscalco 2009 Saxena 2012 Villareal 2004
POAF No POAF
Taux de mortalité rapporté chez les patients présentant une fibrillation atriale.
Histogramme rouge = avec Fibrillation Atriale; Histogramme Blanc = sans Fibrillation Atriale

Postoperative Atrial fibrillation after cardiac surgery is associated with higher hospital mortality
Phan K, Ha HSK, Phan S, Medi C, Thomas SP, Yan TD. New-onset atrial fibrillation following coronary bypass surgery predicts long-term
mortality: a systematic review and meta-analysis. Eur J Cardiothorac Surg 2015;48:817–24.
© AOP Health 78
78
 Risk factors and triggers for new onset
Atrial fibrillation in Critical Care

Patient admitted in Critical Care setting can have already altered atria conduction system or normal
atria, however critical care conditions will contribute to extend injury/remodelling or create injury
© AOP Health 80
 Risk factors and triggers for AF in critical care

Inflammation, Infection, Trauma,
Ischemia, along with
hypovolemia or electrolyte
inbalance are part of many
triggers common in
postoperative setting and
intensive care setting.
Excessive adrenergic stress is
also a frequent trigger
contributing to develop NOAF.

© AOP Health 81
 Atrial fibrillation in Critical Care
Impact on patient outcome
AF No AF

NOAF is associated with higher hospital mortality

Yoshida T, Fujii T, Uchino S, Takinami M. Epidemiology, prevention, and treatment of new-onset atrial fibrillation in critically ill: a systematic review. J Intensive Care. 2015 Apr 23;3(1):19. doi: 10.1186/s40560-015-0085-4.

© AOP Health 82
82
 Atrial fibrillation in Critical Care
Impact on patient outcome
The prospective FROG-ICU cohort confirms relations between NOAF and patient outcome

NOAF is an independent factor of mortality
Arrigo M et al. New-onset atrial fibrillation in critically ill patients and its association with mortality: A report from the FROG-ICU study International Journal of Cardiology 266 (2018) 95–99

© AOP Health 83
83
 Atrial fibrillation in Critical Care
Impact of return to sinus rhythm on patient outcome

Failure to restore sinus rhythm in septic patients with NOAF seems to be associated to higher risk of
hospital mortality as compared to patients with conversion bask to sinus rhythm.

Liu et al. Prognostic impact of restored sinus rhythm in patients with sepsis and new-
© AOP Health 84
onset atrial fibrillation Critical Care (2016) 20:373
 Management of New Onset AF in Critical Care

Identify and correct triggers first,
Then rate control to imoprve
hemodynamic conditions.

If hemodynamic does not improves,
rhythm control can be implemented.

© AOP Health Walkey AJ, Hogarth DK, Lip GYH. Optimizing atrial fibrillation management: from ICU and beyond. Chest. 2015 Oct;148(4):859-864. 85
 AF and Other Acute conditions in CCU/CICU

STEMI/ ACS
Include AF section

Acute Coronary
Syndrome(ischemia)

AF

Other SVT
HF  Acute Heart Failure Troubles du rythme
Acute Cardiac Dysfunction Tachyarythmies
Include AF section 

VT

J-LAND
© AOP Health
Nagai et al. 86
 Atrial Fibrillation and Acute Heart Failure
AF and AHF are often associated in a vicious circle

© AOP Health 87
Regulating autonomic nervous system with drugs
Excessive continuous stimulation by catecholamine triggers desensitization of
beta-adrenergic receptors and calcium cytosol overload
Desensitization of beta-adrenergic receptors is both affecting coupling with Gs protein (transudction of intracellular signal)
and also receptor density on cell surface.

https://doi.org/10.1038/
s41569-020-0394-8

observed
observed mortality mortality

Calcium is quickly in and Because of Prolonged and
out of sarcoplasmic excessive Adrenergic stimulation,
reticulum and contribute Calcium is remains in cytosol
ending up in Ca overload due to
efficiently to contraction
poor recapture in sarcoplasmic
and relaxation even if reticulum by SERCA and leakage
heart arte increase of Ryanodin
De Lucia et al. Front. Pharmacol., 10 August 2018 Sec. Cardiovascular and Smooth Muscle Pharmacology Dridi et al. Nature Review cardiology https://doi.org/10.1038/s41569-020-0394-8
© AOP Health 89
Volume 9 - 2018 | https://doi.org/10.3389/fphar.2018.00904
 Heart Failure severity and classification
NYHA class

Conséquence of Heart
Failure: poor cardiac output,
poor organ perfusion

 incapacity to adjust
cardiac output to organ
needs = reduced muscle
activity = reduced
mobilisation.

Inadequate O2 supply =
Shortness of Breath

© AOP Health 90
 Heart Failure And Ejection Fraction

© AOP Health 91
 Heart Failure and symptoms in acute setting

From Acute Heart Failure to Cardiogenic Shock

observed mortality
© AOP Health 92
 Acute Heart decompensation and AF
Left Ventrocular Ejection fraction potentially alredy altered before the episode of decompensation and further
decrease during the episode. Causes of decompensation of the heart failure can be myocardial infarction or coronary
syndrome (50%), infection (14%), hypertensive crisis (11%), non compliance with HF treatment (8%) and also
Tachyarrhythmia such as AF (16%)
Episodes of cardiac decompensation due to rapid AF
Evolution of Cardiac insufficiency
RAPID AF = Tachyarrhythmia
LVEF%  Rapid HR + loss of « atrial kick »
Hypoperfusion
  adrenergic response

Lower diastolic ventricular
Decrease of Ejection Fraction of left ventricle filling *  EDV
 SV=  Cardiac Output ++

 Oxygenation   ATP  Cardiac Output (CO)
Cardiac adaptation\maladaptation
Peripheral maladaptation
 Force of Contraction
Acute episode of HF  Relaxation*
Coronary Hypoperfusion
Arrigo et al. Precipitating factors and 90-day outcome of acute heart failure: a report  Diastole duration +  CO
from the intercontinental GREAT registry
European Journal of Heart Failure (2017) 19, 201–208 *ventricular relaxing requires energy (ATP)
© AOP Health 94
© AOP Health 95
Acute Heart decompensation and AF

While AF was 16% of cause in Arrigo
cohort, in Chioncel cohort, AF is 30% of
the cause, similar to Myocardial Ischemia

© AOP Health Chioncel et al. American Journal of Therapeutics 25, e475–e486 (2018) 96
 Fibrillation Atriale en Réanimation
Conséquences cliniques en postopératoire

La FA préexistante et la FAPO sont associées à risque de réhospitalisation pour
insuffisance cardiaque plus élévé comparé à une absence de FAPO
Goyal P, Kim M, Krishnan U, Mccullough SA, Cheung JW, Kim LK, Pandey A, Borlaug BA, Horn EM, Safford MM, Kamel H. Post-operative atrial fibrillation and risk of heart failure hospitalization.
Eur Heart©J.AOP
2022 Aug 14;43(31):2971-2980. doi: 10.1093/eurheartj/ehac285
Health 97
Acute HF : Progonosis in relation with cause of Acute HF
Precipitating factors of AHF were identified in
8784 patients (55%), while in 7044 patients (45%)
no specific precipitant could be identified.

ACS was the most common cause (52%), followed
by AF (n=1228, 16%), infection (n=1104, 14%),
uncontrolled hypertension (n=831, 11%), and
non-compliance with HF treatment (n=597, 8%).

Cardiogenic shock was more frequent in patients
with ACS (13%) compared with patients with
infection (6%) and non-compliance (5%) (P
2 mmol/L in the absence of hypovolemia, associated with
in-hospital mortality > 40%

2016 SEPSIS—3 Singer et al.
Singer, M.; Deutschman, C.S.; Seymour, C.W.; Shankar-Hari, M.; Annane, D.; Bauer, M.; Bellomo, R.; Bernard, G.R.; Chiche, J.-D.; Coopersmith,
C.M.; et al. The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis-3). JAMA 2016, 315, 801–810.

© AOP Health 110
Septic Shock epidemiology
Sepsis inciden