Marie Nováková, Department of Physiology1
CARDIAC MECHANICS
HEART AS A PUMP
CARDIAC CYCLE
HEART FAILURE
Marie Nováková,
Department of Physiology
2
CARDIAC OUTPUT (CO)
CO
HR
SV
CO = HR x SV
CORONARY
FLOW
EDV
Venous return
Compliance
Aortal pressure
LV = RV SV = EDV - ESV
Ejection fraction
EF = EDV – ESV / EDV
5l/min
70ml
>60%
REGULATION
ANS
AUTOREGULATION of cardiac contraction
Heterometric: Starling law
Homeometric: Frequency effect
CONTRACTILITY
Ability to contract
Depends on tissue perfusion
(substrates and oxygen supply for
ATP production; Ca2+ availability)
Marie Nováková, Department of Physiology3
Fuyu Kobirumaki-Shimozawa et al., J Physiol Sci (2014) 64:221–232
STARLING LAW
Marie Nováková, Department of Physiology4
Fuyu Kobirumaki-Shimozawa et al., J Physiol Sci (2014) 64:221–232
Marie Nováková,
Department of Physiology
5
Henry Pickering Bowditch
(1840 – 1911)
HOMEOMETRIC AUTOREGULATION
(FREQUENCY EFFECT)
During increasing HR (stimulation frequency) the force of developed
contraction rises
Ratio between intra- and extracellular calcium concentrations increases
Marie Nováková,
Department of Physiology
6
0,5 Hz 2 Hz1 Hz 3 Hz
Marie Nováková, Department of Physiology7
Marie Nováková, Department of Physiology8
CARDIAC RESERVE = maximal CO / resting CO
CORONARY RESERVE = maximal CF / resting CF
CHRONOTROPIC RESERVE = maximal HR / resting HR
VOLUME RESERVE = maximal SV / resting SV
4 - 7
3,5
3 - 5
1,5
CO = cardiac output
CF = coronary flow
HR = heart rate
SV = stroke volume
Marie Nováková, Department of Physiology9
CARDIAC RESERVE
CO (l/min)
WORKLOAD (W/kg)
ATHLETHS HEART
PHYSIOLOGICAL RESPONSE
HEART FAILURE
1 2 3 4
10
30
20
Marie Nováková, Department of Physiology10
IMPORTANT TERMS
Length-tension relationship (curve)
Minimal length l0
Passive, active, total force
Optimal length
Isometric, isotonic, auxotonic contraction
Autoregulation of contraction – heterometric (Starling)
Preload, afterload
Marie Nováková, Department of Physiology11
Passive tension, active tension, isometric contraction, isotonic contraction, auxotonic contraction
Resting tension
force
Resting tension
force
Total force
Total force
Marie Nováková, Department of Physiology12
AFTERLOADED CONTRACTION PRELOAD, AFTERLOAD
1 2 3 4
AP
PRELOAD
(~ enddiastolic filling)
AFTERLOAD
(~ pressure which must be developed)
stimulus
Marie Nováková, Department of Physiology13
P (mmHg)
V (ml)50 120
10
100
80
125
A
B
C
D
ESV (RV)
EDV
Work of the heart = P . V
LAPLACE law:
T = P . r / 2h
P = T . 2h / r
AB – isovolumic contraction
BC – ejection
CD – isovolumic relaxation
DA – filling
CARDIAC CYCLE – P-V LOOP
Marie Nováková, Department of Physiology14
P = T . 2h . r –1 Isovolumic contraction: T rises up, valves closed – increase in P
P = T . 2h . r –1 Ejection: r decreases, h rises, thus P increases (even at the same T)
P = T . 2h . r –1 Isovolumic relaxation: T decreases, valves closed – decrease in P
P = T . 2h . r –1 Ventricular filling: r and T rise, P first falls down, then rises up (length/tension relationship)
Marie Nováková, Department of Physiology15
INCREASED PRELOAD
MODEL
Marie Nováková, Department of Physiology16
INCREASED AFTERLOAD
MODEL
Marie Nováková, Department of Physiology17
INCREASED PRELOAD AND AFTERLOAD
MODEL
Marie Nováková, Department of Physiology18
HEART SOUNDS Caused by vibration of various anatomical structures and event. blood:
• Closure and stretching of valves
• Isovolumic contraction of heart muscle (papillary muscles, tendons)
• Turbulent blood flow
Vibration of ventricular wall
I. – mitral (+ tricuspidal) valve closure
II. - aortal (+ pulmonary) valve closure
III. - fast filling of ventricles - pathological
IV. - contraction of atria – mostly pathological
Z
mitral valve
aortal valve
I. II. III. IV.
C
C
O
O
O – open, C - closed
Splitting of I. or II. sound:
asynchronous closure of M - T valve (I.)
or Ao - P valve (II.)
(inspiration, hypertension….)
Marie Nováková, Department of Physiology19
Z
mitral valve
aortal valve
I. II.
Z
Z
O
O
O – open, C - closed
systole diastole
PHYSIOLOGICAL SOUNDS
AORTAL STENOSIS
MITRAL REGURGITATION
MITRAL STENOSIS
AORTAL REGURGITATION
MURMURS – pathological phenomena based on turbulent blood flow
1. SYSTOLIC
• Stenosis – aortal, pulmonary (1)
• Regurgitation – mitral, tricuspidal (2)
2. DIASTOLIC
• Stenosis – mitral, tricuspidal (3)
• Regurgitation – aortal, pulmonary (4)
3. SUSTAINED:
• Defects of septum
Marie Nováková, Department of Physiology20
POLYGRAPHY
(polygram) Phases of the cycle
Aortic pressure
LV pressure
LA pressure
LV volume
valve closed
Carotid sphygmogram
ECG
Phonocardiogram
Marie Nováková, Department of Physiology21
HEART FAILURE = loss of cardiac reserve
The heart is not able pump sufficient amount of blood into periphery at normal venous return.
SYMPTOMS
fatigue, oedemas, venostasis, dyspnoea, cyanosis
ACUTE x CHRONIC.
COMPENSATED x DECOMPENSATED.
MOST FREQUENT CAUSES:
• Severe arrhythmias
• Overload – volume (aortal insufficiency, a-v
shunts) or pressure (hypertension and aortal
stenosis – left overload, pulmonary hypertension
and stenosis of pulmonary valve – right overload)
• Cardiomyopathy
CO (l/min)
WORKLOAD (W/kg)
ATHLETHS HEART
PHYSIOLOGICAL RESPONSE
HEART FAILURE
1 2 3 4
10
30
20
Marie Nováková, Department of Physiology22
ACUTE FAILURE
CARDIOGENIC SHOCK
COMPENSATION
CHRONIC FAILURE
SUDDEN DEATH
DECOMPENSATION
GRADUAL LOSS OF
CARDIAC RESERVE
COMPENSATION
Marie Nováková, Department of Physiology23
BAROREFLEX
Physiological role: compensation of decrease in minimal volume of circulating fluids
Signal: BP decrease (orthostase, work vasodilatation)
Sensor: baroreceptors
Response: activation of SAS (increased HR, inotropy, BP)
Pathological signal: long-lasting decrease of BP due to heart insufficiency
Results: increased energy outcome – vicious circle
ACTIVATION OF RAAS
Physiological role: compensation of loss of circulating fluids (bleeding)
Signal: decrease in renal perfusion
Sensor: juxtaglomerular system of kidney
Response: BP increase (angiotenzin II.), water retention (aldosteron)
Pathological signal: decrease in renal perfusion due to heart insufficiency
Results: increased preload and afterload, increased energy outcome – vicious circle
HEART FAILURE - COMPENSATION
Ca2+ - antagonists
b – sympatolytics
angiotenzin-converting
enzyme inhibitors (AT II.
receptors)
Marie Nováková, Department of Physiology24
DILATATION (STARLING PRINCIPLE)
Physiological role: compensation of momentary right-left differences
Signal: orthostase, deep breathing, beginning of exercise
Pathological signal: continual blood stasis in the heart
Results: increased energy outcome – vicious circle
HYPERTROPHY
Physiological role: preservation of energetically demanding tension of
ventricular wall
Signal: P = s . 2 h / r, intermittent BP increase (athletes heart)
Response: concentric remodelling
Pathological signal: continual increase of preload or afterload
Results: worsening of oxygenation, fibrotisation – vicious circle
cardiac glycosides (digitalis)diuretics