Heart Physiology Lecture 2 PDF

Summary

This lecture notes details the impact of diet and nutrition on heart physiology, including normal and pathological conditions. It covers factors like sodium, potassium, omega-3 fatty acids, saturated and trans fats, fiber, antioxidants, refined sugars, and magnesium. The lecture explores the mechanisms of action for each factor in both healthy and disease states.

Full Transcript

PKK3004: The Cardiovascular System
(Heart)
Human Anatomy & Physiology
Associate Professor Dr. Nur Fariesha Md Hashim
Department of Biomedical Science, FMHS, UPM
 Role in Impact on
Diet/ Heart Heart Mechanism of Action
Nutrition Physiology Physiology in Pathological
Factor (Normal (Pathological Condition
Condition) Condition)
Maintains fluid
High sodium intake
balance,
is linked to
affecting blood High sodium increases water
hypertension, which
pressure retention, raising blood volume
increases strain on
regulation. and thus blood pressure.
the heart, Increased pressure triggers
Sodium High sodium
intake triggers
contributing to left
ventricular
vasoconstriction and stimulates
the kidneys to the renin-angiotensin-aldosterone
hypertrophy, heart
retain water, system (RAAS), leading to vascular
failure, and
increasing blood and cardiac remodeling.
increased risk of
volume and
stroke.
cardiac output.
Low potassium
Counters the levels can lead to Potassium helps balance sodium
effects of sodium arrhythmias and
levels.
on blood weaken heart Low potassium disrupts electrolyte
Potassi pressure and
supports normal
muscle contraction.
Adequate intake is
balance, affecting cellular
excitability and heart muscle
um muscle
contraction,
essential for
lowering blood
contraction strength, leading to
arrhythmias and increased
 Impact on
Role in Heart Mechanism of
Diet/ Heart
Physiology Action in
Nutrition Physiology
(Normal Pathological
Factor (Pathological
Condition) Condition
Reduces inflammation,
improves endothelial
Condition)
Deficiency may contribute
Omega-3s reduce
inflammation by modulating
Omega-3 function, and supports
to higher blood
triglycerides, arrhythmias,
eicosanoid pathways, lower
stable heart rhythms. triglycerides, and stabilize
Fatty Found in fish, nuts, and
and chronic inflammation,
which increases risk of
heart cell membranes, which
seeds, omega-3s help supports regular heart
Acids maintain lower triglyceride
atherosclerosis and
myocardial infarction.
rhythms and reduces
levels. endothelial dysfunction.
Excessive intake leads to
Saturated and trans fats
atherosclerosis due to LDL
Increases low-density increase LDL cholesterol and
buildup in arterial walls,
Saturated lipoprotein (LDL)
cholesterol, potentially
increasing the risk of
decrease HDL, promoting lipid
accumulation in the arterial
coronary artery disease
and Trans causing fatty deposits in
arteries. Moderate intake
and heart attacks. High
walls and plaque formation.
This causes endothelial injury
trans fat intake is
Fats is crucial for balanced
cholesterol levels.
particularly linked to
and initiates an inflammatory
response, leading to
inflammation and
atherosclerosis.
endothelial dysfunction.
Fiber binds to bile acids and
Helps lower cholesterol Low fiber intake is cholesterol in the intestine,
levels by binding to associated with higher reducing LDL absorption. Low
cholesterol in the cholesterol, elevated blood fiber diets lead to higher LDL
Fiber digestive tract, supports
healthy blood pressure,
sugar levels, and an
increased risk for
levels and blood glucose
spikes, contributing to
and reduces risk of hypertension and endothelial damage and
obesity. cardiovascular disease. inflammatory responses in
blood vessels.
 Impact on
Role in Heart Mechanism of
Diet/ Heart
Physiology Action in
Nutrition Physiology
(Normal Pathological
Factor (Pathological
Condition)
Protects heart Low antioxidant intake Condition
tissue from
Condition)
can lead to increased
Antioxidants neutralize free
radicals, reducing oxidative
Antioxidan oxidative damage oxidative stress, stress and preventing damage
ts and maintains
endothelial
damaging blood
vessels and
to endothelial cells.
Low antioxidant levels allow
(Vitamins function. contributing to free radicals to damage
Found in fruits, hypertension, vascular walls, promoting
C, E) vegetables, and atherosclerosis, and inflammation and
whole grains. heart failure. atherogenesis.
Excess sugar Excess sugar causes insulin
intake raises High sugar intake is
spikes, leading to insulin
insulin, which may linked to obesity,
resistance over time.
increase blood insulin resistance, and
Refined pressure and type 2 diabetes, all of
This promotes hyperglycemia
and inflammation, which
triglyceride levels which increase risks for
Sugars Moderation helps hypertension, coronary
damages blood vessels,
increasing the risk for
maintain a healthy artery disease, and
atherosclerosis and
weight, reducing metabolic syndrome.
hypertension.
strain on the heart.
Low magnesium levels
Supports proper Magnesium regulates ion
can cause arrhythmias
muscle and nerve channels, especially calcium
and increase blood
function, channels.
pressure.
stabilizing heart Low magnesium disrupts
Magnesium rhythms.
Magnesium deficiency
calcium influx, affecting
is linked to higher risk
Found in nuts, vascular tone and heart rhythm,
of coronary artery
seeds, and leafy increasing arrhythmogenic risk
 Impact on Heart
Role in Heart
Diet/Nutrition Physiology Mechanism of Action in
Physiology (Normal
Factor (Pathological Pathological Condition
Condition)
Condition)
Deficiency is associated
Vitamin D regulates calcium
Contributes to vascular with hypertension,
metabolism and vascular smooth
increased arterial stiffness,
health and helps muscle function.
and a higher risk of heart
modulate blood pressure. Deficiency increases parathyroid
Vitamin D Adequate levels help disease.
hormone levels, causing vascular
Chronic low vitamin D
maintain overall calcification, arterial stiffness, and
levels are linked to heart
cardiovascular function. impaired blood pressure
failure and cardiovascular
regulation.
events.

Excessive cholesterol leads to LDL
Necessary for hormone High dietary cholesterol,
oxidation, causing endothelial cell
synthesis and cell especially in combination
injury.
membrane structure, but with high saturated fat
Dietary the body typically intake, can raise blood
This triggers an inflammatory
response, promoting foam cell
Cholesterol regulates cholesterol cholesterol levels, leading
formation and plaque buildup,
production to avoid to atherosclerosis and
which narrows arteries and
excess. coronary artery disease.
increases risk for ischemic events.

Excessive alcohol intake
Alcohol disrupts lipid metabolism,
Moderate consumption increases blood pressure,
increasing triglycerides, and can
may raise high-density weakens heart muscle
damage myocardial cells,
lipoprotein (HDL) (cardiomyopathy), and
Alcohol cholesterol and support raises triglyceride levels,
impairing heart muscle function.
It also activates the sympathetic
vascular health, but heightening risks for
nervous system, increasing heart
effects vary. hypertension, arrhythmias,
rate and blood pressure over time.
and heart failure.
 The Cardiovascular System
A closed system of the heart and blood
vessels
– The heart pumps blood
– Blood vessels allow blood to circulate to all
parts of the body

The function of the cardiovascular system
is to deliver oxygen and nutrients and to
remove carbon dioxide and other waste
products
The structure of the heart
 Heart Anatomy
Approximately the size of your fist
Location
– Superior surface of diaphragm
– Left of the midline
– Anterior to the vertebral column,
posterior to the sternum

9
Heart Anatomy

10
 Coverings of the Heart:
Anatomy
Pericardium – a double-walled sac
around the heart composed of:
1. A superficial fibrous pericardium
2. A deep two-layer serous pericardium
a. The parietal layer lines the internal
surface of the fibrous pericardium
b. The visceral layer or epicardium lines the
surface of the heart
They are separated by the fluid-filled
pericardial cavity

11
 Coverings of the Heart:
Physiology
The Function of the Pericardium:
– Protects and anchors the heart
– Prevents overfilling of the heart with
blood
– Allows for the heart to work in a
relatively friction-free environment

Chapter 18, Cardiovascular System 12
Pericardial Layers of the
Heart

13
 Heart Wall
Epicardium – visceral layer of the
serous pericardium
Myocardium – cardiac muscle layer
forming the bulk of the heart
Fibrous skeleton of the heart –
crisscrossing, interlacing layer of
connective tissue
Endocardium – endothelial layer of the
inner myocardial surface
14
 External Heart: Major
Vessels of the Heart
(Anterior View)
Vessels returning blood to the heart
include:
1. Superior and inferior venae cavae
2. Right and left pulmonary veins
Vessels conveying blood away from the
heart include:
1. Pulmonary trunk, which splits into right and
left pulmonary arteries
2. Ascending aorta (three branches) –
a. Brachiocephalic
b. Left common carotid
c. Subclavian arteries
External Heart: Vessels that
Supply/Drain the Heart
(Anterior View)

Arteries – right and left coronary (in
atrioventricular groove), marginal, circumflex,
and anterior interventricular arteries

Veins – small cardiac, anterior cardiac, and
great cardiac veins
External Heart: Anterior
View
 External Heart: Major
Vessels of the Heart
(Posterior View)
Vessels returning blood to the heart
include:
1. Right and left pulmonary veins
2. Superior and inferior venae cavae
Vessels conveying blood away from
the heart include:
1. Aorta
2. Right and left pulmonary arteries
External Heart: Vessels that
Supply/Drain the Heart
(Posterior View)
Arteries – right coronary artery (in
atrioventricular groove) and the
posterior interventricular artery (in
interventricular groove)
Veins – great cardiac vein, posterior
vein to left ventricle, coronary sinus,
and middle cardiac vein
External Heart: Posterior
View
Gross Anatomy of Heart:
Frontal Section
 Atria of the Heart
Atria are the receiving chambers of the
heart
Each atrium has a protruding auricle
Pectinate muscles mark atrial walls
Blood enters right atria from superior
and inferior venae cavae and coronary
sinus
Blood enters left atria from pulmonary
veins
 Ventricles of the Heart
Ventricles are the discharging chambers of
the heart
Papillary muscles and trabeculae
carneae muscles mark ventricular walls
Right ventricle pumps blood into the
pulmonary trunk
Left ventricle pumps blood into the aorta
Heart Function to Circulate Human Blood
 Myocardial Thickness and Function

Thickness of myocardium varies according to the function of
the chamber
Atria are thin walled, deliver blood to adjacent ventricles
Ventricle walls are much thicker and stronger
– right ventricle supplies blood to the lungs (little flow resistance)
– left ventricle wall is the thickest to supply systemic circulation
 Thickness of Cardiac Walls

Myocardium of left ventricle is much thicker than the right.
Atrial Septal Defect
Ventricular Septal Defect
 Pathway of Blood Through
the Heart and Lungs
Right atrium  tricuspid valve  right
ventricle
Right ventricle  pulmonary semilunar
valve  pulmonary arteries  lungs
Lungs  pulmonary veins  left atrium
Left atrium  bicuspid valve  left ventricle
Left ventricle  aortic semilunar valve 
aorta
Aorta  systemic circulation
Pathway of Blood Through
the Heart and Lungs
 Coronary Circulation
Coronary circulation is the
functional blood supply to the heart
muscle itself

Collateral routes ensure blood
delivery to heart even if major
vessels are occluded
Coronary Circulation:
Arterial Supply
Coronary Circulation:
Venous Supply
 Heart Valves
Heart valves ensure unidirectional
blood flow through the heart
Atrioventricular (AV) valves lie
between the atria and the ventricles
– AV valves prevent backflow into the atria
when ventricles contract
Chordae tendineae anchor AV valves to
papillary muscles
 Heart Valves
Semilunar valves prevent backflow of
blood into the ventricles
Aortic semilunar valve lies
between the left ventricle and the
aorta
Pulmonary semilunar valve lies
between the right ventricle and
pulmonary trunk
Heart Valves
Heart Valves
Atrioventricular Valve
Function
Semilunar Valve Function
Mitral Valve Prolapse
How the heart pumps blood?
 Microscopic Anatomy of
Heart Muscle
Cardiac muscle is striated, short, fat,
branched, and interconnected
The connective tissue endomysium acts as
both tendon and insertion
Intercalated discs anchor cardiac cells
together and allow free passage of ions
Heart muscle behaves as a functional
syncytium
Microscopic Anatomy of
Heart Muscle

Chapter 18, Cardiovascular System 43
 Lecture Outline
Cardiovascular System Function
Functional Anatomy of the Heart
Myocardial Physiology
Cardiac Cycle
Cardiac Output Controls & Blood
Pressure
 Cardiovascular System
Function
Functional components of the cardiovascular
system:
– Heart
– Blood Vessels
– Blood
General functions these components provide:
– Transportation
Everything transported by the blood
– Regulation
Of the cardiovascular system
– Intrinsic v extrinsic
– Protection
Against blood loss
– Production/Synthesis
 Cardiovascular System
Function
To create the “pump” we have to
examine the functional anatomy of
the:

– Cardiac muscle
– Chambers
– Valves
– Intrinsic Conduction System
More about our Pumping
hearts
 Lecture Outline
Cardiovascular System Function
Functional Anatomy of the Heart
Myocardial Physiology
Cardiac Cycle
Cardiac Output Controls & Blood
Pressure
 Functional Anatomy of the
Heart
Cardiac Muscle
Characteristic
s
– Striated
– Short
branched cells
– Uninucleate
– Intercalated
discs
– T-tubules
larger and
over z-discs
 Functional Anatomy of the
Heart
Chambers

4 chambers
– 2 Atria
– 2 Ventricles

2 systems
– Pulmonary
– Systemic
 Functional Anatomy of the
Heart
Valves

Function is to prevent
backflow
– Atrioventricular Valves (AV)
Prevent backflow to the atria
Prolapse is prevented by the
chordae tendinae
– Tensioned by the papillary muscles

– Semilunar Valves
Prevent backflow into ventricles
 Functional Anatomy of the
Heart
Intrinsic Conduction System

Consists of
“pacemaker”
cells and
conduction
pathways
– Coordinate the
contraction of
the atria and
ventricles
How does the heart work?
 Lecture Outline
Cardiovascular System Function
Functional Anatomy of the Heart
Myocardial Physiology
– Autorhythmic Cells (Pacemaker cells)
– Contractile cells
Cardiac Cycle
Cardiac Output Controls & Blood
Pressure
 Myocardial Physiology
Autorhythmic Cells (Pacemaker Cells)
Characteristics of
Pacemaker Cells
– Smaller than
contractile cells
– Don’t contain
conduction myofibers

many myofibrils normal
contractile

– No organized myocardial cell

sarcomere
structure
do not contribute
to the contractile SA node cell
AV node cells
force of the heart
 Myocardial Physiology
Autorhythmic Cells (Pacemaker Cells)

Characteristics of Pacemaker Cells

– Unstable membrane potential
“bottoms out” at -60mV
“drifts upward” to -40mV, forming a pacemaker
potential

– Myogenic
The upward “drift” allows the membrane to reach
threshold potential (-40mV) by itself

This is due to
1. Slow leakage of K+ out & faster leakage of Na+ in
2. Ca2+ channels open as membrane approaches threshold
3. Slow K+ channels open as membrane depolarizes causing
an
efflux of K+ and a repolarization of membrane
 Myocardial Physiology
Autorhythmic Cells (Pacemaker Cells)

Characteristics of Pacemaker Cells
 Myocardial Physiology
Autorhythmic Cells (Pacemaker Cells)

Altering Activity of Pacemaker Cells
– Sympathetic activity
NE and E increase If channel activity
 Myocardial Physiology
Autorhythmic Cells (Pacemaker Cells)

Altering Activity of Pacemaker Cells
– Parasympathetic activity
ACh binds to muscarinic receptors
– Increases K+ permeability and decreases Ca2+
permeability = hyperpolarizing the membrane
» Longer time to threshold = slower rate of action
potentials
 Myocardial Physiology
Contractile Cells
Special aspects
– Intercalated discs
Highly convoluted and
interdigitated junctions
– Joint adjacent cells with
» Desmosomes & fascia
adherens
– Allow for synticial activity
» With gap junctions
– More mitochondria than skeletal
muscle
– Less sarcoplasmic reticulum
Ca2+ also influxes from ECF
reducing storage need
– Larger t-tubules
Internally branching
– Myocardial contractions are graded
 Myocardial Physiology
Contractile Cells
Special aspects
– The action potential of a contractile cell
Ca2+ plays a major role again
Action potential is longer in duration than a “normal” action
potential due to Ca2+ entry
Phases
4 – resting membrane potential @ -90mV
0 – depolarization
» Due to gap junctions or conduction fiber action
» Voltage gated Na+ channels open… close at 20mV
1 – temporary repolarization
» Open K+ channels allow some K+ to leave the cell
2 – plateau phase
» Voltage gated Ca2+ channels are fully open (started during
initial depolarization)
3 – repolarization
» Ca2+ channels close and K+ permeability increases as slower
activated K+ channels open, causing a quick repolarization

– What is the significance of the plateau phase?
 Myocardial Physiology
Contractile Cells

Skeletal Action Potential vs Contractile Myocardial Action Potential
 Myocardial Physiology
Contractile Cells
Plateau phase prevents summation due to the elongated refractory
period
No summation capacity = no tetanus
– Which would be fatal
» Tetanus =a sustained muscle contraction evoked when the motor nerve that
innervates a skeletal muscle emits action potentials at a very high rate.
Summary of Action Potentials
Skeletal Muscle vs Cardiac Muscle
 Lecture Outline
Cardiovascular System Function
Functional Anatomy of the Heart
Myocardial Physiology
– Autorhythmic Cells (Pacemaker cells)
– Contractile cells
Cardiac Cycle
Cardiac Output Controls & Blood
Pressure
The Cardiac Conduction
System
 Cardiac Cycle
Coordinating the activity

Cardiac cycle is the sequence of events as blood
enters the atria, leaves the ventricles and then
starts over

Synchronizing this is the Intrinsic Electrical
Conduction System

Influencing the rate (chronotropy & dromotropy)
is done by the sympathetic and
parasympathetic divisions of the ANS
 Cardiac Cycle
Coordinating the activity
Electrical Conduction Pathway
– Initiated by the Sino-Atrial node (SA node) which is myogenic at 70-80
action potentials/minute

– Depolarization is spread through the atria via gap junctions and
internodal pathways to the Atrio-Ventricular node (AV node)
The fibrous connective tissue matrix of the heart prevents further
spread of APs to the ventricles
A slight delay at the AV node occurs
– Due to slower formation of action potentials
– Allows further emptying of the atria

– Action potentials travel down the Atrioventricular bundle (Bundle of
His) which splits into left and right atrioventricular bundles (bundle
branches) and then into the conduction myofibers (Purkinje cells)
Purkinje cells are larger in diameter & conduct impulse very rapidly
– Causes the cells at the apex to contract nearly simultaneously
» Good for ventricular ejection
 Cardiac Cycle
Coordinating the activity

Electrical
Conductio
n Pathway
 Cardiac Cycle
Coordinating the activity

The electrical system gives rise to
electrical changes
(depolarization/repolarization) that is
transmitted through isotonic body
fluids and is recordable
– The ECG!
A recording of electrical activity
Can be mapped to the cardiac cycle
 Cardiac Cycle
Phases

Systole = period of contraction
Diastole = period of relaxation
Cardiac Cycle is alternating periods of systole and
diastole
Phases of the cardiac cycle
1. Rest
Both atria and ventricles in diastole
Blood is filling both atria and ventricles due to low pressure
conditions
2. Atrial Systole
Completes ventricular filling
3. Isovolumetric Ventricular Contraction
Increased pressure in the ventricles causes the AV valves to
close… why?
– Creates the first heart sound (lub)
Atria go back to diastole
No blood flow as semilunar valves are closed as well
 Cardiac Cycle
Phases

Phases of the cardiac cycle
4. Ventricular Ejection
Intraventricular pressure overcomes aortic pressure
– Semilunar valves open
– Blood is ejected

5. Isovolumetric Ventricular Relaxation
Intraventricular pressure drops below aortic pressure
– Semilunar valves close = second heart sound (dup)
Pressure still hasn’t dropped enough to open AV
valves so volume remains the same (isovolumetric)

Back to Atrial & Ventricular Diastole
The Cardiac Cycle
Cardiac Cycle
Phases
 Cardiac Cycle
Blood Volumes & Pressure
Cardiac Cycle
Putting it all together!
A Quick
revision
Cardiac Muscle Contraction
Heart muscle:
– Is stimulated by nerves and is self-
excitable (automaticity)
– Contracts as a unit
– Has a long (250 ms) absolute refractory
period

Cardiac muscle contraction is similar to
skeletal muscle contraction
 Heart Physiology: Intrinsic
Conduction System
Autorhythmic cells:
– Initiate action potentials
– Have unstable resting potentials called
pacemaker potentials
– Use calcium influx (rather than
sodium) for rising phase of the action
potential
Pacemaker and Action
Potentials of the Heart
Heart Physiology: Sequence
of Excitation

Sinoatrial (SA) node generates
impulses about 75 times/minute

Atrioventricular (AV) node delays
the impulse approximately 0.1 second
 Heart Physiology: Sequence
of Excitation
Impulse passes from atria to ventricles
via the atrioventricular bundle
(bundle of His)
– AV bundle splits into two pathways in the
interventricular septum (bundle branches)
1. Bundle branches carry the impulse
towards the apex of the heart
2. Purkinje fibers carry the impulse to the
heart apex and ventricular walls
Heart Physiology: Sequence
of Excitation
Heart Excitation Related to
ECG
ECG
 Extrinsic Innervation of the
Heart
The heart is
stimulated by the
sympathetic
cardio-acceleratory
center

Heart is inhibited
by the
parasympathetic
cardio-inhibitory
center

87
 Electrocardiography
Electrical activity is recorded by electrocardiogram
(ECG)

P wave corresponds to depolarization of SA node

QRS complex corresponds to ventricular depolarization

T wave corresponds to ventricular repolarization

Atrial repolarization record is masked by the larger
QRS complex
Electrocardiography
 Heart Sounds
Heart sounds (lub-dup) are associated
with closing of heart valves

– First sound occurs as AV valves close and
signifies beginning of systole (contraction)

– Second sound occurs when SemiLunar
valves close at the beginning of ventricular
diastole (relaxation)
Heartbeat and Pulse
 Cardiac Cycle
Cardiac cycle refers to all events
associated with blood flow through
the heart

– Systole – contraction of heart muscle
– Diastole – relaxation of heart muscle
 Phases of the Cardiac Cycle
Ventricular filling – mid-to-late diastole
– Heart blood pressure is low as blood enters
atria (passively) and flows into ventricles
– AV valves are open, then atrial systole occurs
 Phases of the Cardiac Cycle
Ventricular systole (contraction)
– Atria relax
– Rising ventricular pressure results in closing
of AV valves
– Isovolumetric contraction phase
– Ventricular ejection phase opens semilunar
valves
Phases of the Cardiac Cycle
Isovolumetric relaxation – early diastole
– Ventricles relax
– Backflow of blood in aorta and pulmonary
trunk closes semilunar valves

Dicrotic notch – brief rise in aortic
pressure caused by backflow of blood
rebounding off semilunar valves
Phases of the Cardiac Cycle

Chapter 18, Cardiovascular System 96 Figure 18.20
 Cardiac Output (CO) and
Reserve
Cardiac Output is the amount of blood
pumped by each ventricle in one minute
– CO is the product of heart rate (HR) and
stroke volume (SV)
HR is the number of heart beats per minute
SV is the amount of blood pumped out by a
ventricle with each beat

Cardiac reserve is the difference
between resting and maximal CO
 Cardiac Output: Example
CO (ml/min) = HR (75 beats/min) x SV
(70 ml/beat)
CO = 5250 ml/min (5.25 L/min)
Regulation of Stroke Volume
SV = end diastolic volume (EDV)
minus end systolic volume (ESV)
– EDV = amount of blood collected in a
ventricle during diastole
– ESV = amount of blood remaining in a
ventricle after contraction
 Factors Affecting Stroke
Volume
Preload – amount ventricles are
stretched by contained blood

Contractility – cardiac cell contractile
force due to factors other than EDV

Afterload – back pressure exerted by
blood in the large arteries leaving the
heart
 Frank-Starling Law of the
Heart
Preload, or degree of stretch, of cardiac muscle cells
before they contract is the critical factor controlling
stroke volume

Slow heartbeat and exercise increase venous return to
the heart, increasing SV

Blood loss and extremely rapid heartbeat decrease SV
Preload and Afterload
Extrinsic Factors Influencing
Stroke Volume
Contractility is the increase in contractile
strength, independent of stretch and EDV

Increase in contractility comes from:
– Increased sympathetic stimuli
– Certain hormones
– Ca2+ and some drugs
Extrinsic Factors Influencing
Stroke Volume
Agents/factors that decrease
contractility include:
– Acidosis
– Increased extracellular K+
– Calcium channel blockers
 Contractility and
Norepinephrine
Sympathetic
stimulation
releases
norepinephrin
e and initiates
a cyclic AMP
second-
messenger
system

107
 Regulation of Heart Rate
Positive chronotropic factors increase
heart rate
– Caffeine

Negative chronotropic factors
decrease heart rate
– Sedatives
 Regulation of Heart Rate:
Autonomic Nervous System
Sympathetic nervous system (SNS) stimulation is
activated by stress, anxiety, excitement, or exercise

Parasympathetic nervous system (PNS) stimulation
is mediated by acetylcholine and opposes the SNS
– PNS dominates the autonomic stimulation, slowing
heart rate and causing vagal tone
If the Vagus Nerve was cut, the heart would lose its
tone. Thus, increasing the heart rate by 25 beats
per minute.
 Atrial (Bainbridge) Reflex
Atrial (Bainbridge) reflex – a sympathetic
reflex initiated by increased blood in the atria
– Causes stimulation of the SA node
– Stimulates baroreceptors in the atria, causing
increased SNS stimulation

Damming= obstruction
 Chemical Regulation of the
Heart
The hormones epinephrine and
thyroxine increase heart rate

Intra- and extracellular ion
concentrations must be maintained for
normal heart function
 Factors Involved in
Regulation of Cardiac
Output
 Congestive Heart Failure
(CHF)
Congestive heart failure (CHF) is
caused by:
– Coronary atherosclerosis
– Persistent high blood pressure
– Multiple myocardial infarcts
– Dilated cardiomyopathy (DCM) – main
pumping chambers of the heart are
dilated and contract poorly
Heart Disease
Developmental Aspects of the
Heart
 Developmental Aspects of
the Heart

Fetal heart structures that bypass
pulmonary circulation
– Foramen ovale connects the two atria
– Ductus arteriosus connects pulmonary
trunk and the aorta
Examples of Congenital
Heart Defects
 Age-Related Changes
Affecting the Heart

Sclerosis and thickening of valve flaps
Decline in cardiac reserve
Fibrosis of cardiac muscle
Atherosclerosis
 Congestive Heart Failure
Causes of CHF
– coronary artery disease, hypertension, MI, valve disorders,
congenital defects

Left side heart failure
– less effective pump so more blood remains in ventricle
– heart is overstretched & even more blood remains
– blood backs up into lungs as pulmonary edema
– suffocation & lack of oxygen to the tissues

Right side failure
– fluid builds up in tissues as peripheral edema
Congenital Heart Conditions
Coronary Artery Disease
Heart muscle receiving
insufficient blood
supply
– narrowing of
vessels---
atherosclerosis,
artery spasm or clot
– atherosclerosis--
smooth muscle &
fatty deposits in
walls of arteries

Treatment
– drugs, bypass graft,
angioplasty, stent
 Clinical Problems
MI = myocardial infarction
– death of area of heart muscle from lack of O2
– replaced with scar tissue
– results depend on size & location of damage
Blood clot
– use clot dissolving drugs streptokinase or t-PA &
heparin
– balloon angioplasty
Angina pectoris
– heart pain from ischemia (lack of blood flow and
oxygen ) of cardiac muscle
What happens during a heart attack?
By-pass Graft
Percutaneous Transluminal
Coronary Angioplasty
Artificial Heart
Revision again…..
 The Heart
Location
– Thorax between
the lungs
– Pointed apex
directed toward
left hip
About the size
of your fist
 The Heart: Coverings

Pericardium – a double serous
membrane
– Visceral pericardium - Next to heart
– Parietal pericardium - Outside layer

Serous fluid fills the space between
the layers of pericardium
 The Heart Wall: 3 layers

Epicardium
Outside layer
This layer is the parietal pericardium
Connective tissue layer
Myocardium
Middle layer
Mostly cardiac muscle
Endocardium
Inner layer
Endothelium
External Heart Anatomy
 The Heart: Chambers
Right and left side act as
separate pumps
Four chambers
– Atria
Receiving chambers
– Right atrium
– Left atrium
– Ventricles
Discharging chambers
– Right ventricle
– Left ventricle
 Blood
Circulatio
n
 The Heart: Valves

Allow blood to flow in only one direction
Four (4) valves
– Atrioventricular valves – between atria and
ventricles
Bicuspid valve (left) Also Called Mitral Valve
Tricuspid valve (right)
– Semilunar valves between ventricle and artery
Pulmonary semilunar valve
Aortic semilunar valve
 The Heart: Valves

Valves open as blood is pumped
through
Held in place by chordae tendineae
(“heart strings”)
Close to prevent backflow
Operation of Heart Valves
 The Heart:
Associated Great Vessels
Aorta - leaves left ventricle
Pulmonary arteries - leave right
ventricle
Vena cava - enters right atrium
Pulmonary veins (four) - enter left
atrium
 Coronary Circulation
Blood in the heart chambers does not
nourish the myocardium
The heart has its own nourishing
circulatory system
– Coronary arteries
– Cardiac veins
– Blood empties into the right atrium via
the coronary sinus
 The Heart: Conduction
System
Intrinsic conduction
system
(nodal system)
– Heart muscle cells
contract, without nerve
impulses, in a regular,
continuous way
Special tissue sets the
pace
Sinoatrial node (SA)
- Pacemaker
Atrioventricular
node (AV)
Atrioventricular
bundle
Bundle branches
Purkinje fibers
 The Heart’s Cardiac Cycle

Atria contract simultaneously
Atria relax, then ventricles contract
Systole = contraction
Diastole = relaxation
 Heart Contractions

Contraction is initiated by the sinoatrial node
Sequential stimulation occurs at other autorhythmic cells
Filling of Heart Chambers – the
Cardiac Cycle
 The Heart: Cardiac Cycle
Cardiac cycle – events of one
complete heart beat
– Mid-to-late diastole – blood flows into
ventricles
– Ventricular systole – blood pressure
builds before ventricle contracts,
pushing out blood
– Early diastole – atria finish re-filling,
ventricular pressure is low
 The Heart: Cardiac Output
Cardiac output (CO)
– Amount of blood pumped by each side
of the heart in one minute
– CO = (heart rate [HR]) x (stroke volume
[SV])
Stroke volume
– Volume of blood pumped by each
ventricle in one contraction
Cardiac Output Regulation
 Regulation of Heart Rate
Stroke volume usually remains
relatively constant
– Starling’s law of the heart – the more
that the cardiac muscle is stretched, the
stronger the contraction
Changing heart rate is the most
common way to change cardiac
output
 Regulation of Heart Rate
Increased heart rate
– Sympathetic nervous system
Activated in a Crisis
Low blood pressure
– Hormones
Epinephrine
Thyroxine
– Exercise
– Decreased blood volume
 Regulation of Heart Rate
Decreased heart rate
– Parasympathetic nervous system
– High blood pressure or blood volume
– Decreased venous return
Blood Vessels: The Vascular
System
Taking blood to the tissues and back
– Arteries
– Arterioles
– Capillaries
– Venules
– Veins
The Vascular System
 Blood Vessels: Anatomy
Three layers (tunics)
– Tunic intima:
Endothelium
– Tunic media
Smooth muscle
Controlled by sympathetic nervous
system
– Tunic externa
Mostly fibrous connective tissue
 Differences Between Blood
Vessel Types
Walls of arteries are the thickest and their
smooth muscle helps move blood
Lumens of veins are larger because walls are
thinner
Larger veins have valves to prevent backflow
Skeletal muscle “milks” blood in veins toward
the heart
Walls of capillaries are only one cell layer
thick to allow for exchanges between blood
and tissue
 Movement of Blood Through
Vessels
Most arterial blood is pumped
by the heart

Veins use the milking action of
muscles to help move blood
 Capillary Beds
Capillary beds
consist of two
types of vessels
– Vascular shunt –
directly connects
an arteriole to a
venule
 Capillary Beds
True capillaries –
exchange vessels
Oxygen and
nutrients cross to
cells
Carbon dioxide
and metabolic
waste products
cross into blood
Diffusion at Capillary Beds
Major Arteries of Systemic
Circulation
Major Veins of Systemic
Circulation
Arterial Supply of the Brain
Hepatic Portal Circulation
Circulation to the Fetus
 Pulse

Pulse –
pressure wave
of blood

Monitored at
“pressure
points” where
pulse is easily
palpated
 Blood Pressure

Measurements by health professionals
are made on the pressure in large arteries
– Systolic – pressure at the peak of ventricular
contraction
– Diastolic – pressure when ventricles relax

Pressure in blood vessels decreases as
the distance away from the heart
increases
Understanding Blood
Pressure
Measuring Arterial Blood
Pressure
 Blood Pressure: Effects of
Factors
Neural factors
– Autonomic nervous system adjustments
(sympathetic division)
Renal factors
– Regulation by altering blood volume
– Renin – hormonal control
 Blood Pressure: Effects of
Factors
Temperature
– Heat has a vasodilation effect
– Cold has a vasoconstricting effect
Chemicals
– Various substances can cause increases
or decreases
Diet
Variations in Blood Pressure
Human normal range is variable
– Normal
140–110 mm Hg systolic
80–75 mm Hg diastolic
– Hypotension
Low systolic (below 110 mm HG)
Often associated with illness
– Hypertension
High systolic (above 140 mm HG)
Can be dangerous if it is chronic
 Capillary Exchange
Substances exchanged due to
concentration gradients
– Oxygen and nutrients leave the blood
– Carbon dioxide and other wastes leave
the cells
 Capillary Exchange:
Mechanisms
Direct diffusion across plasma
membranes
Endocytosis or exocytosis
Some capillaries have gaps (intercellular
clefts)
– Plasma membrane not joined by tight
junctions
Fenestrations of some capillaries
– Fenestrations = pores
Developmental Aspects of the
Cardiovascular System
A simple “tube heart” develops in the
embryo and pumps by the fourth
week
The heart becomes a four-chambered
organ by the end of seven weeks
Few structural changes occur after
the seventh week
 The Heart
This organ is what pumps
oxygen rich blood, nutrients, Pulmonary Artery
hormones, and the other things (Superior Vena
Cava) From the (Aortic Artery) To the
your body needs to maintain
Body body Pulmonary Veins
your health, to your organs and
tissues.
Valves: (tricuspid valve semilunar
The pulmonary veins you see on (pulmonary) valve, bicuspid (mitral)
valve, and the semilunar (aortic) valve
the right side of the diagram
come from your lungs, where the
blood cells collect oxygen. It’s
then pumped out to the rest of
the body through the Aorta
(Top).
All of the blue sections show
blood cells carrying waste, (C02)
moving back to the lungs (where (Inferior Vena
the C02 will be replaced by Cava) From the
oxygen) through the Pulmonary Body
Artery (Top, blue)
By The Way…
Whenever the blood is pumped from one section of the
heart another valve closes behind it preventing the
blood from moving backwards.
 Blood Flow through the
Heart
Blood from the body travels
into the right atrium, moves
into the right ventricle, and is
finally pushed into lungs in
the pulmonary arteries

The blood then picks up
oxygen and travels back to
the heart into the left atrium
through the pulmonary veins

The blood then travels
through the Left Ventricle and Left Atrium
exits to the body through the Right Atrium
Aorta…
 Blood Flow to Arms
Oxygen rich blood leaves
the heart and travels
through arteries

In the capillaries the
oxygen and
food/nutrients is given to
the body’s cells

The blood finally travels
back through veins to the
heart to pick up oxygen ARTERIES- FROM
HEART
CAPILLARIES
VEINS- TO HEART
 Path to the
Exchange
Pulmonary Vein
Aorta A red blood cell
then travels
Brachial Artery from the heart
through arteries
that eventually
Renal Artery branch into the
body’s vast
Redial Artery system of
capillaries
(microscopic
Ulnar Artery blood vessels
which connect
Iliac Artery arteries and
veins), they
eventually lead
to…
 The Exchange
TRANSACT
Sub-Title
When the itty bitty teeny tiny red blood cells pass
the desired tissue they……………………………….
Oxy-Rich Blood
Cell Tissue

The oxygen the blood cells
are carrying is given to the
body’s tissue.
And the CO2 Tissue
(waste) from
Oxy-Poor Blood Cell
the tissue is
given to the
same blood Technically the Hemoglobin in the blood (a substance full of iron) attracts
cell to be oxygen from the lungs. The red blood cell then carries it to the desired
exhaled. tissue. Because this tissue has a high CO 2 count the hemoglobin lets go of
its oxygen and collects the carbon dioxide. You see the hemoglobin has an
How It Works… affinity for whichever gas has a greater count. Because the tissue has a
large amount of built up waste (CO2) the hemoglobin attracts it and then
replaces it with oxygen, and vise versa in the lungs.

Now lets travel to the legs!!!
 Blood Flow to Legs
!FUN
FACT! 500 ml of
Approximately
blood moves from the
heart and lungs down to
the legs when a person
stands up after lying
down

The oxygen rich blood
cells then travel through
the capillaries where yet
another…
 Gas Exchange Occurs,
The oxygen and CO2 are exchanged…in the
cells
Oxygen Rich
Tissue
Don’t forget that the
Hemoglobin in the
blood cells let go of Oxygen Poor
the cell’s oxygen
because of the large
CO2 (waste) count in
the tissue. Oxygen Rich

Oxygen Poor

Now lets go back to the heart!!!
 Circulation back to
Heart
To upper body

From upper
Capillaries carry the blood
body
to…
To lung
To lung
Venules that connect to
From From lung veins and the…
lung Veins (wide blood vessels)
Right
Atrium Left carries the oxygen-poor
Atrium
blood back to the heart.
Right Left
Ventricle Ventricle

From lower
To lower body
body
Conclusion
As you have learned (Hopefully) the Circulatory
and cardiovascular System is one of the
most important systems in the human
body…

It is the
only
reason
you’re
still
alive and you can
today… attribute the
cooling down,
feeding of and
protection of your
body to it. So the next time you bust open
your leg skateboarding you
can thank your Circulatory
System for patching you up.
Terima Kasih