Transcript Slide 1

CARDIOVASCULAR
SYSTEM
THE HEART
Cardiovascular System
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series of tubes-blood vessels
filled with a fluid-blood
connected to a pump-heart
Arteries
– carry blood away from heart
Veins
– carry blood to heart
pressure generated in heart
pumps blood continuously
through system
Blood flow
– movement of blood through
heart & around body to
peripheral tissues
Circulation
Circulation
• right side of bodyPulmonary Circuit
– carries blood to & from
lungs for gas exchange
• Systemic Circuit
– carries newly
oxygenated blood from
lungs to body & back to
heart
• each circuit begins & ends
at heart
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Heart Anatomy
hollow, small organ
about size of clenched fist
weighs from 250-350 grams
located in middle of chest in
mediastinum
surrounded by pericardial cavity
lining of pericardial cavity is
pericardium
– visceral & parietal part
visceral pericardium -epicardium
– superficial layer that covers
surface of heart
parietal pericardium
– lines inner surface of pericardial
sac which surrounds heart
between these two-pericardial
cavity
filled with pericardial fluid
to lubricate & reduce friction
Heart Wall
• 3 layers
• Epicardium-visceral
pericardium
– covers outer
surface
• Myocardium
– muscular wall
• Endocardium
– simple squamous
epithelium
Microscopic Anatomy
• different from skeletal muscle
in several ways
• cells are smaller
• uninucleated
• have branching
interconnections between
have intercalated discs
– location of gap junctions &
desmosomes
– convey action potentials
from cell to cell
– ensure cells contract
simultaneously
Heart Anatomy
• top of heart-base
• pointed, lower part-apex
• 4 chambers
– 2 atria & 2 ventricles
• coronary sulcus
(atrioventricular
sulcus)
• anterior & posterior
interventricular sulci
– mark external
boundary of right & left
ventricle
Coronary
Sulcus
Heart Anatomy
• each atrium has expandable
extensions- auricles
– hold extra blood
• right atrium receives blood
from systemic circuit via
superior & inferior vena
cavae & coronary sinus
• superior vena cava
– returns blood from body areas
superior to diaphragm
• inferior vena cava
– drains areas below diaphragm
• coronary sinus
– delivers blood from myocardium
of heart
Internal Heart Anatomy
• blood passes into right
ventricle via right AV
(atrioventricular) valve or
tricuspid valve
– keeps blood flowing in one
direction from atrium to
ventricle
– prevents backflow into
atrium
• tiny, white collagen cordschordae tendineae attach to
each flap
• originate at papillary muscles
– help to close valves
• chordae tendineae & papillary
muscles anchor flaps in
closed position
Internal Heart Anatomy
• pectinate muscles-right
atrium
• fossa ovalis also found here
• muscular ridges- ventriclestrabeculae carnae
• moderator band extends
horizontally from right
ventricle wall
– coordinates contraction
of muscle cells
– insures chordae tendinae
tense before ventricles
contract
Internal Anatomy
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from right ventricle blood is pumped to
pulmonary circuit
valves between ventricles & vesselssemilunar valves
– prevent back flow into ventricles
each made of 3 pocket-like flaps
shaped like crescent moons
blood travels via pulmonary semilunar
valve into pulmonary trunk
– start of pulmonary circuit
from pulmonary trunk, blood goes to
left & right pulmonary arteries and to
lungs for gas exchange
after being oxygenated, blood reenters
heart via 2 left & 2 right pulmonary
veins-open into left atrium
blood goes from left atrium to left
ventricle via left AV valve
bicuspid or mitral valve
from here blood is ejected through
aortic semi lunar valveinto aortic arch
Heart Anatomy
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left ventricle
– discharging chamber
contractsblood propelled into
circulation
equal volumes are pumped to both
circuits
right pumps blood to pulmonary circuit
through pulmonary trunk
– short path with low pressure
left pumps blood through systemic
circuit
– long path-runs through entire body
– 5X more resistance to flow
– functional difference between left &
right ventricle is reflected in anatomy
left ventricle walls are 3X as thick as
right ventricle wall
– allows left ventricle to generate more
pressure
pulmonary trunk is attached to aortic
arch by ligamentum arteriosum
Ligamentum
arteriosum
Label Me
Valve Function
• atrioventricular
& semilunar
valves
• open & close in
response to
blood pressure
differences
AV VALVES
• relaxed heart
• AV valve flaps hang
limply in ventricle
– blood flows from atria
into ventricle
• when ventricles
contract
intraventricular
pressure increases
– forces blood superiorly
against flaps causing
flap edges to meet &
close valve
Semi-Lunar Valves
• ventricles
contractintraventricu
lar pressure rises
• blood pushes against
valvesopen
• ventricles relax
intraventricular
pressure fallsblood
flows back from
arteriesfills
cuspsvalve closes
Coronary Circulation
• heart muscle must have its own
source of oxygenated blood
• supplied by coronary arteries
– originate at base of ascending
aorta
– blood pressure
• right coronary artery follows coronary
sulcus & supplies right atrium, parts of
both ventricles & parts of conducting
system
• left coronary artery supplies: left
ventricle, left atrium & interventricular
septum
• great cardiac vein
– begins anterior surface of
ventricles along interventriuclar
sulcus
• curves around left side of heart in
coronary sulcus
• empties into coronary sinus
Heart Beat
• myocytes-autorhythmic
– depolarize spontaneously at
regular time intervals
– initiate contraction without
signals from brain
• each beat begins with action potential
generated at SA node (sino-atrial)pacemaker
– generates impulses at regular
intervals
• to ensure four chambers of heart are
coordinated electrical signals travel
through cardiac conduction system
• sympathetic & parasympathetic
connections to heart can modify heart
beat
– not involved in normal contractions
Conducting System
• autorhythmic cells in SA
node (sinoatrial node)
– right atrium
• AV-atrioventricular
node
– junction of atria &
ventricles
• atrioventricular bundle
or bundle of his
• right & left bundle
branches
• purkinje fibers
Initiation of Contraction
• action potentials are spontaneously initiated by
autorhythmic cells in SA node
• possess leaky membranes
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have unstable resting potentials
exchange Na, K & Ca ions
causes changes in polarization
cells are continuously depolarized
drift slowly toward threshold
• spontaneously changing membrane potentials
are pacemaker potentials
• initiate action potentials which spread
throughout heart
Impulse Conduction
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SA node contract 75X/minute
sets pace for heart beat
– no other area has faster depolarization
rate
– pacemaker
action potential- conducted to AV nodebottom of right atrium
– conduction delayed about 0.1 sec
– AV delay allows atria to respond & have
complete contraction before ventricles
contract
impulse travels to Bundle of Hisatrioventricular bundle
splits into right & left bundle branches
bundle branches go along interventricular
septum toward apex divide into purkinje
fibersmoderator band papillary muscle
of right ventricle contracts before rest of
ventricleapplies tension on chordae
tendineaebraces AV valvesprevents
back flow into atria when ventricles contract
contraction proceeds from bottom of
ventricles
blood is pushed toward base of heart
Label Parts of Conducting System
ECG-EKG-Electrocardiography
• electrical currents can be detected by
placing electrodes (leads) on skin’s
surface
• electrocardiograph amplifies signals
• produces record-EKG, ECG or
electrocardiogram
• measures rate & regularity of beats
• measures size & position of heart
chambers
• sum of all electrical potentials
generated by all cells of heart at any
moment
• each component of EKG reflects
depolarization and/or repolarization
of a part of heart
• because depolarization is signal for
contractionelectrical events shown
as waves on EKG can be associated
with contraction or relaxation of atria
& ventricles
EKG Trace-Deflection Waves
• P Wave
– represents
depolarization of atria
• QRS complex
– represents ventricular
depolarization
– atrial repolarization
occurs during this time
but is obscured by
QRS complex
• T Wave
– represents ventricular
repolarization
EKG Trace
• size, duration & timing of waves tend to be
consistent
• any change may reflect damage to or
problems with conduction system
Abnormal EKG Traces
• lowered P
– AV block
• enlarged R
– may indicate
enlarged ventricle
• flattened T
– cardiac ischemia
• prolonged Q
– repolarization
problem
Contraction
• purkinje fibers distribute action potential to
contractile cells of heart
• action potentialsCa appears among
myofibrils  binds to troponin cross
bridges form contraction
• differences from skeletal muscle contraction
• action potentials-30X longer, from 250300msec
• source of Ca is different
• duration of contraction longer
Action Potential
• resting potential of ventricular
contractile cell is -90mV
• action potential begins when
membrane of ventricular cell is
brought to threshold
• depolarization travels from cell
to cell by ions passing through
gap junctions
• action potential proceeds in 3
steps
• rapid depolarization
• plateau
• repolarization
Action Potential
• rapid depolarization
• fast Na channels openNa rushes
indepolarization
• plateau phase
– action potential flattens as
membrane potential nears +30mV
– Na channels close & slow Ca
channels open
• slow Ca channels remain open
175msec
– as long as Ca enters cellcell
contracts
• repolarization
– takes place as plateau phase ends
– slow Ca channels close & slow K
channels open
– K rushes out of the cell
– restores resting potential
Muscle Tension
• develops during plateau phase
• peaks just after plateau ends
• long plateau helps prevent
sustained contraction or
tetanus
• refractory period
– time when muscle is
inexcitable
– in cardiac muscle lasts as
long as contraction
• important since cardiac muscle
must relax between
contractions so ventricles can
fill with blood
– would stop pumping action
Cardiac Cycle
• time between start of one
heartbeat & start of next
• includes one contraction & one
relaxation
• for each chamber-cycle is
divided into 2 phases:
• contraction or systole
– chamber contracts &
pushes blood into adjacent
chamber or arterial trunk
• relaxation or diastole
– chamber fills with blood
• fluids flow from areas of higher
to areas of lower pressures
• blood flows only if one
chamber’s pressure is higher
than another
Phases of Cardiac Cycle
• beginning all chambers relaxed
• atria & ventricle diastole
• AV valves between atria &
ventricles are opened
• semilunar valves areclosed
• blood flows from veins into atria &
into ventricles-Passive Filling
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-ventricles 70% filled with blood
atria contractatrial systole
complete ventricular filling
end of atrial systole-end of ventricular
diastole
• ventricular volume is greatest at this time
– end-diastolic volume or EDV
– maximum amount of blood ventricles can
hold
Phases of Cardiac Cycle
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atria relax
atrial diastole continues until start of next cardiac
cycle
begins at same time as ventricular systole
ventricles contractpressure in ventricles rises
above pressure in atriaAV valves close
– first heart sound-lubb
both AV & semilunar valves are closed
– blood has nowhere to goventricles continue to
contract
isometric contractionpressure increasestension
no change in ventricular volume
– isovolumetric contraction
once pressure in ventricles is greater than pressure
in arterial trunks, semilunar valve open blood
flows into pulmonary & aortic trucks
beginning of ventricular ejection
each ventricle ejects 70 ml of blood = stroke
volume-SV
as ventricle systole endsventricular pressure falls
rapidly
blood in aorta & pulmonary trunks flows towards
ventricles & fills cusps of semilunar valves causing
them to close
– second heart sound-dupp
ventricular
Phases of Cardiac Cycle
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amount of blood remaining in ventriclesESV or end systolic volume
Ventricular Diastole
– ventricles relax
– all valves are closed
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ventricular pressure-still high
no change in ventricular volume
since all valves are closed this is
isovolumetric relaxation
ventricular pressure falls rapidly now
when ventricular pressure falls below
pressures in aortaatrial pressure forces
AV valves openblood flows from atria
to ventricles
both atria & ventricles are in diastole
ventricular pressure continues to fall as
chambers fill passively
cycle repeats
when heart rate increasesall phases
shorten
greatest reduction in diastole
ventricular
Blood Pressure
• Systolic blood
pressure
– pressure in aorta
– 120 mmHg
• Diastolic blood
pressure
– 80mmHg
• when semilunar valves
close, aortic pressure
rises as elastic arterial
walls recoil
• small, temporary rise in
pressure-dicrotic notch
Heart Sounds
• Ausculation
– listening to heart
using stethoscope
• several areas on
chest where these
are best heard
• Aortic Area
• Pulmonic Area
• Tricuspid Area
• Mitral Area
Heart Sounds
• S1
– AV valves close-lubb
• S2
– semilunars closedupp
• S3
– ventriclular filling
• S4
– atrial contraction
• third & forth are faint
• seldom detected in
normal people
Cardiodynamics
• need to review some terms
• EDV
– amount of blood in ventricles at end of
ventricular diastole
• ESV
– amount of blood in each ventricle at end of
ventricular systole
• Stroke Volume
– amount of blood pumped out of each ventricle
during one beat
• SV = EDV – ESV
Cardiodynamics
• Stroke volume
– most important factor when examining single cardiac cycle
– largest when EDV is as large as can be & ESV is as small as can be
• Cardiac Output
– most important when looking at cardiac function over time
– amount of blood pumped by each ventricle/minute
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– represents blood flow through peripheral tissues or total blood flow
through body
CO (ml/min) = heart rate (beats/min) X SV (ml/beat)
CO = 75bpm X 70mL/beat = 5.250L/minute-average total blood volume
not constant
– varies with body’s state of activity
• exercise increases CO
CO precisely adjusted so peripheral tissues receive adequate supply of
blood under variety of conditions
Control of Cardiac Output
• adjusted by changing
SV or HR
• changes generally
reflect change in both
SV & HR
• HR can be adjusted
with autonomic
nervous system &
hormones
• SV can be adjusted by
changing EDV, ESV
or both
Factors Affecting Stroke Volume
• Preload
–degree of stretch on heart
before contraction
• Contractility
–forcefulness of contraction
• Afterload
–pressure that must be exceeded
before ejection of blood can
occur
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Preload
indicates degree of stretch
prior to contraction
– directly proportional to EDV
greater EDVgreater
preload
the more the heart fills with
blood during diastolethe
greater force of contraction
during systole
relationship-Frank-Starling
Law of the Heart
greater EDVgreater SV due
to stretch on muscle fibers
SV is directly proportional to
EDV
Factors Affecting EDV
• Two key factors
determine EDV:
• duration of
ventricular
diastole
• venous return
• volume of blood
returning to right
atrium
Contractility
• amount of force produced
during contraction at a given
preload
• factors that increase
contractility are positive
inotropic agents
• those that reduce it-negative
inotrophic agents
• positive ionotropic factors
typically stimulate Ca entry
into cells
• negative ionotropic factors
function to block Ca
Afterload
• blood pressure outside semilunar
valves
• opposes opening of these valves
– amount of tension ventricles must
produce to force semilunar valves
open & eject blood
• increased afterload reduces stroke
volume
• greater afterload longer
isovolumetric contraction
• shorter time of ventricular ejection,
and larger ESV
• as afterload increasesSV
decreases
• afterload can be increased by any
factor that restricts blood flow
through arterial system
– constriction of peripheral blood
vesselsdecreases BP &
increases afterload
Regulation of Heart Rate
• nervous system does not initiate
heart beat
• modulates rhythm & force
• sympathetic & parasympathetic
fibers innervate heart via
cardiac plexus
• sympathetic & parasympathetic
fibers SA & AV nodes & atrial
muscle cells
• ventricles also innervated by
sympathetic fibers
Tonic Control of Heart
• both centers are involved
• both fire at steady level
• vagus nerve maintains constant background
firing rate
– inhibits nodes
• if vagus is cutHR increases because SA node
fires on its own at about 100X per minute
• vagus intact
• keeps heart rate 75bpm
Cardiac Center
• located in medulla
oblongata
• has cardioacceleratory &
cardioinhibitory part
• cardioacceleratory center
sends signals by
sympathetic fibers to SA
node, AV node &
myocardium
• secrete norepinephrine
– binds to beta-1 receptors
in heart
– increases heart rate
– Increases the entrance
of calcium
– Increases contractility
Cardiac Center
• cardioinhibitory centers
• send signals via
parasympathetic fibers in
vagus nerve to SA & AV
nodes
• secretes acetylcholine
• opens potassium channels
in nodal cells
• as potassium leaves
cellsbecome
hyperpolarizedfire less
frequentlyheart rate slows
Receptors to Cardiac Centers
• receive & integrate information from
many sources
• sensory & emotional stimuli can act
by cerebral cortex, limbic system &
hypothalamus to change heart rate
• Proprioceptors in muscles & joints
report changes in physical activity
• Baroreceptors or pressure receptors
in aorta & internal carotid arteries
send continuous information to
cardiac centers
• Chemoreceptors send information
about Na, K, hydrogen ions and
oxygen
Chemoreceptors
• responses to fluctuations in blood chemistry are
called chemoreflexes
• in aortic arch, carotid arteries & medulla
oblongata
• monitor ph, carbon dioxide & oxygen levels in
blood
• more important in respiratory rate-can function
to change HR
• carbon dioxide accumulates in blood & cerebral
spinal fluidpH lowers acidosis
• stimulates cardiac center to increase heart rate
• oxygen deficiencyslows heart rate
Hormones
• Catecholamines
–epinephrine &
norepinephrine
–adrenal medulla
–increase heart rate &
contractility