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Cardiovascular Structure and Function

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Cardiovascular Structure and Function Function of CV system: Transport of O2 to tissues and remove waste (delivery and garbage) Transport nutrients to tissues ... – PowerPoint PPT presentation

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Title: Cardiovascular Structure and Function


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Cardiovascular Structure and Function
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Function of CV system
  • Transport of O2 to tissues and remove waste
    (delivery and garbage)
  • Transport nutrients to tissues
  • Regulate body temperature
  • Right and left sides have separate functions

4
R side
  • Atria receives blood from systemic circulation
    (superior and inferior vena cavas)
  • Ventricle pumps blood to lungs for oxygenation
    via pulmonary artery

5
L side
  • Receive blood (oxygenated) from lungs
  • Pump blood into the aorta (thick-walled and
    muscular in nature) to systemic circulation

6
4 chambered muscular organ
  • 2 pumps, pulmonary and systemic circulation
  • Heart muscle is called myocardium
  • Striated, with actin and myosin filaments,
    similar to skeletal muscle
  • Difference, cells are single nucleated,
    interconnected in a form similar to a lattice

7
  • Connected by intercalated disks that allows
    chemical and electrical coupling between cells
  • Thick septum (interventricular septum) that
    separates R and L sides

8
Cardiac Chambers
  • Atria are thin walled, sac-like chambers, low
    pressure
  • function is to receive and store blood while
    ventricles are contracting, act as primer pumps
  • reservoir is more important than pump for blood
    propulsion

9
  • Ventricles are a continuum of muscle fibers
  • contract from apex to base
  • R ventricle is thicker than R atria
  • L ventricle is 3X thicker than the R ventricular
    walls
  • L ventricle can develop 4-5X more pressure than
    the R ventricle

10
Number of valves in heart
  • Thin flaps of endothelium covered fibrous tissue
  • Movement of the valve leaflets are essentially
    passive
  • Orientation of valves is responsible for the
    unidirectional flow of blood through the heart

11
  • Atrioventricular valves prevent backflow of blood
    from the ventricles into the atria
  • also called tricuspid valve (three flaps or
    cusps) and mitral (bicuspid two flaps or cusps)
    valve
  • Between right ventricle and pulmonary artery is a
    semilunar valve (three cusps) also called
    pulmonic valve
  • Between left ventricle and aorta are semilunar
    valve (prevents backflow of blood from aorta into
    the heart)

12
Blood flow through the heart
  • 1. blood flows into right atrium from superior
    and inferior vena cava
  • 2. blood travels from R atrium into R ventricle
  • 3. blood flows through pulmonary artery into the
    lungs (for oxygenation)
  • 4. blood returns from the lungs through the
    pulmonary veins, and is deposited into L atrium

13
  • 5. from L atrium, blood flows into L ventricle
  • 6. blood leaves L ventricle via aorta, enters
    general systemic circulation

14
Flow of electricity through the heart
  • Heart has intrinsic rhythmicity
  • 1. originates in SA (sino-atrial) node, superior,
    lateral aspect of R atrium
  • 2. travels through both atria to AV node
    (atrioventricular), this causes depolarization of
    atria

15
  • 3. from AV node, pause for 0.01 sec, flows
    through AV bundle (aka bundle of His), through R
    and L bundle branches (RBB, LBB)
  • this pause allows time for atrial contraction,
    pumping the last 20-25 of blood into ventricles

16
  • 4. from RBB and LBB, signal travels to the
    purkinje fibers in ventricles, which passes the
    current of depolarization to the ventricle muscle
  • ventricles have a powerful contraction, and
    provide the major impetus to move blood
    throughout the CV system

17
Action Potentials in cardiac muscle
  • resting membrane potential of normal cardiac
    muscle is -85 to -95 millivolts
  • specialized conductive fibers, purkinje, have a
    resting membrane potential of -90 to -100 mV
  • action potential (AP) has a magnitude of 105 mV

18
  • this rise is 20 mV greater than needed, called
    the overshoot potential
  • after depolarization, remains depolarized for 0.2
    sec in atrial muscle and 0.3 sec in ventricular
    muscle, which gives it the plateau
  • plateau is followed by abrupt repolarization
  • this plateau causes a contraction to last 3-15
    times longer than a skeletal muscle twitch

19
Differenced in cardiac and skeletal muscle
membranes
  • Action potential is caused by the opening of two
    types of channels a) fast sodium channels allow
    the sodium ions to enter the cell and b) slow
    calcium channel are slower to open and remain
    open longer (can be several tenths of a second
    sodium can also pass through these channels)

20
  • The permeability of cardiac muscle membrane to
    potassium decreases about 5X
  • This decreases the outflux of K during plateau,
    preventing early recovery
  • When Na and Ca channels close, influx stops,
    permeability for K increases rapidly
  • Rapid influx of K, membrane potential returns to
    resting
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