E109 Lecture 10 Fall 2024 PDF

Summary

This document is a lecture on cardiac muscle contraction, covering topics such as refractory periods, the role of calcium, and the action potentials in cardiac muscle cells. It features illustrations and diagrams.

Full Transcript

Lecture 9: Cardiac Muscle Contraction

Office hours: Nat Sci 2 4201 12-1PM. Come see exam keys
Refractory Period: Cardiac Muscle (End of Lecture 9)

a summation of
force
Cardiac Muscle Contraction: role of calcium
10 9 1 Action potential enters
3 Na+ Ca2+ from adjacent cell.
Ca2+ 2 K+

Iiiiii
ECF 1
ATP NCX Voltage-gated Ca2+
2
ICF channels open. Ca2+
3 Na+ enters cell.
Ca2+
RyR2
2+ 2+
2 3 Ca induces Ca release
through ryanodine
3 receptor-channels (RyR2).
SR L-type Sarcoplasmic reticulum
Ca2+ (SR)
Ca2+ channel 4 Local release causes
Ca2+ stores Ca2+ spark.
4
ATP 2+
5 Summed Ca2+ sparks
8 create a Ca signal.
Ca2+ sparks T-tubule
u 2+
6 Ca ions bind to troponin
5 to initiate contraction.

Ca2+ signal Ca2+ Ca2+ 7 Relaxation occurs when
Ca2+ unbinds from troponin.
6 7 7 Actin
2+
8 Ca is pumped back
into the sarcoplasmic
reticulum for storage.

2+
9 Ca is exchanged with
Na+ by the NCX antiporter.
Contraction Relaxation Myosin
9Metal
10 Na+ gradient is maintained
skeletalcontraction similar tocardiac
remayhff Yalation by the Na+-K+-ATPase.
Review

Contractile cells within the heart are connected through
intercalated disks that contain gap junctions and allow for
transmission of force and graded potentials between cells

Action potentials of cardiac contractile cells are long lasting with
the cell remaining depolarized for substantially longer period of
time

The long refractory period prevent summation of force

The contraction cycle within cardiac muscle has features that
resemble both skeletal and smooth muscle contraction
E109 Lecture 10: Electrical Conduction in the Heart
Lecture 10 Learning Objectives

Observe that autorhythmic cells undergo cyclical
depolarization setting the rhythm and pace of our heart

Learn that sutorhythmic cells are located at the SA node,
the AV and the Purkinje fibers

Understand that the fastest of the autorhythmic cells (SA
node) normally set the pace

Observe that ECGs allow us to detect pathologies that
affect heart rate, Heart rhythm, conductions blocks, or
coordination
Two Types of Cardiac Muscle Cells

Membrane potential
of autorhythmic cell

Membrane potential
of contractile cell
Autorhythmic
cells

depoiarYting
Contractile cells
reg r
ate
Yesaction
cau
potential

causesgraded
potential

spreadsamongcells

Intraction
Contractile Cells: resting potential is stable (true of other cells)

cells
Contractile
1 Resting potential
3 PNa
+20 2 Na+ channels open
4
PK PCa
Membrane Potential (mV)

0 3 Na+ inactivation gate
closes
-20 4 Ca2+ channels open
fast K+ channels close
-40 5
2 PK PCa
5 Ca2+ channels close
slow K+ channels open
-60 PNa

-80 1 1

-100

0 100 200 300
Time (ms)
Action potential: Autorhythmic Cells
Authorhythmic cells
20 4
1 If channels open Na+ enters cells

2 some Ca2+ channels open; If
0 channels close

3 3 Many Ca2+ channels open
larm causing rapid depolarization
–20 5
4 Ca2+ channels close; K+
channels open
irential
Threshold
–40 5 K+ moves out of the cell
2
acalciumchannels
getting us to
open

1
1 1
sonetnto
–60 ftp.yahoo
Pacemaker Action
Potential Potential
naturallydepolarizing
events
always restarts
potentialTime
04 Membrane
Electrical Conduction in the Heart: coordination of contraction
1 1 SA node depolarizes.
SA node

AV node
2 2 Electrical activity goes
rapidly to AV node via
internodal pathways.

3 Depolarization spreads
more slowly across
THE CONDUCTING SYSTEM atria. Conduction slows
through AV node.
OF THE HEART

4 Depolarization moves
SA node rapidly through ventricular
3 conducting system to the
Internodal apex of the heart.
pathways
5 Depolarization wave
spreads upward from
the apex.

AV node

AV bundle 4

Purkinje
fibers

5
Setting the Pace: synced-up with SA node, or out of sync
own
candepolarize ontheir

SA Node AV Node Purkinje
70 bpm 50 bpm 30 bpm Contractile Cells

wee
AV Node Purkinje
50 bpm 30 bpm Contractile Cel

Purkinje
30 bpm Contractile Cell
Electrocardiogram

Right arm Left arm

I

Electrodes are
attached to the
skin surface.

II III

Left leg
Electrocardiogram

ECGs can help assess:
Heart rate
Heart rhythm
Conduction blocks
Coordination (fibrillation)

Atrial Ventricular Ventricular
depolarization depolarization repolarization

SAnode avnode pjF
Heart rate
R 5 sec

P
T Normal ECG

R

P T Pathology

Terrat
Sinus tachycardia is a condition in which the sinoatrial
node fires and the electrical impulse travels through the
normal conduction pathway but the rate of impulse
firing is faster than 100 beats per minute.
Coordination (fibrilation)
R 5 sec

T Normal ECG
P

R

Pathology
T
P

disorganized

Atrial fibrillation: A condition that causes uncoordinated
contraction of the atria causing a disorganized contraction.
Conduction Block
R 5 sec

T Normal ECG
P

Pathology
P P P P P P

AV Conduction block: Signals from SA
node are blocked before reaching the AV
node causing the ventricle contractions to be
paced by the AV node or Purkinje fibers.
Review

Autorhythmic cells undergo cyclical depolarization setting
the rhythm and pace of our heart

Autorhythmic cells are located at the SA node, the AV and
the Purkinje fibers

Under normal conditions the fastest of the autorhythmic
cells (SA node) set the pace

ECGs allow us to detect pathologies that affect heart rate,
Heart rhythm, conductions blocks, or coordination
E109 Lecture 10: Control of Cardiac Output
Control of Cardiac Output

CO (mL/min) = SV(mL) x HR (BPM)
Autonomic Control: target the autorhythmic cells
Autonomic Control
makingchannels moresensitive notsensitive
Normal
20
Parasympathetic stimulation
ACH + permeability causing
0 hyperpolarization

2+permeability slows the
–60 rate of depolarization
Hyperpolarized Slower depolarization

0.8 1.6 2.4
Time (sec)

Normal Sympathetic stimulation norepinephrine
20
If channels open earlier and
stay open longer
0 + permeability)

–20

–40
2+ permeability increases
–60 the rate of depolarization
Depolarized More rapid depolarization

0.8 1.6 2.4
Time (sec)
raising wherefunnychannelsopen
Control of Cardiac Output

muscles

nervoussystem

pressure
increasing
bloodreturnsfaster
Intrinsic Control: Frank-Starling Mechanism
Control of Cardiac Output
Extrinsic Control of Stroke Volume

Ca2+
ECF 1

ICF

RyR2

2
3
SR L-type
Ca2+
Ca2+ channel
4

Ca2+ sparks T-tubule

5

Ca2+ signal

6

Contraction
Review

Cardiac output (volume of blood expelled from the heart
per minute) is determined by the product of Stroke volume
(mL) and Heart rate (BPM)

Heart rate is controlled through antagonistic branches of
the autonomic nervous system

The autonomic nervous system alters the membrane
potential and rate of depolarization in autorhythmic cells

Stroke volume is regulated by intrinsic properties of
contractile cells and modulated by the sympathetic branch