Download Figure 17.17 An electrocardiogram (ECG) tracing.

Figure 17.17 An electrocardiogram (ECG) tracing.
Sinoatrial
node
Atrioventricular
node
QRS complex
R
Ventricular
depolarization
Atrial
depolarization
Ventricular
repolarization
P
T
Q
P-R
Interval
0
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S
0.2
S-T
Segment
Q-T
Interval
0.4
Time (s)
0.6
0.8
Figure 18.6 Blood pressure in various blood vessels of the systemic circulation.
120
Systolic pressure
100
Mean pressure
80
60
40
Diastolic
pressure
20
0
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Figure 18.5 Relative proportion of blood volume throughout the cardiovascular system.
Pulmonary blood
vessels 12%
Systemic arteries
and arterioles 15%
Heart 8%
Capillaries 5%
Systemic veins
and venules 60%
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Figure 18.7 The muscular pump.
Venous valve (open)
Contracted skeletal
muscle
Venous valve
(closed)
Vein
Direction of blood flow
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Figure 18.9 Baroreceptor reflexes that help maintain blood pressure homeostasis. (1 of 2)
3
Impulses from baroreceptors
stimulate cardioinhibitory center (and
inhibit cardioacceleratory center) and
inhibit vasomotor center.
4a
Sympathetic
impulses to heart
cause HR,
contractility, and
CO.
2 Baroreceptors in
carotid sinuses and
aortic arch are
stimulated.
4b
Rate of vasomotor
impulses allows
vasodilation, causing R.
1
Stimulus:
Blood pressure (arterial
blood pres- sure rises
above normal range).
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5
CO and R return
blood pressure to
homeostatic range.
Figure 17.16 Autonomic innervation of the heart.
The vagus nerve
(parasympathetic)
decreases heart rate.
Dorsal motor nucleus
of vagus
Cardioinhibitory
center
Cardioacceleratory center
Medulla oblongata
Sympathetic
trunk
ganglion
Thoracic spinal cord
Sympathetic trunk
Sympathetic cardiac
nerves increase heart rate
and force of contraction.
AV
node
SA
node
© 2014 Pearson Education, Inc. Parasympathetic fibers
Sympathetic fibers
Interneurons
Figure 17.23 Norepinephrine increases heart contractility via a cyclic AMP secondmessenger system.
Norepinephrine
Adenylate cyclase
β1-Adrenergic
receptor
Ca2+
Ca2+
channel
G protein (Gs)
ATP is converted
to cAMP
Cytoplasm
a Phosphorylates plasma
membrane Ca2+
channels, increasing
extracellular Ca2+ entry
GDP
Inactive protein
kinase
Phosphorylates SR Ca2+ channels, increasing
intracellular Ca2+ release
Enhanced
actin-myosin
interaction
Extracellular fluid
Troponin
binds
to
SR Ca2+
channel
Cardiac muscle
force and velocity
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Active protein
kinase
b
c
Phosphorylates SR Ca2+ pumps, speeding
Ca2+ removal and relaxation, making more
Ca2+ available for release on the next beat
Ca2+
Ca2+
Ca2+ uptake pump
Sarcoplasmic
reticulum (SR)
Table 18.2 Effects of Selected Hormones on Blood Pressure
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Figure 18.18 Events and signs of hypovolemic shock.
Acute bleeding (or other events that reduce
blood volume) leads to:
1. Inadequate tissue perfusion
resulting in O2 and nutrients to cells
Initial stimulus
Physiological response
Signs and symptoms
Result
2. Anaerobic metabolism by cells, so lactic
acid accumulates
3. Movement of interstitial fluid into blood,
so tissues dehydrate
Chemoreceptors activated
(by in blood pH)
Major effect
Respiratory centers
activated
Baroreceptor firing reduced
(by blood volume and pressure)
Hypothalamus activated
(by blood pressure)
Brain
Minor effect
Cardioacceleratory and
vasomotor centers activated
Sympathetic nervous
system activated
ADH
released
Neurons
depressed
by pH
Intense vasoconstriction
(only heart and brain spared)
Heart rate
Central
nervous system
depressed
Kidneys
Renal blood flow
Adrenal
cortex
Renin released
Angiotensin II
produced in blood
Aldosterone
released
Rate and
depth of
breathing
Tachycardia;
weak, thready
pulse
CO2 blown
off; blood
pH rises
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Kidneys retain
salt and water
Skin becomes
cold, clammy,
and cyanotic
Blood pressure maintained;
if fluid volume continues to
decrease, BP ultimately
drops. BP is a late sign.
Water
retention
Urine output
Thirst
Restlessness
(early sign)
Coma
(late sign)
Figure 18.12 Body sites where the pulse is most easily palpated.
Superficial temporal artery
Facial artery
Common carotid artery
Brachial artery
Radial artery
Femoral artery
Popliteal artery
Posterior tibial
artery
Dorsalis pedis
artery
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Drug Classifications >> Hypertension >> Variable they Affect
Reduce Stroke Volume
Diuretics
Aldosterone receptor blockers
Angiotensin (ACE) inhibitors
Angiotensin II receptor blockers
Venodilators
Reduce Systemic Vascular Resistance
α1 blockers
Calcium channel blockers
Direct-acting arterial dilators
Decrease Heart Rate
β blockers
Figure 18.13 Distribution of blood flow at rest and during strenuous exercise.
750
750
Brain
750
Heart
250
Skeletal
muscles
Skin
12,500
1200
500
Kidneys
1100
Abdomen
1400
1900
Other
600
Total blood
flow at rest
5800 ml/min
600
600
400
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Total blood flow during
strenuous exercise
17,500 ml/min
Figure 18.17 Bulk fluid flow across capillary walls causes continuous mixing of fluid between the plasma and the interstitial fluid
compartments, and maintains the interstitial environment. (2 of 5)
The big picture
Fluid filters from capillaries at their arteriolar
end and flows through the interstitial space.
Most is reabsorbed at the venous end.
Arteriole
Fluid moves through
the interstitial space.
For all capillary beds,
20 L of fluid is filtered
out per day—almost
7times the total plasma
volume!
17 L of fluid per
day is reabsorbed
into the capillaries
at the venous end.
Venule
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About 3 L per day
of fluid (and any
leaked proteins) are
removed by the
lymphatic system
(see Chapter 20).
Lymphatic
capillary
Figure 18.16 Capillary transport mechanisms. (2 of 2)
Lumen
Caveolae
Pinocytotic
vesicles
Intercellular
cleft
Endothelial
fenestration
(pore)
Basement
membrane
1 Diffusion
through
membrane
(lipid-soluble
substances)
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2 Movement
through
intercellular
clefts (watersoluble
substances)
4 Transport
via vesicles
or caveolae
(large
substances)
3 Movement
through
fenestrations
(water-soluble
substances)
Figure 19.1a Distribution and special features of lymphatic capillaries.
Arterial system
Venous system
Heart
Lymphatic system:
Lymph duct
Lymph trunk
Lymph node
Collecting
lymphatic
vessels, with
valves
Blood
capillaries
Lymphatic
capillary
Tissue
fluid
Tissue cell
Blood
capillaries
Lymphatic
capillaries
Structural relationship between a capillary bed of the blood vascular system and
lymphatic capillaries.
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Figure 19.1b Distribution and special features of lymphatic capillaries.
Filaments anchored
to connective tissue
Endothelial cell
Flaplike minivalve
Fibroblast in loose
connective tissue
Lymphatic capillaries are blind-ended tubes in which
adjacent endothelial cells overlap each other,
forming flaplike minivalves.
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Figure 19.2a The lymphatic system.
Regional
lymph
nodes:
Internal
jugular vein
Entrance of
right lymphatic
duct into vein
Cervical
nodes
Entrance of
thoracic duct
into vein
Thoracic
duct
Axillary
nodes
Cisterna
chyli
Aorta
Collecting
lymphatic
vessels
Drained by the right lymphatic duct
Drained by the thoracic duct
Inguinal
nodes
General distribution of collecting lymphatic
vessels
and regional lymph nodes.
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Inc.
Figure 19.4a Lymph node.
Afferent
lymphatic
vessels
Cortex
• Lymphoid follicle
• Germinal center
• Subcapsular sinus
Efferent
lymphatic
vessels
Hilum
Medulla
• Medullary
cord
• Medullary
sinus
Trabeculae
Capsule
Longitudinal view of the internal structure of a lymph
node and associated lymphatics
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Figure 19.3 Reticular connective tissue in a human lymph node.
Macrophage
Reticular cells on
reticular fibers
Lymphocytes
Medullary sinus
Reticular fiber
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Figure 19.6c The spleen.
Diaphragm
Spleen
Adrenal
gland
Left
kidney
Splenic
artery
Pancreas
Photograph of the spleen in its normal position in
the abdominal cavity, anterior view.
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Figure 19.5 Lymphoid organs.
Tonsils (in pharyngeal
region)
Thymus (in thorax; most
active during youth)
Spleen (curves around
left side of stomach)
Peyer’s patches
(aggregated lymphoid
nodules in small
intestine)
Appendix
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