Cardiovascular System - Chapter 13 PDF

Summary

This chapter details the cardiovascular system, including blood, the heart, and blood vessels. It explains the circulation of blood, the function of different components, and various related processes like blood flow. Also included is information about heart valves, the cardiac cycle, and the lymphatic system.

Full Transcript

Chapter 13

Cardiovascular System
 Cardiovascular System

Cardiovascular System Consists of:
Blood
– Transport medium (cells suspended in fluid)
Heart
– Pump – drives circulation of blood

Blood vessels
– Tubing that conducts blood through circulation
 Blood
Represents about 8% of total body weight
Average blood volume=
Consists of:
1. Erythrocytes
Red blood cells
2. Leukocytes
White blood cells
3. Platelets
Cell fragments
4. Plasma=liquid portion of blood
Comprised of:
– Proteins -Hormones
– Nutrients -Electrolytes
 Plasma
55% of whole blood

Buffy coat: Platelets
platelets and
Leukocytes
leukocytes
(white blood cells)
Packed cell
volume, or Erythrocytes
Erythrocytes
hematocrit (red blood
(45% of whole
cells)
Blood)
 Plasma
Consists of:
Water (90%)
– dissolves materials (gases, nutrients, etc.)
– acts as fluid for transport
Proteins (7-9%)
– Maintain osmotic pressure of blood
albumins
– Lipid transport
– Immunity
Antibodies
– Clotting factors
– Various enzymes
 Formed Elements
Erythrocytes
– Red Blood Cells
Leukocytes
– White Blood Cells Fig 10.2
Thrombocytes
– Platelets
 Erythrocytes
Red blood cells (RBCs)
Contain hemoglobin
– Function?
No nucleus, organelles
Structure
– Biconcave discs
Provides larger surface area for diffusion
of O2
– Flexible membrane
Allows RBCs to travel through narrow
capillaries without rupturing in the
process
 Erythropoiesis
Erythrocyte production
RBCs survive about 120 days
– Spleen removes most of old erythrocytes
– Must be replaced at rate of 2-3 million cells/second
Erythropoiesis occurs in bone marrow
– Hematopoietic stem cells (HSC)
– Multipotent
 Erythropoiesis
Role of Erythropoeitin (EPO)
Figure 13.5
 Anemia
Refers to a below-normal O2-carrying capacity
of the blood
Causes of anemia
– Dietary deficiencies
– Blood Loss
– Bone marrow failure
– Hemolytic anemia
 Platelets
Thrombocytes
Colorless cell fragments
– Lack nuclei
– Have organelles
Come from Megakarocyte cell
Function in hemostasis
Thrombopoietin
– Hormone produced by liver increases number of
megakaryocytes and therefore increases platelet
production
 Hemostasis
Hemostasis=
– Prevents blood loss from a broken blood vessel
Involves 3 major steps
1.Vascular spasm
Reduces blood flow through a damaged vessel
2.Formation of a platelet plug
Platelets aggregate on contact with exposed collagen in
damaged wall of the vessel
Platelets release ADP which causes surface of nearby
circulating platelets to become sticky
3.Blood coagulation (clotting)
Coagulation proteins in blood
 Platelets
At rest inhibited-why?àprostacyclin, nitric oxide
Function
– Formation of platelet plug
– Activate clotting factors
 Clot Formation
Reinforces platelet plug by
formation of clot
Clotting factors are always
present in blood plasma in
inactive precursor form
– Vessel damage that exposes
collagen initiates cascade of
reactions that involve
successive activation of
clotting factors
Convert fibrinogen à fibrin
 Blood Clot Formation
Two pathways-Need both
– Intrinsic pathway
Activated by exposed collagen
– Extrinsic pathway
Released from damaged tissue
Final Outcome
– Fibrinogen (soluble) ® fibrin (insoluble)
 Leukocytes
White blood cells or WBCs
Mobile units of body’s immune defense system
Immune system
– Recognizes and destroys or neutralizes materials
within body that are foreign to “normal self”
– Functions
Defends against invading pathogens
Identifies and destroys cancer cells that arise in body
Functions as a “cleanup crew” that removes worn-out
cells and tissue debris
 Structure of the Heart
Hollow, muscular organ
Located in thoracic
cavity
4 chambers
– 2 Atria Fig 10.7
– 2 Ventricles
Pumps constantly
– variable rate
Two Circuits
– Pulmonary
– Systemic
 Heart Valves
Two sets of valves
1. Atrioventricular (AV) valves
2. Semilunar valves
Purpose
Sounds
 Blood Flow Through the Heart

Deoxygenated blood enters
right side through vena cavae
→right atrium
→right AV valve
→right ventricle
→pulmonary semilunar valve
→pulmonary trunk and arteries
→lungs (pulmonary circuit)
 Blood Flow Through the Heart

Oxygenated blood enters
left side through pulmonary
veins
→left atrium
→left AV valve
→left ventricle
→aortic semilunar valve
→aorta
→tissues (systemic circuit)
 Cardiac Cycle
Cardiac Cycle consists of 2
parts
– Systole
– Diastole
 Cardiac Cycle
Sequence of events
– Systole
1. Isovolumetric contraction
– Ventricles contract, but no blood
ejected
– Blood pressure rises above
pressure in atria
– Atrioventricular valves shut
2. Ejection
– Blood pressure in ventricle
exceeds pressure in arteries
– Blood flows out of ventricles,
causing pressure in ventricles to
fall
 Cardiac Cycle

Sequence of Events
– Diastole
1. Isovolumetric Relaxation
– Pressure in ventricles drops
below arterial pressure
– Semilunar valves prevent
backflow of blood Fig 10.10
– No change in ventricular volume
2. Rapid filling
– Pressure in ventricles falls below
atrial pressure
– AV valves open, allowing blood
to flow into ventricles
3. Atrial contraction
 Electrical Activity of Heart
Heart beats via autorhythmicity
Two specialized types of cardiac muscle cells
1. Autorhythmic cells
Do not contract
Initiate AP's and spread impulse throughout heart
2. Contractile cells
99% of cardiac muscle cells
Do mechanical work of pumping
Normally do not initiate own action potentials
 Electrical Activity of Heart
Heart beats via autorhythmicity
Two specialized types of cardiac muscle cells
1. Autorhythmic cells
Do not contract
Initiate AP's and spread impulse throughout heart
2. Contractile cells
99% of cardiac muscle cells
Do mechanical work of pumping
Normally do not initiate own action potentials
 Electrical Activity of Heart
Sequence
– SA node
Action potential spreads
throughout right and left atria
– AV node
Conduction Delay
Why?
– Bundle of His
– Purkinje fibers
– Spread to non-conducting
ventricular cells through gap
junctions
 Electrical Activity of Heart:
Pacemaker Potential
Mechanism of Autorhymicity SA node
– Membrane permeability
changes with AP
Potassium
– Sodium
Calcium
– Pacemaker Potential
HCN channels
Funny Channels
Open when membrane
potential hyperpolarizes
– Depolarization due to Ca2+ Inherent rate~100
(not Na+) depolarizations/min
 Electrical Activity of Heart:
Myocardial Cells
Electrical Activity of
Contractile Cells
Action Potential
– Depolarization
– Plateau
– Repolarization
 Excitation-Contraction Coupling in
Cardiac Muscle
Components of
both skeletal and
smooth muscle
Gap Junctions
located in
intercalated discs
 Electrical Activity of Heart
Refractory Periods in Heart
Why important?
ECG Tracing
 Electrocardiogram (ECG)
Record of overall spread of electrical activity through
heart
Represents
– Recording electrical activity of cardiac impulse that
reaches body surface
Not a direct recording of a single action potential in a
single cell at a single point in time
Uses?
Figure 13.33b
 Coronary Circulation
Muscle is supplied with oxygen and nutrients by
blood delivered to it by coronary circulation,
not from blood within heart chambers
Coronary vessels=provide blood supply to heart
during diastole
– During systole, coronary vessels are compressed by
contracting heart muscle
Coronary blood flow normally varies to keep
pace with cardiac oxygen needs
 Cardiovascular System

Consists of
– Heart
– Blood
– Blood Vessels
 Vascular Tree
Closed system of vessels
– Pulmonary and Systemic Circuit
Consists of
– Arteries
– Arterioles
– Capillaries
– Venules
– Veins
 Blood Vessels
Both arteries and veins have similar layers
– Tunica Externa
– Tunica Media
– Tunica Interna
Differences
 Arteries
Take blood away from
heart
Function
– Low resistance elastic
conduits
Due to large radius,
arteries offer little
resistance to blood
flow
– Pressure Reservoir
Act as pressure reservoir
to provide driving force
for blood when heart is
relaxing
 Arterioles

Function
– Distribute cardiac output
among systemic organs,
depending on needs
Vasoconstriction
Vasodilation
– Control by intrinsic and
extrinsic factors
 Constant pressure in pipe
(mean arterial pressure)
From pump
(heart)

High Moderate Low
resistance resistance resistance

No flow Moderate flow Large flow
KEY
Control valves = Arterioles
 Capillaries
Structure
– Thin-walled, extensively
branched
Maximized surface area and
minimized diffusion
distance
– Pre-capillary sphincters
Function
– Sites of exchange between
blood and surrounding
cells
Only Tunica Intima
 Types of Capillaries
Continuous
Fenestrated
Discontinuous
 Veins
Function=
– Return blood to heart
– Blood reservoir
Structure
– Large radius offers little
resistance to blood flow
– Low Pressure System
– Valves
 Veins
Problem with gravity
 Veins
Factors which enhance venous return
– Driving pressure from cardiac contraction
– Sympathetically induced venous vasoconstriction
– Skeletal muscle activity
– Effect of venous valves
 Venous Return

Venous Valves
– prevent backflow of
blood
Skeletal Muscle
Activity Fig 10.27
– contraction acts to
“pump” veins
– increases venous
return with increased
activity
 Coronary Artery Disease (CAD)

Leading cause of death in
United States
Pathophysiology
– Atherosclerosis
Risk Factors
 Lymphatic System
Carries Lymph
– Where does lymph come
from?
Functions of lymphatic:
1. Aids immune system
2. Removal of interstitial
fluid and return uni-
directionally to heart
3. Absorbs and transports
fatty acids
 Importance of Lymphatic System
Lack of function leads to edema
Extreme example=Elephantiasis
 For the Exam you Should be Able to:
Define the components of the cardiovascular system
Describe the components of blood
Identify the formed elements of blood
Describe the composition and function of plasma
Describe a RBC
Describe the regulation of red blood cell production
Explain hemostasis and the role of platelets and coagulation
proteins
Differentiate between extrinsic pathway of coagulation and intrinsic
pathway of coagulation
 For the Exam you Should be Able to:
Describe the structure of the heart, including valves, and blood flow
through the heart
Explain how valves open and close
Distinguish between the systemic and the pulmonary circulation.
Compare the two types of heart cells, including the electrical
activity in each
Describe the cardiac cycle in terms of systole and diastole
Explain how the pressure differences within the heart chambers are
responsible for blood flow during the cardiac cycle.
Describe excitation-contraction coupling in heart muscle
 For the Exam you Should be Able to:
Describe the conduction system of the heart
Explain an ECG, including the various waves, and uses
Compare the structure and function of arteries, veins, and
capillaries
Explain the refractory period of the heart, and it’s importance
Describe factors that contribute to venous return against gravity
Define vasoconstriction and vasodilation
Describe the three types of capillaries
Explain the causes and risk factors of atherosclerosis.
Explain how the lymph and lymphatic system relate to the blood
and cardiovascular system.
 For the Exam you Should be Able to:
Compare the structure and function of arteries, arterioles,
capillaries, and veins
Describe the relationship between interstitial fluid, plasma, and
lymph.
Describe factors that contribute to venous return against gravity
Define vasoconstriction and vasodilation
Describe the three types of capillaries
Explain the causes and risk factors of atherosclerosis.
Explain how the lymph and lymphatic system relate to the blood
and cardiovascular system.
Describe the function of the lymphatic system.