Transcript Biology 20
Biology 20
Circulation
Blood
Lymphatic System
Immunity
The Importance of the
Circulatory System
96
000 km of blood vessels
60
trillion cells in body
no
cell is more than 2 cells away from a
blood vessel
2
3
Functions of the Circulatory
System
3 main functions:
1) transports gasses, food, wastes, and hormones
2) carries molecules and cells that help defend against
invading organisms
3) distributes heat throughout the body
4
Blood Vessels
Arteries
carry blood away from heart
elastic
stretch to accommodate blood surge from heart
• pulse
thick walls to allow for stretch
high blood pressure
5
Blood Vessels
Arterioles
small arteries
• arteries branch into many arterioles
connects to capillary
contains smooth muscle which can
contract or relax according to nervous
impulses
sympathetic nerve impulses affect
diameter of arterioles:
• Vasodilatation -- open
• Vasoconstriction -- close
6
Blood Vessels
Capillaries
links arterioles to venules
site of exchange of nutrients and wastes
between blood and interstitial fluid
• I.F. is the fluid that surrounds and bathes body
cells
smallest blood vessels
single layer of cells
big enough for only 1 RBC to pass through
at a time
easily crushed = bruise
7
RBC in a capillary
8
Blood Vessels
Venules
small veins
smooth muscle
large end of capillaries
9
Blood Vessels
Veins
carry blood towards the heart
larger diameter than arteries
lower pressure than arteries
• (2 mmHg compared to 100 mmHg in arteries)
pull of gravity
PROBLEM!!
What forces the blood through a vein?
blood pressure is not high enough to “suck”
blood back to the heart
10
11
Blood Vessels
Solution!!
Veins have one-way valves
• only allow blood to move in one direction
skeletal muscles help veins in getting blood to the
heart -- squeeze veins
wall is not as thick as arteries because blood
pressure is lower – no surge of blood flow
12
One Way Valves
13
Arteries, Veins, Capillaries
14
Arteries, Veins, Capillaries
15
Major Vessels of the Body
Superior Vena Cava
Inferior Vena Cava
Artery from right ventricle to lungs
Pulmonary Veins (4)
Vein to heart from lower body
Pulmonary Artery
vein to heart from upper body
Veins from lungs to left atrium
Aorta
Artery from left ventricle to body
16
Major Vessels
17
The Heart
Structure
roughly in center of chest in thoracic cavity
protective membrane
• pericardium forms a fluid filled sac to reduce friction
size of fist
two separate pumps
• right and left
sides are separated by a septum which
prevents mixing of oxygenated and
deoxygenated blood
18
19
20
21
22
The Heart
Label
the diagram of the heart.
Identify the following structures
(next slide)
Outline the direction of flow of blood through
the heart
• Differentiate between oxygenated blood and
deoxygenated blood by using red and blue
arrows on diagram
List the general function of each structure.
23
The Heart
Right Atrium
Superior Vena Cava
Inferior Vena Cava
Right AV Valve
(Tricuspid)
Right Ventricle
Pulmonary Artery
Pulmonary Valve
Pulmonary Vein
Left Atrium
Left AV Valve (Bicuspid)
Left Ventricle
Aorta
Aortic Valve
Coronary Arteries
Interventricular Septum
Chordae Tendinae
24
25
26
27
The Heart’s Structures
Atria
Structure
• thin walled chamber
Function
• right atria - collect deoxygenated blood from body
and head, and pass to ventricles.
• left atria - oxygenated blood from the lungs, and
pass it to ventricles.
28
The Heart’s Structures
Ventricles
Structure
• thick muscular walls
• larger than atria
• one side is thicker than the other
Function
• right ventricle pumps deoxygenated blood to lungs
• left ventricle pumps oxygenated blood to body
29
The Heart’s Structures
Interventricular
septum
Wall of muscle that separates the right atrium
and ventricle from the left atrium and
ventricle.
30
The Heart’s Structures
Superior Vena Cava
Inferior Vena Cava
Vein to right ventricle of the heart from upper body
Carries deoxygenated blood
Vein to right ventricle of the heart from lower body
Carries deoxygenated blood
Aorta
Artery through which the left ventricle pumps blood to
the body
Carries oxygenated blood
31
The Heart’s Structures
Pulmonary Artery
Pulmonary trunk – split into left and right arteries
Artery from right ventricle carries deoxygenated blood
to lungs
Right pulmonary artery goes to right lung
Left pulmonary artery goes to the left lung.
Pulmonary Veins (4)
Veins from lungs carry oxygenated blood to left atrium
Right pulmonary vein from right lung
Left pulmonary vein from left lung
32
The Heart’s Structures
Atrioventricular valves (AV Valves)
The right AV valve is called the tricuspid valve
and the left AV valve is called the mitral valve
Structure
• flaps of tissue between atria and ventricles
• attached to heart muscle by cords
chordae tendinae
cords prevent flaps from inverting
Function
• Separate atria from ventricles
• prevents back flow of blood from ventricles into atria
33
The Heart’s Structures
Pulmonary valve
Aortic valve
Allows deoxygenated blood from right ventricle into
pulmonary artery, but does not allow it to flow back
into the ventricle.
Allows oxygenated blood to flow from the left ventricle
to the aorta, but not to return back to the ventricle.
Structure
Thin flap, half-moon shaped
34
The Heart’s Structures
35
Three Circulatory Systems
1) Pulmonary Circulation
From the heart to the lungs
and back to the heart
2) Coronary Circulation
From the heart chambers to
the heart muscles and back
to the heart chambers
system of arteries, capillaries
and veins within heart
3) Systemic Circulation
From heart to all other parts
of the body and back to the
heart.
36
Systemic Circulation
Involves 2 smaller systems
Renal Circulation
• To the kidneys
Hepatic Circulation
• From the digestive tract, through liver, then to heart
Important vessels
Carotid Arteries and Jugular Veins
• head
Brachial Artery and Brachial Vein
• arms
Femoral artery and Femoral Vein
• legs
37
Biology 20
Heart Beat
Heart Sounds
Heart Rate
Blood Pressure
Initiating the Heart Beat
Cardiac
muscle contracts without external
nervous stimulation
Sino-Atrial Node (SA Node)
Pacemaker
Coordinates contractions
Special muscle and nerves located in the right
atrium
70 beats/minute
39
40
Initiating the Heart Beat
The SA node sends nerve impulses:
across atria
• contract now!!
To second node
• AV node
• Atrial-ventricular node
41
42
Initiating the Heart Beat
AV
node
mass of nerve tissue in septum
passes nerve impulse through septum
to the bottom of ventricles
Impulse conducted upwards through
nerves in the ventricles
Contraction of ventricles begins
• Contraction begins at apex
Bottom to top contraction
Result…
Atria contract followed by the ventricles.
43
Heart Beat Video
44
Setting the Heart’s Rate
Autonomic
Nervous System in charge!
Sympathetic nerves
• stimulated during times of stress
• Increases heart rate
Parasympathetic nerves
• stimulated during times of non-stress
• returns heart to slow rate
45
Setting the Heart’s Rate
Problem:
SA node malfunction
Ventricular fibrillation
• disorganized and random contraction of heart cells
• no longer pumps blood
death
Solution:
• First -- Electro shock to halt the “short circuit”
• Then -- installation of an artificial pacemaker
46
Electrocardiogram
Electrodes are placed on the body surface
Connected to a recording device
Electrical impulses from heart are displayed
on a screen.
P wave
• atrial contraction
QRS wave
• ventricular contraction
Used to diagnose heart problems
more evident during heavy exercise
Doctors identify dead patches of heart muscle
which will not conduct impulses.
47
48
Cardiac Cycle
One
heart beat
Systole
• ventricles contract
Diastole
• ventricles relax
70
- 75 beats/min
two sides of heart beat in unison
first the atria then the ventricles
49
50
Stages of the Cardiac Cycle
1)
Heart relaxed -- atria filling
Right Atrium
• blood from Superior & Inferior Vena Cava
Left Atrium
• blood returning from lungs via 4 pulmonary
veins
2)
Atria Contract
Ventricular diastole
• Ventricles fill up
blood pushed from atria into ventricles
past the AV valves
51
52
Stages of the Cardiac Cycle
3) Ventricles Contract
ventricular systole
• AV valves close
• Semilunar valves open
Right ventricle
• blood through pulmonary artery to lungs
Left Ventricle
• blood through aorta to rest of body
53
54
Heart Sounds
“lubb
dubb”
Systole (lubb)
longest and loudest
ventricles contract
caused by AV valves closing
Diastole
(dubb)
caused by semilunar valves closing
ventricles relaxing
55
56
Blood Pressure
Measures
amount of pressure in artery
Two parts (120/80)
Systolic pressure
• high number (120)
• pressure in artery when ventricles contract
Diastolic pressure
• low number (80)
• pressure in artery when ventricles relax
• Most important in diagnosis of heart health.
Measured
using a sphygmomanometer!!
57
Steps in finding Blood
Pressure
1) Inflate cuff beyond normal pressure
• this squeezes the artery closed
2) Leak, Look and Listen
• release pressure slowly
• listen to stethoscope for thump
blood forcing its way through the cuff
• read the number on the dial at that point
• this is systolic pressure
3) Wait and Listen
• When thumping stops, blood is moving
unrestricted
• this is diastolic pressure
58
Problems / Diseases
Hypertension
high blood pressure
140/90
can lead to heart attack, stroke, kidney
damage
Caused
by:
high blood volume
• water, salt,
constriction of blood vessels
• tumor on adrenal medulla causing
increased epinephrine
59
Problems / Diseases
Hypotension
low blood pressure
often associated with bleeding
• external or internal
body compensates by
• increasing cardiac output
• increasing peripheral resistances
arteriolar constriction
60
Regulation of Blood Pressure
Negative
Feedback Loop
Monitor:
Baroreceptors
• in walls of aorta and carotid arteries
• measures blood pressure
Control
Center:
Medulla Oblongata
• Blood pressure regulator in the brain stem
61
Regulation of Blood Pressure
Regulators:
Sympathetic Nerve Stimulation
• arterioles constrict
• cardiac output increases
stroke volume & stroke rate
• increases blood pressure
Parasympathetic Nerve Stimulation
• arterioles dilate
• decreased cardiac output
• decrease blood pressure
62
Regulation of Blood Pressure
Example:
M. Oblongata processes info from
baroreceptors
BLOOD PRESSURE TOO HIGH
• decrease sympathetic nerve stimulation
• increase parasympathetic nerve stimulation
sends message to slow heart rate and dilate
arterioles
BLOOD PRESSURE TOO LOW
• decrease parasympathetic nerve stimulation
• increase sympathetic nerve stimulation
increase heart rate
constricts blood flow
63
Biology 20
Blood & Immunity
Blood Functions
1.To carry partially digested food material from
the small intestine and oxygen from lungs.
2. To transport the waste products of
metabolism from the cells to the kidneys,
lungs and skin for elimination from the body.
3. To carry hormones from the endocrine
glands to the cells they control.
4. To control the amount of water and the level
of acidity inside cells.
65
Blood Functions
5. to provide antibodies and white blood
cells that protect against infection.
6. to provide substances that will clot blood
if blood vessels are damaged.
7. to carry enzymes throughout the body.
8. to distribute heat produced during cell
metabolism.
66
Blood Composition
blood is a liquid tissue composed of cells,
cell fragments and a watery medium called
plasma.
an adult male has 5-6 L of blood and an
adult female has 4-5 L of blood.
67
Plasma
55% of blood volume
straw coloured liquid consisting of:
•
•
•
•
90% water
7% proteins (albumin, globulin, fibrinogen)
1% ions (Na+, K+, Cl-, Ca2+)
2% other substances (glucose, fats, amino acids, gases,
urea, hormones, etc.)
if blood is allowed to clot outside the body and the
clotted portion is removed, the fluid portion left is
called serum.
Serum, therefore, consists of plasma from which
the clotting proteins have been removed.
68
Erythrocytes
major function is to transport oxygen
average male has - 5.2 million RBC's/mL blood
average female - 4.7 million RBC's/mL of blood
• low, due to menstruation
bioconcave discs containing hemoglobin
• iron containing protein pigments used in O2 and CO2
transportation.
amongst the most highly specialized of all cells:
• at maturity the nucleus and mitochondria disappear
and other cell structures dissolve
• provides room for 300 million hemoglobin
molecules/RBC.
life span of a RBC is approximately 120-130
days.
69
Erythrocytes
old RBC have fragile cell membranes and are often
ruptured when passing through the spleen.
the hemoglobin released from RBC's is removed from
blood mainly by the liver
iron released into blood, other component called
bilirubin is secreted in bile
• reason why feces is brown
70
Anemia
a deficiency of RBC's caused by either too rapid a
loss or too slow production.
may be caused by blood loss, insufficient vitamin B12
or iron in diet, damage to bone marrow etc.
any condition that causes decreased oxygen being
transported to the tissue will increase the rate of
RBC's production
• e.g. blood loss, high altitude
71
Leucocytes
combat infectious and toxic agents
average adult has 7000 WBC's/mm3 of blood
there are 5 kinds of leucocytes:
1) neutrophils
2) eosinophils
3) basophils
4) monocytes
5) lymphocytes
leucocytes function in 2 ways:
1) by destroying mutating agents by the process of
phagocytosis (#1,2,3,4)
2) by forming antibodies (#5)
72
Leucocytes
lymphocytes are produced in the lymph glands
(lymphnodes)
•
spleen
•
thymus
•
tonsils
Lymph nodes are spongy tissue with 2 functions:
1)
remove foreign particles from lymph fluid before it
returns to general circulation
2)
produce lymphocytes (10 billion/day)
73
Blood Formation
most blood cells are formed in soft centre portion of
marrow of long bones - sternum, ribs, vertebrae
special stem cells in marrow are parent cells of both
red and white cells
• early in development RBC's lose their nuclei and
Mt.
• hemoglobin protein is added as they reach
maturity
(2 000 000 per second)
RBC's increase in number during periods of
strenuous exercise, emotional stress, at high altitudes
or high temp’s.
WBC are produced in lymphoid tissue of the body as
well and are produced in great quantities in times of
infection and disease fighting
platelets are also produced in marrow from tiny
pieces of cytoplasm that break off from the stem cells
74
Blood Groups
How Many?
Four
blood types:
A, B, AB, O
Determined
by a marker on the cells
Antigen
• Stimulates formation of antibodies
• Antigen A = blood type A
Antibody
in plasma must be opposite
76
Antibodies
Wrong bloodtype?
Produced in response to an invader
Attach to antigens --- clumping
Blood will clump
blockages
Agglutination - refers to the clumping of blood cells
caused by antigens (protein markers on cells) and
antibodies (proteins produced by B-lymphocytes in
response to a foreign antigen).
77
78
Blood Types
OK
OK
OK
OK
Bad
OK
Bad
OK
Bad
Bad
OK
OK
Bad
Bad
Bad
OK
79
AB
Both antigens
Universal acceptor
Only donate to AB
O
Universal donor
No antigens on surface
Will not bind to antibodies
Only accept O
80
Rh
Rh-factor
The
Rhesus factor is another type of blood
group.
People either have the antigen (Rh+) or do
not have it (Rh-).
Erythroblastosis fetalis
Another antigen on RBC’s
82
Rhesus Factor
If
If
present – Rh+
~ 85% of people
absent – Rh~15% of people
No
natural antibodies for Rh
Can be produced
83
Rh and pregnancy
Rh
mother, Rh+ father
Baby can be Rh+
First
child – no problem
No mixing
During birth, blood will mix
Mother’s immune system creates Rh+
antibodies
No harm to baby
84
Second
child
If child is Rh+ = problem
Mother has Rh+ antibodies
If they enter baby, blood will clump
Reduced O2 delivery
“blue baby”
Solution – transfuse baby w/ Rh- blood
85
86
What is the most common blood type?
0
Rh-positive
38 percent
0
Rh-negative
7 percent
A
Rh-positive
34 percent
A
Rh-negative
6 percent
B
Rh-positive
9 percent
B
Rh-negative
2 percent
AB
Rh-positive
3 percent
AB
Rh-negative
1 percent
87
Blood Type review
A
really detailed video
the genetics information at the end will be
studied in Bio 30
Clear
written explanation
Fun game…if you’re alone turn the sound
on
88
Blood Clotting
Healing Wounds Video
Platelets
Small
Fragile
Contain
specialized proteins
Initiate clotting
Join with calcium in plasma
First step in clotting
90
Blood Clotting
Clotting involves up to fifteen different substances, but
can be summarized into three stages.
Release of thromboplastin from the platelets or
cells surrounding the injury
The conversion of prothrombin into an enzyme
called thrombin. Thromboplastin, calcium ions,
and several other substances activate this stage.
The conversion of fibrinogen into threads of fibrin.
Fibrin threads trap blood cells and forms a clot.
91
+ Ca 2+
92
Blood Clotting
After clot forms, fibrin threads contract.
This further closes the blood vessel.
After the vessel has been repaired, the
enzyme plasmin dissolves the fibrin clot.
Clotting in an unbroken vessel is called
thrombosis, and is the most frequent
cause of heart attack and stroke.
93
Needs
Calcium
94
95
Fibrin Threads
96
DISEASES OF THE BLOOD
1. ANEMIA
• deficiency of red blood corpuscles by either too
rapid a loss or too slow a production
Symptoms:
• lack of energy
• catch other illnesses easily
• sickle cell anemia
97
DISEASES OF THE BLOOD
2. LEUKEMIA
• cancerous
organs
disease
of
blood-forming
• increase in immature white blood cells
• decrease in red blood cells and platelets
• decreases immunity and O2 capacity
98
DISEASES OF THE BLOOD
3. MONONUCLEOSIS
• “kissing disease”
• Viral disease
• increase in white blood cells production
monocytes
4. HEMOPHILIA
• Body is missing Clotting Factor IV
• Prevents normal clotting of blood
99
Lymphatic System
You don’t need to know a lot
about it, just its main function.
Lymphatic System
lymph the fluid found in lymph vessels that contains
some proteins that have leaked through capillary
walls
A system to return extracellular fluid to circulatory
system
Much like the circulatory system
Leakage from capillaries
Intertwined
Lymph vessels
lymph capillaries are endings which are permeable to all
interstitial fluid
Fluid moves through lymph vessels by skeletal
muscle contractions
No backflow due to one way system of valves
101
102
Some fluid seeps
through cap wall &
is called lymph
This fluid is
returned to the
blood via the
lymphatic
system
103
Lymph nodes
mostly in head, neck, armpit, abdomen, and groin
Before lymph is returned to the blood it passes
through lymph nodes
Nodes contain white blood cells
They filter lymph for invaders
Will destroy foreign particles
Lymph is returned to the circulatory system
through ducts
104
105
Structure of the Lymphatic System
Ducts
• the vessels converge into the great
thoracic duct (GTD) or right lymphatic
duct (RLD)
• the GTD collects lymph from legs, left arm
and left side of head
empties into venuous system at the junction of
the left jugular and subclavian veins
• the RLD drains right arm, right side of head
and trunk
106
Lymphatic
System
107
Functions of the Lymphatic
System
a. Return of Excess filtered fluid
• fluid filtered minus fluid absorbed = too much
left over at cell site.
• Extra fluid returned to blood to prevent edema
(collection of fluid in the interstitial tissues)
b. Return of protein to the blood
• capillaries slightly permeable to protein
• leaked protein must be returned to blood by
lymphatic
• purpose to maintain the protein concentration
difference between the plasma and the
interstitial fluid to prevent large movement of
fluid out of blood
108
Functions of the Lymphatic System
c. Specific transport functions
i.e. transports fat from the G.I. tract
other possibilities
• high molecular weight hormones reach the circulatory system
via the lymphatic system
109
Lymphoid
Organs
Spleen a lymphoid organ that acts as a
reservoir for blood and a filtering site for
lymph
thymus gland a lymphoid organ in which T
lymphocytes mature
110
Immune Response
Immunity
The
immune system is designed to
respond to foreign cells, particles or virus
that are not supposed to be present within
the body.
Of crucial importance is the body’s ability
to correctly distinguish “self” from “nonself”.
112
The Immune Response
WBC are involved in the Immune Response
the bodies first line of defence is the skin and
mucus membranes that prevent foreign substances
from entering
the second line of defence is the "inflammatory
response"
• histamines from injured cells triggers increased
permeability of capillaries in area, thus more WBC
can enter area
• the area becomes walled off and phagocytes invade
the area and rid the tissue of infectious or toxic
agents
• results in inflammation
when phagocytic leucocytes engulf a large
amount of bacteria and damaged tissue, they
die, resulting in pus formation (an accumulation
of damaged/dead tissue, and dead leucocytes). 113
Sick.
Immune Response
The third line of defence is antibody
formation (immune response)
• Highly specific (like enzyme-substrate specifically)
• Lymphocytes produce globular proteins known as
antibodies in response to an antigen (foreign
protein, virus or bacteria)
Antibodies protect the body against invading
agents by:
1) coat antigen so that phagocytic WBC's can ingest
it (yummy)
2) combine with it to inactivate it
3) work with another blood component called a
"complement" to lyse and destroy the infected cells
115
Immune Response
after the first bout of infection the
circulatory antibodies disappear, but
memory cells are now "sensitized" and if
particle returns they trigger quick
antibody production
other cells involved:
• T-lymphocytes (T-cells)
mainly responsible for tissue transplant
rejection
• B-lymphocytes (B-cells)
produce antibodies that circulate in blood
and lymph
• "T-helper cells”
secrete substances which activate B-cells
to produce antibodies
116
Macrophage
Macrophage
Surrounds and
destroys damaged
cells, proteins, and
pathogens
118
Helper T Cells
Helper
T Cells
Helps identify invaders
119
B Cell
B
Cell
Makes and releases
antibodies and
memory cells
120
Memory Cell
Memory
Cell
Stores information
about invaders
121
Antibody
Antibody
Attaches to and
destroys invaders
122
Pathogen
Can be bacteria,
protist, fungi, or virus
“invaders” or any thing
foreign
Antigens
Specific shape
Attaches to pathogens
123
Pathogen
enters body
(wound, infection, etc)
124
Macrophage
surrounds and
destroys the pathogen
125
Antigens
from dead
bacteria protrude from
macrophage
Helper T Cells
identifies the antigen
on the macrophage
126
Helper
T Cells relays
information to B Cells
B Cells make and
release antibodies
accordingly
127
Antibodies
attach to
antigens
128
Antibodies
destroy
antigens
B Cell make Memory
Cells that store
information on
invaders, making it
easier to destroy next
time
129
The
best immune system video ever.
Really this is all you need to know about
your white blood cells.
130