Title: PowerLecture: Chapter 8
1PowerLectureChapter 8
2Learning Objectives
- Describe the composition and functions of blood.
- Explain how red blood cells transport oxygen.
- Explain the basis of blood typing.
- Define hemostasis and distinguish it from
homeostasis. -
3Learning Objectives (contd)
- Describe how blood disorders disrupt homeostasis
and critical body functions, such as clotting.
4Impacts/Issues
5Chemical Questions
- Healthy people have contaminants in their blood.
- The chemicals are products from everyday life
metals, secondhand cigarette smoke, pesticides,
etc. - Most of the chemicals did not even exist 50 years
ago. - Not enough is known about the long-term effects
of these chemicals on human health, especially
for the very young.
6Useful References for Impacts/Issues
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - Environmental Scorecard - In Your Community
- InfoTrac Elevated Blood Lead Levels in Refugee
Children New Hampshire, 20032004. Morbidity
and Mortality Weekly Report, Jan. 21, 2005.
7How Would You Vote?
- To conduct an instant in-class survey using a
classroom response system, access JoinIn Clicker
Content from the PowerLecture main menu. - Government regulation of substances such as lead
seems to be effective. Should other suspect
industrial chemicals be regulated? - a. Yes, until companies are forced to prove their
chemicals are harmless before selling them, they
should be regulated. - No, regulation hampers industry and is not
necessary unless these chemicals are proven
harmful.
8Useful References for How Would You Vote?
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - CDC National Report on Human Exposure to
Environmental Chemicals - Environmental Working Group Body Burden
- NRDC Healthy Milk, Healthy Baby Chemical
Pollution and Mothers Milk
9Section 1
- Blood Plasma, Blood Cells, and Platelets
10Blood Plasma, Blood Cells, and Platelets
- Blood is a connective tissue it contains plasma,
blood cells, and cell fragments called platelets. - Adult women of average size have 4-5 liters of
blood in their bodies men have slightly more.
Figure 8.1
11red blood cell
white blood cell
platelets
Fig. 8.1, p.143
12Blood Plasma, Blood Cells, and Platelets
- Plasma is the fluid part of blood.
- Roughly 55 of whole blood is plasma, which is
mostly water. - Plasma proteins perform a variety of tasks
- Albumin is important in maintaining osmotic
balance and transports chemicals such as
therapeutic drugs. - Other plasma proteins include protein hormones,
as well as proteins involved in immunity, blood
clotting, and the transport of lipids and
vitamins. - Plasma further contains ions, glucose, amino
acids, signaling molecules, and dissolved gases.
13Blood Plasma, Blood Cells, and Platelets
- Red blood cells carry oxygen and CO2.
- Erythrocytes, or red blood cells, (45 of whole
blood) are biconcave disks. - They contain hemoglobin, an iron-containing
protein that binds with oxygen. - They also carry a small amount of carbon dioxide.
- Red blood cells originate from stem cells in the
bone marrow.
14natural killer cells
T lymphocytes
neutrophils
mast cells
eosinophils
basophils
B lymphocytes
forerunners of white blood cells (leukocytes)
?
stem cells in marrow
monocytes (immature phagocytes)
red blood cells (erythrocytes)
dendritic cells
macrophages
platelets
megakaryocytes
Fig. 8.2, p.145
15Blood Plasma, Blood Cells, and Platelets
- White blood cells perform defense and cleanup
duties. - Leukocytes, or white blood cells, make up a minor
portion of whole blood and are responsible for
housekeeping and defense they also are derived
from bone marrow. - Leukocytes are of two main types
- Granulocytes have stainable granules in the
cytoplasm they include neutrophils, eosinophils,
and basophils and they work in body defense
activities. - Agranulocytes have no visible granules monocytes
become macrophages and lymphocytes become B
cells, T cells, and natural killer cells.
16Blood Plasma, Blood Cells, and Platelets
- Platelets help clot blood.
- Platelets are fragments of megakaryocytes
produced by bone marrow stem cells. - They are short lived, numerous, and function in
blood clotting.
17Functions
Components
Relative Amounts
Plasma portion (50-60 of total volume)
91-92 of plasma volume 7-8 1-2
Solvent Defense, clotting, lipid transport,
roles in extracellular fluid volume, etc. Roles
in extracellular fluid volume, pH, etc.
- Water
- Plasma proteins (albumin, globulins, fibrinogen,
etc.) - Ions, sugars, lipids, amino acids, hormones,
vitamins, dissolved gasses
Plasma portion (50-60 of total volume)
- White blood cells Neutrophils Lymphocytes
Monocytes(macrophages) Eosinophils
Basophils - Platelets
- Red blood cells
3,000-6,750 1,000-2,700 150-720 100-360
25-90 250,00-300,000 4,800,000-5,400,000 per
microliter
Phagocytosis during inflammation Immune
responses Phagocytosis in all defense
responses Defense against parasitic worms Secrete
substances for inflammatory response and for fat
removal from blood Roles in clotting Oxygen,
carbon dioxide transport
Fig. 8.1, p.143
18Video Immortality Industry
- This video clip is available in CNN Today Videos
for Anatomy and Physiology, 2004, Volume VIII.
Instructors, contact your local sales
representative to order this volume, while
supplies last.
19Useful References for Section 1
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - InfoTrac FDA to Hear Artificial Blood Test
Proposal. UPI NewsTrack, July 6, 2006.
20Section 2
- How Blood Transports Oxygen
21How Blood Transports Oxygen
- Hemoglobin is the oxygen
- carrier.
- Only a tiny amount of oxygen
- is dissolved in blood plasma.
- Most of the oxygen is bound to the heme groups of
hemoglobin oxygen-bearing hemoglobin is called
oxyhemoglobin. - What determines how much oxygen hemoglobin can
carry?
22How Blood Transports Oxygen
- The amount of oxygen bound to hemoglobin changes
as conditions in the tissues vary. - Binding of oxygen is favored by conditions in the
lungs abundant oxygen, cooler temperature, and
neutral pH. - Release of oxygen is favored in the tissues where
the oxygen levels are lower, temperatures higher,
and pH more acidic. - Hemoglobin also transports a small amount of
carbon dioxide.
23LUNGS
TISSUES
more O2 cooler less acidic
less O2 warmer more acidic
HbO2
HbO2
Hb O2
Hb O2
p.146
24Animation Globin and Hemoglobin Structure
CLICKTO PLAY
25How Blood Transports Oxygen
- Each hemoglobin molecule has four polypeptide
chains (globin proteins), each of which possesses
a heme group containing an iron molecule each
iron binds one molecule of oxygen.
26Fig. 8.3b, p.146
heme group
coiled and twisted polypeptide chain of one
globin molecule
27Useful References for Section 2
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - Royal Society of Chemistry Transport of Oxygen
in the Blood - InfoTrac Hemoglobin Levels Are Testy Issue. New
York Daily News, Feb. 12, 2006.
28Section 3
- Hormonal Control of Red Blood Cell Production
29Hormonal Control of Red Blood Cell Production
- Red blood cells form from stem cells located in
red bone marrow. - The hormone erythropoietin from the kidneys is
the stimulus for stem cell division. - Mature red blood cells have no nuclei and live
for only about 120 days. - Macrophages remove old blood cells from the
bloodstream amino acids are returned to the
blood, iron is returned to the bone marrow, and
heme groups are converted to bilirubin. - Red cell counts remain rather constant at 5.4
million/microliter for males and 4.8 million for
females.
30Hormonal Control of Red Blood Cell Production
- A negative feedback loop stabilizes the red blood
cell count. - The kidneys monitor oxygen content of the blood
when it drops too low, the kidneys secrete
erythropoietin. - Erythropoietin stimulates bone marrow to produce
more red blood cells this increases the ability
of the blood to carry oxygen. - As oxygen levels rise, the information feeds back
to the kidneys, which stop secreting
erythropoietin.
31Kidney
Erythropoietin
The kidneys detect reduced O2 in the blood.
When less O2 is delivered to the kidneys, they
secrete the hormone erythropoietin into the blood.
Reduced oxygen in blood
Developing red blood cells in red bone marrow
Erythropoietin stimulates production of red blood
cells in bone marrow.
Relieves
The additional circulating RBCs increase O2
carried in blood.
Increased oxygen in blood
The increased O2 relieves the initial stimulus
that triggered erythropoietin secretion.
RBCs
Fig. 8.4, p.147
32Section 4
- Blood Types Genetically Different Red Blood
Cells
33Blood Types Genetically Different Red Blood
Cells
- All cells of the human body have surface proteins
and other molecules that serve as self
identification markers. - Any protein marker that prompts a defensive
action is called an antigen. - The human body produces antibodies that recognize
markers on foreign cells as nonself and
stimulate immune reactions.
34Blood Types Genetically Different Red Blood
Cells
- The ABO group of blood types includes key self
markers on red blood cells. - ABO blood groups are based on glycoprotein
surface markers on red blood cells. - Type A has A markers type B has B markers.
- Type AB has both markers type O has neither
marker. - Depending on ABO blood type, the body will also
possess antibodies to other blood types ABO
blood typing is done to prevent incompatible
blood types from being mixed.
35Blood Types Genetically Different Red Blood
Cells
- Mixing incompatible blood types can cause the
clumping called agglutination. - Type A blood types do not have antibodies against
A markers, but they do have antibodies to type B
Type B blood types do not have type B antibodies,
but they do have type A antibodies, etc. - A type A person cannot donate blood to a type B
person because they are incompatible. - When mixed, markers on the surface of red blood
cells (not just the ABO markers) that do not
match will cause the blood cells to undergo
agglutination, a defense response where the blood
cells clump.
36Table 8.1, p.148
37Table 8.2, p.151
38Blood Types Genetically Different Red Blood
Cells
- Clumped cells can clog small blood vessels,
damage tissues, and cause death.
incompatible blood cells
compatible blood cells
Fig. 8.5b, p. 149
39Fig. 8.5a, p.149
Donor type B blood
Recipient with type A blood
Antigen A
Antigen B
Antibody to type A blood
Antibody to type B blood
Red blood cells from donor agglutinated by
antibodies in recipients blood
Red blood cells usually burst
Clumping blocks blood flow in capillaries
Side effects disrupt kidney function
Oxygen and nutrient flow to cells and tissues is
reduced
40Fig. 8.5a, p.149
Red blood cells from donor agglutinated by
antibodies in recipients blood
Red blood cells usually burst
Clumping blocks blood flow in capillaries
Side effects disrupt kidney function
Oxygen and nutrient flow to cells and tissues is
reduced
Stepped Art
41Useful References for Section 4
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - InfoTrac Babies Accept Hearts with All Blood
Types. UPI NewsTrack, April 5, 2005.
42Section 5
43Rh Blood Typing
- Rh blood typing looks for an Rh marker.
- Rh blood typing looks for the presence (Rh) or
absence (Rh-) of antigen on red blood cells. - An Rh- person transfused with Rh blood will
produce antibodies to the Rh marker.
44Rh Blood Typing
- An Rh- mother who bears an Rh child can also
become sensitized to the Rh antigen secondary
children may be at risk from maternal antibodies. - In hemolytic disease of the newborn, too many
cells may be destroyed and the fetus dies. - Medical treatment (RhoGam) given to the mother
after the birth of the first Rh baby can
inactivate the Rh antibodies.
45Rh Blood Typing
- There are also many other markers on red blood
cells. - Hundreds of different blood cell markers are
known most are widely scattered in the human
population. - To avoid problems with transfusions, blood
undergoes cross-matching to exclude incompatible
blood types from being used.
46Useful References for Section 5
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - InfoTrac Rh Disease Its Still a Threat.
Contemporary OB/GYN, May 2004.
47Section 6
- New Frontiers of Blood Typing
48New Frontiers of Blood Typing
- Blood DNA Investigating crimes and identifying
mom or dad. - Blood cell markers can be used to compare
evidence from crime scenes to samples taken from
possible perpetrators. - Because blood groups are determined by genes,
they are a useful source of information about a
persons genetic heritage. - Blood typing can also be used to help determine
the identity of a childs father or mother.
49New Frontiers of Blood Typing
- For safetys sake, some people bank their own
blood. - Even with screening, blood transfusions still
carry the risk of being incompatible or
potentially contaminated with infectious agents. - In autologous transfusions, individuals
pre-donate blood to - themselves prior
- to surgeries in case
- transfusion is needed.
Figure 8.7
50New Frontiers of Blood Typing
- Blood substitutes must also avoid sparking an
immune response. - Blood substitutes have potential uses in
situations where it is not feasible to perfectly
match blood, such as in an ambulance or on the
battlefield. - To date, however, substitutes have
- been difficult to manufacture OxygentTM is an
oxygen carrier - that has currently reached the final
- stages of clinical trials.
51Useful References for Section 6
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - InfoTrac Autologous Blood Transfusion A Safer
Way of Transfusion. GP, Feb. 24, 2006.
52Section 7
- Hemostasis and Blood Clotting
53Hemostasis and Blood Clotting
- Hemostasis prevents blood loss.
- Hemostasis is the process that stops bleeding to
prevent excess loss of blood. - Spasms of the smooth muscle in the damaged blood
vessel stop blood flow for a few minutes by
constriction of the vessel. - Platelets clump to plug the rupture they then
release serotonin and other chemicals to prolong
the spasm and attract more platelets. - Finally, the blood coagulates to form the clot.
- Hemostasis can only seal tears and punctures that
are relatively small.
54Fig. 8.8, p.152
Platelets stick to collagen fibers of damaged
vessel wall
Injury to blood vessel
Wall of vessel contracts
More permanent clot forms
Platelet plug
Blood flow decreases
Blood flow
Blood flow decreases
Blood flow ceases
Prothrombin
Damaged cells and platelets release substances
that activate clotting factors
Ca2
Prothrombin activator
Fibrinogen
Ca2
Thrombin
Fibrin threads (clot)
55Hemostasis and Blood Clotting
- Factors in blood are one trigger for blood
clotting. - In the intrinsic clotting mechanism, internal
damage activates a plasma protein (factor X)
that triggers the formation of thrombin. - Thrombin acts on fibrinogen to form insoluble
threads of fibrin that will entrap blood cells
and platelets to form a clot.
56Hemostasis and Blood Clotting
- Factors from damaged tissue also can cause a clot
to form. - In the extrinsic clotting mechanism, blood
clotting is triggered by the release of
substances outside the blood itself due to damage
there the pathway is similar to the intrinsic
mechanism.
Figure 8.8
57Hemostasis and Blood Clotting
- Clots that form in unbroken vessels can be
life-threatening. - A clot that stays where it forms is called a
thrombus one that breaks free and moves is
called an embolus. - A stroke occurs when an embolus blocks flow to
some part of the brain. - Hemophilia is a genetic disorder where clotting
factors are absent from the blood so it does not
clot properly.
58Fig. 8.9, p.153
Damage to skin
Epidermis
Dermis
Blood clot
Blood vessels
Neutrophils defensive WBCs)
59Fig. 8.9, p.153
Scab
Regenerating epithelium
Collagen fiber
Blood vessel
Collagen fiber
60Useful References for Section 7
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - American Academy of Family Physicians
Hypercoagulation - InfoTrac Factor V Leiden as a Common Genetic
Risk Factor for Venous Thromboembolism. Journal
of Nursing Scholarship, Spring 2006.
61Section 8
62Blood Disorders
- Anemias are red blood cell disorders.
- Anemias develop when red blood cells deliver too
little oxygen to the tissues. - Two types result from nutrient deficiencies
- In iron-deficiency anemia, red cells contain too
little hemoglobin, usually resulting from an
iron-poor diet. - Pernicious anemia is caused by a deficiency of
folic acid or vitamin B12. - Aplastic anemia results from a destruction of the
red bone marrow and its stem cells.
63Blood Disorders
- Hemolytic anemias are
- caused by the premature
- destruction of red blood cells.
- Sickle cell anemia, a genetic
- disease, is one cause.
- Malaria is a major cause of
- hemolytic anemia and follows
- infection by a protozoan
- transmitted by mosquitoes.
- In thalassemia, individuals produce abnormal
hemoglobin.
Figure 8.10
64Fig. 8.10, p.154
65Fig. 8.10, p.154
66Blood Disorders
- Carbon monoxide poisoning prevents hemoglobin
from binding oxygen. - Carbon monoxide (CO) is a colorless, odorless gas
present in auto exhaust fumes and smoke from
wood, coal, charcoal, and tobacco. - CO binds to hemoglobin 200 times more tightly
than oxygen, thus blocking oxygen transport to
tissues.
67Blood Disorders
- Mononucleosis and leukemias affect white blood
cells. - Infectious mononucleosis is caused by the
Epstein-Barr virus, which triggers overproduction
of lymphocytes. - Leukemias are very serious cancers in which there
is an overproduction of white blood cells and
destruction of bone marrow chronic myelogenous
leukemia is one type.
68Fig. 8.11, p.154
69Blood Disorders
- Other viral infections, such as HIV (the human
immunodeficiency virus), can also harm or destroy
white blood cells. - Toxins can destroy blood cells or poison the
blood in other ways. - Septicemia can occur when bacteria release toxins
into the blood Staphylococcus aureus (Staph A)
is one important example. - Toxemia happens when metabolic poisons accumulate
in the body toxemia can occur if the kidneys do
not adequately filter the blood and remove these
poisons.
70Video Global AIDS
- This video clip is available in CNN Today Videos
for Biology, 2003, Volume VII. Instructors,
contact your local sales representative to order
this volume, while supplies last.
71Useful References for Section 8
- The latest references for topics covered in this
section can be found at the book companion
website. Log in to the books e-resources page at
www.thomsonedu.com to access InfoTrac articles. - Leukemia Lymphoma Society
- National Heart, Lung, and Blood Institute Blood
Diseases and Resources Information - InfoTrac When Mono Strikes. Nina M. Riccio.
Current Health 2, March 2000. - InfoTrac Anemia That Run-Down Feeling. Shiela
Globus. Current Health 2, Mar. 1999.