1. Blood – only fluid tissue of body
What type of tissue is blood?
Epithelial Connective
Muscle Nerve
Functions include, among others:
Nutrient and waste management
Heat management
Body defenses

2. Physical Characteristics of Blood
Color range
Oxygen-rich = scarlet red
Oxygen-poor = dull red
pH = 7.35–7.45 (slightly alkaline)
Blood temperature = 100.4°F (slightly higher than body temp)
5 - 6 quarts per healthy adult
8% of body weight

3. Blood has 2 major components:
Formed elements = living cells (40-50%)
Plasma = non-living matrix (50-60%)
Figure 10.1 (1 of 2)

4. Blood Plasma is mostly (90%) water and…
Over 100 dissolved substances!
Nutrients (like glucose)
Salts (electrolytes)
Respiratory gases (O2 and CO2)
Hormones
Plasma proteins
Waste products (urea, for eg.)

5. Plasma proteins = most abundant plasma solutes
Most made by liver
Plasma proteins include
Albumin—regulates osmotic pressure
Clotting proteins—help stop blood loss
Antibodies—made by white blood cells, help identify pathogens
Plasma proteins usually remain in the blood, i.e. not taken up by cells

6. Participating…
Blood is made of living cells and cell fragments collectively known as _________ elements and a non-living matrix known as ___________. Though mostly water, blood plasma contains blood ___________ which help control osmotic balance, identify foreign agents, and help with blood clotting among others.
formed
plasma
proteins

7. Blood Plasma changes continuously, but must stay within critical bounds for homeostasis
Cells constantly take nutrients, add waste
Organs adjust constantly to maintain balance
For example, pH ( ) of blood is critical (below 6.8 or above ‘not compatible with life’)
Acidosis = blood too acidic
Alkalosis = blood too basic
Respiratory system and kidneys restore pH in both cases

8. Formed Elements Erythrocytes – red blood cells (RBCs), most abundant
Leukocytes - White blood cells (WBCs), many different types
Platelets – cell fragments, for blood clotting

9. Erythrocytes carry O2 (some CO2)
Anatomy of mature erythrocytes:
Flexible biconcave disks full of hemoglobin
Anucleate (no nucleus) and no mitochondria (ATP generation is anaerobic)
5 million RBCs per mm3 of blood!
How does anaerobic respiration by RBCs aid RBC function?

10. Hemoglobin = iron-containing protein
Binds reversibly to O2 (why reversibly?)
4 O2 binding sites per hemoglobin (each requires iron)
1 billion O2 molecules can be carried per RBC!

11. Participating…
One reason we need the element ________ in our diets is to build functional _______________ molecules that carry O2 inside of _____________, a.k.a red blood cells (RBCs). Do RBCs have a nucleus?
iron
hemoglobin
erythrocytes
No, Sir or Madame.

12. Homeostatic imbalance of RBCs
Anemia = decrease in O2-carrying ability of blood (many possible causes, not enough iron among others)
Sickle cell anemia (SCA) = abnormally shaped hemoglobin crystallizes in low O2 (offers resistance to malaria)

13. Some common anemias…
Table 10.1

14. Leukocytes (a.k.a. WBCs) help defend the body against disease
Leukocyte anatomy:
Complete cells, have nucleus & organelles
Can move in and out of blood vessels (diapedesis)
Respond to chemicals from damaged tissues

15. Some Leukocyte (a.k.a. WBC) anatomy…
2 major types = granulocytes and agranulocytes
Granulocytes – contain vesicles (granules) to kill invaders or signal damage
Neutrophils – eat microbial pathogens
Eosinophils – kill parasites (worms)
Basophils – signal tissue damage w/ histamine
Neutrophils – eat microbial pathogens
Eosinophils – kill parasites (worms), respond to allergies
Basophils – signal tissue damage w/ histamine

16. Characteristics of Formed Elements of the Blood
Table 10.2 (1 of 2)

17. Some Leukocyte (a.k.a. WBC) anatomy…
2 major types = granulocytes and agranulocytes
Agranulocytes – no ‘granules’
Lymphocytes – major immune cells, identify and help kill invaders
Monocytes – eat marked invaders or infected cells, fight chronic infections

18. Characteristics of Formed Elements of the Blood
Table 10.2 (2 of 2)

19. Abnormalities of leukocytes…
Leukocytosis – high WBC count = infection
Leukopenia – low WBC count from drugs, stress, AIDs
Leukemia – cancer in bone marrow = excess WBCs

20. Participating…
White blood cells are collectively known as ___________. These cells are divided into 2 general cell types known as ______________ and agranulocytes. They actively participate in which of the following:
leukocytes
granulocytes
Killing parasitic worms
Identifying and consuming microbial pathogens
Delivering O2 and removing CO2 from tissues
Releasing chemical signals if tissues are damaged

21. Formed Elements come from stem cells in red bone marrow
Hemocytoblast stem cells
Secondary stem cells
Basophils
Eosinophils
Neutrophils
Monocytes
Lymphocytes
Erythrocytes
Platelets
Lymphoid stem cells
Myeloid stem cells
Hematopoiesis = blood cell formation
Figure 10.4

22. Erythrocytes are replaced every 100 – 120 days
Why can’t RBCs just repair themselves?
No DNA, no protein synthesis, no nothing but Hb
Old RBCs recycled by spleen or liver
Kidneys detect low O2 levels, send hormone to marrow to stimulate RBC production
Erythropoietin stimulates
Enhanced erythropoiesis
Red bone marrow
More RBCs
Normal blood oxygen levels
Imbalance

23. Control of Erythrocyte Production
Normal blood oxygen levels
Figure 10.5, step 1

24. Control of Erythrocyte Production
Low RBC count,
O2 availability, or
increased O2
demand
Normal blood oxygen levels
Imbalance
Figure 10.5, step 2

25. Control of Erythrocyte Production
Reduced O2 levels in blood
Stimulus: Decreased RBC count, decreased availability of O2 to blood, or increased tissue demands for O2
Normal blood oxygen levels
Imbalance
Figure 10.5, step 3

26. Control of Erythrocyte Production
Reduced O2 levels in blood
Stimulus: Decreased RBC count, decreased availability of O2 to blood, or increased tissue demands for O2
Kidney
releases erythropoietin
Normal blood oxygen levels
Imbalance
Figure 10.5, step 4

27. Control of Erythrocyte Production
Reduced O2 levels in blood
Erythropoietin stimulates
Kidney releases erythropoietin
Red bone marrow
More RBCs
Normal blood oxygen levels
Imbalance
Figure 10.5, step 6

28. Control of Erythrocyte Production
Reduced O2 levels in blood
Stimulus: Decreased RBC count, decreased availability of O2 to blood, or increased tissue demands for O2
Increased O2 in blood
Erythropoietin stimulates
Kidney releases erythropoietin
Enhanced erythropoiesis
Red bone marrow
More RBCs
Normal blood oxygen levels
Figure 10.5, step 7

29. White Blood Cell and Platelet formation - also hormone controlled
Hormone release stimulated by cell damage (some bacteria)
Hemocytoblast stem cells
Secondary stem cells
Basophils
Eosinophils
Neutrophils
Monocytes
Lymphocytes
Erythrocytes
Platelets
Lymphoid stem cells
Myeloid stem cells

30. Participating…
Kidneys detect low O2 levels and release hormones to stimulate new ____________ production. Damaged cells release hormones that stimulate ____________ production. Both are made from _________ cells found in ___ _______ _________ .
erythrocyte
leukocyte
stem
red
bone
marrow
Basophils
Eosinophils
Neutrophils
Monocytes
Lymphocytes
Erythrocytes
Platelets

31. Hemostasis = stoppage of bleeding
3 major phases:
Vascular spasms – vessels contract
Platelet plug formation
Coagulation (blood clotting)

32. Platelets stick to collagen fibers of damaged vessel wall 2
Blood flow
Injury to
blood vessel
Blood flow
decreases
Wall of vessel
contracts 1
Platelet
plug
Blood flow
decreases
Platelets stick to collagen fibers of damaged vessel wall 2
Blood flow
ceases
More permanent
clot forms, pulls
walls together 3
Ca2+
Fibrinogen
Prothrombin
Thrombin
Fibrin threads
(clot)
Damaged cells, platelets release substances to
activate clotting
activator
FigureHowabloodclotformsThemicrographshowsredbloodcells trappedinafibrinnet

33. Hemostasis Blood usually clots in 3 to 6 minutes
Clot remains as endothelium regenerates
Clot breaks down after tissue repair

34. Undesirable Clotting Thrombus – clot in unbroken vessel (thrombosis)
Embolus – internal clot breaks free and circulates (embolism)
Can = stroke or heart attack

35. Some Blood Disorders…
Thrombocytopenia – platelet deficiency from cancer, radiation, drugs
bruises develop from normal activity
Hemophilia – clotting factors missing
Hereditary disorder
Requires transfusion or injection of clotting factors

36. Human Blood Groups
Blood cells have genetically determined ‘self’ markers (Type A, for example)
Self markers act as antigens (foreign substances) if transfused
Antibodies “recognize” antigens (eg. antibody B recognizes type B blood as foreign)
Antibodies cause blood to clump = agglutination

37. Human Blood Groups Over 30 red blood cell types are ‘common’
ABO and Rh(+/-) blood groups cause most vigorous transfusion reactions
Type AB = A and B antigens
Type B = B antigens
Type A = A antigens
Type O = no AB antigens

38. Red blood cells usually burst
Donor
type B blood
Recipient with
type A blood
Antigen B
Antigen A
Antibody to
type A blood
Antibody to
type B blood
Red blood cells from
donor agglutinated
by antibodies in
recipient’s blood
FigureAnimatedAgglutinationinredblood cellsaExampleofanagglutinationreactionThis diagramshowswhathappenswhentypeBbloodis transfusedintoapersonwhohastypeAbloodbWhatanagglutinationreactionlookslikeInthe micrographontheleftcommingledredbloodcells arecompatibleandhavenotclumpedThecellson therightareamixofincompatibleABOtypesand theyhaveclumpedtogetherDonatedbloodistyped inordertoavoidanagglutinationresponsewhenth bloodistransfusedintoanotherperson
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

39. ABO Blood Groups Type A can receive A and O blood
Type B can receive B and O blood
Type AB can receive A, B, AB, and O (universal recipient)
Blood type O can receive O blood (universal donor)

40. Participating…
Red blood cells have ‘self’ markers that may act as __________ if transfused. ___________ will bind to ‘self’ markers and cause erythrocytes to stick together, i.e. ______________. In the ABO blood types, type ____ is the universal donor and type ____ is the universal recipient.
antigens
Antibodies
agglutinate O AB

41. Aside from transfusion problems, Rh can also affect pregnancies…
Rh– mother with Rh+ baby
1st Rh+ pregnancy proceeds without problems
Mom’s immune system makes Rh+ anitbodies after 1st Rh+ birth
2nd Rh+ pregnancy, mom’s antibodies attack Rh+ blood = hemolytic disease of newborn
RhoGAM shot prevents Rh+ antibody formation in mom

42. Blood Typing – antibodies mixed with blood sample, agglutination signals antigen presence
Figure 10.8