Blood

1. Blood

2. Circulatory System • The circulatory system consists of: • Heart • Blood Vessels • Blood • Adults have 4-6 liters of blood. • The study of blood is hematology

3. What are the Functions of Blood? • Transportation: • Oxygen, nutrients, wastes, carbon dioxide, and hormones • Defense: • Against invasion by pathogens • Regulatory functions: • Body temperature, water-salt balance, and body pH

5. Composition of blood • Formed elements: produced in red bone marrow • Red blood cells/erythrocytes (RBC) • White blood cells/leukocytes (WBC) • Platelets • Plasma • 91% water and 9% salts and organic molecules

6. Composition of blood Venipuncture by phlebotomist

7. Fig. 6.2

8. Formed Elements • The formed elements are produced in red bone marrow which is found in almost every bone of a child, but in only certain bones of adults. • Flat bones of sternum, hips • Ends of long bones • Red bone marrow contains pluripotent stem cells, which divide and give rise to all of the various types of blood cells.

10. Erythrocytes • Red blood cells (RBC) • Discoid shape • Biconcave disks • No nucleus • Lack many organelles

11. RBC • RBC’s are the most abundant formed elements. • There are 4 to 6 million red blood cells per mm3 of whole blood. • RBC’s have 2 main functions. • To pick up oxygen from the lungs and deliver it to tissues of the body. • To pick up carbon dioxide from the tissues and unload it in the lungs.

12. Red blood cells They contain many molecules of hemoglobin. Hemoglobin is a pigment that makes RBC’s red. Oxygen binds to heme on the hemoglobin molecule

13. How Red Blood Cells Carry Oxygen • Red blood cells contain hemoglobin, the respiratory pigment that transports oxygen. • Each hemoglobin molecule has four polypeptides that comprise the protein globin and an iron-containing, oxygen-carrying heme portion. • Oxyhemoglobin and deoxyhemoglobin are the names for the shapes that hemoglobin can take with or without bound hemoglobin.

14. How Red Blood Cells Help Transport Carbon Dioxide • Hemoglobin directly transports about 25% of carbon dioxide which binds to the terminal amino groups of the globin molecules. • The remaining carbon dioxide is transported as the bicarbonate ion in the plasma. • The enzyme carbonic anhydrase, contained in red blood cells, catalyzes the reaction of carbon dioxide and water to form carbonic acid. • When blood containing bicarbonate ions reaches the lungs, carbon dioxide diffuses out of the blood into the lungs and is exhaled.

15. RBC life cycle • Last about 120 days • As a RBC ages, its membrane becomes fragile. • Eventually it ruptures as it tries to flex through narrow capillaries. • RBC’s are destroyed in the liver and the spleen • The spleen= the erythrocyte graveyard • RBC’s have a hard time passing through its small channels. • Here the old cells become trapped, broken up, and destroyed.

16. RBC life cycle

17. RBC life cycle • Hemoglobin is released when blood cells are broken down. • Iron is recovered and recycled to the bone marrow. • Pigments from hemoglobin are excreted as bile pigments. • The kidneys release the erythropoietin hormone which stimulates bone marrow stem cells to make more red blood cells.

19. Disorders of RBC’s • Anemia • A condition resulting from too few RBC’s or hemoglobin that causes a run-down feeling • Sickle-Cell Disease • Sickle-cell disease is a hereditary condition in which the hemoglobin molecule is abnormal and the individual has sickle-shaped red blood cells that tend to rupture as they pass through the narrow capillaries.

20. Disorders of RBC’s • Hemolytic disease of the newborn • A condition with incompatible blood types that leads to rupturing of blood cells in a baby before and continuing after birth

21. White Blood Cells

22. White Blood Cells • White blood cells (leukocytes) are large, nucleated, and function in immunity. • Some live days and others live months or years. • Memory cells last for decades! • WBC’s are not as numerous as RBC’s • Colony-stimulating factors (CSFs) are proteins that regulate the production of white blood cells.

23. White Blood Cells • Functions of WBC’s • Found in the blood as well as tissues • Can squeeze through pores in the capillary wall to go and fight infections (diapedesis) • Invade tissues when needed • Fight infection • Important part of the immune system • Numbers can double within hours if needed

24. White Blood Cells • The immune system defends the body against pathogens, cancer cells, and foreign proteins. • An antigen is a cell or other foreign substance that provokes an immune response. For example: • Foreign proteins • Viruses • Bacteria • Abnormal or foreign cells

25. How do blood cells leave circulation? Diapedesis

26. WBC types • Agranulocytes • Lymphocytes • Monocytes • Granulocytes • Neutrophils • Eosinophils • Basophils

27. Neutrophils Most numerous WBC Contains a multi-lobed nucleus Fight off bacterial infections Upon infection they move out of circulation into tissues to engulf pathogens

28. Lymphocyte • 2nd most numerous WBC • Develops into B and T cells that are important in the immune system • B lymphocytes mature into plasma cells that make antibodies • T lymphocytes control immune response • Important in fighting off viral infections

29. Monocyte • Largest of the WBC’s • Count increases in inflammation and viral infections • Leave the bloodstream and transform into macrophages • Play a role in immune response

30. Eosinophils Small percentage of WBC’s Many large granules function in parasitic infections and play a role in allergies

31. Basophils Smallest percentage of WBC’s Release histamine related to allergic reactions Histamine dilates blood vessels and constricts air tubes leading to lungs

32. Disorders of WBC’s • Severe combined immunodeficiency disease (SCID) • An inherited disease in which stem cells of WBC’s lack an enzyme that allows them to fight any infection • Lymphoma • A group of cancers that begin in cells of the immune system. There are two basic categories of lymphomas: Hodgkin lymphoma and non-Hodgkin lymphomas, which includes a large, diverse group of cancers of immune system cells.

33. Leukemia • A group of cancers in which white blood cells proliferate without control

34. Disorders of WBC’s Infectious mononucleosis- also know as the “kissing disease” occurs when the Epstein-Barr virus (EBV) infects lymphocytes resulting in fatigue, sore throat, and swollen lymph nodes 50% monocytes with at least 10% atypical lymphocytes (large, irregular nuclei),

35. Platelets

36. Platelets Small fragments of megakaryocytes Aide in blood clotting Live for about 10 days About 200 million are made per day

37. Platelets and Blood Clotting • Blood Clotting • When tissues are damaged, platelets stick to the damaged area, partially sealing torn blood vessels. • Injured tissues release prothrombin activator, which converts prothrombin to thrombin. • This step requires calcium ions. • Thrombin functions as an enzyme to convert fibrinogen into long threads of insoluble fibrin.

38. Disorders of Platelets • Thrombocytopenia • A disorder in which the number of platelets is too low due to not enough being made in the bone marrow or the increased breakdown outside the marrow • Thromboembolism • A spontaneous clot is called a thrombus if it remains in the vessel; if it dislodges and travels, it is called an embolus. • A thromboembolus can result in a heart attack or stroke when the clot plugs a vessel in the heart or brain

39. Disorders of Platelets • Hemophilia • Hemophilia is an inherited clotting disorder carried on the X chromosome which results in the deficiency of a clotting factor. Injections of this factor can treat the disease. • Victim hemorrages • Can die from bleeding internally

40. Blood Typing • A blood transfusion is the transfer of blood from 1 individual to another • For transfusions to be safe, blood must be typed so that agglutination (clumping) does not occur • Blood typing involves determining the ABO blood group and Rh factor so that the transfusion can be done safely. • Blood typing usually involves determining the ABO blood group and whether the individual is Rh- or Rh+

41. ABO Blood Groups • The most common system for typing blood is the ABO system. • Blood types A, B, and AB correspond with having specific antigens on the surface of RBCs; type O is an absence of these antigens. • All persons have antibodies in their plasma for the A and/or B antigen not carried on their own RBCs. • If the corresponding antigen and antibody are combined, clumping, or agglutination, occurs.

43. Blood typing For example: Type A blood -has A antigen on its surface -has B antibodies in the plasma What can you say about someone with type AB blood?

46. Blood types Plasma

47. Determining compatibility for blood transfusion First consider the antigens found on the blood transfusion recipient Second, consider the antibodies found in the donor blood If the antibodies in the donor blood can recognize the antigen on the recipient’s blood then the blood will agglutinate (clump) and cause rejection

49. Blood Compatibility Type O blood is sometimes called the universal donor because the red blood cells of type O blood lack A and B antigens. Type O blood will not agglutinate regardless of the recipient’s antibodies.

50. Blood Compatibility Type AB blood is called the universal recipient because the plasma lacks A and B antibodies Type AB recipient blood won’t clump with any type of donor blood