Blood rev 12-12

1. Blood rev 12-12 • The circulatory system consists of the heart, blood vessels and the blood. • The circulatory system is essential to supply cells with what they need and remove substances they no longer need. BIO 102 blood-cardiovascular HANDOUT

2. The Functions of Blood Blood is actually a liquid body tissue and is classified as a connective tissue; we have ~ 5 liters of blood Blood carries out three essential tasks: • Transportation: oxygen, carbon dioxide, nutrients, waste, hormones • Regulation: body temperature, volume of water in the body, pH of body fluids • Defense: contains specialized defense cells to protect against illness and excessive bleeding through clotting mechanisms • necessary for homeostasis. BIO 102 blood-cardiovascular HANDOUT

3. Blood Components All blood cells and platelets develop from stem cells in red bone marrow. Blood is made up of: • Formed elements (cellular components--45%): • RBCs or erythrocytes; most abundant cell type; primarily is a carrier of oxygen and carbon dioxide • WBCs or leukocytes • Platelets • Plasma (liquid and dissolved solutes--55%): • Water • Electrolytes (ions of elements) • Proteins (albumins, globulins, clotting proteins) • Hormones • Gases (oxygen and carbon dioxide) • Nutrients and wastes BIO 102 blood-cardiovascular HANDOUT

4. RBC (erythrocytes) Production=Erythropoiesis • Stem cells develop into immature cells called erythroblasts. • s become erythrocytes in about 1 week • lose nucleus and organelles as mature so can’t reproduce • New RBC must develop (from stem cells) because with no nucleus, RBC can’t accomplish any cellular activities and wear out quickly • Old or damaged RBC are removed from blood and destroyed in the liver and spleen by macrophages in a process called phagocytosis. • Many cell components are recycled: hemoglobin is broken up into amino acids, iron atoms returned to bone marrow, heme group converted to bilirubin BIO 102 blood-cardiovascular HANDOUT

5. Red Blood Cells • contain hemoglobin, a protein which carries oxygen and carbon dioxide • live for approximately 4 months. • As they mature, expel nucleus so can carry more hemoglobin. • also assume a biconcave shape • makes them more flexible and allows more to fit into blood vessels to increase the surface area available for gas exchange. BIO 102 blood-cardiovascular HANDOUT

6. Hemoglobin Molecule • Hemoglobin is an oxygen binding protein; consists of 4 polypeptide chains coiled around a “heme group” • The “heme group” has an iron atom in center. This combines easily with oxygen at the lungs AND lets go of the oxygen when reaching body tissues. • When hemoglobin combines with oxygen, it turns red. This is why blood is red. BIO 102 blood-cardiovascular HANDOUT

7. Hematocrit • is a measure of the oxygen carrying capacity of blood • is obtained by spinning down blood and measuring the amount of formed elements • RBCs make up nearly 99% of formed elements • Normal hematocrit • men: 43-49% women: 37-43% BIO 102 blood-cardiovascular HANDOUT

8. Regulation of RBC production is a negative feedback control loop • Cells in the kidneys check the availability of oxygen. If levels are low, these cells are signaled to secrete the hormone erythropoietin. This is carried to red bone marrow where more RBC are produced. • When the oxygen levels are appropriate, the kidney cells stop production of erythropoietin. BIO 102 blood-cardiovascular HANDOUT

9. White Blood Cells-WBC or leukocytes Functions: protection from infection, regulation of the inflammatory reaction • Types: • Granular: • neutrophils, eosinophils, basophils • Mature in the red bone marrow • Granules are actually vesicles filled with proteins and enzymes • Agranular: • lymphocytes, monocytes • monocytes mature in red bone marrow; lymphocytes mature in the thymus gland BIO 102 blood-cardiovascular HANDOUT

10. Circulating levels of WBC rise whenever the body is threatened by viruses, bacteria, or other health challenges • Each type of WBC can produce chemicals which travel, via the blood, to the bone marrow where they stimulate the production of more WBC Most WBC remain in the blood vessels; some circulate in the intercellular fluid and the lymphatic system. BIO 102 blood-cardiovascular HANDOUT

11. Types of WBC • Neutrophils-most common WBC • see in acute infections; first WBC to combat infection • main function is phagocytosis (bacteria and fungi) • Eosinophils- approximately 2-4% of WBCs • see in parasitic infections and in allergic reactions BIO 102 blood-cardiovascular HANDOUT

12. Basophils- rare • initiate the inflammatory response— granules in the cell cytoplasm contain histamine which starts the inflammatory response • Lymphocytes-second most common WBC; found in tonsils, blood, spleen, lymph nodes, thymus • manufactures antibodies and eliminates anything foreign to the body • play crucial role in immune response • Monocytes • active in phagocytosis • elevated in chronic infections BIO 102 blood-cardiovascular HANDOUT

13. Platelets • are small cell fragments; play essential role in process of blood clotting • platelet production regulated by hormone thrombopoietin • platelets are stable as they circulate, but when encounter a “rough surface,” form a temporary plug and initiate the clotting mechanism • body also requires vitamin K for normal blood clotting BIO 102 blood-cardiovascular HANDOUT

14. Clotting process or hemostasis • damage to a blood vessel triggers a vasospasm or constriction of the damaged blood vessel • platelets in the area swell, become sticky, adhere to damaged area and produce plug which becomes clot • platelets also release chemicals to help in clot formation • prothrombin activator converts prothrombin (a plasma protein) into thrombin • thrombin converts the fibrinogen molecules to fibrin which traps blood cells, forms clot and seals hole BIO 102 blood-cardiovascular HANDOUT

15. Blood Typing • Each of us has one of 4 types of blood--A, B, AB, O-- along with some specific glycoproteins or antigens • cells have surface proteins that immune system can recognize as “self” or “non-self”. The immune system will recognize foreign cells as non-self . • An antigen is a substance that can mobilize the immune system to defend itself. Antigens provide a biological “signature” of a person’s blood type. • The immune system builds antibodies---an opposing protein that can kill the non-self cells. • Antibodies can cause foreign blood cells to stick together so they can be destroyedthe transfused blood cells stick together within our blood vessels. • can be fatal BIO 102 blood-cardiovascular HANDOUT

16. Another antigen found in blood is the Rh antigen--if you have it, your blood is classified as Rh positive. If you do not have this, your blood is classified as Rh negative. Blood Typing Tests • Based on the interaction between antigens and antibodies • performed with anti-sera which contain high concentrations of anti-A and anti-B antibodies • blood samples are mixed with each anti-sera BIO 102 blood-cardiovascular HANDOUT

17. if agglutination or clumping occurs with anti-A sera, you have type A blood anti-B sera, you have type B blood • if clumping occurs with both anti-A and anti-B, you have type AB blood • if no clumping occurs with either anti-A and anti-B sera, you have type O blood • antibodies you have in your body are opposite of your blood type BIO 102 blood-cardiovascular HANDOUT

18. Blood Typing BIO 102 blood-cardiovascular HANDOUT

19. Blood Disorders • Carbon monoxide poisoning: competes with oxygen • Anemia: reduction in oxygen-carrying capacity Types of Anemia • Iron deficiency anemia occurs when insufficient iron ingested so fewer hemoglobin molecules are available. • Aplastic anemia where bone marrow doesn’t produce enough stem cells • Hemorrhagic anemia is caused by extreme blood loss BIO 102 blood-cardiovascular HANDOUT

20. Pernicious Anemia body is unable to absorb vitamin B12 from the digestive tract. Thebody uses B12 to produce normal RBC. • Sickle cell Anemia: inherited disorder in which RBC become sickle or crescent shaped when oxygen concentration of blood is low. This shape doesn’t travel easily through blood vessels because the cells clump, get stuck in the vessels and cause a great deal of pain. • Sickle shaped cells can’t carry normal amount of oxygen. BIO 102 blood-cardiovascular HANDOUT

21. Polycythemia describes an abnormally high RBC count • thickness of blood increases and slows down flow of blood. • Treatment: • phlebotomy with return of plasma to dilute the blood • Drink a lot of water BIO 102 blood-cardiovascular HANDOUT

22. Leukemia is form of cancer with uncontrolled production of abnormal or immature WBC in bone marrow. This crowds out the production of normal WBC, RBC, and platelets. • Multiple myeloma: cancer where abnormal plasma cells in bone marrow increase production. These cells are important for the manufacture of antibodies. • Mononucleosis is a contagious infection of lymphocytes linked to the Epstein-Barr virus. • Spread by oral route; swollen spleen • Septicemia also called “blood poisoning”. It occurs when organisms invade the blood, overpower our body’s defenses and multiply rapidly in the blood. BIO 102 blood-cardiovascular HANDOUT

23. Thrombocytopenia is reduction in the number of platelets • Hemophilia: inherited condition caused by deficiency of one or more clotting factors (known as clotting factor VIII) • When a blood vessel is damaged, blood either clots very slowly or not at all BIO 102 blood-cardiovascular HANDOUT

24. The Cardiovascular System Blood Vessels Arterial system Structure: • Endothelium: thin inner layer of squamous epithelial cells • Middle: thick layer of smooth muscle woven with elastic connective tissue • outer layers: tough supportive layer of connective tissue, primarily collagen • anchors vessels to surrounding tissues and helps protect them from injury • Aneurysm: ballooning of the arterial wall • Endothelium of blood vessel becomes damaged and blood seeps through and accumulates between the middle and outer layers of the blood vessel BIO 102 blood-cardiovascular HANDOUT

25. The Cardiovascular System • Functions: • Arteries: carry blood away from heart • Need thicker muscular wall due to pressure of blood being pumped by aorta • Walls keep blood moving during diastole • Elastic walls stretch during systole and rebound during diastole thus pushing blood through arteries • Because blood pressure is less by the time blood has reached the arterioles (smallest arteries), they do not have the outermost layer of connective tissue and the muscular layer is thinner. BIO 102 blood-cardiovascular HANDOUT

26. Capillaries: thin walled blood vessels; branching design allows exchange of gases, nutrients, waste, and defensive cells between vessel and tissue • are one epithelial cell thick (have no muscle in their wall) • are so thin that blood cells can only pass through them in single file • Precapillary sphincter, a band of smooth muscle, is located where the arteriole meets the capillary and controls the blood flow to each capillary • vasoconstriction • vasodilation BIO 102 blood-cardiovascular HANDOUT

27. Venous system • Functions: carry blood to heart • Structure: veins: three layers, thin-walled • like the walls of arteries, the walls of veins consist of 3 layers of tissue. • Outer 2 layers are much thinner than arteries • veins have larger diameters (lumen) than arteries • pressure in veins is much lower than that in arteries which is why their walls are not as strong as arteries • Blood pressure lower in veins than in capillaries • veins can act as a blood volume reservoir BIO 102 blood-cardiovascular HANDOUT

28. larger diameter of veins allows them to stretch to accommodate large volumes of blood at low pressures • because veins can stretch, is more difficult for them to return blood to the heart against force of gravity • people who spend a lot of time on their feet may get varicose veins BIO 102 blood-cardiovascular HANDOUT

29. Factors which help veins to return blood to heart • Contraction of skeletal muscles • as we move and muscles contract and relax, they press against veins and help push blood to heart • the work of the skeletal muscles helps valves pump blood. Called a skeletal muscle pump • One-way valves—blood can only flow in one direction • Open passively to allow blood to move toward heart and close whenever blood flows backward BIO 102 blood-cardiovascular HANDOUT

30. Pressure changes associated with breathing • movements associated with breathing help pump blood. This is called a respiratory pump and helps to push blood from the abdomen to chest and to heart. • when we breathe, pressure changes in the thoracic and abdominal cavities • during inhalation, abdominal pressure increases and squeezes abdominal veins • simultaneously, pressure within the thoracic cavity decreases which dilates the thoracic veins and thus propels the blood. BIO 102 blood-cardiovascular HANDOUT

31. Lymphatic System----works closely with the circulatory system to maintain proper volume of blood and interstitial fluid; • Picks up substances in interstitial fluid that are too large to diffuse into capillaries • Lipid droplets absorbed during digestion • Invading organisms • Transports these to larger lymphatic vessels which return fluid to veins near heart • also functions in immune system • Structure: • Lymphatic vessels • Lymph BIO 102 blood-cardiovascular HANDOUT

32. The Heart Structure: composed of cardiac muscle enclosed by pericardium • Pericardium protects the heart, anchors it to surrounding structures, prevents it from overfilling with blood • Pericardial cavity separated from heart muscle; contains a tiny amount of fluid to allow heart and pericardium to glide smoothly every time heart contracts • Heart beat rate determined by the SA Node Sino-Atrial node BIO 102 blood-cardiovascular HANDOUT

33. The Heart • Layers: Epicardium: thin, outermost layer made up of epithelial and connective tissue • Myocardium: thick layer primarily of cardiac muscle • Endocardium: innermost layer of endothelial tissue resting on a layer of connective tissue; is continuous with the endothelium that lines blood vessels BIO 102 blood-cardiovascular HANDOUT

34. The Heart • 4 Chambers: two atrias, two ventricles • Atrias are on the top • Ventricles are the 2, more muscular chambers on the bottom • Septum, a muscular partition, separates the right and left sides of the heart BIO 102 blood-cardiovascular HANDOUT

35. The Heart • Valves: prevent blood from flowing backward • Two atrioventricular valves: tricuspid (right) and bicuspid (mitral--left) • Chordae tendinae: strands of connective tissue which connect to muscular extensions (papillary tendons or muscles) of ventricular wall • prevent the valves from being pushed backward • Two semilunar valves: pulmonary and aortic • Have 3 flaps BIO 102 blood-cardiovascular HANDOUT

36. Lung Lung BIO 102 blood-cardiovascular HANDOUT

37. Flow of blood through the heart: • Deoxygenated blood through the vena cava to the right atrium • Deoxygenated blood through the right atrioventricular valve to the right ventricle • Deoxygenated blood through the pulmonary semilunar valve to the pulmonary trunk and the lungs • Oxygenated blood through the pulmonary veins to the left atrium • Oxygenated blood through the left atrioventricular valve to the left ventricle BIO 102 blood-cardiovascular HANDOUT

38. Oxygenated blood through the aortic semilunar valve to the aorta Blood flow through the tissues: • Oxygenated blood through branching arteries and arterioles to the tissues • Oxygenated blood through the arterioles to capillaries • Deoxygenated blood from capillaries into venules and veins • Ultimately to the vena cava and into the right atrium BIO 102 blood-cardiovascular HANDOUT

39. Cardiac Anatomy Quiz BIO 102 blood-cardiovascular HANDOUT

40. Coronary arteries supply the heart muscle with blood (myocardium is too thick to be supplied with oxygen and nutrients by diffusion from blood passing through it) • Coronary arteries branch from the aorta as it leaves the heart and circle the heart’s surface • Cardiac veins bring the blood back to right atrium BIO 102 blood-cardiovascular HANDOUT

41. Cardiac cycle is a measure of blood pumped with each beat multiplied by number of heart beats per minute • Heart relaxes and all four chambers fill; blood is sucked in as heart muscle expands • Atrial contraction: more blood into the already filled ventricles • Ventricular contraction: blood is ejected into the aorta and pulmonary trunk • Systole refers to contraction • Relaxation of the entire heart = diastole BIO 102 blood-cardiovascular HANDOUT

42. Heart Sounds and Heart Valves • Lub-dub • Lub signals the closure of the 2 AV valves • Dub signals the aortic and pulmonary semilunar valves closing • Heart murmurs are created by obstructions blood encounters as it flows through heart BIO 102 blood-cardiovascular HANDOUT

43. Cardiac conduction system is a group of specialized cardiac muscle cells that initiate and distribute electrical impulses throughout heart • is responsible for the coordinated sequence of the cardiac cycle which spreads from atria to ventricles • Consists of: sinoatrial node, atrioventricular bundle and its 2 branches and Purkinje fibers BIO 102 blood-cardiovascular HANDOUT

44. Sinoatrial (SA) node • Provides the stimulus that starts the heartbeat • Is a small mass of cardiac muscle cells close to where the right atrium and the superior vena cava meet • Emits an electrical impulse that travels across both atria stimulating waves of contraction • Is called the cardiac pacemaker because it initiates the heartbeat • Atrioventricular (AV) node • Located between the atria and ventricles • Muscle fibers are smaller in diameter which causes a slight delay of the electrical impulse. This allows the atria time to contract and empty their blood into the ventricles before the ventricles contract BIO 102 blood-cardiovascular HANDOUT

45. Atrioventricular bundle: • Located in the septum between the 2 ventricles • These fibers branch and extend into Purkinje fibers, smaller fibers that carry the impulse to all cells in the ventricular myocardium • The impulse travels down the septum (to the lower part of the ventricles) and then spreads rapidly upward through the purkinje fibers, the lower part of the ventricles contract first and squeeze blood into the pulmonary trunk and the aorta. BIO 102 blood-cardiovascular HANDOUT

46. Electrocardiograms (EKG/ECG) We can track the electrical activity of the heart as weak electrical differences in voltage with an EKG • Place “leads” or electrodes at the chest, wrists and ankles • Three formations: • P wave: impulse across atria • QRS complex: spread of impulse down septum, around ventricles in Purkinje fibers (this occurs just as the ventricles start to contract) • T wave: end of electrical activity in ventricles BIO 102 blood-cardiovascular HANDOUT

47. Arrhythmias are an abnormal rhythm or rate of heartbeat • Some arrhythmias are common and not potentially dangerous • ventricular fibrillation is leading cause of cardiac death • Can treat with medication or “cardioversion” with an electric shock or artificial pacemakers BIO 102 blood-cardiovascular HANDOUT

48. Blood Pressure • Force that blood exerts on the wall of a blood vessel as a result of pumping action of heart • Definitions: “normal”: • Systolic pressure: highest pressure, pressure reached during ventricular contraction to eject blood from the heart • Diastolic pressure: lowest pressure, pressure when the ventricles relax • Arteries store energy generated during systole and during diastole they use that stored energy to supply blood to the tissues • Measurement: sphygmomanometer BIO 102 blood-cardiovascular HANDOUT

49. Hypertension: high blood pressure: • Definition • The silent killer • Risk factors: heredity, age, race, sex, obesity, high salt intake, smoking, sedentary lifestyle, stress, diabetes, heavy drinking • Hypotension: blood pressure too low so blood can’t be pushed throughout the body and back to the heart; generally thought of as reducing blood flow to the brain • Clinical signs: dizziness, fainting • Causes: orthostatic, severe burns, blood loss BIO 102 blood-cardiovascular HANDOUT

50. Regulation of the Cardiovascular System: Baroreceptors Baroreceptors: pressure receptors in aorta and carotid arteries which help maintain arterial blood pressure • Steps in mechanism: • Blood pressure rises, arterial vessels stretched • Signals sent to cardiovascular center in the brain • Heart signaled to lower heart rate and force of contraction • Cardiac output (amount of blood and rate that the heart pumps into the aorta) lowered • Arterioles vasodilate (increasing arteriole diameter) and thus increasing blood flow to tissues • Combined effect lowers blood pressure The opposite happens when blood pressure is too low BIO 102 blood-cardiovascular HANDOUT