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Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system - system of internal transport Q. What needs to be transported? - oxygen, RBC’s - carbon dioxide - nutrients - waste products of metabolism (CO2 to lungs, urea and other waste to kidneys) - hormones - body defense substances like antibodies and WBC - temp. regulation (heat transfer) Q. When would an organism not need a CS? When every cell is in contact with the outside world and get what it needs (nutrients, etc…) and can get rid of waste. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 1. must reach EVERY cell a. capillaries - tiny blood vessels - within a few cells of every cell - Site of diffusion; one cell width in diameter b. interstitial fluid - “pond” b/w capillaries and tissue cells Nutrients and wastes diffusing between the capillaries (top), interstitial fluid (blue) and tissue cells (bottom). Fig. 23.1B Fig. 23.1A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 2. Many animals do not have a true circulatory system a. Porifera - Circulation achieved by flagellated collar cells circulating sea water through the pores up and out through the osculum. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 2. Many animals do not have a true circulatory system a. Cnidaria Use GV cavity as “circulatory system” Fig. 23.2A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 2. Many animals do not have a true circulatory system a. Cnidaria b. Platyhelminthes (phylum) Planaria - tiny (3-12mm) freshwater flat worm Use GV cavity as “circulatory system” Fig. 23.2A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved a. Open circulatory system Fig. 23.2B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved a. Open circulatory system i. many invertebrates - mollusks (phylum containing snails, clams, squids etc…) - arthropods ii. open ended vessels iii. blood and interstitial fluid are the same Fig. 23.2B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved a. Open circulatory system i. many invertebrates - mollusks (phylum containing snails, clams, squids etc…) - arthropods ii. open ended vessels iii. blood and interstitial fluid are the same – called hemolymph iv. grasshopper Hemolymph is moved toward the abdomen/tail end by rhythmic muscle contractions and enters the pores of tubular heart. Pores have a one way valve so hemolymph cannot flow back into body cavity, but is forced through open-ended tubes to maintain circulation when hearts Fig. 23.2B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved a. Open circulatory system i. many invertebrates - mollusks (phylum containing snails, clams, squids etc…) - arthropods ii. open ended vessels iii. blood and interstitial fluid are the same – called hemolymph iv. grasshopper Reminder, circulatory system NOT used for transport of gases (O2, CO2) as tracheal system will do this. Fig. 23.2B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved a. Open circulatory system i. many invertebrates - mollusks (phylum containing snails, clams, squids etc…) - arthropods ii. open ended vessels iii. blood and interstitial fluid are the same – called hemolymph iv. grasshopper It is much like a fish tank where the tubular hearts would be like the filter in that is sucks water from the tank and puts it back in. The tank would be the body cavity. Fig. 23.2B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved a. Open circulatory system i. many invertebrates - mollusks (phylum containing snails, clams, squids etc…) - arthropods ii. open ended vessels iii. blood and interstitial fluid are the same – called hemolymph iv. grasshopper **Compare efficiency of this type of circulatory system to a closed circulatory system like outs where blood is maintained in vessels. Less efficient as oxygen, nutrients and waste products like CO2 are constantly mixed in the coelum (body cavity) Fig. 23.2B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved b. Closed circulatory system (cardiovascular system) i. Blood confined to vessels ii. Three types of vessels - arteries - veins - capillaries iii. Earthworm (Annelida) - aortic arches “heart” - dorsal/ventral vessels - Peristalsis moves blood through vessels in combination with hearts pumping Fig. 23.2C Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved b. Closed circulatory system (cardiovascular system) i. Blood confined to vessels ii. Three types of vessels - arteries - veins - capillaries iii. Earthworm (Annelida) - aortic arches “heart” - dorsal/ventral vessels - Peristalsis moves blood through vessels in combination with hearts pumping The dorsal blood vessels are responsible for carrying blood to the front of the earthworm’s body. The ventral blood vessels are responsible for carrying blood to the back of the earthworm’s body. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved b. Closed circulatory system (cardiovascular system) i. Blood confined to vessels ii. Three types of vessels - arteries - veins - capillaries iii. Fish - two chamber heart - follow the path of blood Fig. 23.2C Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved b. Closed circulatory system (cardiovascular system) i. Blood confined to vessels ii. Three types of vessels - arteries - veins - capillaries iii. Fish - two chamber heart - follow the path of blood Fig. 23.2C Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved c. Compare the CVS of fish and mammals i. Fish - single circuit - heart sees only oxygen poor blood - blood helped along by movement Fig. 23.3 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved c. Compare the CVS of fish and mammals Fig. 23.3 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved c. Compare the CVS of fish and mammals ii. Mammals (and birds) - two pumps in one - 4 chamber heart - dual circuit (pulmonary and systemic) - right side O2 poor, left side O2 rich - Compare flow rate - Follow flow path Q. Why do endotherms need a greater flow rate? Fig. 23.3 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? Circulatory system 3. Two basic true circulatory systems have evolved d. Mammals and birds evolved not from fish, but from reptiles. Hypothesize the number of chambers in a reptilian heart? iii. Amphibians and some reptiles - Have a three chambered heart (2 atria and one ventricle) where blood mixes in the ventricle and is sent to the pulmonary and systemic circuits. Less efficient than birds and mammals. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 1. Heart a. Size? b. location? c. composition? - compare walls of atria to those of ventricles. d. Explain the purpose of valves Alternative valve names Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 2. Follow the flow a. Start at RV b. RV to R,L pulmonary artery through semilunar valve c. R,L PA to lungs - O2 and CO2 exchange in lung cap. d. Lungs to LA via pulm. veins e. LA to LV through AV valve f. LV to aorta through SL valve Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 2. Follow the flow a. Start at RV b. RV to R,L pulmonary artery through semilunar valve c. R,L PA to lungs - O2 and CO2 exchange in lung cap. d. Lungs to LA via pulm. veins e. LA to LV through AV valve f. LV to aorta through SL valve g. Arteries branch off aorta north to head and arms h. Aorta heads south where arteries branch to abdominal organs an legs Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 2. Follow the flow a. Start at RV b. RV to R,L pulmonary artery through semilunar valve c. R,L PA to lungs - O2 and CO2 exchange in lung cap. d. Lungs to LA via pulm. veins e. LA to LV through AV valve f. LV to aorta through SL valve g. Arteries branch off aorta north to head and arms h. Aorta heads south where arteries branch to abdominal organs an legs Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 2. Follow the flow (exchange O2/CO2/nutrients/etc..) i. Arteries -> Arterioles -> Capillary beds -> Venules -> Veins j. Upper body veins drain into superior vena cava k. Lower body to inferior vena cava l. SVC and IFC empty into RA Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 2. Follow the flow (exchange O2/CO2/nutrients/etc..) i. Arteries -> Arterioles -> Capillary beds -> Venules -> Veins j. Upper body veins drain into superior vena cava k. Lower body to inferior vena cava l. SVC and IFC empty into RA Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 2. Follow the flow (exchange O2/CO2/nutrients/etc..) i. Arteries -> Arterioles -> Capillary beds -> Venules -> Veins j. Upper body veins drain into superior vena cava k. Lower body to inferior vena cava l. SVC and IVC empty into RA m. RA to RV through AV valve Q. Explain why the wall of the LV is thicker than that of the RV? Fig. 23.4 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT (loose connective tissue) iii. smooth inner surface Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries - outer layer of elastic conn. tissue Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries - outer layer of elastic conn. tissue Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries - Needs to be thicker as they receive high pressure blood from the heart. http://ebsco.smartimagebase.com/generateexhibit.php?ID=14555&TC=&A=1189 Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries - outer layer of elastic conn. tissue to recoil after expanding c. Many veins have valves to maintain unidirectional flow http://ebsco.smartimagebase.com/generateexhibit.php?ID=14555&TC=&A=1189 Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries - outer layer of elastic conn. tissue c. Many veins have valves http://ebsco.smartimagebase.com/generateexhibit.php?ID=14555&TC=&A=1189 Fig. 23.9B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 3. Structure-function of blood vessels a. capillaries i. thin walls ii. simple squamous wrapped in LCT iii. smooth inner surface b. Arteries and veins i. thicker walls - same epithelium - layer of smooth muscle - thicker in arteries - outer layer of elastic conn. tissue c. Many veins have valves http://ebsco.smartimagebase.com/generateexhibit.php?ID=14555&TC=&A=1189 Fig. 23.5 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 4. Rhythmic Heart Contraction a. Cardiac cycle i Complete sequence of filling and pumping heart ii. Two phases - diastolic - heart at rest - AV valves open - SL valves closed - all chambers fill with blood http://library.med.utah.edu/kw/pharm/hyper_heart1.html Fig. 23.6 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? http://library.med.utah.edu/kw/pharm/hyper_heart1.html The Human Circulatory System Fig. 23.6 4. Rhythmic Heart Contraction a. Cardiac cycle i Complete sequence of filling and pumping heart ii. Two phases - systolic - atria contract “dub” - ventricles fill-up - ventricles contract - AV valves slam shut (“lub”) - SL valves open - blood enters atria “lub” - SL valves close (“dub”) b. Heart murmur - Occurs when a valve leaks a bit, you can hear a faint ”swish” with a stethoscope. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 5. Keeping the Rhythm a. Sinoatrial node (SA) node - heart’s natural pacemaker - generates an electrical signal - travels through atria to AV node - Called Perkinje fibers Fig. 23.7 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 5. Keeping the Rhythm b. Atrioventricular (AV) node - .1 sec delay after receiving signal - sends new electrical signal to ventricles - ventricles contract Fig. 23.7 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 5. Keeping the Rhythm * Conclusion: heart will beat if removed from body all by itself (Indiana Jones and the temple of doom), but it will be faster than normal. The brain has control over the rate at which it beats. Fig. 23.7 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 5. Keeping the Rhythm b. Electrocardiogram (ECG) - electrical signal of heart generates electrical signal in skin Fig. 23.7 Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 5. Keeping the Rhythm b. Electrocardiogram (ECG) - electrical signal of heart generates electrical signal in skin Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 6. Failure of the heart’s pacemaker a. Artificial pacemaker - tiny electronic device inserted near AV node to control heart rate Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 7. Cardiovascular Disease Atherosclerosis a. Chronic CV disease - plaques develop on inner walls of arteries due to diet/genetics - blood clots that formed elsewhere in the system and break off can get trapped (thromboembolism – blood clot breaks and gets stuck in another part of the circulatory system like heart/brain.) - These are also sites of irregular blood clot formation that can lead to a thromboembolism of the heart (heart attack) or brain (stroke). b. Leading cause of heart attack and stroke Fig. 23.8B Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 7. Cardiovascular Disease Heart Attack a. Coronary arteries - blockage - 1/3rd die immediately - survivors have impaired ability to pump blood; cardiac muscle does not regenerate and is replaced with inelastic scar tissue. - leading cause of death in US http://www.healthcentral.com/cholesterol/understanding-cholesterol-13-115.html Fig. 23.8A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 7. Cardiovascular Disease Stroke a. Rapid loss of brain function - caused by disturbance in blood vessels in brain – either a blockage or a burst. Aneurysm – swelling of a blood vessel caused by weakening of the vessel walls. The larger the aneurysm the more likely it will burst. - Neurons being serviced by this vessels die; neurons do not regenerate. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 7. Cardiovascular Disease Atherosclerosis c. Treatment - drugs to lower cholesterol - angioplasty Insert a device containing a balloon on the end and inflate the balloon thereby pushing the plaque out of the way. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 7. Cardiovascular Disease Atherosclerosis c. Treatment - drugs to lower cholesterol - angioplasty - stenting Perform the angioplasty with an expandable mesh that will be left in place to hold the vessel open and keep the plaque out of the way. Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 7. Cardiovascular Disease Atherosclerosis c. Treatment - drugs to lower cholesterol - angioplasty - stenting - coronary bypass Run a vein from the leg between aorta or some other local artery to a point past the blockage assuring blood flow to the downstream region. How can you minimize your risk of CV disease? Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 8. Blood Pressure a. Force exerted on walls of blood vessels - keeps blood moving through system – heart pumps blood into arteries and arteries will swell and rebound aiding in the movement of the blood. - pulse b. Two different pressures - systolic pressure - diastolic pressure c. What determines blood pressure? - cardiac output - resistance to blood flow imposed by narrow opening of arterioles - friction in capillaries - Clogged arteries Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure a. Measure pressure on arterial walls b. Average “normal” blood pressure 120/80 What do these numbers mean? Blood pressure is measured with a sphygmomanometer and a stethoscope. When the cuff is inflated, it will cut off blood flow to the arm as shown. Sphygmomanometer – blood pressure cuff used to measure blood pressure Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure a. Measure pressure on arterial walls b. Average “normal” blood pressure 120/80 What do these numbers mean? The medical worker will slowly decrease the pressure in the cuff… Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure a. Measure pressure on arterial walls b. Average “normal” blood pressure 120/80 What do these numbers mean? When the pressure in the cuff falls below the pressure exerted by the heart on the arteries when it pumps, blood will move past the cuff and be heard. This is the systolic pressure as it is the pressure exerted during the systolic (pumping) phase of the cardiac cycle = 120mm Hg in this case. Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure a. Measure pressure on arterial walls b. Average “normal” blood pressure 120/80 What do these numbers mean? Nothing is heard when the heart is not beating (diastolic phase of the cardiac cycle) since the pressure in the arteries is lower. Therefore it is only heard when the heart beats at this time. Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure a. Measure pressure on arterial walls b. Average “normal” blood pressure 120/80 What do these numbers mean? The pressure in the cuff will be lowered even further until blood flow is no longer heard indicating a smooth, continuous flow of blood = the diastolic or resting pressure (80mm Hg in this case). Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure a. Measure pressure on arterial walls b. Average “normal” blood pressure What do these numbers mean? 120/80 Top number is systolic pressure. Bottom number is diastolic pressure. Fig. 23.9A Chapter 23: Circulation NEW AIM: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure c. Hypertension i. High blood pressure - persistent systolic pressure > 140 and/or - diastolic pressure > 90 ii. Affects 25% of population iii. “silent killer” - weakens heart and blood vessels - heart failure, heart attack, stroke, kidney failure, vision loss - promotes plaque formation iv. Risk factors - age, race, family history, excess weight, inactivity, Tobacco use, excessive alcohol, stress, sleep apnea, etc… Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 9. Measuring Blood Pressure c. Hypertension v. How can we control hypertension? - diet - exercise - avoid excess alcohol - avoid smoking - Medication to lower the pressure Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 10. How does our body regulate blood pressure and blood distribution? a. Constrict smooth muscles in arterioles leading to capillaries (vasoconstriction) b. Constrict smooth muscles within capillary beds Predict what would happen in blood capillary beds of the digestive tract before and after eating. Fig. 23.11 Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 10. How does our body regulate blood pressure and blood distribution? a. Constrict smooth muscles in arterioles leading to capillaries (vasoconstriction) b. Constrict smooth muscles within capillary beds After eating, the sphincter muscles leading to the capillaries of the jejunum would relax allowing maximum blood to enter the jejunum so as to pick up the maximum amount of nutrients. Fig. 23.11 Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 11. How are substances transferred through capillary walls? a. Simple of Facilitated Diffusion through membranes - Small solutes (O2, CO2, monomers, etc…) b. Endocytosis/Exocytosis - larger substances – endocytose on inside and exocytose to interstitial fluid Fig. 23.12A Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 11. How are substances transferred through capillary walls? c. Leakage – capillaries are leaking as the cells they are made of are not tightly attached to each other. Therefore, substances smaller than cells can diffuse (passive) out of the blood directly into the interstitial fluid without going through a cell. Also, the pressure exerted by the heart/arteries recoiling can push (active) these substances out between the cells as well. Fig. 23.12B Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 12. What exactly is…blood? a. How much blood in an average human? 4 to 6 L (1 to 1.5 gallons) b. Two main components Fig. 23.12B Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 12. What exactly is…blood? a. How much blood in an average human? 4 to 6 L (1 to 1.5 gallons) b. Two main components 90% Fig. 23.12B albumin Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 12. What exactly is…blood? a. How much blood in an average human? 4 to 6 L (1 to 1.5 gallons) b. Two main components Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) a. RBC = erythrocytes (Gr erythros, red) b. 25 to 50 billion in blood c. Describe their shape (structure)? - small biconcave disks - no nuclei - no mitochondria ??? d. How does this structure fit its function? - large surface area for O2 diffusion - pack 250 million hemoglobins per cell, no nucleus to take up space, no mitochondria to use up oxygen being carried. These cells have no reason to divide or make new protein. This is all being done in the bone marrow. Fig. 23.14 Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) e. Site of production? i. Bone marrow of large bones pelvis, sternum, ribs, vertebrae, ends of upper humerus and femur ii. Predict how RBC production is regulated - erythropoietin (EPO) EPO is a glycoprotein hormone secreted by the kidneys when blood oxygen levels are low, which signals hematopoetic stems cells in the bone marrow to undergo mitosis and make more RBC’s Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) e. Site of production? i. Bone marrow of large bones pelvis, sternum, ribs, vertebrae, ends of upper humerus and femur ii. Predict how RBC production is regulated - erythropoietin (EPO) EPO is used as an illegal “performance-enhancing drug”. The athlete will have more RBC’s circulating and will therefore carry more oxygen to muscle cells for cell respiration thereby generating more ATP – dangerous as blood thickens and can cause heart failure and death. Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) f. Life span of an RBC i. 120 days (3-4 months) ii. Broken down and recycled by spleen and liver – only the heme is discarded as bilirubin – secreted with bile by the liver (the iron is saved and recycled) iii. At what rate are they dying and being replaced? ~2,000,000 per second Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) g. anemia i. A qualitative or quantitative deficiency of hemoglobin - reduced oxygen carrying capacity ii. SOME Causes - excessive blood loss - sickle cell anemia (genetic) - Vitamin/mineral deficiency 1. pernicious anemia - Casued by an impaired absorption of vitamin B-12 by intestines, which is needed to make thymine (nitrogenous base of DNA nucleotides). Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) g. anemia i. A qualitative or quantitative deficiency of hemoglobin - reduced oxygen carrying capacity ii. SOME Causes - excessive blood loss - sickle cell anemia (genetic) - Vitamin/mineral deficiency - pernicious anemia - impaired absorption of vitamin B-12 by intestines - therefore DNA replication is inhibited resulting in the inhibition of mitosis resulting in fewer, larger RBC’s made Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 13. Structure-function of the Red Blood Cell (RBC) g. anemia i. A qualitative or quantitative deficiency of hemoglobin - reduced oxygen carrying capacity ii. SOME Causes - excessive blood loss - sickle cell anemia (genetic) - Vitamin/mineral deficiency 1. pernicious anemia - impaired absorption of vitamin B-12 by intestines - needed for thymine biosynthesis No iron, no carrying 2. iron deficiency (most common cause) O2 by hemoglobin - especially women due to blood loss during menstration Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 14. What about those White Blood Cells (WBC’s)? a. White blood cell = leukocyte (Gr leukos, white) i. Help defend the body - fight infections (pathogens) - prevent cancer ii. Five major types Function of each will be discussed with the immune system. Just now the types for now. Fig. 23.15 Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 14. What about those White Blood Cells (WBC’s)? a. White blood cell = leukocyte (Gr leukos, white) i. Help defend the body - fight infections (pathogens) - prevent cancer ii. Five major types iii. Where would you predict they spend most of their time? - interstitial fluid - lymphatic tissue Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System The Lymph System 12. What about those White Blood Cells (WBC’s)? Substances like water, salts, etc… that a. White blood cell = leukocyte (Gr leukos, white) diffuse or are pushed out at the capillary beds need to reenter the blood i. Help defend the body stream. This is accomplished by the - fight infections (pathogens) lymphatic system. - prevent cancer ii. Five major types iii. Where would you predict they spend most of their time? - interstitial fluid - lymphatic tissue Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System The Lymph System 12. What about those White Blood Cells (WBC’s)? The fluid entering the lymphatic system is a. White blood cell = leukocyte (Gr leukos, white) now called lymph and will enter at lymphatic capillaries. On its way back to i. Help defend the body the blood stream it will pass through - fight infections (pathogens) lymph nodes that contain lots of WBCs, - prevent cancer which will destroy any foreign items in the lymph like bacteria and viruses. The ii. Five major types iii. Where would you predict they - interstitial fluid - lymphatic tissue lymph will enter back into the circulatory vena cava. spendsystem most at of the their time? Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Lymph System Know the various lymph system organs. Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 14. What about those White Blood Cells (WBC’s)? a. White blood cell = leukocyte (Gr leukos, white) i. Help defend the body - fight infections (pathogens) - prevent cancer ii. Five major types (already discussed) iii. Where would you predict they spend most of their time? - interstitial fluid in tissues - lymphatic tissue iv. Predict where they are produced. - Same place as the RBC’s…bone marrow – all blood cells are made in the bone marrow. Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 15. What happens when you bust a blood vessel? a. Blood clotting (coagulation) i. plugging the leaks ii. The Glue - platelets - fibrin iii. Coagulation cascade - clotting factors - mostly proteases in your blood already, in an inactive form (made by liver cells) – why? Clotting needs to be fast, you can’t wait for the proteins to be made/secreted, and they obviously need to be inactive (proenzymes) until needed… Fig. 23.16 Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 15. What happens when you bust a blood vessel? a. Blood clotting (coagulation) i. plugging the leaks ii. The Glue - platelets - fibrin iii. Coagulation cascade - clotting factors - mostly proteases in your blood already, in an inactive form (made by liver cells) – why? iv. cofactors - Ca++ - Vitamin K (made by intestinal bacteria) A blood clot = a thrombus Fig. 23.16 Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 15. What happens when you bust a blood vessel? b. Hemophilia i. group of genetic disorders that impair body's ability to control blood clotting. - Hemophilia A - most common form - lack of Factor VIII - Hemophilia B - lack of Factor IX - Hemophilia C - lack of Factor XI Why is hemophilia more common in males? - Sex-linked, genes for factors are on the X chromosome Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 15. What happens when you bust a blood vessel? c. Thrombosis i. Formation of a thrombus (blood clot) within a blood vessel. -Causes * The composition of the blood (hypercoagulability) * Quality of the vessel wall (endothelial cell injury) * Nature of the blood flow - obstructs blood flow - Thromboembolism Thrombus = blood clot Embolism = when an object migrates from one part of body and causes blockage of a blood vessel in another part. Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 16. Leukemia a. Cancer of white blood cells b. Occurs in bone marrow i. displaces normal bone marrow cells - reduced RBC’s and platelets - anemia and impaired clotting - normal WBC’s suppressed or dysfunctional - suppressed immune system c. Fatal if not treated i. Radiation and chemotherapy ii. Bone marrow transplant iii. Stem cell treatment Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 17. Fetal Blood Flow a. Maternal blood supplies fetus with nutrients and O2 and takes away fetal waste. This happens by diffusion through the placenta. b. Compare hemoglobin in the fetus to hemoglobin in the mother. Recall that hemoglobin is an example of quartanary structure, and is composed of four polypeptide chains: 2 α and 2 β in us, and 2 α and 2 δ in a fetus. Why would a fetus need a different form of hemoglobin than the mother? It is all about affinity for oxygen. Fetal hemoglobin has a higher affinity. If it didn’t, the oxygen would not move from mom to fetus. The fetus also has 50% more hemoglobin in its blood. The delta (δ) gene is turned off in you and I, while the β gene is turned on. Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 17. Fetal Blood Flow c. Fetal circulation - Umbilical vein (because it is moving towards the heart) is carrying oxygen/nutrient rich blood to the fetus. - Follow the blood flow in the diagram: 1. Umbilical vein 2. Through liver to inferior vena cava 3. To right atrium of heart Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 17. Fetal Blood Flow c. Fetal circulation - The fetal heart has a hole (foramen ovale) between the atria…why? - Normally, the blood goes from RA to RV and to lungs, but fetal lungs are nonfunctional and do not need as much blood. - Much of the blood flows into the LA, bypassing the lungs so that it can get to the cells in the rest of the body more quickly and efficiently!! - The foramen ovale closes up at birth. Chapter 23: Circulation NEW: How have different organisms evolved to perform circulation? The Human Circulatory System 17. Fetal Blood Flow c. Fetal circulation - Just another image of fetal circulation
