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Copyright Notice! This PowerPoint slide set is copyrighted by Ross Koning and is thereby preserved for all to use from plantphys.info for as long as that website is available. Images lacking photo credits are mine and, as long as you are engaged in non-profit educational missions, you have my permission to use my images and slides in your teaching. However, please notice that some of the images in these slides have an associated URL photo credit to provide you with the location of their original source within internet cyberspace. Those images may have separate copyright protection. If you are seeking permission for use of those images, you need to consult the original sources for such permission; they are NOT mine to give you permission. Blood movement within the four-chambered heart of vertebrates return from body …to lung semilunar valve tricuspid valve …from lung semilunar valve mitral valve Note: arteries take blood away from the heart…veins return to heart The difference is NOT about whether the blood is oxygenated or not! ©1996 Norton Presentation Maker, W. W. Norton & Company …to body 2 Atria contract: ventricles filled, valves close ©1996 Norton Presentation Maker, W. W. Norton & Company Heart relaxes: atria filled by 1 system pressure 3 LUB DUB!! Ventricles contract: blood sent to lungs and body 4 Heart relaxes: system pressure closes valves atrial contraction “LUB” and Purkinje fibers ventricular contraction ©1996 Norton Presentation Maker, W. W. Norton & Company initial instrinsic stimulus from “pacemaker” “DUB” Frog Lab Exercise: neural and intrinsic control The sounds are the slamming of valves…contraction is silent! ventricular depolarization ventricular release atrial depolarization ventricle relaxation ventricle filling In abnormal heart behavior, this recording may reveal where trouble spots exist within the heart’s electrical controls. Blood Pressure (mm Hg) Electrical Potential (mV) An electrocardiogram (EKG): the electrical changes recorded from electrodes attached to the skin reveal the electrical activity of the heart. See Fig 45.25 pg 922 Comparative structure of blood vessels High Pressure Exchange Low Pressure Which of these has the greatest surface to volume ratio? ©1996 Norton Presentation Maker, W. W. Norton & Company See Fig 45.20 pg 918 smooth muscle no valves vein less smooth muscle valves significant ©1996 Norton Presentation Maker, W. W. Norton & Company artery ©1996 Norton Presentation Maker, W. W. Norton & Company Veins in valves: “check valves” prevent back flow during heart cycles: Pressure Pulse Pressure Subsides Valves prevent backflow abnormal valve during atrial contraction “varicose veins” blood flow no flow thrombus ©1996 Norton Presentation Maker, W. W. Norton & Company Blood clotting (thrombosis) in a veinule A thrombus that breaks free and moves through the rest of the circulation system is called a thromboembolus and can lodge in other areas of the body resulting in pulmonary (lung) embolism, stroke (brain), or myocardial (heart) infarction. Atheroschloersis: “hardening of the arteries” Normal artiole Arteriole occluded with fatty plaque plaque Blood flow will be restricted, oxygenation will be reduced. Even a small group of cells could completely cut off the flow (myocardial infarction). ©1996 Norton Presentation Maker, W. W. Norton & Company Blood pressure varies with distance from heart aorta BP is usually arteries measured in systolic pressure the radial artery arterioles 100 40 20 veinules 60 diastolic pressure When a sphygmomanometer gives a result of 120/80 mm Hg, it is interpreted as close to normal for men. capillaries Blood pressure (mm Hg) 120 80 See Fig 45.27 pg 923 veins vena cava 0 Distance traveled by blood from left ventricle Vena cava Veins Arterioles Capillaries Venules Arteries 50- -5,000 40- -4,000 30- -3,000 20- -2,000 10- -1,000 Cross-sectional Area (cm2) Velocity (cm/sec) Aorta Flow rate in blood vessels in a circulation system Distance travelled by blood from left ventricle Branching explains why you don’t get the “thumb on the hose nozzle” effect Human capillaries are only wide enough for one RBC to pass ©1996 Norton Presentation Maker, W. W. Norton & Company Frog foot webbing capillaries come close to each body cell ©1996 Norton Presentation Maker, W. W. Norton & Company Capillary walls are a single endothelial cell joined at edges pinocytosis (vesicular transport) brings materials through capillary wall ©1996 Norton Presentation Maker, W. W. Norton & Company Red Blood Cells (erythrocytes) and White Blood Cells Figure 44.11 page 985 Figure 44.15 page 989 Oxygen is bound to hemoglobin at the chelation site of iron (Fe) in heme: H3C C HC H3C C H2C C COOH C CH C C N C N CH2 CH2 HC O=O Fe C C N C C C C CH2 CH3 CH2 CH3 C CH N C HC C CH CH2 notice the resonating bond system to help trap the oxygen molecule in large electron cloud COOH Iron is a macroelement for vertebrates! Gas exchanges at the blood-tissue interface CO2 tissue cell cytosol CO2 CO2 + H2O O2 HCO3- + H+ capillary plasma red blood cell CO2 + H2O HCO3- + H+ H+ + HbO2 CO2 + HbO2 HbCO2 + O2 HHb + O2 circulation direction CO2 CO2 HbO2 CO2 HbO2 H2O HbO2 H2O H2O HbO2 lungs HCO - H+ 3 O2 HHb HCO3O2 O2 CO2 HHb HCO3- HbO2 H+ HCO 3 - tissues HHb HCO3O2 O2 Percent saturation of Hb with O2 Dissociation curves for hemoglobin explain oxygen exchange 100 Unloading to tissues at normal pH circulation 80 60 Normal blood pH 40 20 Exercise Rest 0 0 Lungs 20 40 60 80 100 120 Oxygen partial pressure (mm Hg) Percent saturation of Hb with O2 Dissociation curves for hemoglobin explain oxygen exchange 100 Unloading to tissues at normal pH circulation 80 60 Normal blood pH 40 Oxygen unloaded at low pH (high CO2) Low blood pH 20 Exercise Rest 0 0 Lungs 20 40 60 80 100 120 Oxygen partial pressure (mm Hg) Percent saturation of Hb with O2 A placental mammal fetus has fetal hemoglobin with higher affinity for oxygen than the mother’s hemoglobin in the placenta 100 Unloading to fetal tissues 80 transfer of oxygen from maternal to fetal hemoglobin in the placenta 60 40 20 0 Fetus Mother 0 20 40 60 80 100 Oxygen partial pressure (mm Hg) Myoglobin in tissues has higher oxygen affinity than hemoglobin Human and Maternal/Fetal circulation capillary bed artery or vein? artery or vein? ©1996 Norton Presentation Maker, W. W. Norton & Company artery or vein? shunts away from lungs artery or vein? arterioles veinules artery capillary bed Note: What kind of circulation is shown in placenta? The mammal body tissues possess myoglobin, which has an even higher affinity for oxygen: Percent saturation of Hb with O2 See Fig 45.17 pg. 915 Unloading to fetal tissue myoglobin 100 80 transfer of oxygen from maternal to fetal hemoglobin in the placenta 60 Fetus 40 20 0 Mother 0 20 40 60 80 100 Oxygen partial pressure (mm Hg) Myoglobin in tissues has higher oxygen affinity than hemoglobin gas exchange muscular pump glucose control nitrogenous waste gas exchange nutrient exchange blood cell replacement absorbing nutrients ©1996 Norton Presentation Maker, W. W. Norton & Company Circulation system in mammal (Homo sapiens)