Deck 34: Circulation and Gas Exchange

A) apolipoproteins.
B) immunoglobulins.
C) erythropoietin.
D) epinephrine.
E) platelets.

A) an open circulatory system.
B) a closed circulatory system.
C) a gastrovascular cavity.
D) branched tracheae.
E) hemolymph.

A) one capillary bed.
B) two capillary beds.
C) three capillary beds.
D) four capillary beds.
E) five capillary beds.

A) 4.2 L/minute.
B) 4.2 mL/minute.
C) 0.42 L/minute.
D) 42 L/minute.
E) 420 L/minute.

A) left ventricle → aorta → lungs → systemic circulation
B) right ventricle → pulmonary vein → pulmocutaneous circulation
C) pulmonary vein → left atrium → left ventricle → pulmonary circuit
D) vena cava → right atrium → right ventricle → pulmonary circuit
E) right atrium → pulmonary artery → left atrium → ventricle

A) are the route by which blood flows from the atria to the ventricles.
B) are found only on the right side of the heart.
C) are the attachment sites where the pulmonary veins empty into the heart.
D) are able to prevent backflow of blood in the aorta and pulmonary arteries.
E) are at the places where the anterior and posterior venae cavae empty into the heart.

A) annelids
B) molluscs
C) fishes
D) frogs
E) insects

A) amphibians.
B) birds.
C) fishes.
D) mammals.
E) reptiles.

A) active transport to move oxygen into the salamander from the water.
B) facilitated diffusion to move oxygen into the salamander from the water.
C) facilitated diffusion of carbon dioxide from the salamander into the water.
D) simple diffusion of oxygen into the salamander from the water.
E) active transport of carbon dioxide from the salamander into the water.

A) fully oxygenated blood.
B) plasma in which carbon dioxide has been added.
C) a lining of endothelial cells.
D) circular smooth muscle cells that can alter the size of the arterioles.
E) white blood cells and platelets.

A) the arteries.
B) the arterioles.
C) the venules.
D) the capillaries.
E) the veins.

A) open circulatory system.
B) closed circulatory system.
C) lymphatic system.
D) two-chambered heart.
E) four-chambered heart.

A) 500 mL/minute.
B) 1,000 mL/minute.
C) 1,750 mL/minute.
D) 2,800 mL/minute.
E) 4,800 mL/minute.

A) because they are larger than reptiles and amphibians
B) because they use more energy than equivalent-sized reptiles and amphibians
C) because they have more viscous blood than reptiles and amphibians
D) because they cannot obtain as much oxygen from the air as reptiles and amphibians

A) temperature differences between the lungs and the active tissue.
B) the slow rate at which diffusion occurs over large distances.
C) the problem of communication systems involving only the nervous system.
D) the need to cushion animals from trauma.
E) the need fetal organisms have for maintaining an optimal body temperature.

A) is a major contributor to heart attacks.
B) would block conductance between the bundle branches and the Purkinje fibers.
C) would cause blood flow rate to increase.
D) would disrupt the rate and timing of cardiac muscle contractions.
E) would have a direct effect on blood pressure monitors in the aorta.

A) an increase in the amount of carbon dioxide moving from the blood to the lungs.
B) an increase in the amount of oxygen moving from the lungs into the blood.
C) a decrease in the amount of oxygen moving from the lungs into the blood.
D) an increase of pressure that would cause the capillary beds to burst.
E) a decrease in the amount of work needed for effective ventilation of the lungs.

A) the arteries.
B) the arterioles.
C) the venules.
D) the capillaries.
E) the veins.

A) the intracellular fluid.
B) the blood plasma.
C) the cytosol.
D) the hemolymph.

A) the capillary walls are not thin enough to allow oxygen to exchange with the cells.
B) the capillaries are far from the heart, and blood flow slows as distance from the heart increases.
C) the diastolic blood pressure is too low to deliver blood to the capillaries at a high flow rate.
D) the systemic capillaries are supplied by the left ventricle, which has a lower cardiac output than the right ventricle.
E) the total cross-sectional area of the capillaries is greater than the total cross-sectional area of the arteries or any other part of the circulatory system.

A) increased activity of the immune system.
B) a broken limb.
C) blood sugar that is abnormally high.
D) dehydration.
E) sodium depletion.

A) hemoglobin will not release oxygen.
B) fluids will tend to accumulate in tissues.
C) the pH of the interstitial fluids will increase.
D) most carbon dioxide will be bound to hemoglobin and carried away from tissues.
E) plasma proteins will escape through the endothelium of the capillaries.

A) even small changes in body weight may signify changes in blood volume and therefore blood pressure.
B) many people who have dialysis are diabetic and must control their weight carefully.
C) dialysis removes blood proteins, and these weigh more than other blood components.
D) dialysis is likely to cause edema, and such swelling must be controlled.
E) reclining posture during dialysis can cause a tendency for weight gain.

A) mouse
B) rabbit
C) human
D) hippopotamus
E) giraffe

A) aorta.
B) arteries.
C) arterioles.
D) capillaries.
E) superior vena cava.

A) measurement of fatty deposits on the endothelium of arteries.
B) measurement of the LDL/HDL ratio in peripheral blood.
C) percent of blood volume made up of platelets.
D) blood pressure being greater than 140 mm Hg systolic and/or >90 diastolic.
E) number of leukocytes per mm3 of blood.

A) lying down after standing up.
B) eating a meal.
C) stressed and secreting stress hormones.
D) responding to increased blood pressure.
E) having an allergy attack with lots of histamine secretion.

A) vasoconstriction.
B) vasodilation.
C) narrowing of the arteries.
D) a reduction in blood flow in that region.
E) a decreased amount of blood in the capillaries of that vascular bed.

A) 400 mm Hg.
B) 82 mm Hg.
C) 40 mm Hg.
D) 21 mm Hg.
E) 4 mm Hg.

A) an animal that is small and compact, without the need to pump blood very far from the heart.
B) an animal with abundant lipid storage.
C) a species that has very wide-diameter veins.
D) an animal that has a very long distance between its heart and its brain.
E) an animal that makes frequent, quick motions.

A) maintain the blood's osmotic pressure.
B) transport water-soluble lipids.
C) carry out gas exchange.
D) undergo aerobic metabolism.
E) transport oxygen.

A) loss of osmotic pressure in the capillaries.
B) development of an osmotic pressure difference across capillary walls.
C) loss of fluid from capillaries.
D) increased diffusion of CO₂.
E) increased diffusion of Hb.

A) more fluid entering the venous capillaries
B) an increase in the blood pressure in the capillary bed
C) the accumulation of more fluid in the interstitial areas
D) fewer proteins leaking out of the blood to enter the interstitial fluid
E) the area of the blockage becoming abnormally small

A) 24 hours.
B) 1 week.
C) 1 month.
D) 4 months.
E) 80 years or more.

A) stopping smoking
B) eating more trans fats
C) exercising more
D) taking statin drugs

A) growth hormone and pancreas, respectively.
B) erythropoietin and kidney, respectively.
C) cortisol and adrenal gland, respectively.
D) epinephrine and adrenal gland, respectively.
E) acetylcholine and bone marrow, respectively.

A) fibrinogen only
B) hemoglobin only
C) fibrinogen and immunoglobulin only
D) hemoglobin and immunoglobulin only
E) fibrinogen, hemoglobin, and immunoglobulin

A) low-density lipoproteins.
B) immunoglobulins.
C) erythropoietin.
D) epinephrine.
E) platelets.

A) epinephrine.
B) fibrin.
C) thrombin.
D) prothrombin.
E) collagen.

A) a decrease in its carbon dioxide content.
B) a decrease in its oxygen content.
C) an increase in its ability to sustain aerobic organisms.
D) a decrease in the water's density.
E) a decrease in the movement of the water molecules.

A) trachea.
B) larynx.
C) bronchi.
D) bronchioles.
E) alveoli.

A) erythropoietin levels in the blood.
B) the concentration of red blood cells.
C) hemoglobin levels in the blood.
D) CO₂ and O₂ concentration and pH-level sensors.
E) the lungs and the larynx.

A) the flow of water across the gills of a fish and that of blood within those gills.
B) the flow of blood in the dorsal vessel of an insect and that of air within its tracheae.
C) the flow of air within the primary bronchi of a human and that of blood within the pulmonary veins.
D) the flow of water across the skin of a frog and that of blood within the ventricle of its heart.
E) the flow of fluid out of the arterial end of a capillary and that of fluid back into the venous end of the same capillary.

A) the sudden change from the uterine environment to the air.
B) the overproduction of surfactants.
C) the incomplete development of the lung surface.
D) lung collapse due to inadequate production of surfactant.
E) mutations in the genes involved in lung formation.

A) the rib muscles and diaphragm contract, increasing the lung volume.
B) the volume of the alveoli increases as smooth muscles contract.
C) gas flows from a region of lower pressure to a region of higher pressure.
D) pulmonary muscles contract and pull on the outer surface of the lungs.
E) a positive respiratory pressure is created when the diaphragm relaxes.

A) 160 mm Hg.
B) 16 mm Hg.
C) 120/75.
D) 21/760.
E) 760/21.

A) the cerebrum and cerebellum.
B) the medulla oblongata and the pons.
C) the adrenal medulla and the adrenal cortex.
D) the thalamus and the hypothalamus.
E) the frontal lobe and the temporal lobe.

A) residual volume.
B) vital capacity.
C) tidal volume.
D) countercurrent exchange.

A) 5.9 mm Hg.
B) 59.2 mm Hg.
C) 76 mm Hg.
D) 160 mm Hg.
E) 592.8 mm Hg.

A) nitrogen.
B) oxygen.
C) carbon dioxide.
D) sodium.

A) water is less dense than air.
B) water contains much less O₂ than air per unit volume.
C) gills have less surface area than lungs.
D) gills allow only unidirectional transport.
E) gills collapse in air.

A) pH decreases, which causes breathing rate to increase.
B) pH decreases, which causes breathing rate to decrease.
C) pH increases, which causes breathing rate to increase.
D) pH increases, which causes breathing rate to decrease.

A) 0 mm Hg.
B) 80 mm Hg.
C) 160 mm Hg.
D) 380 mm Hg.
E) 760 mm Hg.

A) in their specialized external gills.
B) in their specialized internal gills.
C) in the alveoli of their lungs.
D) across the finest branches of the trachea and cell membranes.
E) across all parts of their thin exoskeleton.

A) coats their lungs.
B) blocks the openings into the tracheal system.
C) interferes with gas exchange across the capillaries.
D) clogs their bronchi.
E) prevents gases from leaving the atmosphere.

A) 100 mm Hg.
B) 127 mm Hg.
C) 151 mm Hg.
D) 182 mm Hg.
E) 219 mm Hg.

A) they are too large for a circulatory system to operate well.
B) they live without the need for oxygen.
C) they do not produce carbon dioxide.
D) countercurrent exchange mechanisms cannot function well in their living conditions.
E) nearly all of their cells are in direct contact with the external environment.

A) endocytosis.
B) blood pressure.
C) diffusion.
D) active transport.
E) osmosis.

A) a decrease in the volume of the thoracic cavity.
B) a decrease in the residual volume of the lungs.
C) the contraction of the diaphragm.
D) the closure of the mouth.
E) the expansion of the rib cage.

A) the brain directly measures and monitors carbon dioxide and causes breathing changes accordingly.
B) the medulla oblongata, which is in contact with cerebrospinal fluid, monitors pH and uses this measure to control breathing.
C) the brain alters the pH of the cerebrospinal fluid to force the animal to retain more or less carbon dioxide.
D) the lungs sense changes in oxygen concentration, which causes the medulla oblongata to speed up or slow breathing.
E) the medulla oblongata is able to control the concentration of bicarbonate ions in the blood.

A) animal had evolved from birds.
B) animal was endothermic and had a high metabolic rate.
C) animal was most closely related to alligators and crocodiles.
D) animal was likely an invertebrate animal.
E) species had little to no need to regulate blood pressure.

A) 1
B) 2
C) 3
D) 4

A) snake
B) frog
C) tiger
D) whale

A) the partial pressure of oxygen.
B) the partial pressure of carbon dioxide.
C) hemoglobin concentration.
D) temperature.
E) pH.

A) the amphibian equivalent of hypertension.
B) skin cancer.
C) gill abnormalities in the next generation of tadpoles.
D) tracheal tube abnormalities.
E) diminished absorption of oxygen.

A) 70%
B) 80%
C) 90%
D) 100%

A) A
B) B
C) C
D) D
E) E

A) are both found within blood cells.
B) are both red in color.
C) are both freely dissolved in the plasma.
D) both transport oxygen.
E) are both found in mammals.

A) A
B) B
C) C
D) D
E) E

A) hemoglobin.
B) bicarbonate ions.
C) carbonic acid.
D) actin and myosin.
E) myoglobin.

A) Bar-headed geese hemoglobin can bind more oxygen at higher altitudes than human hemoglobin.
B) Bar-headed geese hemoglobin can bind more oxygen at lower altitudes than human hemoglobin.
C) Bar-headed geese hemoglobin can bind more oxygen at higher temperatures than human hemoglobin.
D) Bar-headed geese hemoglobin can bind more oxygen at lower temperatures than human hemoglobin.

A) a slower rate of oxygen consumption so that its breathing will not have to be accelerated.
B) a decrease in myoglobin concentration in the muscles.
C) a relatively slow heart rate in order to lower oxygen consumption.
D) a lower pressure of oxygen in the alveoli.
E) a much higher rate of oxygen consumption for its size.

A) the oxygen dissociation curve for hemocyanin is linear.
B) hemocyanin carries more carbon dioxide.
C) hemocyanin has protein coupled to copper rather than iron.
D) the protein of hemocyanin is not bound to metal.
E) hemocyanin is bound to sodium ions.

A) hemoglobin to release all bound oxygen molecules.
B) an increase in the affinity of hemoglobin to bind oxygen molecules.
C) hemoglobin to denature.
D) an increase in the binding of H+ by hemoglobin.
E) hemoglobin to more readily give up its oxygen molecules.

A) hemoglobin.
B) plasma proteins.
C) carbon dioxide.
D) carbonic acid.

A) zero membranes-oxygen binds directly to hemoglobin, a protein dissolved in the plasma of the blood.
B) one membrane-that of the lining in the lungs-and then bind directly to hemoglobin, a protein dissolved in the plasma of the blood.
C) two membranes-in and out of the cell lining the lung-and then bind directly to hemoglobin, a protein dissolved in the plasma of the blood.
D) four membranes-in and out of the cell lining the lung and in and out of the endothelial cell lining an alveolar capillary-and then bind directly to hemoglobin, a protein dissolved in the plasma of the blood.
E) five membranes-in and out of the cell lining the lung, in and out of the endothelial cell lining an alveolar capillary, and into the red blood cell-to bind with hemoglobin.

A) converted to bicarbonate ions by an enzyme in red blood cells.
B) bound to hemoglobin.
C) transported in the erythrocytes as carbonic acid.
D) simply dissolved in the plasma.

A) 26 mm Hg
B) 53 mm Hg
C) 159 mm Hg
D) 254 mm Hg

A) More oxygen molecules will bind to hemoglobin.
B) Fewer oxygen molecules will bind to hemoglobin.
C) Carbon dioxide molecules will bind to hemoglobin instead of oxygen.
D) The number of oxygen molecules bound to hemoglobin will not change.