Deck 26: Oxygen, Carbon Dioxide, and Internal Transport at Work: Diving by Marine Mammals

A) 3 atm
B) 13 atm
C) 30 atm
D) 300 atm

A) short and shallow.
B) long and shallow.
C) very evenly distributed between short and shallow and long and deep dives.
D) long and deep.

A) Diving behavior of male and female northern elephant seals
B) Foraging behavior of male and female sperm whales
C) Migration movements of male and female northern elephant seals
D) Foraging movements of bottlenose dolphins

A) Elephant seal
B) Cuvier's beaked whale
C) Weddell seal
D) Northern fur seal

A) Northern fur seal
B) Weddell seal
C) Ribbon seal
D) Harbor seal

A) Individual dive depths from one seal over many days
B) Dive depths for many seals of one species over many days
C) Dive depths for one seal during one day
D) Dive depths for many seals of one species during one day

A) Northern fur seal
B) Ribbon seal
C) Elephant seal
D) Harbor seal

A) A voluntary versus a forced dive
B) A morning versus an evening dive
C) A foraging-related versus a defense-related dive
D) A short versus a long dive (relative to the maximum duration for the species)

A) O₂ bound to hemoglobin
B) O₂ bound to myoglobin
C) O₂ dissolved in body fluids other than lungs
D) O₂ contained in the lungs

A) A significant bradycardia occurs during a forced dive.
B) A significant bradycardia occurs during a voluntary dive.
C) Lactic acid increases primarily after a forced dive.
D) Lactic acid increases primarily after a voluntary dive.

A) It is absent during a forced dive.
B) It represents an adjustment to the pattern of blood flow that allows the dive to be extended.
C) It exists in all diving mammals.
D) It is strongly present during a voluntary dive.

A) oxygen-carrying capacity of the blood.
B) total volume of the blood.
C) circulatory rate.
D) oxygen-carrying capacity and the total volume of the blood.

A) four times greater than
B) 1.5 times greater than
C) similar to
D) 1.5 times less than

A) 4 times greater than
B) 2 times greater than
C) similar to
D) 2 times less than

A) Lungs
B) Blood
C) Myoglobin
D) Interstitial fluids

A) Oxygen-carrying capacity
B) Total oxygen stores
C) Mass-specific oxygen stores
D) Mass-specific metabolic rates

A) I
B) II
C) III
D) IV

A) the lungs.
B) the blood.
C) myoglobin.
D) dissolved O₂ in fluids other than blood.

A) 10 times greater than
B) 2 times greater than
C) similar to
D) 2 times less than

A) high
B) low
C) constant
D) zero

A) Large amounts of air in the lungs affect buoyancy.
B) Alveoli are typically the first components of the respiratory system to collapse.
C) A large store of O₂ also means a large store of N₂.
D) In compression-resistant thoraxes, it increases shallow dive time.

A) kidneys.
B) brain.
C) lungs.
D) skeletal muscle.

A) Brain
B) Limbs
C) Lungs
D) Heart

A) chronic tachycardia.
B) sinus bradycardia.
C) diving bradycardia.
D) diving tachycardia.

A) Heart rate
B) Stroke volume
C) Cardiac output
D) Heart rate and cardiac output

A) Stroke volume
B) Blood pressure
C) Overall resistance to blood flow
D) Stroke volume and blood pressure

A) In freely diving seals, diving heart rate varies with dive duration in a graded manner.
B) In freely diving seals, the degree of bradycardia is proportional to dive duration.
C) In forcibly submerged seals, the degree of bradycardia is proportional to dive duration.
D) In forcibly submerged seals, the degree of bradycardia is inversely proportional to dive duration.

A) 60 beats/min
B) 50 beats/min
C) 10 beats/min
D) The answer is not shown on the y axis scale.

A) ventilation rates
B) heart rates
C) metabolic rates
D) oxygen consumption

A) Weddell seal
B) Fish that regularly emerge into the air briefly, such as grunion and flying fish
C) Teleost fish
D) Humans

A) Blood
B) Muscle
C) Brain
D) Blood and muscle

A) Blood circulation to muscle was significantly increased during the dives.
B) Oxygen supplies for the brain and myocardium remained low during the dives.
C) Muscles switch to anaerobic metabolism at some point during the dives.
D) Circulating blood oxygen continued to be made available from oxygen in muscle.

A) Length of dive
B) Time after animal resurfaces
C) Duration of anaerobic tolerance
D) Time

A) Blood concentration of lactic acid rises following a dive.
B) During a dive, lactic acid in the muscles increases dramatically.
C) During a dive, lactic acid is metabolized and eventually reaches undetectable levels.
D) Blood lactic acid and muscle lactic acid concentrations are typically mismatched during and after dives.

A) O₂ supplies
B) O₂ supplies and O₂ consumption
C) O₂ consumption and tissue tolerance to lactic acid
D) O₂ supplies, O₂ consumption, and tissue tolerance to lactic acid

A) hearts that function more efficiently.
B) brains that tolerate hypoxia better.
C) muscles that remain active in the absence of oxygen longer.
D) a more functional nervous system.

A) greater than
B) lower than
C) lower than or equal to
D) greater than or equal to

A) Low blood O₂
B) High blood CO₂
C) Low blood pH
D) High blood CO₂ and low blood pH

A) increased sensitivity; blood CO₂ and H⁺
B) increased sensitivity; blood O₂
C) blunted sensitivity; blood CO₂ and H⁺
D) blunted sensitivity; blood O₂

A) a significant amount of time to fully metabolize the lactic acid.
B) access to air at the water's surface and a significant amount of time to fully metabolize the lactic acid.
C) an immediate shallow dive to metabolize accumulated lactic acid.
D) access to land in order to metabolize accumulated lactic acid.

A) via an implanted catheter during voluntary dives in the lab.
B) via an implanted catheter during free diving in the wild.
C) following free diving in the wild.
D) following voluntary dives in the lab.

A) longest; net accumulation of lactic acid above resting level.
B) longest; accumulation of lactic acid.
C) deepest; accumulation of lactic acid.
D) longest; alteration of metabolic rate.

A) time spent underwater; the time available for foraging
B) recovery time at the surface; the time spent underwater
C) the time available for foraging; exposure to predation
D) exposure to predation; the time available for foraging

A) 90; shorter
B) 75; shorter
C) 75; longer
D) 90; longer

A) allowing their tissue to cool.
B) postponing the digestion of food while diving.
C) developing a tolerance for lactic acid.
D) gliding instead of swimming continuously.

A) Gliding alone
B) Alternation of stroking and gliding
C) Continuous stroking
D) Gliding and alternation of stroking and gliding

A) in scuba divers who dive very deep.
B) when N₂ is absorbed from a high-pressure source.
C) when N₂ comes out of solution in the blood.
D) when N₂ is absent in the plasma.

A) bubbles of gas forming in the blood.
B) joint pain.
C) bubbles of gas forming in the blood and joint pain.
D) bubbles of gas forming in the blood, joint pain, and paralysis.

A) can occur during sudden ascents; can also occur during sudden ascents
B) can occur during sudden ascents; is incredibly rare, even during sudden ascents
C) is incredibly rare, even during sudden ascents; can occur during sudden ascents
D) is incredibly rare, even during sudden ascents; is also incredibly rare, even during sudden ascents

A) through increased solubility of N₂ in blood plasma.
B) via alveolar collapse.
C) by binding excess N₂ to hemoglobin.
D) by sequestering excess N₂ in the spleen.

A) II
B) I and II
C) II and III
D) I, II, and III

A) To prevent alveolar collapse.
B) To prevent O₂ from diffusing into blood from lungs.
C) To prevent O₂ from diffusing from blood into lungs.
D) To enhance recovery upon ascent.