Deck 28: Respiratory System Peak Performance

A) pharynx
B) lung
C) trachea
D) alveoli
E) voice box

A) the lungs.
B) trachea.
C) bronchi.
D) alveoli.
E) All of the above.

A)downward; inhalation
B)upward; exhalation
C)downward; exhalation
D)undulating; inhalation
E)undulating; exhalation

A) mouth and lungs
B) trachea and larynx
C) bronchi and bronchioles
D) alveoli and bronchioles
E) bronchioles and alveoli

A) increase in lung air pressure
B) upward movement of the diaphragm
C) relaxation of the diaphragm and rib cage muscles
D) A and B only
E) A, B, and C all are involved.

A) The movement of the body surface compresses and expands the tracheal tube system to ventilate air.
B) The spiracles are able to adjust to ventilate air.
C) Carbon dioxide and oxygen are able to diffuse directly into the muscle cells of the insect so there is no need to ventilate air.
D) Tracheoles are able to contract their muscles to ventilate air.
E) Insects are not capable of forced movement of air at any time.

A) mouth→larynx→trachea→pharynx→bronchi→bronchioles→alveoli
B) mouth→larynx→pharynx→trachea→bronchi→bronchioles→alveoli
C) mouth→larynx→pharynx→trachea→bronchioles→bronchi→alveoli
D) mouth→pharynx→larynx→trachea→bronchi→bronchioles→alveoli
E) mouth→pharynx→trachea→larynx→bronchioles→bronchi→alveoli

A) the volume of water over the lungs
B) the size and number of gill filaments
C) the size of the operculum
D) A and B only
E) A, B, and C all dictate respiratory surface.

A) pharynx
B) bronchi
C) trachea
D) alveoli
E) throat

A) rib cage muscles
B) diaphragm
C) lung muscles
D) bronchial muscles
E) cavitation muscles

A) bronchi
B) throat
C) trachea
D) alveoli
E) bronchioles

A)pharynx
B)bronchioles
C)trachea
D)larynx
E)bronchi

A) pharynx
B) lungs
C) trachea
D) alveoli
E) vocal chords

A) alveioli
B) bronchioles
C) lungs
D) larynx
E) bronchi

A) relaxation of the diaphragm and rig cage muscles
B) a swallowing motion in the upper respiratory tract
C) an increase in outside air pressure
D) contraction of the diaphragm and rib cage muscles
E) upward movement of the diaphragm

A) spiracle
B) trachea
C) tracheoles
D) body wall surface
E) antennae

A) oxygen; carbon dioxide
B) oxygen; oxygen
C) carbon dioxide; carbon dioxide
D) carbon dioxide; nitrogen
E) carbon dioxide; oxygen

A)brochioles
B)alveoli
C)bronchi
D)respiratory vessels
E)gill filaments

A) The gas exchange system requires water over the gill filaments.
B) Carbon dioxide will build up in the blood of the fish.
C) There will be a lack of oxygen to key organ systems in the fish.
D) B and C only
E) A, B, and C are all reasons

A) capillaries
B) air pockets
C) operculum
D) ram ventilation
E) cardiorespiratory surfaces

A) operculum
B) gill filaments
C) gills
D) fins for swimming
E) fish mouth

A)the body
B)the aorta
C)the lungs
D)the left side of the heart
E)the coronary arteries

A) Carbon dioxide and oxygen are exchanged directly at the muscle cells.
B) Diffusion of gasses occurs with the air directly.
C) Insect cells do not conduct aerobic respiration.
D) A and B only.
E) B and C only.

A)low; decreases
B)high; increases
C)low; increases
D)high; decreases
E)Levels of oxygen in the tissue have no effect on oxygen diffusion.

A) plasma
B) red blood cells
C) white blood cells
D) It forms air bubbles and moves through the cardiovascular system.
E) Carbon dioxide does not move into blood directly

A) capillaries
B) left atrium
C) aorta
D) pulmonary artery
E) filaments

A)Insects and fish require oxygen as a reactant for cellular respiration.
B)Insects use nitrogen gasses as both a reactant and product of cellular respiration,and fish use oxygen as a reactant and carbon dioxide as a product of cellular respiration.
C)Insects and fish create carbon dioxide as a waste product of cellular respiration.
D)Both A and C.
E)All of the above are hurdles.

A) Both have thin walls that are just nearly one cell thick.
B) Both have small plasma membranes.
C) Both are full of oxygen-depleted blood for gas exchange.
D) Both are supplied with osmotic pressure from the diaphragm.
E) Both are uniquely thick walled to allow quick diffusion of gasses.

A) insect alveoli
B) gill filaments
C) tracheoles
D) bronchi
E) operculum

A)insect alveoli
B)gill filaments
C)tracheoles
D)bronchi
E)spiracle

A) in the form of carbonic acid
B) as gas bubbles
C) as oxygenated carbon
D) attached to hemoglobin
E) as dissolved carbon dioxide

A) decreased partial pressure of oxygen in the tissue due to use in cellular respiration
B) increased pH in the tissue due to repeated contractions
C) increase in temperature in the tissue due to repeated contractions
D) A and C only
E) A, B, and C will each increase the release of oxygen.

A) increasing the heart rate
B) increasing the production of red blood cells
C) moving to lower altitudes
D) breathing harder to increase the barometric pressure
E) allowing blood to move slowly through the lungs

A) carbon dioxide
B) glucose
C) fermentation products
D) diffusion
E) ATP

A) arteries
B) capillaries
C) aorta
D) bronchioles
E) bronchiole veins

A) arteries
B) veins
C) pulmonary artery
D) Both A and B
E) All of the above.

A)What is the relationship between the barometric pressure at this altitude and the ability of this person to deliver oxygen in the blood?
B)What is the body's response to this change?

A) plasma
B) white blood cells
C) platelets
D) red blood cells
E) erythrocytosis

A) This ability has nothing to do with genetics.
B) traits
C) Mendelian genetics
D) adaptation
E) diffusion

A) altitude sickness
B) recovery training
C) asthma
D) anemia
E) barometric sickness

A) altitude sickness
B) recovery training
C) asthma
D) anemia
E) barometric sickness

A) homeostasis
B) erythrocytes
C) partial pressure
D) barometric pressure
E) hypoxic pressure

A) hemoglobin protein in the red blood cells
B) four heme groups in each of the hemoglobin proteins
C) Iron in each of the heme groups physically binds to oxygen.
D) A and B only
E) A, B, and C all provide oxygen-carrying capability.

A)Diffusion slows once there are equal concentrations in the blood and lungs.
B)The oxygen levels in the alveoli and blood move toward equilibrium.
C)The blood is flowing past the alveoli in capillaries and out to the heart.
D)Oxygen does diffuse back into the lungs in small amounts, but the overall movement of oxygen is from the high concentration in the lungs to the low concentration in the blood.
E)All of the above are correct.

A) The diffusion rate of oxygen into the blood is always constant and does not change due to a change in the number of available oxygen molecules in the alveolar air.
B) The diffusion rate is increased because there are more oxygen molecules available in the alveolar air.
C) The diffusion rate is decreased because there are more oxygen molecules available in the alveolar air.
D) The diffusion rate is increased because there are fewer oxygen molecules available in the alveolar air.
E) The diffusion rate is decreased because there are fewer oxygen molecules available in the alveolar air.

A) centimeters of mercury (cmHg)
B) millimeters of mercury (mmHg)
C) centimeters of helium (cmHe)
D) millimeters of helium (mmHe)
E) Barometric pressure is not measured but mathematically calculated.

A) low carbon dioxide levels in the blood
B) low carbon dioxide levels in the atmosphere
C) high oxygen levels in the blood
D) high carbon dioxide levels in the blood
E) low oxygen levels in the blood

A) train high, live low
B) hypoxic conditions
C) partial pressure training
D) altitude training
E) live high, train lowA

A) a lack of a suitable control group
B) Training of any kind will result in increases in performance.
C) Statistical analysis cannot be performed on these studies.
D) A and B only.
E) A, B, and C all make these studies hard to interpret.

A)an inverse relationship
B)a direct relationship
C)a reverse relationship
D)no relationship
E)no difference

A) erythropoietin
B) testosterone
C) estrogen
D) oxygone
E) progesterone

A) High blood pH is sensed by the brain.
B) Low blood pH is sensed by the brain.
C) High carbon dioxide levels are measured by the brain.
D) Low carbon dioxide levels are measured by the brain.
E) The brain does not have the ability to directly detect changes in the blood.

A) increased heart rate to deliver oxygen through the cardiovascular system
B) increased carbonic acid levels in the blood
C) decreased pH in the blood
D) increase in cellular respiration in the tissues
E) All of the above are associated with increased breathing rates.

A) in the lungs of the individual
B) Increased red blood cells would be found in the kidneys because that is the site of natural erythropoietin.
C) The increase in red blood cells would be most obvious in the arterial blood supply and not the venous supply.
D) In the bone marrow there would be an increase in the number of immature red blood cells being produced.
E) There is no source of red blood cells to look at for a change in production.

A) Increase the size of your respiratory surface through training.
B) Train and strengthen the muscles controlling the chest to increase lung volume.
C) Increase the number of red blood cells through stressing the respiratory system with hypoxic conditions.
D) B and C only are ways to increase oxygen delivery.
E) A, B, and C are all ways to increase oxygen delivery.

A) serum sickness
B) erythrocytosis
C) acidosis
D) altitude sickness
E) sea sickness

A) the demand for oxygen
B) the demand for carbon dioxide
C) an increase in blood pH
D) an increase in blood carbon dioxide levels
E) a decrease in blood carbon dioxide levels

A) hypoxic chamber
B) altitude chamber
C) anaerobic chamber
D) high chamber
E) reverse chamber

A) brain
B) testes or ovaries
C) lungs
D) cardiac tissues
E) kidneys

A) Red blood cell numbers go up at high altitudes.
B) Oxygen delivery is greatly increased with a high partial pressure of oxygen at sea level.
C) Carbon dioxide will not be produced in as high an amount at high altitude.
D) A and B only.
E) A, B, and C are all correct.

A) Increased carbon dioxide is the product of increased cellular respiration.
B) Increased cellular respiration requires increased oxygen.
C) Increased carbon dioxide is controlled by the pH of the blood.
D) A and B only.
E) All of the above are ways the two are related.