an upward movement of the diaphragm

movement of the ribs closer together due to the contraction of the inspiratory intercostal muscles

downward movement of the diaphragm

a and b

b and c

be lower than alveolar pressure

be between +5 and +10 mmHg above the atmospheric pressure

alternate between being less than and greater than the atmosphere pressure

change as respiratory demands of the body change

be the same as the atmosphenc pressure

dissolved in the plasma

bound to haemoglobin

in carbonic acid

in bicarbonate ions

in carbonic anhydrase

coronary

pulmonary

cerebral

muscle

skin

mouth

largest bronchi

medium sized bronchi

smallest bronchi

alveoli

higher flow

lower resistance

higher arterial pressure

higher capillary pressure

higher cardiac output

hypercapnia

anoxia

hypoxia

hypocapnia

a and c

an increased pH

decreased association between hemoglobin and O2

decreased pH

vasodilatation

b and c

Tidal Volume

Expiratory Reserve Volume

Residual Volume

Inspiratory Reserve Volume

a, b and d

abdominal

external intercostal muscles

diaphragm

pectoral muscle

b and c

vasoconstriction in the lungs

dilation of the bronchi

vasodilation in the lungs

constriction of the bronchi

a and b

regulation of lung blood pressure

lung ventilation

diffusion of gases between the alveolar air and blood

fat metabolism

b and c

membrane thickness

membrane area

tidal volume

diffusion quotient

a and b

trachea

bronchus

bronchioles

alveoli

larynx

gradient of change of ventilation is greater than that of per fusion

ventilation increases up the lung

perfusion increases up the lung

V/Q ratio at apex is greater than at base

none of the above

is produced by type 1 alveolar cells

acts like detergent in water

reduces the amount of negative intrapleural pressure

reduces blood flow to the lungs

increases pulmonary compliance

70% dissolved in plasma

70% carbamino hemoglobin

70% bicarbonate

10% bicarbonate

unaffected by pO2

the diaphragm and mm. intercostales interni

the diaphragm and mm. intercostales externi

mm. abdominales

mm. serrati posteriores inferiores

all of the above

epinephrine

atropine

epinephrine and atropine

bradikinine and histamine

acetylcholine

is produced by type II alveolar cells

consists of phospholipids, proteins and carbohydrates

decreases the alveolar surface tension at the end of expiration

protects the lungs from atelectasis and edema

all of the above

consists of alveolar epithelium, pulmonary capillary endothelium and their base membranes with very thin interstitial space between them;

diffusion of 02 and CO2 occurs across it

has better permeability for 02 than CO2

a and b

none of the above

increased level of catecholamines

decreased level of catecholamines

increase of acetylcholine and serotonin levels

increase of bradikinine and histamine levels

a, c and d

polypnoe

eupnoe

tachypnoe

dyspnoe

hyperpnoe

the thoracic cage recoils and the diaphragm moves upwards

the intrapleural pressure decreases

the intrapleural pressure increases

a and b

a and c

α-adrenergic receptors

β-adrenergic receptors

M-cholinergic receptors

N-cholinergic receptors

H2 receptors

the volume of air, which passes through the lungs per minute

bigger than the Residual Volume (RV)

an element of the Functional Residual Capacity (FRC)

a, b and c

0.5-1 approximately

higher than the atmospheric pressure

lower than the atmospheric pressure

equal to the atmospheric pressure

depends on the water molecules surface tension and elastic fibers

b and d

includes the volume of air within the an passages up to the terminal bronchioles

is the space where gas exchange doesn't occur

is approximately 140 ml

is approximately 500 ml

is about 6 L.min-1

the volume of air. which remains in the lungs after maximal expiration

the volume of air, which remains in the lungs after maximal inspiration

is about 2-3 L

is the tidal volume plus the inspiratory reserve volume

a component of the Vital Capacity (VC)

increased pCO2

decreased pCO2

decreased pO2

increased pO2

increased pH

is a sum of ERV+TV+IRV

depends on sex and age

depends on chest measurement

is a sum of IC+ERV

is a sum of TV+ERV+RV

on the external surface of the lungs

on the medial surface of the lungs

in the trachea, bronchi and bronchioles

around the alveoli

on the external and medial surfaces of the lungs

has a higher CO2 content than the atmosphere

has lower 02 content than in the atmosphere

consists of N2 approximately equal to that in the atmosphere

has the name components as the atmosphere

a, b and c

around the alveoli

around the terminal branches of the bronchi

on the external and the medial surface of the lungs

a and b

all of the above

on the ventral surface of medulla oblongata

on the dorsal surface of medulla oblongata

in arcus aortae and arteria carotis communis

in the inferior and superior venae cavae and the right atrium

in the hypothalamus

carbamino Hb

carboxi Hb

NaHCO3

physically dissolved in fluids

carbamino Hb and physically dissolved in the fluids

decreased pCO2

increased pO2

alkalosis

decreased pCO2 and increased pO2

increased pCO2 and decreased pO2

the upper parts of the lungs in upright position

the middle parts of the lungs in upright position

the lower parts of the lungs in upright position

in all parts of the lungs in supine position

b and d

the ribs move upward

the diaphragm lifts up

the antero-posterior dimensions of the chest are increased

the transverse dimensions of the thorax are increased

the scalene and sternocleidomastoid muscles can be recruited for inspiration

4200 ml

1500 ml

6000 ml

8000 ml

10000 ml

diffusion

filtration

osmosis

active transport

passive transport

small gas bubble in the plasma

gas bound to the hemoglobin in the red blood cells

bicarbonate ions in the plasma

gas bound to white blood cells and albumin

gas transported through the lymphatic system

a drop in blood pH

a rise in blood pH

a drop in blood oxygen levels

a drop in carbon dioxide levels

none of the above

bronchioles

bronchi

pulmonary capillaries

roots of the lungs

trachea

respiratory system

endocrine system

gastrointestinal system

excretory system

any opening into the body

acidic

alkaline

icy

open

none of the above

7.05

7.15

7.25

7.35

6.50

pH rises

HCO3- ions pass from tissues to red blood cells

Cl- ion concentration in red cells falls

its oxygen dissociation curve shifts to the right

its oxygen dissociation curve shifts to the left

are stretch receptors in the walls of the intenal carotid arteries

have a blood flow per unit volume similar to that in the brain

are influenced by the blood temperature

generate less afferent impulses when blood H+ concentration rises

and the aortic bodies are mainly responsible tor the increased ventilation in hypoxia

the surface tension of the fluid lining alveolar walls

lung compliance

in effectiveness as the lungs are inflated

in amount when pulmonary blood flow is interrupted

the airflow resistance in bronchi

ratio of lung residual volume to vital capacity

percentage of vital capacity expelled in one second

lung volume level at which small airways start to close during expiration

elastic fibers in lungs

tidal volume

intrapleural pressure is lowest at mid-inspiration

intrapulmonary pressure is lowest around mid-inspiration

intraoesophageal pressure is lowest at mid-inspiration

the rate of air flow is greatest at end-inspiration

the lung volume/intrapleural pressure relationship is the same as in expiration

is carried as carboxyhaemoglobin on the haemoglobin molecule

uptake by the blood increases its oxygen-binding power

uptake by the blood leads to similar increases in H+ and HCO3- ion concentrations

stimulates ventilation when breathed at a concentration of 20 per cent

content is greater than oxygen content in arterial blood

the rate of alveolar ventilation at rest exceeds the rate of alveolar capillary perfusion

the ventilation/perfusion (V/Q) ratio in less 0.6 dieting maximal exercise

the V/Q ratio is higher at the apex than at the base of the lungs when a person is standing

oxygen transfer can be explained by active transport

dead space decreases during inspiration

bronchial mucosal irritation

local beta adrenoceptor stimulation

a fall in bronchial pO2

inhalation of air warmed to 37°C

circulating noradrenaline

intrapulmonary pressure

aortic pressure

intra-abdominal pressure

dead space pO2

diastolic arterial pressure

pulmonary ventilation

alveolar H2O vapour pressure

arterial pO2

intrapleural pressure

cerebral blood flow

venous return to the heart is increased

less energy is expended than during expiration

lung expansion is assisted by surface tension forces in the alveoli

lung expansion begins when intrapleural pressure falls below atmospheric

the relative concentration of surfactant increases in alveoli

the gas remaining in the lungs at the end of a full expiration

greater on average in women than in men

3-4 litres on average in young adults

measured directly using a spirometer

smaller in old than in young people

an increase in ventilation due: to stimulation of peripheral and central chemoreceptors

a decrease in ventilation due to stimulation of central and peripheral chemoreceptors

a decrease in arterial pressure

a decrease in cerebral blood flow

a decrease in the plasma bicarbonate level

periods when cerebrospinal fluid pH is reduced

compensated chronic renal failure

periods when plasma bicarbonate level is raised

deep sleep

exercise because of the ensuing fall in arterial pO2

arterial mean pressure is about one-sixth systemic mean arterial pressure

blood flow/minute is greater then the systemic blood flow/minute

vascular resistance is about 50 per cent that of systemic vascular resistance

vascular capacity is similar to systemic vascular capacity

arterial pressure increases by about 50 per cent when cardiac output rises by 50 per cent

combination with the myoglobin molecule

combination with plasma globulins

physical solution in red blood cells

greater quantity in red blood cells than in plasma

greater quantity as HCO3- than as other forms

occurs m the pulmonary capillaries

occurs if blood temperature decreases

favors oxygen delivery to the tissues

favors oxygen uptake from the lungs by alveolar capillary blood

occurs if the pH of the blood increases

expressed as volume change per unit change in pressure

minimal during quiet breathing

increased by the surface tension of the fluid lining the alveoli

decreased by surfactant

changed by parallel displacement of the line relating lung volume to distending pressure

saturates inspired air with water vapour before it reaches the alveoli

removes all particles from inspired air before it reaches the alveoli

decreases when blood catecholamines levels rise

decreases during a deep inspiration

is equal to the tidal volume

the volume of air expired from full inspiration to full expiration

increased as one grows older

greater in women than in men of the same age and height

related more to total body mass than to lean body mass

the sum of the inspiratory and expiratory reserve volumes

the amount of O2 consumed after cessation of exercise

incurred because the pulmonary capillary walls limit 02 uptake during exercise

possible since skeletal muscle can function temporarily without oxygen

associated with a decrease in blood lactate

associated with metabolic alcalosis

its shape is sigmoid

blood saturates with CO2 when pCO2 exceeds normal alveolar levels

blood contains some CO2 even when the pCO2 is zero

oxygenation of the blood drives CO2 out of the blood

adding CO2 to the blood drives 02 out of the blood

stimulation of cholinergic receptors

stimulation of beta adrenoceptors

histamine aerosols

non steroidal anti-inflammatory drugs

mineralcorticoids

allows intrapleural pressure to rise to atmospheric pressure

causes the underlying lung to collapse by compressing it

increases the functional residual capacity

leads to a slight inward movement of the chest wall

increases the vital capacity

physiological dead space

the surfactant

residual volume

vital capacity

the intrapleural pressure

collapse of the alveoli supplied by the bronchus

a rise in local intrapleural pressure

an increase in physiological dead space

an increase in blood flow to the lung tissue supplied by the bronchus

cyanosis

decreases the O2 content of blood at a given pO2

impairs O2 delivery to the tissues at the normal tissue pO2

occurs in blood perfusing hot extremities

occurs in blood with lower pH than with higher pH

is characteristic of adult blood when compared with fetal blood

is exposed to a pressure equal to that at the surface

has a raised pressure of nitrogen in the alveoli

has a four-fold increase in the oxygen content of blood

has a fourfold increase in alveolar water vapour pressure

expends less energy than manna! on the work of breathing

may be caused by high levels of carboxyhaemoglobin in the blood

may be caused by high levels of methaemoglobin in the blood

is seen in fingers of hands immersed in iced water

occurs more easily in anaemic than in polycythaemic patients

is severe in cyanide poisoning

metabolic acidosis

alkaline urine

cool extremeties

decreased cerebral blood flow

raised plasma bicarbonate

is reflexly initiated by irritation of the alveoli

is associated with relaxation of airways smooth muscle

depends on contraction of the diaphragm for expulsion of air

differs from sneezing in that the glottis is initially closed

is equivalent of sneezing

total ventilation/perfusion ratio

peak expiratory flow rate

respiratory quotient

tidal volume

dead space

lower systemic arterial oxygen content

has no effect on the O2 in systemic circulation

increase the physiological dead space

lower systemic arterial carbon dioxide content

be compensated (with respect to oxygen uptake) by a high ratio in the other lung

normally equals the rate of O2 consumption by the body/min

is normally more than 95 per cent combined with haemoglobin

must fall by about half if haemoglobin concentration is halved

is more closely related to PO2 than to percentage saturation of the blood with O2

must double if body oxygen consumption doubles

the pressure inside the lungs must be higher than the atmospheric pressure

the pressure inside the lungs must become lower than the atmospheric pressure

the pressure inside the lungs must be equal to the atmospheric pressure

the diaphragm must be relaxed

the external intercostal muscles must be relaxed

more carbon monoxide produced

more bicarbonate ions produced

an increase in protons

there would be a shift to the left

there would be a shift to the right first, then to the left

60; 40

40; 60

46; 40

66; 46

46; 100

tidal volume

expiratory reserve volume

maximum expiratory flow rate

eupnea

inspiratory reserve volume

Hb + O2 -> HbO2

Hb + CO2 -> HbCO2

HbCO2 -> Hb + CO2

H2CO3 -> HCO3- + H+

Na+ + HCO3- -> NaHCO3

inhibits alveolar collapse

assists pulmonary compliance

assists elastic recoil

resists elastic recoil

impairs gas exchange

triggers inspiration

decreased ventilation rate

nothing

for forced breathing

inhibits apneustic center, sets limits to over inflation of lungs

pons

apneustic center

arterial blood chemistry

medulla oblongata

stretch receptors

formation of N2 bubbles

formation of CO2 bubbles

due to fatigue

due to increase in barometric pressure

formation of O2 bubbles

95%

80%

65%

50%

40%

oxygen

hydrogen

carbon dioxide

N2

CO

congenital heart disease

gas gangrene

CO poisoning

N2 toxicity

advanced pulmonary carcinoma

decrease in pO2, increase in pCO2

decrease in pO2, decrease in pCO2

increase in both pO2 and pCO2

increase in pO2, decrease in pCO2

no change in pO2 and pCO2

type 1 pneumatocytes

type 2 pneumatocytes

goblet cells

pulmonary vessels

bronchial smooth muscle cells

decrease in blood volume

decrease in muscle strength

increase in red cell mass

loss of bone mass

osteroporosis

increases in asthma

decreases in emphysema

increases in paraplegic patients

does not affect work of breathing

decreases in asthma

hyperventilation

hypoventilation

hypercapnoea

hypoxia

none of the above

-4 mm Hg

+4 mm Hg

-6 mm Hg

+6 mm Hg

-10 mm Hg

oxygen consumption

cardiac output

stroke volume

arterial pCO2

ventilation/perfusion ratio

a fall in blood pressure

stimulation of central chemoreceptors

cianosis

increased breathing

constriction of the pupils

alveolar ventilation

blood bicarbonate level

appetite for food

exercise tolerance

muscle strength