Unit 4 Material

Question 1

The respiratory system includes (3)

Answer 1

Ventilation, gas exchange between blood and lung and tissues, oxygen utilization to make ATP (cellular respiration)

Question 2

External respiration is

Answer 2

ventilation and gas exchange in lungs

Question 3

Internal ventilation is

Answer 3

oxygen utilization and gas exchange in tissues

Question 4

Gas exchange in the lungs occurs via

Answer 4

diffusion

Question 5

O2 concentration is higher in the ______ rather than the _______, so O2 diffuses into _____.

Answer 5

Lungs.
Blood.
Blood.

Question 6

CO2 concentration in the ______ is higher than in the ______, so CO2 diffuses out of the _______.

Answer 6

Blood.
Lungs.
Blood.

Question 7

The respiratory system is anatomically divided into

Answer 7

Conduction zone and respiratory zone

Question 8

Zone that gets air into the respiratory zone

Answer 8

Conduction zone

Question 9

Zone that is site of gas exchange

Answer 9

Respiratory zone

Question 10

Air sacs in the lungs where gas exchange takes place

Answer 10

Alveoli

Question 11

How many alveoli are there and why are there so many

Answer 11

300 million. To provide large surface area to increase diffusion rate.

Question 12

Alveoli form clusters at the end of

Answer 12

Respiratory bronchioles

Question 13

Type I alveolar cells

Answer 13

95-97% total surface area where gas exchange occurs

Question 14

Type II alveolar cells

Answer 14

Secrete pulmonary surfactant and reabsorb sodium and water, preventing fluid buildup

Question 15

Pathway of Air (10)

Answer 15

Air travels down the nasal cavity > pharynx > larynx (glottis and vocal cords) > Trachea > Right and left primary bronchi > Secondary bronchi > Tertiary bronchi > Terminal bronchioles > Respiratory zone > terminal alveolar sacs

Question 16

CH 16 SLIDE 9

Answer 16

Shows pics of conducting and respiratory zones

Question 17

Functions of the conducting zone (3)

Answer 17

Transports air to the lungs.
Warms, humidifies, filters, and cleans air.
Voice production in the laryx.

Question 18

Mucus traps small particles and cilia move it away from the lungs

Answer 18

Mucociliary escalator and mucociliary clearance.

Question 19

What does the thoracic cavity contain

Answer 19

Heart, trachea, esophagus, and thymus within the central mediastinum, and lungs

Question 20

This lines the thoracic cavity

Answer 20

Parietal pleura

Question 21

This covers the lungs

Answer 21

Visceral pleura

Question 22

Potential space between the parietal and visceral pleura

Answer 22

Intrapleural space

Question 23

What does the diaphragm separate

Answer 23

The thoracic and abdominal cavities

Question 24

CH 16 SLIDE 12

Answer 24

Thoracic cavity cross section

Question 25

Air moves from area of ____ pressure to ______ pressure

Answer 25

Higher to lower

Question 26

Pressure differences between the two ends of the conducting zone occur due to

Answer 26

changing lung volumes

Question 27

Important physical properties of the lungs (3)

Answer 27

Compliance, elasticity, and surface tension

Question 28

Pressure of air outside the body

Answer 28

Atmospheric pressure

Question 29

Pressure in the lungs

Answer 29

Intrapulmonary or intraalveolar pressure

Question 30

Pressure within the intrapleural space. Contains a thin layer of fluid to serve as lubricant

Answer 30

Intrapleural pressure

Question 31

1 atmosphere is

Answer 31

1033.25 cm H2O = 760 mm Hg

Question 32

Inspiration pressure

Answer 32

Intrapulmonary pressure is lower than atmospheric pressure. Generally about -1cm H2O

Question 33

Pressure below that of atmosphere is called

Answer 33

Subatmospheric or negative pressure

Question 34

Expiration pressure

Answer 34

Intrapulmonary pressure is greater than atmospheric pressure. Generally about +1cm H2O

Question 35

Intrapulmonary pressure at inspiration

Answer 35

-1 cm H2O

Question 36

Intrapulmonary pressure at expiration

Answer 36

+1 cm H2O

Question 37

Intrapleural pressure at inspiration

Answer 37

-8 cm H2O

Question 38

Intrapleural pressure at expiration

Answer 38

-5 cm H2O

Question 39

Transpulmonary pressure at inspiration

Answer 39

+7 cm H2O

Question 40

Transpulmonary pressure at expiration

Answer 40

+6 cm H2O

Question 41

The difference between intrapulmonary and intrapleural pressure is called the

Answer 41

Transpulmonary pressure

Question 42

Keeps the lungs against the thoracic wall and allows them to expand during inspiration

Answer 42

Intrapleural pressure

Question 43

Boyle’s law

Answer 43

States that the pressure of a gas is inversely proportional to its volume

Question 44

An increase in lung volume during inspiration decreases intrapulmoanary pressure to subatomospheric levels…

Answer 44

air goes in

Question 45

A decrease in lung volume during expiration increases intrapulmonary pressure above atmospheric levels

Answer 45

Air goes out

Question 46

The premise that lungs can be expanded when stretched is called

Answer 46

Lung compliance. Change in lung volume per change in transpulmonary pressure

Question 47

The ease in which lungs expand under pressure

Answer 47

Lung compliance

Question 48

This is reduced by factors that produce resistance to distention such as the infiltration of connective tissue in pulmonary fibrosis

Answer 48

Lung compliance

Question 49

Premise that lungs return to initial size after being stretched

Answer 49

Elasticity

Question 50

Lungs are elastic because they have a lot of

Answer 50

Elastin fibers

Question 51

Because lungs are stuck to the thoracic wall, they are always under

Answer 51

Elastic tension

Question 52

Tension increases during inspiration and is reduced by

Answer 52

Elastic recoil during expiration

Question 53

This resists distension

Answer 53

Surface tension

Question 54

Exerted by fluid secreted on the alveoli

Answer 54

Surface tension

Question 55

In surface tension, fluid is absorbed by active transport of ___ and secreted by active transport of ___

Answer 55

Na+ and Cl-

Question 56

Raises the pressure of the alveolar air as it acts to collapse the alveolus

Answer 56

Surface tension

Question 57

People with cystic fibrosis have a genetic defect that causes an impalance of fluid absorption and secretion

Answer 57

Surface tension

Question 58

Law of Laplace

Answer 58

Pressure is directly proportional to surface tension and inversely proportional to radius of alveolus. Small alveoli would be at greater risk of collapse without surfactant

Question 59

Surfactant is secreted by

Answer 59

Type II alveolar cells

Question 60

Surfactant is consisted of

Answer 60

Hydrophobic protein and phospholipids

Question 61

What does surfactant do

Answer 61

Reduces surface tension between water molecules by reducing the number of hydrogen bonds between water molecules. Prevents collapse. Allows a residual volume of air to remain in the lungs

Question 62

Surfactant gets more concentrated as alveoli get smaller during

Answer 62

expiration

Question 63

Acute respiratory distress syndrome (ARDS)

Answer 63

High risk for alveolar collapse due to septic shock, reduced compliance, and reduced surfactant. Not treatable with surfactant

Question 64

Respiratory distress syndrome (RDS)

Answer 64

Premature babies may be born with a high risk for alveolar collapse because surfactant production begins late in fetal life. Treated with surfactant.

Question 65

Muscles involved in breathing (4)

Answer 65

Diaphragm, external intercostal muscles, internal intercostal muscles, parasternal intercostal muscles.

Question 66

Muscle that contracts in inspiration, relaxes in expiration.

Answer 66

Diaphragm.
Lowers in inspiration making cavity larger.
Raises in expiration, making cavity smaller.

Question 67

Muscle that raises the rib cage during inspiration

Answer 67

External intercostal muscles

Question 68

Muscle that lowers the rib cage during forced expiration

Answer 68

Internal intercostal muscles

Question 69

Muscle that works with the external intercostal

Answer 69

Parasternal intercostal muscles

Question 70

Muscles used for forced expiration

Answer 70

Scalenes, pectoralis minor, and sternocleidomastoid. And abdominal msucles

Question 71

Quiet respiration occurs with the relaxation of what muscles

Answer 71

Inspiration muscles, which is a passive process

Question 72

How does inspiration work?

Answer 72

Volume of thoracic cavity (lungs) increases vertically when diaphragm contracts (flattens) and laterally when parasternal and external intercostals raise the ribs.
Thoracic and lung volume increase > intrapulmonary pressure decreases > air in.

Question 73

How does expiration occur?

Answer 73

Volume of thoracic cavity (and lungs) decreases vertically when diaphragm relaxes (dome) and laterally when external and parasternal intercostals relax for quiet expiration or internal intercostals contract in forced expiration to lower the ribs.
Thoracic and lung volume decreases > intrapulmonary pressure increases > air out.

Question 74

CH 16 SLIDE 31

Answer 74

Mechanisms of Pulmonary Ventilation

Question 75

How does spirometry work?

Answer 75

Breathing into and out of a device that records volume and frequency of air movement on a spirogram

Question 76

What does spirometry measure? and what can it diagnose?

Answer 76

Lung volumes and capacity.

Diagnose restrictive and obstructive lung disorders

Question 77

Tidal volume is…

Answer 77

Amount of air expired or inspired in quiet breathing is called

Question 78

Expiratory reserve volume is…

Answer 78

Amount of air that can be forced out after tidal volume is called

Question 79

Inspiratory reserve volume is…

Answer 79

Amount of air that can be forced in after tidal volume

Question 80

Residual volume is…

Answer 80

Amount of air left in lungs after maximum expiration

Question 81

Vital capacity is…

Answer 81

Maximum amount of air that can be forcefully exhaled after a maximum inhalation

Question 82

Total lung capacity is …

Answer 82

Air in the lungs after a maximum inspiration

Question 83

Inspiration capacity is…

Answer 83

Air that can be inspired after a normal expiration

Question 84

functional residual capacity is…

Answer 84

Air left in the lungs after a normal expiration

Question 85

Inspiration reserve volume + expiratory reserve volume + tidal capacity =

Answer 85

Vital capacity

Question 86

Residual volume + expiratory reserve volume =

Answer 86

Functional residual capacity

Question 87

Tidal volume x breaths per minute (~6L/min) =

Answer 87

Total minute volume

Question 88

Restrictive pulmonary disorder

Answer 88

Lung tissue is damages. Vital capacity is reduced, but forceful expiration is normal

Question 89

Example of pulmonary restrictive disorder

Answer 89

Pulmonary fibrosis

Question 90

Obstructive pulmonary disorder

Answer 90

Lung tissue is normal. Vital capacity is normal, but forced expiration is reduced.

Question 91

Examples of obstructive pulmonary disorder

Answer 91

Asthma; caused by inflammation, mucus, secretion, and construction of bronchioles.
Emphysema

Question 92

Subjective feeling of shortness of breath

Answer 92

Dyspnea

Question 93

Atmospheric pressure is measured using what

Answer 93

Barometer

Question 94

At sea level, the atmospheric pressure is

Answer 94

760 mmHg

Question 95

Dalton’s law

Answer 95

The total pressure of a gas mixture is equal to the sum of the pressures of each gas in it

Question 96

Partial pressure

Answer 96

The pressure of an individual gas; can be measured by multiplying the % of that has by the total pressure

Question 97

O2 makes up 21% of the atmosphere, so partial pressure of O2 = 760 x 21% =

Answer 97

159 mmHg

Question 98

Pdry is

Answer 98

PN2 + PO2 + PCO2 = 760 mmHg

Question 99

Pwet (air gets out of lungs) is

Answer 99

PN2 + PO2 + PCO2 + PH2O = 760 mmHg

Question 100

Pressure of water at 37 C is constant

Answer 100

47 mmHg

Question 101

Partial pressure of O2 at sea level is

Answer 101

.21(760-47) = 150 mmHg

Question 102

In the alveoli, the percentage of oxygen _____, and CO2 ____, changing the partial pressure of both

Answer 102

Decreases, increases

Question 103

Henry’s Law: The amount of gas that can dissolve in liquid depends on;

Answer 103

Solubility of the gas in the liquid.
Temperature of the liquid.
Partial pressure of the gases, determining factor.

Question 104

CH 16 SLIDE 47

Answer 104

Relationship between Alveoli and capillaries

Question 105

Blood PO2 only measures what

Answer 105

Oxygen dissolved in plasma, not bound to hemoglobins

Question 106

Properly functioning lungs give systemic arterial blood PO2 less than 5 mmHg than

Answer 106

Alveolar air. Normal PO2 is 100 mmHg

Question 107

CH 16 SLIDE 50

Answer 107

Partial pressure of Gas in Blood

Question 108

The rate of blood flow through the lungs is equal to that through the systemic circuit

Answer 108

5.5 L/minute cardiac output

Question 109

The pressure difference between the left atrium and the pulmonary artery is only

Answer 109

10 mmHg

Question 110

Why is vascular pressure very low

Answer 110

Low resistance pathway.

Reduces possibility of pulmonary adema.

Question 111

Pulmonary arterioles construct when alveolar partial pressure O2 is __ and dilate when partial pressure O2 is __

Answer 111

Low, high.

Question 112

Blood flow to alveoli is __ when they are full of Oxygen

Answer 112

Increased

Question 113

Systemic arterioles constrict when partial pressure O2 is __

Answer 113

High. This ensure that only tissues that need oxygen are sent blood.

Question 114

Voluntary breathing comes from what part of the brain

Answer 114

Cerebral cortex

Question 115

Involuntary breathing comes from

Answer 115

The respiratory control centers of the medulla oblongata and pons

Question 116

Motor neurons that innervate the diaphragm from the phrenic nerve and arise from

Answer 116

the cervical region of the spinal cord

Question 117

Motor neurons that innervate the other breathing muscles arise form the

Answer 117

Thoroacolumbar region of the spinal cord

Question 118

Medulla rhythmicity center

Answer 118

Contains inspiratory and expiratory neurons that stimulate or inhibit the phrenic nerve controlling respiratory muscles in a reciprocal way to produce the rhythmic pattern of breathing

Question 119

What influences the activity of the medulla

Answer 119

The pons

Question 120

The automatic control of breathing is influenced by feedback from chemoreceptors, which monitor…

Answer 120

pH of fluids in the brain and pH, CO2, and O2 of the blood.

Question 121

Which ones senses changed in blood CO2 that lead to changes in brain pH since H+ can’t cross BBB

Answer 121

Central chemoreceptors in medulla

Question 122

Which sense blood CO2 and pH

Answer 122

Peripheral chemoreceptors in carotid and aorta arteries

Question 123

When blood O2 is very low and actually has change, it’s called…

Answer 123

Hypoxic drive and affects the carotid bodies

Question 124

CH 16 SLIDE 60

Answer 124

Regulation of ventilation by the CNS

Question 125

When ventilation is inadequate, CO2 levels rise and pH falls is called

Answer 125

Hypercapnia

Question 126

If hyperventilation, CO2 levels fall and pH rises this is called

Answer 126

Hypocapnia

Question 127

Oxygen levels do not change as rapidly because of oxygen reserves in

Answer 127

hemoglobin

Question 128

Ventilation is controlled to maintain constant levels of

Answer 128

CO2 in the blood. Oxygen naturally follows

Question 129

CH 16 SLIDE 62

Answer 129

Chemoreceptor Control of Breathing

Question 130

Plasma O2 concentration is systemic arteries is about

Answer 130

0.3mL/100mL of blood

Question 131

Total O2 content of blood depends on

Answer 131

PO2 and hemoglobin concentration

Question 132

Most of the oxygen in blood is bound to

Answer 132

hemoglobin

Question 133

each hemoglobin can carry ___ molecules of O2

Answer 133

4

Question 134

___ million hemoglobin per RBC

Answer 134

280

Question 135

Hemoglobin where iron is reduced from (Fe2+) and can bind with O2

Answer 135

Oxyhemoglobin/ rediced (deoxyhemoglobin) hemoglobin

Question 136

Hemoglobin with oxidized iron (Fe3+) can bind do O2. Some drugs can cause this

Answer 136

Methemoglobin

Question 137

Hemoglobin is bound with carbon monoxide; has stronger bond with CO and O2

Answer 137

Carboxyhemoglobin

Question 138

When hemoglobin binds to oxygen in the lungs, it’s called

Answer 138

Loading

Question 139

When oxyhemoglobin drops off oxygen in the tissues, it’s called

Answer 139

Unloading

Question 140

High PO2 favors (unloading or loading)

Answer 140

loading

Question 141

Strong bond favors _____ and inhibits ______

Answer 141

Loading, unloading

Question 142

Oxygen remaining in the veins after unloading serves as

Answer 142

Oxygen reserve

Question 143

22% oxygen unloading at

Answer 143

rest

Question 144

39% oxygen unloading at

Answer 144

light exercise

Question 145

80% oxygen unloading at

Answer 145

heavy exercise

Question 146

pH and temperature change the affinity of hemoglobin for

Answer 146

O2; which ensures that muscles get more O2 when exercising.

Question 147

Oxygen unloading is higher at ___ pH

Answer 147

Lower; Bohr effect

Question 148

How do RBCs obtain their energy?

Answer 148

From the anaerobic metabolism of glucose…which created 2,3-DPG, increases unloading

Question 149

When is 2,3-DPG created?

Answer 149

If a person is anemic or at high altitudes

Question 150

CH 16 Slide 73

Answer 150

Factor chart that affects affinity of Hemoglobin for O2

Question 151

Similar to hemoglobin, only 1 heme, so can only carry 1 oxygen molecule

Answer 151

Muscle hemoglobin

Question 152

Where is muscle hemoglobin found?

Answer 152

In skeletal and cardiac muscles

Question 153

Describe muscle hemoglobin affinity to O2

Answer 153

Higher affinity. Oxygen is only released when PO2 is very low.

Question 154

Three ways in which carbon dioxide is carried in the blood

Answer 154

Dissolved in plasma, as carbaminohemoglobin attached to amino acid in hemoglobin, as bicarbonate ions

Question 155

The enzyme that catalyzes the reaction to form carbonic acid

Answer 155

Carbonic anhydrase

Question 156

Once bicarbonate ions is formed in the RBC, it diffuses where

Answer 156

plasma

Question 157

H+ RBC attach to hemoglobin and attract

Answer 157

Cl-

Question 158

What is the chloride shift?

Answer 158

The exchange of bicarb out of and Cl- into RBC

Question 159

In pulmonary capillaries, increased PO2 favors the production of

Answer 159

oxyhemoglobin

Question 160

The production of oxyhemoglobin makes H+ dissociate from hemoglobin and recombine with bicarb to form

Answer 160

Carbonic acid (H2CO3)

Question 161

In low PCO2, carbonic anhydrase converts carbonic acid (H2CO3) back to

Answer 161

CO2 + H2O

Question 162

pH of the blood ranges

Answer 162

7.34 - 7.45

Question 163

Volatile acid

Answer 163

Carbonic acid because it can be converted and exhaled

Question 164

Nonvolatile acids are buffered by…and are regulated by

Answer 164

Bicarbonate .

Kidneys.

Question 165

What is the major buffet run the blood

Answer 165

Bicarbonate ion

Question 166

When blood pH falls below 7.35, it is called

Answer 166

Acidosis

Question 167

caused by hypoventilation rise of CO2 which increases H+ (lowers pH)

Answer 167

Respiratory acidosis

Question 168

Caused by excessive production of acids or loss of bicarbonate (diarrhea)

Answer 168

Metabolic acidosis

Question 169

When blood pH rises above 7.45 it is called

Answer 169

Alkalosis

Question 170

Caused by hyperventilation, pH increases

Answer 170

Respiratory alkalosis

Question 171

Caused by inadequate production of acids or overproduction of bicarbonates, loss of digestive acids from vomiting

Answer 171

Metabolic alkalosis

Question 172

Respiratory acidosis and alkalosis occurs with abnormal

Answer 172

CO2 concentration

Question 173

Metabolic acidosis or alkalosis occurs with abnormal

Answer 173

bicarbonate concentration

Question 174

Ventilation is insufficient, PCO2 is high, carbonic acid is high, and respiratory acidosis occurs

Answer 174

Hypoventilation

Question 175

Rate of ventilation is faster than CO2 production. Less carbonic acid forms, PCO2 is low, and respiratory alkalosis occurs

Answer 175

Hyperventilation

Question 176

A person with metabolic acidosis will hyper/hypoventilate to blow off CO2, H+ decreases, pH rises.

Answer 176

Hyperventilate

Question 177

A person with metabolic alkalosis will hyper/hypoventilate, slowsslow down respiration, build up CO2, H+ increase, pH lowers

Answer 177

Hypoventilate

Question 178

Ch 16 slide 91/92

Answer 178

Charts comparing respiratory acid-base

Question 179

Kidneys function to regulate the extracellular fluid in the environment including (5)

Answer 179

Volume of blood plasma, wastes, electrolytes, oH, secrete erythopoieten

Question 180

Where is urine made

Answer 180

In the kidney nephrons

Question 181

Urine is transported using

Answer 181

peristalsis

Question 182

Order of urine to exit the body

Answer 182

Made in kidney nephrons > drains into renal pelvis > down ureter to bladder > through urethra

Question 183

Two distinct regions of the kidney

Answer 183

renal cortex and renal medulla (renal pyramids and columns)

Question 184

Renal pyramids drain into

Answer 184

Minor calyx > major calyx > renal pelvis

Question 185

the muscles that line the wall of the urinary bladder are called

Answer 185

Detrusor muscles

Question 186

The internal urethral sphincter is what kind of muscle

Answer 186

Smooth muscle

Question 187

The external urethral sphincter is what kind of muscle

Answer 187

skeletal muscle

Question 188

Neurons in the S2-S4 normally inhibit parasympathetic nerves to the

Answer 188

detrusor muscles. called guarding reflex

Question 189

Where is the micturition center located

Answer 189

in the pons

Question 190

How many nephrons does each kidney have

Answer 190

more than a million

Question 191

Consists of small tubules and associated blood vessels

Answer 191

Nephrons

Question 192

Ch 17 Slide 9/10

Answer 192

Anatomy of the kidneys

Question 193

Order of the renal blood vessels

Answer 193

Renal artery > Interlobar arteries > Arcuate arteries > Interlobular arteries > Afferent arterioles Glomerulus >
Efferent arterioles > Peritubular capillaries > Interlobular veins > Arcuate veins > Interlobar veins > Renal vein

Question 194

What parts make up the renal corpuscle

Answer 194

Glomerular capsule and the glomerulus

Question 195

Filtrate produced in the renal corpuscle passes into the

Answer 195

Proximal convoluted tubule

Question 196

After filtrate passes through the proximal convoluted tubule, the fluid passes into the

Answer 196

descending and ascending limbs of the loop of Henle

Question 197

After the loop of Henle, fluid passes into the

Answer 197

distal convoluted tubule and then into the collecting duct and then into the minor calyx

Question 198

Two types of nephrons

Answer 198

Juxtamedullary (better at making concentrated urine), and cortical

Question 199

Fenestrated capillaries of the glomerulus allow for what to happen

Answer 199

Large pores allow for water and solutes to leave but not blood cells and most plasma proteins

Question 200

Filtrate must pass through

Answer 200

Capillary fenestrae, glomerular basement membrane, visceral later of the glomerular capsule composed of cells called podocytes

Question 201

CH 17 SLIDE 17

Answer 201

Glomerular Corpuscle and Filtration Barrier

Question 202

What is the major barrier for the filtration of plasma proteins in the glomerular corpuscle

Answer 202

Slits in the pedicles called slit diaphragm pores

Question 203

Proteins in urine are caused by and is called

Answer 203

Defects in the slit diaphragm pores.

called proteinuria

Question 204

How does the fluid in the glomerular capsule get there (3)

Answer 204

hydrostatic pressure of the blood, colloid osmotic pressure, and very permeable capillaries

Question 205

Net filtration pressure in the glomerular capillaries is

Answer 205

10 mmHg

Question 206

What is the Glomerular Filtration Rate (GFR)

Answer 206

the volume of filtrate produced by both kidneys each minute (115-125mL = 180 L/day)

Question 207

How long does it take for the total blood volume to be filtered

Answer 207

40 minutes

Question 208

Extrinsic regulation of filtration rates occurs from

Answer 208

Sympathetic nervous system

Question 209

Intrinsic regulation of filtration rate occurs from and is called

Answer 209

the kidneys; renal autoregulation

Question 210

What happens to filtration with the sympathetic nervous system.

Answer 210

In F/F situation, vasoconstriction, which helps divert blood to heart and muscles, urine formation decreases to compensate for the drop in blood pressure.

Question 211

What happens to filtration during renal autoregulation

Answer 211

GFR is constant even if BP fluctuates. Myogenic constriction.
Tubulogolmerular feedback

Question 212

What is myogenic constriction?

Answer 212

Smooth muscles in arterioles sense an increase in blood pressure

Question 213

What is tubuloglomerular feedback

Answer 213

Cells in the ascending limb of the loop of Henle (macula densa) sense a rise in water and sodium as occurs with increased blood pressure

Question 214

Ch 17 Slide 25

Answer 214

Chart comparing Glomerular Rates regulation

Question 215

What is reabsorption

Answer 215

The return of filtered molecules to the blood

Question 216

where does 85% of reabsorption occur

Answer 216

In the proximal tubules of the descending hoop of Henle

Question 217

Osmolality of filtrate in the glomerular capsule is equal to that of

Answer 217

Blood plasma (isoosmotic)

Question 218

Na+ is actively transported in/out of the filtrate into the peritibular blood to set up a concentration gradient to drive osmosis

Answer 218

Out

Question 219

Active transport in the proximal tubule

Answer 219

Cells have a lower Na+ concentration than filtrate, so Na+ diffuses into these cells and is then pumped out on the other side

Question 220

Passive transport in the proximal tubule

Answer 220

The pumping of sodium into the interstitial space attracts negative Cl - out of the filtrate. Water follows Na+ and Cl- into the tubular cells and the interstitial space. Then into the peritubular capillaries

Question 221

How much water is absorbed through the descending limb of the Loop of Henle

Answer 221

20% of water. The rest is absorbed in the nephron under the control of ADH

Question 222

Fluid entering the loop of Henle is ____ to extracellular fluids

Answer 222

Isotonic

Question 223

What part of the Loop of Henle sets up a gradient for the osmosis of water?

Answer 223

Ascending portion

Question 224

NaCl is actively pumped into the interstitial fluid from the thick segment. Walls are not permeable to water. Surrounding fluid becomes concentrated at the bottom of the tube. Tubular fluid entering the descending loop of Henle becomes more hypotonic as it ascends the loop

Answer 224

Ascending Loop of Henle

Question 225

is permeable to water but not salt. Water is drawn out of the filtrate and into the interstitial space where it is picked up by capillaries. As it descends, it becomes more solute concentrated

Answer 225

Descending loop of henle

Question 226

Mechanism created between the two portions of the loop of Henle

Answer 226

Positive feedback. the more salt the ascending limb removes, the saltier the fluid entering it will be.

Question 227

Countercurrent multiplication

Answer 227

the more salt the ascending limb removes, the saltier the fluid entering it will be.

Question 228

Countercurrent mechanism steps

Answer 228

Interstitial fluid is hypertonic due to NaCl pumped out of the ascending limb.
Water leaves descending limb by osmosis, making the filtrate hypertonic going into the ascending limb.
More NaCl in the ascending limb can now be pumped out into the interstitial fluid.
The greater concentration of the interstitial fluid draws more water from the descending limb.
Filtrate in ascending limb now more concentrated.
Continues until the maximum NaCl concentration of the inner medulla is reached.

Question 229

Ch 17 Slide 38

Answer 229

Diagram showing Countercurrent Exchange

Question 230

What is the vasa recta

Answer 230

Specialized blood vessels around Loop of Henle which create the countercurrent system because it takes in salts from the descending region but lose them again in the ascending region. Keeps the salt in the interstitial space.

Question 231

What pulls water down the ascending region of the vasa recta, which is removed from the interstitial space

Answer 231

High salt concentration at the beginning

Question 232

Urea

Answer 232

Waster product of protein metabolism which contributes to countercurrent exchange

Question 233

Where does urea come from?

Answer 233

Transported out of collecting duct and into interstitial fluid. Diffuses back into ascending limb and cycles around continuously. Helps set up solute concentration gradients.

Question 234

Ch 17 slide 44

Answer 234

Puts it all together

Question 235

Last stop in urine formation, impermeable to NaCl but permeable to water

Answer 235

collecting duct

Question 236

Collecting duct and ADH path sequence

Answer 236

ADH binds to receptors on collecting duct cells > cAMP > protein kinase > vesicles with aquaporin channels fuse to plasma membrane

Question 237

Where is ADH produced, stored, and released

Answer 237

Produced in hypothalamus. Stored and released from posterior pituitary gland. Release stimulated by increase in blood osmolality

Question 238

Renal clearance - excretion

Answer 238

Just getting rid of stuff

Question 239

Renal clearance - reabsorption

Answer 239

Everything that could get excreted, but doesn’t. Returns stuff to the blood.

Question 240

Renal clearance - secretion

Answer 240

Substances are moved form the peritubular capillaries into the tubules

Question 241

Excretion rate =

Answer 241

(Filtration rate + secretion rate) - reabsorption rate

Question 242

Excretion rate is used to measure

Answer 242

GFR (glomerular filtration rate), an indicated of renal health

Question 243

Organic anion transporters and organic cation transporters are

Answer 243

membrane carriers specific to foreign substances that transport drugs into the tubules

Question 244

Drug secreting carriers are polyspecific

Answer 244

overlap function

Question 245

GFR =

Answer 245

(rate of urine formation x inulin concentration) / (inulin concentration in plasma)

Question 246

What is para-aminohippuric acid (PAH)

Answer 246

An exogenous molecule injected for measurement of total renal blood flow

Question 247

All PAH in the peritubular capillaries will be secreted by

Answer 247

OATs, so the time it takes to clear all PAH injected indicates blood flow to these capillaries

Question 248

Ch 17 Slide 58

Answer 248

Renal clearance of PAH

Question 249

Where is glucose completely reabsorbed

Answer 249

In the proximal tubule via secondary active transport, with sodium, facilitated diffusion, and simple diffusion

Question 250

Glucose/Na+ cotransporters have a maximum and if maximum is reached, then the carriers are

Answer 250

saturated. Saturation spills glucose into the urine = glycosuria and is a sign of diabetes.

Question 251

Kidneys match electrolyte excretion to

Answer 251

ingestion

Question 252

Na+ healthy levels are important for

Answer 252

Blood pressure and blood volume

Question 253

Control of K+ is important in

Answer 253

healthy skeletal and cardiac muscle activity

Question 254

Aldosterone plays a big role in

Answer 254

Na+ and K+ balance

Question 255

Aldosterone independent response

Answer 255

Increase in blood K+ triggers an increase in the number of K+ channels in the cortical collecting duct. Channels removed when blood K levels drop.

Question 256

Aldosterone dependent response

Answer 256

Increase in blood K triggers adrenal cortex to release aldosterone. Increases K secretion in the distal tubule and collecting duct.

Question 257

A rise in blood K directly stimulates production of aldosterone in the

Answer 257

adrenal cortex

Question 258

A fall in blood Na indirectly stimulates production of aldosterone via the

Answer 258

renin-angiotensin-aldosterone system

Question 259

Where is the juxtaglomerular apparatus located

Answer 259

Where the afferent arteriole comes into contact with the distal tubule

Question 260

What does the juxtaglomerular apparatus sense

Answer 260

A decrease in plasma Na which results in a fall in blood volume

Question 261

Granular cells secrete renin into the

Answer 261

afferent arteriole

Question 262

Angiotensinogen is converted into angiotensin I by

Answer 262

the juxtaglomerular apparatus

Question 263

What converts Angiotensin I into angiotensin II

Answer 263

Angiotensin-convering enzyme (ACE)

Question 264

The juxtaglomerular apparatus stimulates the cortex to make what

Answer 264

Aldosterone. Promotes the reabsorption of Na from distal tubule and cortical collecting duct.

Question 265

Low salt levels result in lower blood volumes due to inhibition of

Answer 265

ADH secretion

Question 266

Renin is secreted by granular cells when they detect

Answer 266

Reduced blood volume

Question 267

What is the macula densa

Answer 267

Part of the distal tubule that forms the juxtaglomerular apparatus

Question 268

What does the macula densa do?

Answer 268

Sensor for tubuloglomerular feedback needed for regulation of glomerular filtration rate. Controlled via negative feedback

Question 269

When there is more Na and H2O in the filtrate, a signal is sent to the afferent arteriole to

Answer 269

inhibit the production of renin

Question 270

Increases in blood volume also increase the release of

Answer 270

atrial natriuretic peptide hormone from the atria of the heart when atrial walls are stretched

Question 271

What does atrial natriuretic peptide do?

Answer 271

Stimulates kidneys to excrete more salt and therefore more water. Decreases blood volume and blood pressure.

Question 272

B-type natriuretic peptide is secreted in response to

Answer 272

increased volume and pressure within the ventricles and it acts like ANP to promote diuresis

Question 273

Reabsorption of __ stimulates the secretion of other positive ions; K and H

Answer 273

Na

Question 274

Acidosis stimulates the secretion of __ and inhibits the secretion of __ ions and can lead to hyperkalemia

Answer 274

H and K ions

Question 275

Alkalosis stimulates the secretion and excretion of more

Answer 275

K

Question 276

Hyperkalemia stimulates the secretion of __ and inhibits the secretion of __ and can lead to acidosis

Answer 276

K and H ions

Question 277

Kidneys maintain blood pH by reabsorbing bicarbonate and secreting __; urine is thus acidic

Answer 277

H

Question 278

Proximal tubule uses Na/H pump to let __ out and __ in

Answer 278

Na; H