Kidney (K1-K9)

Question 1

these are firm, reddish brown glands, located close to the dorsal body wall high in the abdomen at the level of the thoracolumbar junction

Answer 1

kidneys

Question 2

this kidney is usually more cranial (except the pig)

Answer 2

right

Question 3

the right kidney is embedded in this of the liver, which secures its position

Answer 3

renal fossa

Question 4

this is tough and fibrous covering of the kidneys that restricts their ability to expand

Answer 4

capsule

Question 5

within the kidney, the parenchyma can be visually divided into these two sections

Answer 5

outer cortex and inner medulla

Question 6

this part of the kidneys contains the renal corpuscles and convoluted parts of renal tubules; it is light in color and granular in appearance

Answer 6

cortex

Question 7

this part of the kidney is characterized by its striated appearance and contains collecting ducts and nephric loops

Answer 7

inner medulla

Question 8

these are the functional units of the kidney, the structures that are apparent within the cortex and medulla

Answer 8

nephrons (corpuscle, tubules, loops, and ducts)

Question 9

these are paired tubes that form as the internal ducts within the kidneys join to form a common expansion (renal pelvis); exit the kidney at the hilus and follow a saggital course towards the pelvis

Answer 9

ureters

Question 10

the ureter bends medially to enter this in the male

Answer 10

genital fold

Question 11

the ureter bends medially to enter this in the female

Answer 11

broad ligament

Question 12

what are the three regions of the bladder

Answer 12

apex, the neck, body

Question 13

this region of the bladder is a cranial blind end

Answer 13

apex

Question 14

this region of the bladder is a funnel-shaped region between ureter openings and urethra

Answer 14

the neck

Question 15

this region of the bladder is situated between the neck and apex

Answer 15

the body

Question 16

this is the duct through which urine is discharged from the bladder

Answer 16

urethra

Question 17

the male urethra consists of these two components

Answer 17

pelvic and penile

Question 18

each kidney is supplied by this artery arising from the abdominal aorta

Answer 18

renal artery

Question 19

veins that correspond with the arteries of the kidney join to form this single vein that enters the vena cava

Answer 19

renal vein

Question 20

efferent arterioles arising from juxtamedullary nephrons descend into the medulla and give rise to this, which descend and re-ascend close to the Loops of Henle

Answer 20

vasa recta

Question 21

this is the functional unit of the kidney and consists of the renal corpuscles and renal tubules

Answer 21

nephron

Question 22

what are the two major parts of the nephron

Answer 22

renal corpuscles and renal tubules

Question 23

these are responsible for the filtration of blood and are made up of Bowman’s capsule and the glomerulus

Answer 23

renal corpuscles

Question 24

this part of the renal corpuscles consists of a single layer of flattened cells resting on a basement membrane

Answer 24

Bowman’s capsule

Question 25

this is a network of capillaries that arise from the afferent arteriole, and invaginate Bowman’s capsule

Answer 25

glomerulus

Question 26

the renal cortex is easily identified at low magnification due to the presence of these, which are not found in the renal medulla

Answer 26

renal corpuscles

Question 27

the capillary loops of the glomerulus are supported by specialized connective tissue called this

Answer 27

glomerular mesangium

Question 28

these cells are contractile and can modify the diameter of glomerular capillaries (secrete vasoactive substances and other factors)

Answer 28

mesangial

Question 29

this is the first part of the renal tubule which drains Bowman’s capsule and is made up of a coiled section and a shorter straight segment

Answer 29

proximal tubule

Question 30

this is the coiled section of the proximal tubule; it is lined by simple, cuboidal epithelium with a prominent brush border which increases surface area for absorption; it is the longest and most convoluted part of the nephron

Answer 30

proximal convoluted tubule (PCT)

Question 31

this is the shorter straight segment of the proximal tubule; it is lined by low cuboidal epithelium with no brush border and leads onto the loop of Henle

Answer 31

proximal straight tubule (PST)

Question 32

name the three parts of the loop of Henle

Answer 32

descending thin limb, ascending thin limb, thick ascending limb

Question 33

the cells in th thick ascending limb of loop of Henle that lie closest to Bowman’s capsule are specialized cells known as this; they mark the end of the thick ascending limb and start of distal convoluted tubule

Answer 33

macula densa

Question 34

this is a group of specialized cells that regulate renal blood blow comprised of 3 cell types

Answer 34

juxtaglomerular apparatus

Question 35

what are the 3 cell type that comprise the juxtaglomerular apparatus?

Answer 35

1. extraglomerular mesangial cells
2. granular cells
3. macula densa cells

Question 36

once the fluid has been deposited into the calyx it is known as this and no longer changes

Answer 36

urine

Question 37

this is an area of the urinary bladder and is a dorsal triangular area connecting the ureteral openings and urethral exit; has a smooth mucosa and originates from mesoderm

Answer 37

trigone

Question 38

the male urethra is lined by this type of epithelium

Answer 38

stratified or psuedostratified columnar epithelium

Question 39

the female urethra is predominately lined by this type of epithelium (but changes to stratified squamous epithelium near the external urethral orifice)

Answer 39

urinary epithelium

Question 40

this species kidney has obvious external demarcation of the cortex and separation of the medulla into lobes/pyramids

Answer 40

bovine

Question 41

what is the classification of the bovine kidney

Answer 41

multilobar or multipyramidal

Question 42

this species kidney is multilobar, however has a single cortex with a smooth outer surface and has a flattened appearance

Answer 42

pig

Question 43

these species (5) kidney is unilobar, the cortex and medulla fuse into a single unit and the linearly fused papillae form a renal crest

Answer 43

cat, dog, horse, rodent, and sheep

Question 44

these 2 species have the standard smooth, bean-shaped kidneys that are reddish brown and cannot be distinguished from each other

Answer 44

dog and sheep

Question 45

this species has a unilobular kidney with a fused cortex and is heart-shaped/triangle-shaped

Answer 45

horse

Question 46

approximately 2/3 of total body water (40% total body weight) is located within cells and known as this

Answer 46

intracellular fluid (ICF)

Question 47

one third (20% total body weight) is located outside of cells and known as this

Answer 47

extracellular fluid (ECF)

Question 48

what are the two subcategories of extracellular fluid

Answer 48

interstitial or intravascular

Question 49

what percent of total lean bodyweight is made up of water

Answer 49

60%

Question 50

what is the ratio of fluid percentages in the body? (total lean bodyweight made of water:intracellular fluid:extracellular fluid)

Answer 50

60:40:20

Question 51

the intracellular and extracellular fluid compartments are separated by this

Answer 51

cell membrane

Question 52

the interstitial and intravascular fluid compartments are divided by this

Answer 52

vascular endothelium

Question 53

what are the three main colloid particles within plasma?
vascular endothelium is not permeable to them

Answer 53

albumin, globulins, and fibrinogen

Question 54

the particles within a particular fluid compartment exert this meaning they can cause fluid to move by osmosis to one or other side of the membrane, towards the area of higher solute concentration (higher osmolarity)

Answer 54

osmotic pressure (tonicity)

Question 55

this is a measure of all particles dissolved within a fluid compartment , whether or not they can cross the semi-permeable membrane

Answer 55

total fluid osmolarity

Question 56

particles that can cross the semi-permeable membrane contribute to this but not to this

Answer 56

osmolarity but not osmotic pressure

Question 57

what is the average plasma osmolarity in a dog

Answer 57

300 mOsm/kg

Question 58

this pressure is the contribution of colloid particles and their associated electrolytes towards plasma oncotic pressure

Answer 58

oncotic pressure (aka colloid osmotic pressure, COP)

Question 59

this is the only difference between intravascular and interstitial fluid

Answer 59

the concentration of proteins

Question 60

standard biochemical tests measure solutes within this fluid and may not reflect changes in total body solute levels

Answer 60

extracellular fluid

Question 61

fluid flux across the capillary endothelium is described by this equation

Answer 61

Starling’s equation

Question 62

what are the Starling forces in Starling’s equation

Answer 62

the oncotic and hydrostatic pressure gradient’s between the capillary and interstitium

Question 63

along the length of the capillary, this pressure increases and this pressure decreases

Answer 63

oncotic pressure increases, hydrostatic pressure decreases

Question 64

fluid moves (into or out of?) the capillary at the arteriolar end/beginning

Answer 64

out of (into the interstitium)

Question 65

fluid moves (into or out of?) the capillary at the end ?

Answer 65

into the capillary

Question 66

why is plasma COP essential to prevent excessive fluid efflux into the the interstitium?

Answer 66

intravascular and interstitial osmolality would be identical and fluid would move freely out of capillaries causing oedema and potential loss of blood volume

Question 67

this is a gel-like matrix on the luminal surface of endothelial cells now thought to determine transcapillary fluid flux

Answer 67

glycocalyx

Question 68

these are fluids containing electrolytes and other solutes that can freely cross the capillary endothelium to pass between the intravascular and interstitial space

Answer 68

crystalloids

Question 69

crystalloids are classified according to this

Answer 69

their osmolarity relative to that of plasma

Question 70

fluids with osmolarity greater than plasma (300 mOsm/kg) are termed this
ex: 7.2% NaCl

Answer 70

hypertonic

Question 71

fluids with osmolarity lower than plasma (300 mOsm/kg) are termed this
ex: 0.45% NaCl

Answer 71

hypotonic

Question 72

fluids with osmolarity similar to plasma (300 mOsm/kg) are termed this
ex: 0.9% NaCl

Answer 72

isotonic

Question 73

this type of saline is very effective for resuscitating patients in severe shock because water is pulled rapidly out of the intracellular space and redistributes between the interstitial and intravascular spaces

Answer 73

hypertonic saline

Question 74

these losses of water are easy to measure, i.e. urine

Answer 74

sensible losses

Question 75

these losses of water are difficult to measure, i.e. feces, saliva, evaporation from respiratory tract, skin

Answer 75

insensible losses

Question 76

this component of urinary water loss is the amount of water required for the kidney to excrete solutes such as urea

Answer 76

obligatory loss

Question 77

this component of urinary water loss is the removal of any water excess to body requirements

Answer 77

free loss

Question 78

healthy dogs drink about this much water per day

Answer 78

50-60 mL/day

Question 79

if a dog drinks more than 100 mL of water per day it is defined as this

Answer 79

polydipsia

Question 80

what is the normal urine output of a healthy dog?

Answer 80

1-2 mL/kg/hour

Question 81

name some causes of abnormal fluid loss

Answer 81

vomiting, diarrhea, polyuria, high body temp, excessive panting, hemorrhage, exudation/transudation into a body category, ongoing physiological losses due to reduced water intake

Question 82

fluid is often lost first from here

Answer 82

extracellular fluid

Question 83

a loss of hypotonic fluid will have this effect on ECF tonicity resulting in this shift of fluid

Answer 83

hypertonic, water moves out of ICF

Question 84

a loss of hypertonic fluid will have this effect on ECF tonicity resulting in this shift of fluid

Answer 84

hypotonic, water moves into ICF

Question 85

this type of fluid loss is loss of water in excess of solute

Answer 85

hypotonic

Question 86

this type of fluid loss is loss of water and solute in equal proportions

Answer 86

isotonic

Question 87

this type of fluid loss is loss of solute in excess of water

Answer 87

hypertonic

Question 88

perfusion of tissue with blood depends on this fluid compartment

Answer 88

intravascular fluid compartment

Question 89

hydration depends on these 2 fluid compartments

Answer 89

interstitial and intracellular fluid compartments

Question 90

this is the process by which water and solutes leave the vascular system through the filtration barrier of the glomerular capillaries and enter the Bowman’s space

Answer 90

glomerular filtration

Question 91

the volume of filtrate formed per unit of time by glomerular filtration is known as this

Answer 91

Glomerular Filtration Rate (GFR)

Question 92

this is a network of capillaries between the afferent and efferent arterioles, encased within the Bowman’s capsule

Answer 92

glomerular filter

Question 93

what are the three major layers of the glomerular capillary membrane which make up the filtration barrier

Answer 93

1. glomerular endothelium
2. basement membrane
3. podocytes

Question 94

this layer of the glomerular capillary membrane prevents filtration of plasma proteins because of the strong negative electrical charges associated with the proteoglycan molecules

Answer 94

basement membrane

Question 95

what 3 layers is the basement membrane of the glomerular capillary membrane made up of

Answer 95

1. lamina rara interna: fused to endothelium
2. lamina densa: middle
3. lamina rara externa: fused to epithelium

Question 96

which is the most significant filtration barrier of the glomerular capillary?

Answer 96

basement membrane

Question 97

this is a layer of intricate interlocking cells that make up the visceral epithelium of the glomerular capillary membrane

Answer 97

podocytes

Question 98

this is the resulting product of glomerular filtration

Answer 98

an ultrafiltrate of plasma

Question 99

solutes pass through the 3 layers of glomerular capillary membrane to form an ultra filtrate which enters this

Answer 99

proximal tubule

Question 100

the glomerular filtration barrier restricts the filtration of molecules on the basis of these 3 things

Answer 100

size, weight, and electrical charge

Question 101

all surfaces of the glomerular filtration barrier contained fixed polyanions, which repel macromolecules with this charge (prevents protein loss with urine since many proteins in the blood have this charge)

Answer 101

negative

Question 102

which Starling’s forces favor glomerular capillary filtration

Answer 102

hydrostatic pressure in glomerular capillary (oncotic pressure in Bowman’s capsule is near zero so doesn’t really favor filtration)

Question 103

which Starling’s forces oppose glomerular capillary filtration

Answer 103

oncotic pressure in glomerular capillary bed and hydrostatic pressure in Bowman’s space

Question 104

for glomerular capillaries, the net ultrafiltration pressure always (favors or opposes?) filtration
so, the direction of fluid movement is always (into or out of?) capillaries

Answer 104

favors filtration, out of capillaries

Question 105

GFR is regulated by changes in the hydrostatic pressure within the glomerular capillary which is mediated by changes in this

Answer 105

resistance of the afferent and efferent arteriole

Question 106

afferent arteriolar resistance is (positively or negatively?) correlated with the hydrostatic pressure in the glomerular capillary and therefore GFR?

Answer 106

negatively (decrease in resistance increases hydrostatic pressure and GFR)

Question 107

efferent arteriolar resistance is (positively or negatively?) correlated with the hydrostatic pressure in the glomerular capillary and therefore GFR?

Answer 107

positively (decrease in resistance decreases hydrostatic pressure and GFR)

Question 108

what is the equation for renal blood flow (RBF)?

Answer 108

RBF = (renal artery pressure - renal vein pressure) / total renal vascular resistance

Question 109

the blood flow through the kidneys serves these 5 important functions

Answer 109

1. indirectly determines GFR
2. modifies rate of solute & water reabsorption by proximal tubule
3. participates in concentration & dilution of urine
4. delivers O2, nutrients, and hormones to cells of nephron and returns CO2 and reabsorbed fluid and solutes to general circulation
5. delivers substrates for urinary excretion

Question 110

what are the 3 major sites for renal resistance

Answer 110

1. interlobular arteries
2. afferent arterioles
3. efferent arterioles

Question 111

Vasodilation of the afferent arteriole (decreased resistance) will have this effect on RBF and GFR

Answer 111

increase both RBF and GFR

Question 112

Vasoconstriction of the afferent arteriole (increased resistance) will have this effect on RBF and GFR

Answer 112

decrease both RBF and GFR

Question 113

Vasodilation of the efferent arteriole (decreased resistance) will have this effect on RBF and GFR

Answer 113

increase RBF and decrease GFR

Question 114

Vasoconstriction of the efferent arteriole (increased resistance) will have this effect on RBF and GFR

Answer 114

decrease RBF and increase GFR

Question 115

what are the 2 autoregulation mechanisms that maintain constant RBF and GFR when the systemic blood pressure is between 80-200 mmHg

Answer 115

myogenic reflex and tubuloglomerular feedback

Question 116

this reflex responds to changes in arterial blood pressure by constricting or dilating the afferent arteriole to maintain RBF and GFR at a constant level

Answer 116

myogenic

Question 117

this reflex responds to changes in the NaCl concentration of tubular fluid and has a predominant effect on the afferent arteriole to regulate RBF and GFR

Answer 117

tubuloglomerular feedback

Question 118

the NaCl concentration of tubular fluid is sensed by this part of the juxtaglomerular apparatus (JGA)

Answer 118

macula densa

Question 119

what are the 3 components of the juxtaglomerular apparatus (JGA)?

Answer 119

1. macula densa
2. extraglomerular mesangial cells
3. juxtaglomerular cells

Question 120

this component of the juxtaglomerular apparatus (JGA) is the thick ascending limb of Loop of Henle

Answer 120

macula densa

Question 121

this component of the juxtaglomerular apparatus (JGA) surround the capillary loop

Answer 121

extraglomerular mesagnial cells

Question 122

this component of the juxtaglomerular apparatus (JGA) are specialized smooth muscle cells and make up the afferent and efferent arterioles

Answer 122

juxtaglomerular cells

Question 123

when increased tubular fluid NaCl concentration is sensed by the macula densa, ATP and adenosine are released by the macula densa cells which has this effect on the afferent arteriole

Answer 123

vasoconstrictive effect (decreases RBF & GFR)

Question 124

when decreased tubular fluid NaCl concentration is sensed by the macula densa, signals are initiated with these 2 effects

Answer 124

vasodilation of afferent arteriole and increased renin release from JGA cells

Question 125

the ideal glomerular biomarker for measuring GFR must have these 3 characteristics

Answer 125

1. be readily filtered across the glomerular capillaries, with no size or charge restrictions
2. be secreted unchanged
3. cannot effect GFR

Question 126

this is the most tradition biomarker used for determining glomerular filtration; fructose polymer with 5000 Da molecular weight

Answer 126

inulin

Question 127

this is an end-product of muscle catabolism and is an example of an endogenously produced biomarker for GFR
-it is freely filtered by the glomerulus at a constant rate but is a poor sensitive marker for GFR as blood serum levels do not increase until GFR decreases > 75%

Answer 127

creatinine

Question 128

this is defined as the amount of substance filtered by the glomerulus into the Bowman’s space per unit time

Answer 128

filtered load

Question 129

this is the movement of filtered solutes and water from tubular lumen back into the peritubular capillary

Answer 129

reabsorption

Question 130

what are the 4 general mechanisms for reabsorption within the nephron

Answer 130

diffusion, facilitated diffusion, coupled transport, and active transport

Question 131

this is when solutes dissolved in water are also carried along with the water when it is reabsorbed across tubule segments

Answer 131

solvent drag

Question 132

if both solutes are transported via coupled transport in the same direction, the carrier protein is known as this

Answer 132

symporter

Question 133

name 2 examples of symporters (one in the proximal tubule and one in the thick ascending limb of the loop of Henle)

Answer 133

1. Na-glucose transporter
2. Na-K-2Cl transporter

Question 134

if each solute is transported via coupled transport in opposite directions, the carrier protein is known as this

Answer 134

antiporter

Question 135

name an example of an antiporter in the proximal tubule

Answer 135

Na-H transporter (Na into cell, H+ out of the cell into the lumen)

Question 136

what is the most prevalent example of active transport within the kidney (within the basolateral membrane)

Answer 136

Na-K-ATPase pump

Question 137

this is when solutes cross the tubular epithelium by passing BETWEEN the cells (through tight junctions)

Answer 137

paracellular transport

Question 138

this is when solutes cross the tubular epithelium by passing THROUGH cells

Answer 138

transcellular transport

Question 138

this type of junction in tubular epithelium promotes the reabsorption of a large concentration of solutes and water; commonly seen within the proximal tubule

Answer 138

leaky junction

Question 139

this type of junction in tubular epithelium have a low basal water permeability and effectively bar paracellular flow of water and solutes; typically found within the distal tubule

Answer 139

tight junctions

Question 140

most reabsorption of water and solutes that have been filtered by the glomerulus occurs here

Answer 140

proximal convoluted tubule (PCT)

Question 141

this is the longest and most convoluted part of nephron with a rich capillary network of peritubular capillaries surrounding it

Answer 141

proximal convoluted tubule (PCT)

Question 142

in mammals, the peritubular capillary originates at this and subdivides, wrapping closely around the proximal tubule, allowing for the return of reabsorbed molecules back into the bloodstream

Answer 142

efferent arteriole

Question 143

what are 4 reasons the proximal convoluted tubule has such a high efficacy for solute reabsorption

Answer 143

1. rich peritubular capillary network
2. brush border of microvilli
3. lateral cellular interdigitations of basolateral cell membrane
4. large numbers of mitochondria and protein carrier molecules

Question 144

this accounts for almost half of the total solutes in the tubular fluid entering the PCT and most of the rest are anions that must accompany it to maintain electroneutrality

Answer 144

sodium

Question 145

this is the first step in the process of solute reabsorption in the PCT
-achieved by the Na-K-ATPase pump

Answer 145

active transport of sodium out of tubular epithelial cell into interstitium

Question 146

how is glucose reabsorbed across the tubular epithelium in the PCT?

Answer 146

glucose transporters (not paracellular transport)

Question 147

why is glucose able to be almost completely reabsorbed in the PCT?

Answer 147

it is impermeable to the tight junctions

Question 148

how are many of the solutes (including urea, potassium, calcium and magnesium) reabsorbed in the PCT?

Answer 148

paracellular transport via leaky tight junctions

Question 149

this is responsible for concentrating or diluting the tubular fluid using concurrent multiplication

Answer 149

loop of Henle

Question 150

this limb of the loop of Henle has low, simple squamous epithelium with few mitochondria so there is relatively little active transport of solutes here; however it is highly permeable to water with aquaporin 1 receptors and is responsible for 20% of water resorption

Answer 150

thin descending limb

Question 151

the descending limb of the loop of Henle does not reabsorb solutes, so the tubular fluid tonicity (increases or decreases?) along its length and becomes this

Answer 151

increases, hypertonic

Question 152

solutes are reabsorbed within this limb of the loop of Henle (impermeable to water)

Answer 152

ascending limb

Question 153

the epithelial cells within this segment of the loop of Henle are relatively tall with many mitochondria and membrane in-foldings to allow for high capacity active solute transport

Answer 153

thick ascending limb

Question 154

these segments of the renal tubule are commonly referred to as the ‘diluting segment’ of the nephron because there is resorption of solutes without water which dilutes the tubular fluid

Answer 154

ascending limb of the loop of Henle & distal tubule

Question 155

this is known as the connecting segment and has properties of both the distal tubule and the collecting duct

Answer 155

late distal tubule

Question 156

this is the site for final urine processing by regulated tubular resorption and secretion largely by the actions of aldosterone and vasopressin

Answer 156

late distal tubule and collecting ducts

Question 157

what are the two distinct epithelial cells found in the late distal tubule and collecting ducts

Answer 157

principal cells and intercalated cells

Question 158

these cells in the late distal tubule/collecting ducts act to resorb both water and sodium & secrete potassium

Answer 158

principal cells

Question 159

this hormone acts to amplify the process of principal cells by up regulating and activating the basolateral Na-K-ATPase pumps, up regulating the apical sodium channels, and stimulating potassium secretion into the tubular lumen

Answer 159

aldosterone

Question 160

the water permeability of principal cells is directly controlled by this hormone which binds to specific receptors on the basolateral membrane, resulting in the insertion of water specific channels into the luminal membrane

Answer 160

vasopressin

Question 161

these cells found in the late distal tubule/collecting ducts are largely involved with regulation of acid base balance

Answer 161

intercalated cells

Question 162

name the 2 types of intercalated cells

Answer 162

alpha and beta

Question 163

this type of intercalated cells are the most important and function to secrete H+ ions and reabsorb HCO3 ions (key role in acid-base regulation)
-also resorb potassium into tubular fluid

Answer 163

alpha intercalated cells

Question 164

this type of intercalated cell functions to secrete HCO3 and reabsorb H+

Answer 164

beta intercalated cells

Question 165

where is the majority of sodium (65%) reabsorbed?

Answer 165

PCT (proximal convoluted tubule)

Question 166

these are channels for the transfer of water which are expressed in the luminal cell membranes in the descending limb of the loop of Henle

Answer 166

Aquaporins (AQP)

Question 167

most of the nephrons in the kidney are short-loop nephrons, so they don’t have this section

Answer 167

ascending thin limbs of Henle’s loop

Question 168

by what mechanism does the distal convoluted tubule reabsorb salt without water

Answer 168

Na-Cl symporter

Question 169

what 3 types of baroreceptors are important in regulating sodium excretion

Answer 169

1. arterial baroreceptors
2. cardiopulmonary baroreceptors
3. intrarenal baroreceptors

Question 170

these stretch receptors detect low perfusion pressure, usually when intravascular volume is too low

Answer 170

high-pressure arterial stretch receptors

Question 171

these stretch receptors detect whether intravascular volume is too high

Answer 171

low-pressure venous stretch receptors

Question 172

these cells in the brain have sensory sodium channels that detect and respond to extracellular sodium concentrations and respond by modulating the activity of nearby neurons involved in the control of body sodium

Answer 172

glial cells

Question 173

this is the most important controller of sodium excretion and volume sensing

Answer 173

RAAS

Question 174

this is the most important peptide produced by the RAAS,

Answer 174

angiotensin II

Question 175

this is produced in the kidneys by the juxtaglomerular apparatus and converts angiotensinogen to angiotensin I

Answer 175

renin

Question 176

this is the rate limiting step of the formation of angiotensin II

Answer 176

amount of renin available to convert angiotensinogen to AI

Question 177

these are the 3 key regulators of renin production

Answer 177

1. sympathetic input
2. aferent arteriole pressure
3. macula densa response

Question 178

this is released from postganglionic sympathetic nerve cells and activates the release of renin from the juxtaglomerular granular cells

Answer 178

norepinephrine

Question 179

the granular cells respond directly to pressure in the afferent arteriole; when pressure decreases, renin production (increases or decreases?)

Answer 179

increases

Question 180

what are the 4 key actions of angiotensin II via the RAAS?

Answer 180

1. stimulates behavioral actions
2. promotes sodium reabsorption
3. controls the secretion of aldosterone
4. vasoconstrictor

Question 181

this is a key hormone secreted mainly by the heart; it inhibits the release of renin (and the actions of AII that promote sodium reabsorption), acts on the medullary collecting duct to inhibit sodium reabsorption, and relaxes the afferent arteriole promoting increased glomerular filtration

Answer 181

atrial natriuretic peptide (ANP)

Question 182

these are agents that increase urine flow; their goal is to reduce ECF volume to correct or prevent edema and they work by increasing sodium excretion

Answer 182

diuretics

Question 183

the most powerful diuretics act by blocking this in the thick ascending limb of the loop of Henle (called loop diuretics)

Answer 183

Na-K-Cl symporter

Question 184

this group of diuretics block the Na-Cl symporter in the DCT

Answer 184

thiazide diuretics

Question 185

what is the most dangerous unwanted side effect of many diuretics

Answer 185

increased secretion of potassium (hypokalemia)

Question 186

the vast majority of body potassium is (intracellular or extracellular?)

Answer 186

intracellular

Question 187

a patient with hypokalemia has a more (negative or positive?) resting potential than normal; this makes the cell (more or less?) excitable

Answer 187

negative (potassium ions diffuse faster out of cell); less excitable

Question 188

this is the rapid homeostatic mechanism that prevents large post prandial swings in serum potassium

Answer 188

intracellular sequestration (extrarenal potassium homeostasis)

Question 189

what are the two major factors that stimulate the Na-K-ATPase pump for potassium uptake?

Answer 189

insulin and adrenaline

Question 190

what happens to potassium when extracellular hydrogen levels are high (acidosis) so H+ moves into the cells

Answer 190

potassium moves out of the cell to maintain electroneutrality

Question 191

potassium can be both secreted and reabsorbed in this part of the kidney (reabsorption always but secretion only when the body needs to get rid of potassium)

Answer 191

distal nephron

Question 192

Reabsorption of potassium always occurs at these 3 parts in the kidney

Answer 192

1. proximal convoluted tubule (paracellular route)
2. thick ascending limb of loop of Henle (Na-K-2Cl cotransporter)
3. Collecting ducts (intercalated cells)

Question 193

Secretion of potassium only occurs when the body needs to get rid of potassium in this location in the kidneys

Answer 193

collecting ducts (principal cells)

Question 194

these cells in the collecting ducts reabsorb sodium and secrete potassium

Answer 194

principal cells

Question 195

this is the dominant stimulus for renal potassium excretion; it is secreted by the adrenal glands in response to angiotensin II and by increased plasma potassium concentration
it acts on the principal cells to enhance sodium reabsorption and potassium secretion

Answer 195

aldosterone

Question 196

which one inhibits the Na-K-ATPase pumps and which stimulates them: acidosis and alkalosis?

Answer 196

acidosis inhibits, alkalosis stimulates

Question 197

this is the most commonly used K+ wasting diuretic; it acts on the thick ascending limb of loop of Henle where it inhibits the luminal Na-K-Cl cotransporter, exacerbating potassium loss

Answer 197

furosemide

Question 198

what are the 2 classes of potassium-sparing diuretics

Answer 198

1. aldosterone receptor antagonists
2. aldosterone independent mechanisms

Question 199

this is an aldosterone receptor antagonist diuretic which blocks the aldosterone receptor located on basolateral side of the cortical collecting duct principal cells (causing lack of potassium excretion)

Answer 199

spironolactone

Question 200

the production of either concentrated or dilute urine by the kidney is regulated via these 3 main mechanisms

Answer 200

1. dilution of tubule fluid by TAL and DCT
2. generation of hypertonic medullary interstitium
3. variability of water permeability of collecting duct in response to vasopressin

Question 201

a change in this is the major determinant of the volume of water lost by the kidney

Answer 201

change in plasma osmolality

Question 202

this is defined as 1 mole of any fully dissociated substance dissolved in water

Answer 202

osmole

Question 203

this is defined as the concentration of osmoles in a mass of solvent (kg)

Answer 203

osmolality

Question 204

this is defined as the concentration of osmoles in a volume of solvent (L)

Answer 204

osmolarity

Question 205

this is the major determinant of plasma osmolality

Answer 205

serum sodium concentration

Question 206

these are located within the hypothalamus and sense changes in plasma osmolality

Answer 206

osmoreceptors

Question 207

an increase in plasma osmolality sensed by osmoreceptors in the hypothalamus results in increased production and release of this into circulation

Answer 207

vasopressin

Question 208

name 3 effects of vasopressin that have a direct effect on both the volume of urine produced and the urine concentration/osmolality

Answer 208

1. net absorption of water from tubule lumen
2. stimulates reabsorption of urea
3. enhances reabsorption of NaCl

Question 209

the formation of a dilute or concentrated urine is achieved via a countercurrent mechanism within the nephron including these 3 structures

Answer 209

1. loop of Henle
2. cortical and medullary collecting ducts
3. blood supply to these segments

Question 210

what are the 2 countercurrent systems present within the nephron?

Answer 210

1. loop of Henle
2. vasa recta

Question 211

this limb of the loop of Henle is permeable to water and impermeable to solutes

Answer 211

descending limb

Question 212

this limb of the loop of Henle is permeable to solute and impermeable to water

Answer 212

ascending limb

Question 213

at any point along the loop of Henle, the fluid in the ascending limb has (higher or lower?) osmolality than the fluid in the descending limb

Answer 213

lower

Question 214

osmolality of the tubular fluid and interstitium at the tip of the hairpin turn of the loop of Henle is much (greater or lesser?) compared to those at the corticomedullary junction

Answer 214

greater

Question 215

these are the most abundant solutes within the interstitial medulla

Answer 215

NaCl and urea

Question 216

this is generated by the liver as a product of protein metabolism and is freely filtered by the glomerulus

Answer 216

urea

Question 217

what are the 2 basic steps for the formation of dilute urine

Answer 217

1. NaCl reabsorption w/o water in the thick ascending limb of loop of Henle
2. absence of vasopressin causing no water reabsorption in collecting tubules

Question 218

what are the two major steps for the excretion of a concentrated urine

Answer 218

1. medullary interstitium is made hyperosmotic by reabsorption of NaCl without water in ascending limb of loop of Henle
2. vasopressin increases permeability of collecting duct to water to be reabsorbed passively

Question 219

this is a capillary network derived from efferent arterioles that form a parallel set of hairpin loops with the loop of Henle within the medulla;
highly permeable to solute and water & return NaCl and H2O back into systemic circulation; plays integral role in maintenance of medullary osmotic gradient

Answer 219

vasa recta

Question 220

what percent of the total body calcium is distributed in the extracellular and intracellular fluid?

Answer 220

1%

Question 221

what are the 3 forms of calcium present in the total extracellular calcium?

Answer 221

1. free (55%)
2. Protein bound (35%)
3. complexed to other anions (10%)

Question 222

this is the biologically active form of calcium and is the most important for physiological control of calcium concentrations

Answer 222

ionized form

Question 223

what form of extracellular Ca is favored with acidemia (increased acid w/in the blood)?

Answer 223

ionized Ca (free)

Question 224

what form of extracellular Ca is favored with alkalemia (acid deficit w/in the blood)?

Answer 224

protein bound (albumin-bound)

Question 225

what happens to the total calcium concentration when there is decreased albumin concentration?

Answer 225

decreases (decr. protein bound fraction of Ca)

Question 226

what is the distribution of phosphorus in the body? (3 locations)

Answer 226

1. bone (80-85%)
2. soft tissues (15%)
3. extracellular space (1%)

Question 227

where is the majority of filtered calcium reabsorbed?

Answer 227

proximal tubule

Question 228

what percent of phosphorous is excreted with the urine

Answer 228

20% (bc it only reabsorbed in proximal tubule)

Question 229

where is PTH synthesized?

Answer 229

parathyroid gland (by chief cells)

Question 230

what is the major and principal stimulus for PTH release?

Answer 230

decreased plasma calcium concentration

Question 231

what is responsible for the minut-to-minute control of serum [iCa]?

Answer 231

PTH

Question 232

what effect does PTH have on serum [Ca] and serum [phosphorous] ?

Answer 232

increases serum [Ca], decreases serum [phosphorus]

Question 233

what are the 3 mechanisms by which PTH increases serum [Ca] and decreases serum [phosphorus]

Answer 233

1. effect on nephron (incr. Ca reabsorption and Phosphorus excretion in urine)
2. effect on bone (activates osteoclasts to release Ca and phosphorous into circulation)
3. stimulates formation of active form of vitamin D (calcitriol)

Question 234

this initial form of vitamin D is synthesized in the skin with the help of UV light

Answer 234

vitamin D3

Question 235

this initial form of vitamin D is ingested in the diet

Answer 235

vitamin D2

Question 236

the liver converts vitamin D2 and D3 to this (due to presence of 25-hydroxylase)

Answer 236

calcidiol

Question 237

this is found within the proximal tubular cells of the nephron and acts on calcidiol to form calcitriol (the active form of vitamin D)

Answer 237

1⍺-hydroxylase

Question 238

what affect does PTH have on the synthesis of 1⍺-hydroxylase (and therefore the formation of calcitriol)?

Answer 238

increases it

Question 239

this is responsible for the day-to-day control of serum [iCa]

Answer 239

calcitriol

Question 240

what effect does calcitriol have on the serum [Ca] and serum [phosphorus]

Answer 240

increases both

Question 241

what is the major site of action for calcitriol

Answer 241

intestinal tract

Question 242

what effect does calcitriol have on the intestinal tract?

Answer 242

increases calcium and phosphate absorption

Question 243

what effect does calcitriol have on the kidney?

Answer 243

stimulates reabsorption of both calcium and phosphate w/in distal tubule

Question 244

what effect does calcitriol have on the bones?

Answer 244

bone resorption (increases circulating Ca and phosphorous)

Question 245

what effect does PTH have on the kidney?

Answer 245

stimulates Ca reabsorption by thick limb of LoH and inhibits phosphate reabsorption in proximal tubule

Question 246

what effect does PTH have on bones

Answer 246

activates osteoclasts (bone breakdown so more Ca and Phosphorous into circulation)

Question 247

name 4 factors that stimulates PTH release

Answer 247

1. hypocalcemia
2. hyperphosphatemia
3. decr. PTH
4. decr. calcitriol

Question 248

name 4 factors that stimulates calcitriol release

Answer 248

1. hypophosphatemia
2. hypocalcemia
3. incr. PTH
4. decr. calcitriol

Question 249

name 4 factors that inhibit PTH

Answer 249

1. hypophosphatemia
2. hypercalcemia
3. incr. PTH
4. incr. calcitriol

Question 250

name 4 factors that inhibit calcitriol

Answer 250

1. incr. calcitriol
2. hypercalcemia
3. hyperphosphatemia
4. decr. PTH

Question 251

name the effect hypercalcemia has on PTH, calcitriol, and calcitonin

Answer 251

decr. PTH, decr. calcitriol, incr. calcitonin

Question 252

name the effect hypocalcemia has on PTH, calcitriol and calcitonin

Answer 252

incr. PTH, incr. calcitriol, decr. calcitonin

Question 253

this is a hormone synthesized and released from the thyroid gland in response to increased calcium concentration

Answer 253

calcitonin

Question 254

which hormone essentially has the opposite effects to PTH

Answer 254

calcitonin

Question 255

this is a protein secreted mainly by osteocytes with the overall effect to decrease plasma concentration of ionized phosphorous

Answer 255

fibroblast growth factor 23 (FGF-23)

Question 256

what is the equation for pH?

Answer 256

pH = -log[H+]

Question 257

under this pH, the patient will be dead

Answer 257

< 6.8

Question 258

above this pH, the patient will be dead

Answer 258

> 8

Question 259

is considered normal pH

Answer 259

7.4

Question 260

this is the main extracellular buffer

Answer 260

bicarbonate (HCO3-)

Question 261

these are weak acids or bases which can either bind to or release H+ (H+ titration) to prevent large changes in pH

Answer 261

buffers

Question 262

what is the equation for bicarbonate buffering with H+

Answer 262

HCO3- + H+ <-> H2CO3

Question 263

when bicarbonate titrates H+, the extra CO2 produced stimulates this in order to eliminate it from the lungs

Answer 263

hyperventilation

Question 264

what is the kidneys’ role in maintaining acid-base balance (metabolic component)

Answer 264

reabsorption of filtered bicarbonate and generation of new bicarbonate

Question 265

what is the lungs’ role in maintaining acid-bace balance (respiratory component)

Answer 265

eliminate or retain CO2 based on H+ concentration

Question 266

this acts as a urinary buffer to allow excretion of H+

Answer 266

ammonium (NH4)

Question 267

Describe the process of renal ammoniagenesis in the proximal tubule and fate of the ammonium

Answer 267

1. glutamine is taken up by the proximal tubular cells and converted to bicarbonate and ammonium
2. ammonium is secreted into tubular lumen
3. ammonium is reabsorbed into medullary interstitium at LoH
4. ammonium is secreted again into the collecting duct

Question 268

this is the enzyme which catalyzes H2O + CO2 <-> HCO3- + H+ reaction; it is present in large quantities in the proximal tubule brush border and cytosol of cells

Answer 268

carbonic anhydrase

Question 269

what happens to H+ secreted from the proximal tubule into the tubular lumen?

Answer 269

recombine with filtered HCO3- (prevents loss of bicarbonate)

Question 270

this is where 80%of bicarbonate is reabsorbed

Answer 270

proximal tubule

Question 271

this part of the nephron secretes a quantity of H+ equal to that generated by the animal’s metabolism; secrete H+ combines with a urinary buffer to be excreted in the urine

Answer 271

collecting duct (distal nephron)

Question 272

this type of cell in the collecting duct secretes H+

Answer 272

type A intercalated cells

Question 273

this type of cell in the collecting duct secretes HCO3-

Answer 273

type B intercalated cells

Question 274

urine leaving the collecting duct of carnivores has this pH

Answer 274

5.5-7.5

Question 275

urine leaving the collecting duct of ruminants has this pH

Answer 275

6-9