Renal

Question 1

What are the functions of the kidney?

Answer 1

Regulation of water, inorganic ion balance, and acid/base balance
Removal of metabolic waste products from the blood and their excretion in the urine
Removal of foreign chemicals from the blood and their excretion in the urine
Production of hormones/enzymes

Question 2

What hormones/Enzymes are produced by the kidney? what do they do?

Answer 2

Erythropoietin (stimulates RBC production)
Renin (RAAS system, increases bp/Na balance)
1, 25 dihydroxyvitamin D: active vitamin (involved in Ca balance)

Question 3

How is the kidney organized? How what veins/arteries are present?

Answer 3

Medullary Lobes, with cortical lobules
Many nephrons (renal corpuscle, tubule)

Renal artery - Interlobar artery - arcuate artery - interlobular artery - afferent arteriole (reverse for veins) efferent arteriole - capillary - veins….

Question 4

Describe the nephorn’s structures

Answer 4

Glomerulus
Bowmans space (in bowman's capsule)
Proximal convoluted tubule
Proximal straight tubule
Descending thin limb of Henle's loop
Ascending thin limb of Henle's loop
Thick ascending limb of Henle's loop
Distal convoluted tubule
Cortical collecting duct
Medullary collecting duct
Renal pelvis

Question 5

What are the two layers of the renal corpuscle

Answer 5

Parietal layer (outside)
Visceral layer (touching glomerulus, podocytes)

Question 6

How is the nephron vascularized?

Answer 6

Peritubular capillaries

Question 7

What are the three processes of urine production?

Answer 7

Glomerular filtration
Tubular secretion (capillaries -> tubules)
Tubular reabsorption (tubules -> capillaries)

Question 8

What is filtered by glomerular filtration?

Answer 8

Water, low-moleculary weight substances

Cells, proteins, protein-bound substances do not cross

Question 9

How do you calculate the amount of urine excreted?

Answer 9

Amount filtered + amount secreted - amount reabsorbed

Question 10

What is the only substance that is not reabsorbed?

Answer 10

Para-amino-hippurate

Question 11

True/False? In a healthy person, glucose never enters the nephron

Answer 11

False (enters nephron but is completely reabsorbed)

Question 12

How is net glomerular filtration pressure calculated?

Answer 12

Glomerular Capillary blood pressure - Fluid pressure in Bowman’s Space - Osmotic force due to plasma proteins (oncotic pressure)
Usually: 60 - 15 - 29 = 16

Question 13

What is the glomerular filtration rate? How is it controlled? Which of those methods is under physiological control?
What is a normal GFR?

Answer 13

The volume of fluid filtered from the glomeruli into Bowman's space per unit time
Regulated by:
Net Filtration rate (most important)
Membrane Permeability
Surface area Available for Filtration

Normal GFR = 180 L/day

Question 14

How can you increase GFR? How can you increase it?

Answer 14

Increase: Constrict aferent arteriole or dilate eferent arteriole

Decrease: constrict eferent arteriole or dilate aferent arteriole

All methods control Glomerular capillary pressure (increasing GFR decreases Pgc, decreasing GFR increases Pgc)

Question 15

What is filtered load? How is it calculated?

When is net reabsorption present? When is net secretion present?

Answer 15

Total amound of any free filtered substance per unit time

Filtered Load = GFR x plasma concentration of the substance

Filtered Load > amount excreted: absorption
Filtered Load < amount excreted: secretion

Question 16

What is the differene between paracellular and transcellular reabsorption?

Answer 16

Transcellular: from tubular lumen to tubular epithelial cell (needs transport proteins) and then into peritubular capillary

Paracellular: directly from tubular lumen to peritubular capillary through tight junctions between epithelial cells

Question 17

True/False? Filtered loads are typically quite small

Answer 17

False

Question 18

True/False? Reabsorbtion of waste products is relatively incomplete

Answer 18

True

Question 19

True/False? Reabsorption of the most useful plasma components is relatively incomplete

Answer 19

False

Question 20

True/False? Reabsorbtion of some substances are completely unregulated

Answer 20

True (eg glucose, amino acids)

Question 21

What are two methods of reabsorbtion?

Answer 21

Diffusion

Mediated transport

Question 22

Where does water reabsorption take place?

Answer 22

Proximal tubule

Question 23

What is typically associated with mediated transport?

Answer 23

Sodium reabsorption (for secretion and reabsorbtion)

Question 24

How does mediated transport work for eg amino acids?

Answer 24

AA are brought into tubular epithelial cell (Na symporter - Na enters epithelial cell as well)
AAs leave through channels
Na/K ATP ase pumps Na into peritubular capillary and K into cell

Question 25

What is a tranpsort maximum (Tm)

Answer 25

When the membrane transport proteins become saturated and the tubule cannot reabsorb the substance anymore

Question 26

What are the two most important substances secreted by tubules?

Answer 26

Hydrogen ions and potassium

Question 27

Where does ion reabsorption take place?

Answer 27

Henle’s loop

Question 28

Where does solute secretion take place?

Answer 28

Proximal tubule

Question 29

What is the purpose of the DCT and CD?

Answer 29

Fine tuning (small volume of water/solutes) determines final amounts excreted in urine

Homeostatic Controls are exerted here

Question 30

What is clearance and how is it calculated?

Answer 30

The volume of plasma from which a substance is completely cleared by the kidneys per unit time
Clearance of S, C_S = (mass of S excreted/time)/Plasma concentration of S (P_S)`

Question 31

What is Inulin? How is it used?

Answer 31

A polysaccharide that is administered intravenously to measure clearance

Inulin is freely filtered at the glomerulus but it is not reabsorbed, secreted, or metabolised

The clearance of inulin is equal to the volume of plasma originally filtered (C_IN = GFR)

Question 32

What is Creatine? How is it used?

Answer 32

A waste product produced by muscle

Filtered freely at glomerulus and is NOT reabsorbed

It is secreted at the tubule but very minor, NOT metabolized
Thus, creatinine clearance is used as a clinical marker for GFR (a good approximation)

Question 33

If urine volume is V,
Urine concentration of creatine is Ucr
and Plasma concentration of creatine is Pcr
How would you calculate GFR?

Answer 33

Creatine clearance ~ GFR = UcrV/Pcr

Question 34

What happens if clearance of a substance is greater than GFR? What happens if it is less than GFR? What happens most often?

Answer 34

Clearance > GFR: secreted at tubule
Clearance < GFR: reabsorbed at tubule

Reabsorbtion is most common

Question 35

How much water and sodium are secreted at the tubule?

Answer 35

None

Question 36

Name the only location in the nephron where sodium reabsorption does not take place

Answer 36

The descending thin loop of Henle

Question 37

Reabsorption of what substance is dependent on sodium reabsorption?

Answer 37

Water

Question 38

How does sodium travel from the tubular lumen to the cortical collecting duct cells (i.e. at the apical membrane)
What about in the proximal tubule?

Answer 38

Through diffusion down its gradient

Na/H antiporter
Na/glucose symporter

Question 39

How does sodium travel from the collecting duct cell to the interstitial fluid (i.e. at the basolateral membrane)?

Answer 39

Through an active Na/K ATPase pump

Question 40

How is total body sodium sensed?

Answer 40

Changes in total body sodium ~ changes in extracellular fluid folume (major extracellular solute)
Sensed by baroreceptors in CV system

Question 41

True/False? Plasma concentration of Soduim is an accurate marker for total body sodium

Answer 41

False

PNa only reflects the relative relationship of total body Na and water

Question 42

How is sodium regulated in the kidneys?

Answer 42

Sodium excreted = sodium filtered - sodium reabsorbed
Recall Na is NOT secreted in tubules

Excretion regulated by:
GFR (minor)
Sodium reabsorption (MAJOR)

Question 43

How does the GFR regulate sodium if excess sodium is lost eg due to diarrhea?

Answer 43

Na decreased = plasma volume decreased
= Venous pressure decreased *
= Atrial pressure decreased *
= Cardiac output decreased
= Arterial blood pressure decreased*
* have an effect on renal sympathetic nerves, constricts aferent arterioles
= Net decrease in GF pressure = decrease in GFR = decrease in Na and H2O excretion

Question 44

What is the key hormone involved in sodium control via reabsorption?

Answer 44

Aldosteroe (steroid hormone)

Question 45

Where does aldosterone stimulate the reabsorption of sodium?

Answer 45

DCT and CCD

Question 46

Describe the Renin-angiotensin-Aldosterone System

Answer 46

Kidneys secrete Renin
Renin catalyzes the activation of angiotensinogen (secreted hepatically) into angiotensin I
Angiotensin I is converted by ACE into Angiotensin II
Angiotensin II acts on the adrenal cortex to secrete Aldosterone
Aldosterone promotes Na reabsorption

Question 47

Which part of the kidneys secrete renin?

Answer 47

The juxtaglomerular cells

Question 48

True/False? Aldosterone stimulates H2O reabsorption in the CCD

True/False? Aldosterone directly stimulates H2O absorption

Answer 48

True

False

Question 49

What is ANP and how does it function?

Answer 49

Atrial natriuretic peptide
Secreted by cells in cardiac atria
Acts on the tubules to inhibit Na reabsorption and increases GFR

ANP is secreted when there is an increase in total body sodium
“pressure natriuresis”

Question 50

Define Osmolarity, Hypoosmotic, Isoosmotic, hyperosmotic

Answer 50

Osmolarity: The total solute concentration of a solution
Measure of water concentration: The higher the osmolarity, the lower the concentration

Hypoosmotic: Having total solute concentration less than that of normal ECF

Isotonic: Having total solute concentration equal to that of ECF

Hypertonic: Having total solute concentration greater than that of ECF

Question 51

How much water is reabsorbed?

Answer 51

99%

Question 52

Describe the mechanism of water reabsorption in the proximal tubule

Answer 52

• Na+ goes down its gradient from the lumen to tubular epithelial cells
• As a result, lumenal osmolarity decreases and interstitial osmolarity increases
• To compensate, H2O travels through tight junctions AND through osmosis of epithelial cells
• Bulk flow forces H2O into peritubular capillaries

Question 53

What are the two critical components to dynamic regulation of water?

Answer 53

The highosmolarity of the medullary interstitium

Permeability of CD to water (regulated by Vasopressin)

Question 54

How is urine concentrated?

Answer 54

Through the countercurrent multiplier system

Question 55

What does urine concentration depend on?

Answer 55

Hyperosmolarity of the interstitial fluid

Question 56

What are the effects of vasopressin on water concentration?

Answer 56

In the presence of Vasopressin, water diffuses out of the ducts into the interstitial fluid in the medulla to be excreted

Question 57

What are the two steps in the countercurrent multiplier system? What are the properties of each limb of Henle’s loop that make this possible?

Answer 57

step 1: The ascending loop of henle actively reabsorbs NaCl (osmolarity decreases)

Step 2: The descending loop of Henle detects the increased osmolarity of the interstitial fluid and releases water to compensate

Step 1 depends on the fact that the ascending loop is impermeable to water
Step 2 depends on the fact that the descending loop is permeable to water

Question 58

The descending limb of Hele’s loop is ____molar compared to the ISF whereas the ascending limb is ___molar compared to the ISF

Answer 58

Iso

Hypo

Question 59

What is the vasa recta?

Answer 59

The blood vessels in the medulla

Hairpin like structure, minimizes excessive loss of solute from the interstitum

Question 60

Besides NaCl, what also contributes to medullary hyperosmolarity?

Answer 60

Urea

Question 61

What would happen if instead of a vasa recta a capillary was placed running down the nephron?

Answer 61

The osmolar gradient would be lost

Question 62

What does water reabsorption depend on? What does THAT depend on?

Answer 62

Water permeability of the tubules
Permeability depends on the tubular segment
eg proximal tubule has high permeability to water
eg CCD and MCD permeability is subject to physiological control (vasopressin)

Question 63

What does vasopressin do? How?

Answer 63

Increases secretion of water in collecting duct by adding aquaporins to the LUMENAL membrane of the collecting duct cells

Question 64

What is the pathological cause of Diabetes insipidus?

Answer 64

Malfunction in vasopressin system

Question 65

What happens to the concentration of solutes (osmolarity) in the collecting duct with and without vasopressin?

Answer 65

With vasopressin: Concentrates as water leaves

Without vasopressin: Water stays in CD and keeps same osmolarity

Question 66

How is vasopressin release regulated?

Answer 66

Osmoreceptor control (most important)
Baroreceptor control (less important)

Question 67

What is a possible reason for why we feel thirsty?

Answer 67

Increased plasma osmolarity

Question 68

Do you lose more water or sodium when you sweat?

Answer 68

Water

Question 69

What is the most abundant intracellular ion?

Answer 69

Potassium

Question 70

What is the fate of ingested potassium?

Answer 70

90% excreted into urine, 10% excreted into feces/sweat

Question 71

How do the kidneys regulate potassium?

Answer 71

Freely filtered at glomerulus

Normally - tubules reabsorb most of the filtered K so very little filtered K appears in urine

Question 72

Unlike Sodium or water, Potassium can be _____ at cortical collecting ducts

Answer 72

Secreted

Question 73

Changes in K excretion are due mainly to changes in K ______ in the CCD (some in DCT)

Answer 73

Secretion

Question 74

Secretion of K in the CCD is compled with reabsorption of what ion?

Answer 74

Na

Question 75

How is potassium secretion regulated?

Answer 75

Dietary intake of potassium

Aldosterone

Question 76

How does Aldosterone regulate K?

Answer 76

Increases reabsorption of Sodium
Sodium reabsorption coupled to Potassium Secretion
Potassium secreted

Question 77

When can K be excreted when it shouldn’t?

Answer 77

During RAAS

Question 78

What happens to ion regulation during hyperaldosteronism?

Answer 78

Increased fluid volume, hypertension, HYPOKALEMIA, suppressed RAAS, metabolic alkalosis also observed

Question 79

What is the optimal pH of the body? What concentration of Hydrogen is needed?

Answer 79

7.4, [H+] = 40 nanomol/L

Question 80

What is the important reaction that governs Hydrogen ion balance? What happens when you lose an ion in this equation?

Answer 80

CO2 + H2O <=> H2CO3 <=> HCO3- + H+

When a bicarb is lost, the equation shifts to the right to compensate and a H+ is gained

Question 81

What are 4 ways to gain a Hydrogen Ion, and what are the 4 opposite ways to lose a H+ ion?

Answer 81

1. Generation of a Hydrogen ion from CO2 / Hyperventilation (loss of CO2)
2. Production of nonvolatile acids from metabolism of proteins / utilization of hydrogen ions in the metabolism of various organic anions
3. Gain of H+ due to loss of bicarb in diarrhea/ Loss of Hydrogen ions in vomitus
4. Gain of hydrogen ions due to loss of bicarb in urine / Loss of hydrogen ions in urine

Question 82

Name 3 nonvolatile acids

Answer 82

Phosphoric acid
Sulfuric Acid
Lactic acid

Question 83

What is a buffer solution?

Answer 83

Any substance that can reversibly bind hydrogen ions
Most hydrogen ions are buffered by extracellular and intracellular buffers

Buffer- + H+ <=> HBuffer

Question 84

True/False? Buffering eliminates hydrogen ions from the body

Answer 84

False (it only keeps them locked up)

Question 85

What is the ultimate balance of hydrogen ions controlled by?

Answer 85

Respiratory system (by controlling CO2)
Kidneys (by controlling HCO3-)

Question 86

How do the kidneys control H+ ions?

Answer 86

By controlling excretion/production of HCO3-

Low H+ conc (alkalosis): Kidneys excrete HCO3-
High H+ conc (acidosis): Kidneys produce HCO3-

Question 87

What is the Henderson-Hasselbach equation?

Answer 87

pH = 6.1 + log([HCO3-]/[CO2])
pH = -log(Ka) + log([HCO3-]/0.03[CO2])
where Ka is the dissociation constant for CO2/HCO3- system
0.03 is solubility of CO2 at 37 C

Question 88

How do the kidneys handle HCO3-?

Answer 88

H2O and CO2 combine in tubular epithelial cells to form H2CO3 which dissociates into H+ and HCO3-
H+ is secreted into tubular lumen where it combines with a filtered bicarb and forms H2CO3 which reforms H2O and CO2
HCO3- enters ISF

Question 89

Where does most HCO3- reabsorption occur?

Answer 89

In the proximal tubule

Question 90

How is a new HCO3- added to the plasma?

Answer 90

Either by excreting a H+ (using nonbicarbonate buffers such as phosphate)
or by glutamine metabolism with NH4+ secretion

Botth processes are considered to be H+ excretion (which shifts the reaction to produce more bicarb)

Question 91

How do the kidneys add a new HCO3- to the plasma using Phosphate?

Answer 91

H2O and CO2 combine in tubular epithelial cells to produce H2CO3 which dissociates into H+ and HCO3-
The H+ is ACTIVELY pumped into lumen where it binds to filtered phosphate forming phosphoric acid which is then excreted
The HCO3- is then released into the ISF

• This only happens after all the HCO3- has been reabsorbed and is no longer available from the lumen

Question 92

How do the kidneys add a new HCO3- to the plasma using glutamine?

Answer 92

Glutamine enters the tubular epithelial cells with Na+
Glutamine is broken down into NH4+ and HCO3-
NH4+ enters tubular lumen using a sodium antiporter (Na+ enters epithelial cell) and the NH4+ is excreted
The HCO3- is then released itno the ISF

• mianly occurs in proximal tubule, this is called “H+ ecretion bound to NH3”

Question 93

During respiratory acidosis, what happens to H+ levels? HCO3- levels? CO2 levels?
What causes the HCO3- change? What causes the CO2 change?
What about alkalosis?

Answer 93

H+: inc
HCO3-: inc (renal compensation)
CO2: inc (primary abnormality)
reverse for alkalosis

Question 94

During metabolic acidosis, what happens to H+ levels? HCO3- levels? CO2 levels?
What causes the HCO3- change? What causes the CO2 change?
What about alkalosis?

Answer 94

H+: inc
HCO3-: dec (primary abnormality)
CO2: dec (reflex ventilatory compensation)
reverse for alkalosis

Question 95

What are the renal responses to acidosis? what is the net result?

Answer 95

High H+ conc
Sufficient H+ are secreted to reabsorb all filtered HCO3-
Still more H+ are secreted and this contributes new HCO3- to the plasma as these H+ are excreted bound to non-HCO3- buffer (eg HPO4–)
Tubular glutamine metabolism and ammonium excretion are enhanced, which also contributes new HCO3- to plasma

Net result: more HCO3- than usual added to plasma, compensating for acidosis (urine is acidic)

Question 96

What are the renal responses to alkalosis? What is the net result?

Answer 96

(low H+ concentration)
Rate of H+ secretion is inadequate to reabsorb all filtered HCO3-, so HCO3- is excreted in urine
Little or no H+ secretion on non-HCO3- buffers
Tubular glutamine metabolism and ammonium excretion are decreased so that little/no new HCO3- is contributed to plasma
Net result: Plasma HCO3- will decrease, thereby compensating for alkalosis (urine is alkaline)

Question 97

How do diuretics function?

Answer 97

Act on tubules to inhibit the reabsorption of sodium along with chloride and/or bicarb, resulting in increased excretion of these ions (water excretion rises too)

Question 98

Where does a loop diuretic act ? how?

Answer 98

Acts on thick ascending limb of loop of henle
Inhibits cotransport of Na, Cl and K
eg furosemide, most commonly used diuretic

Question 99

Where does a potassium-sparing diuretic act/ how?

Answer 99

Inhibits Na reabsorption in the CCD, and therefore inhibits K secretion there
Thus, unlike other diuretics, plasma [K] stays the same
Blocks action of aldosterone or blocks the (ald-regulated) epithelial Na channel in CCD
eg amiloride

Question 100

When would you use diuretics? name two cases

Answer 100

Congestive heart failure (lower CO)

Hypertension (retention of salt and water causes high BP)

Question 101

What are common features of kidney disease/failure?

Answer 101

Proteinuria 
Accumulation of waste products in blood
High [K] in blood
Metabolic acidosis
Anemia
Decreased Vitamin D (leading to hypocalcemia)

Question 102

When do Kidneys fail?

Answer 102

When more than 90% of nephrons stop working (Fatal)

Question 103

What are three methods of renal replacement therapy?

Answer 103

Hemodialysis
Peritoneal dialysis
Kidney transplantation

Question 104

What is hemodialysis

Answer 104

A machine filters your blood
"arterial blood" goes through pump
given anticoagulant
dialysis fluid drained off
Dialyzer removes waste products
Dialysis fluid input (concentrate and purified water)
Airtrap and air detector
"venous" blood returned to patient

Question 105

What is peritoneal dialysis?

Answer 105

The lining of the patien’ts abdominal cavity is used as a dialysis membrane
Fluid is injected into the cavity, solutes diffuse into the fluid from the person’s blood, and the fluid is exchanged several times a day

Question 106

WHat is a kidney tranplantation?

Answer 106

Either from a recently deceased person of from a living relative/or immunosimilar donor
Antirejection treatments have improved over the years (organ shortage is nor a problem)
Donors can funciton with just one kidney