Renal Physiology

Question 1

water distribution in body

Answer 1

intracellular vs extracellular compartments

majority of water is intracellular

Question 2

types of solutes

Answer 2

two types of solutes: effective and ineffective

effective: can be sequestered in a compartment to contribute to an osmotic gradient - need active transport to get across a membrane ex. sodium, glucose

ineffective: diffuse freely based on relative concentration ex. urea

Question 3

total blood osmolality

effective osmolality

Answer 3

total osmolality = 2[Na} + [blood glucose}/18 + BUN/2.8

effective osmolality = 2[Na] + [blood glucose]/18

Question 4

renal autonomic innervation

Answer 4

NOT INNERVATED BY PSNS

SNS activity controls

• vasoconstriction
• Na reabsorption
• renin secretion

Question 5

basics renal functions/processes

Answer 5

• filtration: movement of plasma constituents from glomerulus into Bowman’s capsule
• reabsorption: movement of constituents from forming urine into renal interstitium/back into circulation [vast majority of filtrate is reabsorbed back into circulation. 1-1.5L of 180L gets excreted daily]
• secretion: movement of constituents from renal circ, interstitium, or tubule epithelium into the forming urine

Question 6

nephron structure and how it can impact GFR

Answer 6

• afferent arteriole: vsm capable of contraction
• glomerulus: site of filtration via fenestrations (net negative charge; cations move through more easily)
• efferent arteriole
• peritubular capillaries

rise/fall in glomerular bp - rise/fall in filtration

Question 7

clearance equation

Answer 7

clearance refers to the proportion of a substance that is excreted in urine

C = [urine] * volume of urine / [plasma] C = UV/P

Question 8

glomerular regulation of intraglomerular pressure

Answer 8

renal autoregulation

• • kidneys will act to protect glomerular filtration at level of nephron
• high bp: contraction of afferent arteriole to reduce glom filt low bp: contraction of efferent arteriole to increase glom filt

Question 9

filtered load vs fractional excretion

Answer 9

filtered load: how much solute makes it into Bowman’s capsule per unit time

fractional excretion: ratio of solute excreted to filtered load (how much of what’s filtered is actually excreted)

Question 10

give examples of solute that are…

• not filtered.
• filtered; no reabs, no sec.
• filtered; partly reabs.
• filtered; mostly reabs.
• filtered; completely reabs.
• filtered; secreted.

Answer 10

• not filtered. - large proteins
• filtered; no reabs, no sec. - inulin
• filtered; partly reabs. - urea
• filtered; mostly reabs. - albumin
• filtered; completely reabs. - glucose
• filtered; secreted. - creatinine

Question 11

virtually no pressure drop occurs between afferent and efferent ends of glomerulus, even in cases where MAP changes a lot describe the mechanisms that regulate glomerular filtration pressure

Answer 11

glomerular pressure regulated mainly at afferent artiolar level

• efferent constriction can also raise glomerular pressure afferent arteriolar vsm constriction/dilation can be triggered by…
  1. SNS tone - norepi adrenoceptor dependent vasoconst
  2. autoregulation - concerted action of SNS, natriuretic peptides, paracrine factors (NO, prostaglandins), and RAAS
• happens due to either PRESSURE INDUCED DISTENSION OF AFF ART or TUBULAR GLOM FEEDBACK SYSTEM

Question 12

describe how distension of vsm and vascular endothelium in efferent arteriole can affect autoregulation

Answer 12

stretch induced activation of cation channels, depolarization, mobilization of Ca within vsm, contraction!

Question 13

TGF - tubular glomerular feedback

describe one physiological conditions where TGF varies from its normal functioning

Answer 13

regulated by concentrations of sodium in forming urine in the thick ascending limb

how it works:

• urine in TAL flows past macula densa, whose cells sense Na concentration (in close proximity with JG cells that secrete renin)
• elevated Na conc stimulates macula densa cells to release factors that stimulate aff arteriole to vasoconstrict (ATP, adenosine, thromboxane)
• GFR lowered

special case: volume expansion

-in these cases, you DONT want TGF to work because you need pressure natriuresis to run its course -increased water content keeps Na conc relatively low, so TGF is desensitized! and diuresis can occur

Question 14

name the key hormones involved in renal regulation of GFR and RBF

Answer 14

• renin
• angiotensin
• atrial natriuretic peptide
• arginine vasopressin (ADH, vasopressin)
• norepi
• aldosterone [no direct effect - resp for Na retention]

Question 15

name the key players in the RAS and where they are typically found

Answer 15

• angiotensinogen [in proximal tubule cells - also hepatocytes]
• renin [from renal JG cells]
• ACE [in proximal tubule brush border - also lungs/heart/periph vasc/brain]

Question 16

describe the function of ACE2

Answer 16

found in renal and cardiac tissues

ACE2 converts AII into angiotensin 1-7

• angiotensin 1-7 binds to Mas receptor (Gprotein coupled) and stimulates:
  
  • vasodil, blocks prolif
  • promotes bradykinin -counteracts effects of AII
  • possibly cardioprotective and antiHTN

Question 17

how is renin regulated?

Answer 17

renin secretion from jg cells is REGULATED in response to:

• negative feedback from AII
• SNS tone (jg cells have beta1 receptors)
• -distension of aff arteriole (high bp)*
• -macula densa signals (TGF)*
• -ANP*
• [volume related]*

Question 18

how does ACE effect vasoconstriction?

Answer 18

1. produce vasoconstrictor: renin conversion to AII can happen, leading to vasoconstriction
2. degrade vasodilator: ACE, while in town to convert AI to AII, also degrades bradykinin (vasodilator)

Question 19

how does renin secretion help correct hypovolemia?

Answer 19

1. AII leads to systemic vasoconstriction, higher bp
2. facilitates RENAL CONSERVATION

• AII vasoconst of renal arteries steadies glomerular pressure AND drops flow in peritubular capillaries
• key for establishing hemodynamics favoring reabsorption of water, sodium

Question 20

describe the expression AT1 receptors and the effects of binding

Answer 20

AT1 = main receptor form in humans

expression

• vsm (afferent and predominantly efferent artioles, renal tubules, periph vasc)
• adrenal cortex
• renal tubule epithelium/JG cells

effects of binding to AT1

• vasoconst in efferent arterioles = maintains optimal filtration
• might activate Na reabs through transporters NHE3, NKCC2, NCC, ENaC as well as Na/K ATPase
• stimulus for aldosterone production/release from zona glom in adrenal cortex

Question 21

describe the expression AT2 receptors and the effects of binding

Answer 21

AT2 involved in fetal organogenesis

expression in adult: lung, renal coronary, myocardial tissues, cardiac fibroblasts

effects of binding to AT2

• might mediate natriuresis and vasodilation via NO, guanylyl cyclase, bradykinin
  
  • regardless, AT2 has a more modulatory effect (AT1 vasoconst effects will predominate)

Question 22

how do renin and ACE inhibitors work?

how does this link to ACE escape???

Answer 22

block active sites within renin and/or ACE disrupts production of AII, which precludes its vasoconstrictive and antrinatriuretic effects.

also stops ACE-dependent bradykinin degradation to preserve its vasodil effect

• also knocks out the negative feedback of AII on renin, which means more renin, which means ACE escape…

Question 23

what is ACE escape?

Answer 23

• drop in AII also leads to drop in feedback inhibition on renin, which leads to upregulation of renin
• even with ACE blocked, this renin can lead to AII formation if it finds pathways of ACE-independent II production (chymases)

Question 24

describe the effect of norepi on renal regulation

Answer 24

norepi targets both afferent and efferent arteriors, effecting…

1. vasoconstriction : lowers gfr and renal blood flow via ALPHA1 RECEPTORS (to maintain volume/conserve/establish favorable hydrostatic gradients)
2. renin secretion : stimulates secretion of renin from JG cells via BETA1 RECEPTORS
3. some Na/water reabs : high SNS activity can enhance reabs from tubules via ALPHA2 RECEPTORS

Question 25

describe how AVP is secreted and the effect of AVP on renal regulation

Answer 25

AVP is produced by cells of the hypothalmic supraoptic and paraventricular nuclei and stored in/released from the posterior pituitary -secreted in response to hyperosmolarity

effects of AVP

1. vasoconstriction within renal microcirculation and peripheral arterioles via V1 receptor
2. water reabs (AQP2) and Na reabs (ENaC) via V_2 receptor_
   * also increases rate of Na reabs via NKCC (TAL), NCC (DCT), and ENaC (DCT)

*V3 receptors are expressed in corticotrops of ant pit - leads to secretion of ACTH

Question 26

describe how ANP is secreted and the effect of ANP on renal regulation

Answer 26

secreted by atrial myocytes in response to increased RAP

• will exert vasodilatory effects within afferent and efferent arterioles
• will decrease sensitivity of TGF mech

in total

1. increases GFR and RBF
2. desensitizes TGF allowing for diuresis
3. also supresses renin secretion

Question 27

renal hypoperfusion can lead to ischemic acute renal failure.

describe some mechanisms in place to prevent this

Answer 27

• autoregulation sustains normal blood flow and GFR in low perfusion P states (mediated by prostaglandins)

what about lower perfusion Ps?

mobilization of locally produced vasoconstrictors that hit the afferent arteriole (drop GFR and RBF, but create gradients better for reabs)

Question 28

renal hypoperfusion can lead to ischemic acute renal failure.

describe some things that increase susceptibility to renal failure

Answer 28

• structural changes in renal arterioles and small arteries
• impaired production of vasodil prostaglandins
• aff arteriolar vasoconst
• inability to increase eff arteriolar vasoconst

basically, things that drop GFR (aff vasoconst, eff inability to vasocont)

Question 29

what are some clinical signs of renal hypoperfusion?

Answer 29

• increased urinary specific gravity (1.015)
• decreased urinary Na
• urea elevated plasma BUN:creatinine (> 20:1)

Question 30

name and describe the two mechanisms of reabsorbtion

Answer 30

1. transcellular: movement across apical and basolateral pl membranes via transporter or channel
   * requires metabolic energy either to establish gradient or power transport directly
2. paracellular: movement through tight junctions between tubule epithelial cells

• passive mechanism due to eletrochem/concentration gradients
• SOLVENT DRAG (movement of Na with water) occurs this way

Question 31

describe Na reabsorbtion in the proximal tubule

what role does GFR play?

Answer 31

approx 70% of filtered load Na is reabsorbed in first half of prox tubule

transport across apical membrane:

Na-glucose cotransporters (SGLT1, SGLT2)

Na-H exchangers

transport across basolateral membrane into interstitium:

Na/K ATPases

Na-HCO3 symporters

• filtration leads to relatively low pressure in eff arteriole and peritubular capillaries
  
  • hydraulic gradient exists
  • high GFR means lower pressure in efferent arteriole and peritubular capillaries
    
    • even greater hydraulic gradient for reabs!

Question 32

describe Na reabsorbtion in the loop of henle and thick ascending limb

Answer 32

thin ascending limb: active Na reabsorbtion (important part of counter current multiplier mechanism to maintain tonicity in renal interstitium)

TAL: impermeable to water, but Na reabs takes place (TAL aka “diluting segment)

apical membrane:

Na-H exchangers

Na/K/Cl via NKCC2 (whose gradient is maintained by ROMK2)

basolateral membrane: Na/K ATPases

Question 33

how and where do loop diuretics act?

Answer 33

loop diuretics are bound to albumin in plasma and CANNOT be filtered through glomerulus. end up moving into forming urine via prox tubule transporters. travel to TAL via urine to block NKCC2

mech of action:

• blocks Na reabs through NKCC2
• simultaneously promotes elimination of NaCl and K [K wasting], as well as Ca wasting

Question 34

describe Na reabsorbtion in the distal convoluted tubule

Answer 34

apical membrane: Na/Cl cotransporter (NCC)

*can be blocked via thiazide diuretics

basolateral membrane: Na/K ATPases

Question 35

how and where to thiazide diuretics act?

Answer 35

thiazide diuretics block action of NCC in the DCT

Question 36

describe reabsorbtion in the cortical collecting tubules

Answer 36

“aldosterone sensitive distal nephron” bc it reacts to the secretion of aldosterone

apical membrane:

• ENaC - Na reabs

*stimulated by AVP, AII and aldosterone *sets up an electrochem gradient that favors K secretion

• ROMK2 - K secretion

basolateral membrane:

• Na/K ATPases

*stimulated by AVP

Question 37

name the K sparing diuretics where and how do they work?

Answer 37

amiloride, spironolactone

amiloride works by blocking ENaC in the DCT by blocking Na reabs

spironolactone works by blocking mineralocorticoid/aldosterone receptor in DCT, indirectly blocking Na reabs

thus prevent creation of the gradient that would favor K secretion, so they are K sparing diuretics

Question 38

how/where is aldosterone secretion stimulated?

Answer 38

aldosterone is secreted from zona glomerulosa cells of adrenal cortex (mineralocorticoid)

• triggered by either
  1. AII binding to AT1 receptors in adrenal cortex
  2. hyperkalemia

Question 39

describe the effects of aldosterone on reabsorbtion (general effects; acute vs. chronic)

Answer 39

• causes vasoconstriction in vsm, has effects on transcription
• aldosterone acts on distal nephon, primarily on Na reabs and POTENTIALLY K secretion

two phases: acute (1-4h) and chronic (beyond)

acute: stimulate ENaC activity in DCT

• increased Na reabs might directly activate ROMK2 K secretion to balance electrochem gradient created

chronic: increase expression and import of ENaC and Na/K ATPase into principal cell plasma membranes

general idea: conserve Na, create a gradient for water reabs too, battle volume depletion

Question 40

describe the aldosterone paradox

Answer 40

in volume depleted conditions, RAAS is activated to conserve sodium/water.

• proximally: NHE3/AII
• distally: NCC/AII; NCC/aldosterone, ENaC/aldosterone

in euvolemic, hyperkalemic conditions: high K stimulates change in expression of aldosterone-sensitive kinases (WNK1, WNK4, SGK1) in distal nephron AND release of aldosterone from adrenal cortex aldosterone WITHOUT AII

• activity of ROMK2 more affected than Na reabs, so you get more K secretion

Question 41

what is aldosterone escape

Answer 41

• when kidneys are exposed to continuous high levels of aldosterone, pressure natriuresis occurs to get rid of Na/water and avoid a hypertensive state
• due to increased aldosterone activity in hyperald, patients are usually NOT hypernatremic, but often ARE hypokalemic!

therefore the excretion of water and Na allows them to avoid the edema/HTN state that might otherwise be induced

Question 42

describe the difference between salt-sensitive and salt-insensitive HTN

Answer 42

normally, ingestion of salt leads to higher Na blood levels leads to hypervolemia corrected by pressure natriuresis

in salt-sensitive individuals, increases in salt might reset the renal fx curve such that pressure natriuresis doesn’t occur like it should

• salt-sensitive HTN patients experience increase in bp on ingesting salt

salt-insensitive HTN patients experience no change in bp on ingesting salt

Question 43

describe the working theory of how the brain’s RAAS can impact bp

Answer 43

• brain possesses salt sensors coupled to bp
• elevated csf [NaCl] leads to upreg of brain AII binding to brain AT1
• brain has enzymes needed for aldosterone synthesis - starts synthesizing aldosterone -aldosterone binds to mineralocorticoid receptors, leading to changes in ENaC flux
• leads to generation of cardiotonic steroids like OUABAIN

ouabain: -affects NCX in arteriolar vsm, favoring vasoconstriction -potentiates activation of brain AT1 (more aldosterone production AND more SNS tone) *higher SNS tone = more alpha1 vasoconstriction systemically) -impairs NO production in renal medullary vasa recta (no vasodil) in total, shifts the pressure natriuresis plot to the right and messes with ability to excrete NA/water when needed

Question 44

describe Na reabsorbtion in the collecting duct

Answer 44

1-3% of remaining filtered load

apical membrane: ENaC

basolateral membrane: Na/K ATPase

Question 45

general mech and major risks of hypernatremia

Answer 45

• disprop loss of water
• disprop gain of Na

major risk: can shift osmostic gradient such that water is pulled out of cells, causing shrinking of organs like BRAIN

symptoms: muscle weakness, lethargy, restlessness; coma/death if v severe

Question 46

general mech and major risks of hyponatremia

symptoms (hyponat vs severe hyponat)

Answer 46

excessively dilute [Na] plasma

3 types: hypo, eu, hypervolemic

• major risk: can draw water into intracellular space, cause swelling
  symptoms: lethargy, nausea, muscle weakness, irritability, anorexia

severe hyponatremia symptoms: drowsiness, confusion, depressed reflexes, seizures, coma, death

Question 47

causes of euvolemic hyponatremia

Answer 47

too much AVP or hyperthyroidism

• glucocorticoid deficiency (cortisol normally exerts negative feedback on AVP - deficiency means extra AVP)
• SIADH (inappropriate levels of AVP)
• hypothyroidism (not well understood)

Question 48

causes and effects of hypovolemic hyponatremia

Answer 48

causes:

intrarenal: diuretics, osmotic diuresis, aldosterone deficiency

*urine chemistry would show high Na

extrarenal: fluid loss (diarrhea, vomiting, sweating)

*urine chem would show low Na because compensation would be in effect

effects: tachycardia, flattened neck veins, orthostatic hypotension high BUN (decreased renal perfusion)

Question 49

causes of hypervolemic hyponatremia

Answer 49

• heart failure (conservation mode to raise volume and CO)
• renal failure: decreased GFR means less filtration but more excretion
• overhydration

Question 50

Type I hypoaldosteronism

Answer 50

psuedohypoaldosteronism seen in infants once they don’t have mother’s endocrine system protecting them

• might stem from mutations in SCNN1 - messes with amount and/or function of ENaC
• impairs Na reabsorption, leading to mass excretion of Na and water

Question 51

diabetes insipidus (DI)

Answer 51

LACK OF AVP SIGNAL/RECEPTION

involves either:

• lack of AVP secretion
• mutations that disrupt V2 receptors (in nephron - ENaC Na reabs and AQP2 water reabs)
• symptoms
  
  • mass diuresis (polyuria) of dilute urine [IMPORTANT - DM URINE WILL BE SOLUTE RICH. DI URINE IS TASTELESS/SOLUTE-POOR]
  • volume loss triggers osmoreceptors to combat hypoosmolality via thirst (polydipsia) since water is moving through the system steady, ions may be drawn to it
  • ion imbalance!

Question 52

SIADH (syndrome of inappropriate ADH secretion)

Answer 52

EXTRA AVP SIGNAL/RECEPTION

involves either

• erratic/unpredictable elevations in serum AVP
• constitutive activation of V2receptor [despite low AVP levels]

_***euvolemic hyponatremia_

• patients cant diurese the way they need to to maintain normal plasma osmolality
• defining characteristics:

1. highly conc urine
2. urine Na > 40
3. euvolemic hyponatremia
4. hypoosmolality

*all must be present WITHOUT glucocorticoid and thyroid hormone deficiency*

Question 53

dehydration can drop plasma sodium and chloride levels - how else can chloride levels be affected?

Answer 53

metabolic acidosis can lead to hyperchloremia (in non-AG metabolic acidosis)

Question 54

how is NaCl transport modulated in the kidneys

Answer 54

glomerular-tubule balance (GT balance) : healthy nephron can reabs more Na when more Na is filtered

RAAS:

• AII - hits Na/H exchanger proximally, hits ENaC distally, stimulates aldosterone secretion
• aldosterone - hits ENaC/NCC distally

SNS-norepi: stimulates RAS via beta1 receptors in JG cells so indirectly promotes Na retention

• activates type alpha receptors in tubule epithelium
  
  • coupled to activation of Na/H exchangers and Na/K ATPases [net effect, Na reabs, H secretion]

ANP, prostaglandins, bradykinin, dopamine: impair Na reabs

Question 55

importance of K regulation

Answer 55

K is the most abundant INTRAcellular cation

• critical in maintaining resting membrane potential in cells
• extracellular K is closely monitored and adjusted
• kidneys help manage reabs/excretion (approx 80-90% of filtered load has to be reabs)

Question 56

describe K reabsorption in nephron

Answer 56

prox tubule: majority of filtered K is reabsorbed here via paracellular jx (PASSIVE) and basolateral K pumps/channels

desc and asc limbs: lots of recycling here. secretion on way down, reabs on way up. generally, reabs>secretion.

TAL: _charge-driven reabs via para and trans_cellular routes

CCT: roles of principal cells AND rate of flow principal

• secrete K due to LUMEN-NEGATIVE TRANSEPITHELIAL VOLTAGE gradient via ROMK2
• faster flow = relatively greater removal of positive charge from forming urine than negative charge
  
  • apical ROMK2 and K/Cl symporters AND basolateral K channeles and Na/K ATPases support secretion

*intercalated cells mediate K reabs through coordinated action of apical K/H ATPases and basolateral Na/K ATPases and K channels

Question 57

what effect does aldosterone have on K secretion? what other factors can affect this effect?

Answer 57

in general, aldosterone will act at distal ENaC to upreg Na reabs this will create the electrochem gradient that is corrected by K secretion by ROMK2

chronic aldosterone will also upreg expression of Na/K ATPases

**in cases of hypovolemia, GFR and flow will be decreased, which in turn will decrease the gradient for K secretion

• takeaway: Na/K trade is NOT ABSOLUTE

Question 58

how does SNS activity affect K secretion?

Answer 58

SNS activity causes reduction in K secretion/excretion

• _conservation of wate_r is a theme for SNS
  
  • part of this process is uptake of K by cells, which reduces filtered load of K
  • SNS also directly downmodulates K secretion

Question 59

how does the kidney contribute to acid/base balance in the body?

Answer 59

kidneys are responsible for keeping acids under control by…

• reabs/reclaiming HCO3 : majority of HCO3 action occurs in proximal tubule, some in distal
• excreting nonvolatile acids

**in general, preventing loss of HCO3 is more important than excreting H

Question 60

net urinary acid secretion

Answer 60

difference between HCO3 excretion in urine AND collective loss of H in urine

Question 61

describe how bicarbonate is reclaimed and where this process takes place

Answer 61

almost all filtered bicarb is “reabsorbed” BUT NOT DIRECTLY

• biochemically cumbersome instead, bicarb is broken down and reassembled = reclamation
  
  • in the proximal tubule, CA IV breaks bicarb down into CO2 and OH
  • H secretion provides H for formation of water
  • CO2 and water are both moved into tubule epithelial cell, where CA II catalyzes reassembly of bicarb, which is moved out into interstitium for delivery to circulation

Question 62

what are the roles of H secretion in proximal tubule?

Answer 62

1. bicarbonate reclamation [dissociation and reassembly via CA IV and CA II]
2. excretion via NH3-NH4 buffering system

Question 63

describe the ammonia-ammonium buffering system

Answer 63

in the proximal tubule, NH3 buffers H to make NH4

NH4 moves through nephron to TAL [less acidic], where it dissociates into NH3 and H again

NH3 moves into interstitium and then goes one of two places…

1. back to proximal tubule to jump into the earlier part of the cycle again
2. to collecting tubule to combine with H to form NH4 which is ultimately excreted

Question 64

describe typical renal management of an aklalosis

Answer 64

NOT more excretion of bicarb!!! instead, reduce excretion of titratable acid and ammonium (raise urine pH)

rationale: every time H is secreted (like for those processes), MORE bicarb is made to be reclaimed!

• excreting less acid means it stays in circ to lower pH AND that even more bicarb isnt generated = win/win

Question 65

why are hypokalemia and hypochloremia often seen in metabolic alkalosis?

Answer 65

usually some defect in renal bicarb secretion and excretion due to ECV depletion and Cl loss

• hypokal: H moves out from interior of cells, K moves into cells via ion swap
• hypochlor: excess bicarb leads to inability to move additional negative charge (chloride ion) via reabs

Question 66

how can the level of aldosterone alter acid/base balance?

Answer 66

in principal cells:

• Na reabs creates a gradient that favors H secretion

in intercalated cells:

• aldosterone stimulates H/K exchanger and H ATPase that mediate H secretion

Question 67

give a general overview of renal tubule acidoses

Answer 67

impaired net H secretion

1. Type 1 RTA - distal - autoimmune or drugs/toxins
2. Type 2 RTA - prox - prox tubule ability to reabs HCO3 impaired
3. Type 4 RTA - distal - aldosterone deficiency or resistance

Question 68

Type 1 RTA

Answer 68

• distal tubule
• autoimmune or drugs/toxins in origin
• net reduction in H secretion within collecting tubules, which means secretion of ammonium and titratable acid impaired
  
  • H RETENTION and ACIDEMIA

mechanism: impaired funxtions of H-ATPase and Cl/HCO3 exchanger

• high pH urine
• acidemia also results in bone resorption (part of buffering!), so might see hypercalciuria, hyperphosphaturia, kidneys stones
• hyper or hypokal can be seen

Question 69

Type 2 RTA

Answer 69

• proximal tubule
• prox bicarb reabs is impaired BUT distal works fine!
  
  • just too weak to actually do all thats required, so plasma bicarb is low

mechanism: defects in Na/H exchanger, Na/K ATPase, carbonic anhydrase are all implicated

• problems in K and NaCl reabs and ultimately Na wasting/hyperaldosteronism

*hyperald ends up exacerbating the hypokal often seen phosphate wasting and vit D deficiency also often seen (…WHY?)

Question 70

Type 4 RTA

Answer 70

• distal tubule
• aldosterone deficiency or resistance
• usually volume-depleted, hyperkal, with a HCO3 no less than 15
• H-ATPase activity is lowered bc of lack of aldosterone…
  
  • which has direct effects on H-ATPase
    
    • which drives distal Na reabs to create an electronegative lumen and gradient for H secretion

ultimately, impedes NH4 production and excretion, which blocks NH4 recycling and NH3 secretion in distal nephron

Question 71

how can urine anion gap be used to inform cause of metabolic acidosis?

Answer 71

UAG = Na + K - Cl

in metabolic acidosis that is NOT KIDNEY RELATED,

• kidneys will attempt to compensate through distal acidification and NH4 production.
• NH4 will pull Cl with it to be excreted as NH4Cl
• SO in summary: good kidneys working with a metabolic acidosis will have extra Cl and a NEGATIVE UAG

in RTAs,

• kidneys arent doing their job, so you WONT see a higher level of Cl in urine, and POSITIVE UAG is the result

Question 72

what is urea?

describe the purpose of urea recycling describe urea recycling (process and transporters involved)

Answer 72

urea is the nitrogenous end product of a.a. metabolism

• freely filtered, reabs, secreted
• reabs > secretion, so not all that is filtered is excreted

HOWEVER, v little is returned to circulation so where does it go?

• hangs out in medullary interstitium to contribute to relatively high osmolarity this allows it to…
  1. help concentrate urine (pulling water into hyperosmolar renal interstitium)
  2. stick around in medullary interstitium for eventual excretion

PROCESS/TRANSPORTERS

prox tubule: most of filtered load (50%) is reabs

thin desc/asc limbs: lots of urea secreted via UT2 facilitated transporter (up to 110% filtered load)

medullary collecting ducts: reabs back into medullary interstitium via UT1, UT4 faciliated transporters

Question 73

identify the players in plasma glucose regulation

Answer 73

plasma glucose should be 75-115

two hours post-prandial, shouldnt exceed 120

increase plasma glucose: glucagon, epi, cortisol, GH

decrease plasma glucose: insulin mechanisms:

• -glucose uptake and glycogenesis/adipogenesis
• -absorbtion of dietary glucose from GI
• -glycogenolysis
• -gluconeogenesis

Question 74

describe the functional roles of the pancreas and its cellular organization

Answer 74

dual function:

• digestive/exocrine - acini glands
• endocrine - islets of Langerhans localized around pacreatic cap beds
  
  • islets of L have 3 populations of cells:
    
    • alpha - glucagon
    • beta - insulin
    • delta - somatostatin

Question 75

insulin functions

Answer 75

STORAGE HORMONE: promotes glycogenesis and lipogenesis

• works with GH to promote muscle anabolism
• production/secretion is triggered by a rise in plasma glucose
• functions to stimulate glucose uptake in liver, sk muscle, fat
• BLOCKS liver gluconeogenesis

***stimulates cellular uptake of K and FFA

Question 76

describe the signalling cascade through which insulin is released

how does it circulate?

Answer 76

• glucose binds to GLUT2 in pl membrane of beta cells (islets of L) and moves into cell
• inside beta cells, glucose –> G6P via glucokinase
• G6P signals a cascade which involves increase in intracellular ATP, which causes ATP-sensitive K channels to close, causing depol
• depol causes voltage-gated Ca channels to open, leading to influx of Ca leading to activation of secretory mechanism

insulin circulates in bioactive form! not bound to anything

Question 77

how does insulin work?

Answer 77

insulin circulates in bioactive form and activates specific cell surface receptors in target cells

complex signaling mechanisms activate glucose carrier proteins which mediate uptake via facilitated diffusion

Question 78

how does insulin affect carb metabolism in the liver

Answer 78

insulin promotes glycogenesis and glucose use by the kidney

insulin inhibits gluconeogenesis and glycogenolysis

Question 79

describe glycogenesis

Answer 79

• takes place in liver cells
• glucose diffuses into hepatic cells
• glucose converted to G6P via glucokinase G6P…
  
  • cant exit the cell (making glucose movement one-way)
  • intermediate that can be used for glycogen synthesis or ATP production pathways

Question 80

describe the effects of increased plasma glucose on the pancreas

Answer 80

changes in intracellular glucose can stimulate changes in beta cell glucokinase activity

***mediates secretion of insulin!

Question 81

what effect does insulin have on skeletal muscle

Answer 81

• promotes uptake of glucose
• promotes glycogenesis so as to provide muscle with stored glucose when muscle becomes metabolically active

Question 82

describe the effects of insulin on fat metabolism

Answer 82

skeletal muscle: inhibits activity of lipoprotein lipase (blocks muscle from using FFA oxidation for energy)

adipose tissue: promotes uptake of glucose, promotes use of glucose (instead of FFA) for energy

liver: MAKES A TON OF FAT stimulates fatty acid synthesis, augments conversion of excess glucose into fatty acids, increase systhesis of hepatic triglyceride and lipoprotein

Question 83

describe the effects of insulin on protein metabolism

Answer 83

strong anabolic effects (esp in concert with GH)

• can impair some protein catabolism
• increases uptake of some amino acids into muscle
• can stimulate translation

Question 84

how is insulin secretion regulated?

what happens when there is no insulin secretion?

Answer 84

• rapid secretion in response to glucose > 100
• quick drop in the 80-90 range
• no insulin? fat metabolism in most tissues

Question 85

glucagon basics

Answer 85

• secreted from alpha cells of islets of Langerhaans
• thought to act only in liver
• HYPERGLYCEMIC HORMONE (promotes hyperglycemia)
  
  • upreg gluconeogenesis
  • upreg glycogenolysis

Question 86

how is glucagon secretion regulated?

Answer 86

inversely to blood glucose levels and serum insulin levels

high in fasted state (glucose < 80-90)

Question 87

what is the importance of glucagon in neonates

Answer 87

transitional period of adjusting from maternal nutrients to nutrition from ingested food = risk of hypoglycemia

• glucagon makes sure that proper glucose levels are maintained

Question 88

somatostatin basics

Answer 88

• secreted by DELTA CELLS of islet of Langerhans
• usually increase during post-prandial period
• has transitory inhibitory effects on insulin and glucagon secretion

Question 89

diabetes mellitus

Answer 89

disturbance in normal carb metabolism that results from insulin insufficiency via…

• LOSS OF ENDOGENOUS INSULIN PRODUCTION
• INSULIN INSENSITIVITY/RESISTANCE

Question 90

diabetes mellitus: 3Ps and symptoms

Answer 90

polydipsia: increased glucose content means increased pl osmolality = thirst/POLYDIPSIA

polyuria: increased filtered glucose = more glucose in forming urine = POLYURIA

polyphagia: lack of insulin leads to less anabolism = weight loss/POLYPHAGIA

Question 91

how is metabolic demand met in DM?

Answer 91

impaired glucose uptake means body shifts to other sources of energy

• FATS: lipolysis through FFA oxidation and formation of ketoacids
  
  • could lead to DKA!!!

Question 92

Type 1 DM

Answer 92

HYPOINSULINEMIA and HYPERGLYCEMIA

Type 1A: autoimmune in nature, resulting from degeneration of beta cells or suppression of beta cell fx

Type 1B (idiopathic, nonautoimmune diabetes): undefined cause

• beta cell destruction
• TX? insulin replacement!

Question 93

Type 2 DM

Answer 93

INSULIN RESISTANCE

• hyperglycemia and normal/elevated insulin
• approx 90% of all DM
• more prevalent in women
• defect at level of insulin receptor, transport, or insulin-dependent signal transduction
• combos of resistance and abnormal insulin levels lead beta cells to try to compensate and ultimately fail

Question 94

android obesity

connection: how does visceral fat respond to insulin resistance?

Answer 94

• accumulation of f_at distributed around abdominal wall and visceral mesenteric_ locations
• correlated with devpt of hypertension and dyslipidemia and other CVD risk factors
• increased waist-to-hip ratio and elevated BMI
• mutations and/or abnormal expression/activity of adipokines (adiponectin and leptin), cytokines (TNFalpha) and FFA can alter glucose metabolism and insulin sensitivity

under conditions of insulin resistance, lipolysis of visceral fat leads to high triglycerides and LDL and low HDL

• drives atherogenic potential up to increase CV risk

Question 95

how do adipokines, cytokines, and FFA alter glucose metabolism and insulin sensitivity?

Answer 95

leptin and adiponectin (adipokines) - increase sensitivity to insulin

TNFalpha - impede insulin-dep glucose metabolism; exert positive feedback on FFA secretion

FFA - stimulate secretion of TNFalpha by adipocytes

Question 96

what is glucose counterregulation? what role do the kidneys play?

Answer 96

glucose counterregulation is the sum of the body’s actions to prevent hypoglycemia and address it if it occurs

the kidneys:

• use lactate, glutamine, and glycerol for gluconeogenesis - stimulated by glucagon/glucocorticoids/norepi/epi
  
  • account for up to 20% of gluconeogenesis (in fasting, hypoglycemia, acidosis)

Question 97

how is glucose reabsorbed in the kidney?

Answer 97

glucose is freely filtered and reabsorbed - usually complete reabs in the prox tubule

apical: Na-glucose cotransporters: SGLT1, SGLT2
basolateral: GLUT1, GLUT2 facilitated diffusion transporters

Question 98

what is the normal range of plasma glucose?

how does diabetes and effects on insulin affect serum glucose and the filtration/reabs process?

Answer 98

normally 65(fasting)-125(postprandial). normal max 180. HEALTHY KIDNEY CAN HANDLE THIS via SGLTs and GLUTs

DM (lack of insulin or insulin resistance) leads to hyperglycemia - massive increase in filtered load - glucosuria once the reabs machinery is saturated

Question 99

what factors affect glomerular proteinuria?

Answer 99

progression: microalbuminurea → proteinuria/macroalbuminurea → diabetic nephropathy → loss of renal fx

glom proteinuria determined by:

• mean transcapillary hydraulic pressure diff
• glom surface area
• size and charge selectivity of the glom membrane

***microalbuminurea increases probability of CV morbidity

Question 100

why is albuminurea/proteinurea a problem?

Answer 100

in diabetics, albumin is in glycosylated state = glycated albumin

glycated albumin functions as an antigen causing immune/cellular responses in nephron

• generation of ROS which can chelate proteins and damage glom
• overload tubule intracellular lysosomes
• produce inflammatory cytokines
• increase synth of ECM proteins in tubular tissues

all leads to GLOMERULOSCLEROSIS, fibrosis, renal failure

Question 101

effects of diabetes on glomerular function/progression

Answer 101

• early on, glomerulus and tubular epithelium can hypertrophy and develop thick basement membranes
  
  • accompanied by high GFR and microalbuminuria
  • unfavorable remodeling increased by: HTN, hyperlipidemia, hyperglycemia
• poor glycemic regulation and diabetic HTN cause pressure-induced capillary stretch in endothelium
  
  • increased vasc permeability = glom injury
  • amplifying cycle of increased reabs in prox tubule and stimulatory effect on GFR

Question 102

how do aberrant signals re: ECF volume and/or bad interpretation of ECF volume feedback affect renal function?

Answer 102

jcan lead to osmotic imbalanced and increased tubule reabs within the nephron, which stimulates GFR

can mess with TGF function too

Question 103

tubulointerstitial fibrosis

Answer 103

unchecked extracellular glucose assaults renal interstitial and tubule cells

high glucose = RAS triggered = promotes release of intrarenal fibrogenic substances AND inhibits production of antifibrogenic factors

leads to glomerulosclerosis, promotion of epithelian-to-mesenchymal cell transitions

Question 104

how can overactive RAS affect kidney function

Answer 104

• promotion of tubulointerstitial fibrosis through release of fibrogenic factors and inhibition of antifibrogenic compounds
• AII induces phosphorylation of IRS1 (insulin receptor substrate 1) - key component of insulin dependent signal transduction = insulin resistance
• can impair nephrin - typically aids in restricting protein filtration across diaphragm slit pores - which leads to leaky glom
• elevated aldosterone causes high Na retention = high water retention = elevated bp/diabetic HTN

tx: renin inhibitor, ACE inhibitor, ARBs
- benefits seen to prescribing them in combo

Question 105

how does diabetic ketoacidosis affect total and plasma K?

what should the treatment be?

Answer 105

metabolic acidosis can cause hyperkalemia via H/K ion swapping

• hyperglycemia = hyperosmolality = osmotic diuresus
  
  • hyperkalemia but with continuous K excretion leading to drop in total K
• volume depletion from diuresis = RAS triggering = aldosterone
  
  • further K excretion

Tx: insulin! BUT remember insulin also triggers cellular uptake of K - could swing patient into hypokalemic state soooo insulin + monitoring

Question 106

what is the primary regulator of Ca and PO4 in blood?

Answer 106

PTH

low Ca - PTH secreted

high Ca - PTH secretion decreased

Question 107

how and where is calcitriol synthesized? what triggers its synthesis?

Answer 107

calcitriol is activated vitamin D

PTH acts in kidney (where key enzymes located) to convert hydroxylate 25-hydroxy vit D to 1,25-dihydroxy vit D aka CALCITRIOL

calcitriol synthesis is stimulated by…

• hypophosphatemia
• PTH

Question 108

what is the function/effect of calcitriol?

Answer 108

• stimulates Ca reabsorption
• blocks PO4 excretion

acts on…

BONE: stimulates resorption and release of calcium and phosphate

KIDNEY: augments PTH dependent Ca reabs in distal nephron; blocks PTH dependent PO4 excretion in nephron

INTESTINES: stimulates Ca and PO4 uptake in sm int

ENDOCRINE: blocks PTH secretion - can cause secondary hypoparathyroidism

Question 109

what is the general function of PO4?

describe effects of PTH and calcitriol on PO4

Answer 109

PO4 can serve as a buffer for plasma and urinary titratable acid

usually freely filtered and mostly reabs…

• PTH blocks reabs by blocking Na-PO4 cotransporter, promotes PO4 excretion
• calcitriol blocks the effect of PTH on PO4 excretion

Question 110

describe the fate of Ca in the nephron

Answer 110

same general pattern as Na

• proximal tubule:
  
  • majority of reabs happens
  • Ca reabs coupled to H and Na reabs
  • mostly paracellular reabs
• TAL
  
  • coupled to Na by gradients generated by NKCC2
    
    • loop diuretics that block Na reabs also block Ca reabs!
• distal tubule
  
  • Ca reabs stimulated by PTH, agumented by calcitriol
  • thiazide diuretics also enhance distal Ca reabs

Question 111

describe effects of PTH and calcitriol on urine concentration

Answer 111

overall, promotes…

Ca reabs x2

PO4 excretion, PO4 excretion block

so…

hypocalciuria

hyperphophaturia

MAKES SENSE! PTH is secreted due to low serum Ca!

Question 112

secondary hyperparathyroidism

Answer 112

aka HIGH BONE TURNOVER RENAL OSTEODYSTROPY

• chronic renal disease impairs Ca reabs in tubules –> hypocalcemia
  
  • triggers PTH secretion from parathyroid
  • which would normally trigger calcitriol formation [which would augment Ca reabs in distal nephron and Ca uptake in sm intestine]
  • BUT…chronic renal disease = cant make calcitriol!!!
  • ALSO…chronic renal disease = cant reabsorb phosphate!!!
• diminished calcitriol = diminished negative feedback on PTH = secondary hyperparathyroidism​
  
  • bone resorption happens, but Ca reabs does not
    
    • hypocalcemia gets worse
    • hyperphosphatemia occurs
      
      • directly induces hypocalcemia AND can induce parathyroid hyperplasia

Question 113

hypoparathyroidism

Answer 113

inadequate production of PTH or resistance to PTH

• main fx of PTH: Ca reabs in distal kidney, calcitriol production, bone resorption

signs:

hypocalcemia

hyperphosphatemia

low urinary Caj

Tx: vitamin D and maintaining low-normal serum Ca to avoid kidney stones

Question 114

countercurrent multiplier mechanism and effect on urine production

Answer 114

reabs/secretion capacity of nephron lets it maintain osmotic gradients in medullary interstitium

counter current exchange maintains hypertonicity of interstitium by having vasa recta recycle NaCl, water, and urea back into systemic circulation

• as blood moves down vasa, lots of water loss, but this declines as you go further down
• influx of NaCl and urea increases deeper into the medulla
• higher blood osmolality means water is pulled back in as blood moves up vasa

end result: blood leaving vasa recta has more water and more solute than when it started

Question 115

characteristics of vasa recta

Answer 115

1. looped conformation
2. relatively low blood flow
3. inability to perform active transport

Question 116

OUABAIN

Answer 116

can be released in response to brain’s RAAS system responding to salt (ex. in salt-sensitive HTN)

• affects NCX in arteriolar vsm, favoring vasoconstriction
• potentiates activation of brain AT1 (more aldosterone production AND more SNS tone)
  
  • *higher SNS tone = more alpha1 vasoconstriction systemically)
• impairs NO production in renal medullary vasa recta (no vasodil) in total, shifts the pressure natriuresis plot to the right and messes with ability to excrete NA/water when needed