8 Water Homeostasis

Question 1

Homeostasis

Answer 1

• Ability of the body to maintain a constant internal environment depsite fluctuations in diet, fluid intake, & other environmental conditions
  
  • Maintain a constant volume, stable electrolyte compositoin of body fluids, etc.
• Kidney
  
  • Main organ responsible for homeostasis
  • Regulates water balance

Question 2

Normal water content & distribution

• Total body water (TBW)
• TBW distribution

Answer 2

• Total body water (TBW)
  
  • 60% of body weight in adult men
  • 50% of body weight in adult women due to higher proportion of adipose tissue
  • Decreases w/ age
• TBW distribution (70kg adult man: 42L)
  
  • Intracellular fluid (ICF): 2/3 (28L)
  • Extracellular fluid (ECF): 1/3 (14L)
    
    • Interstitial fluid (ITF): 3/4 (10.5L)
    • Intravascular fluid (IVF): 1/3 (3.5L)

Question 3

Water balance

• Water balance
• Water is added to the body via 3 major sources
• Water is lost from the body via 4 major sources

Answer 3

• Water balance
  
  • Water input = water output
• Water is added to the body via 3 major sources
  
  • Ingested liquids
    
    • Ex. pure water
  • Ingested solid food
    
    • Ex. peanut butter (low content) & watermelon (high content)
  • Synthesized in the body from oxidized carbohydrates
    
    • Ex. metabolic water
• Water is lost from the body via 4 major sources
  
  • Urine (most important)
    
    • Low urine volume (ex. dehydration, 0.5 L/day): need to retain water
    • High urine volume (ex. drink a lot of water, 18 L/day): need to excrete water
  • Sweat
    
    • Varies w/ physical activity & environmental temperature
  • Feces
    
    • Normally: small amt lost
    • Can be increased to several liters w/ severe diarrhea
  • Insensible losses
    
    • Evaporation in the respiratory tract & skin
    • Neither perceived nor directly measured

Question 4

Osmolarity, osmolality, & tonicity

• Osmole
• Osmolarity
• Osmolality
• Tonicity
• Both osmolality & tonicity

Answer 4

• Osmole
  
  • # of moles of a compound that contribute to osmotic pressure
• Osmolarity
  
  • # osmoles (mmol) / volume of solution (L)
  • Difficult to determine b/c volume changes w/ temperature & pressure
• Osmolality
  
  • # osmoles (mmol) / weight of water (kg)
  • Easier to determine b/c amt of solvent remains constant despite changes in temperature & pressure
• Tonicity
  
  • # particles in sol’n that can’t cross a semi-permeable membrane
  • # particles that exert an osmotic effect driving water out of cells
• Both osmolality & tonicity
  
  • Refer to the # of particles in 2 soln’s separated by a semi-permeable membrane

Question 5

Plasma tonicity

• Main osmoles in plasma
• Plasma osmolality (Posm) calculation
• Normal plasma osmolality
• Plasma tonicity (Pton) calculation
• Normal plasma tonicity

Answer 5

• Main osmoles in plasma
  
  • Na
  • Glucose
  • Urea (BUN)
• Plasma osmolality (Posm) calculation
  
  • Posm (mmol/kg) = 2*[Na] (mEq/L) + serum glucose/18 (mg/dl) + BUN/2.8 (mg/dl)
  • Double Na for negative ions associated w/ na that contribute to plasma osmolality
  • Divide serum glucose by 18 & BUN by 2.8 for units
• Normal plasma osmolality
  
  • 280-295 mOsm/kg
• Plasma tonicity (Pton) calculation
  
  • Pton (mmol/L) = 2*[Na] (mEq/L) + serum glucose/18 (mg/dl)
  • Exclude BUN b/c urea freely crosses cell membranes & doesn’t contribute to plasma tonicity
• Normal plasma tonicity
  
  • 270-285 mOsm/kg

Question 6

Plasma tonicity

• Main determinant of plasma tonicity
• Plasma tonicity vs. TBW
• Plasma tonicity vs. water shifts among dif body fluid compartments

Answer 6

• Main determinant of plasma tonicity
  
  • Na conc
  • Decrease Na conc –> plasma becomes hypotonic
  • Increase Na conc –> plasma becomes hypertonic
• Plasma tonicity vs. TBW
  
  • Decrease TBW –> water deficit concentrates osmotic particles in plasma –> increase plasma tonicity –> hypertonic plasma
  • Increase TBW –> excess water dilute osmotic particles in plasma –> decrease plasma tonicity –> hypotonic plasma
• Plasma tonicity vs. water shifts among dif body fluid compartments
  
  • Hypotonic plasma –> water flows from ECF to ICF –> cell swells
  • Hypertonic plasma –> water flows from ICF to ECF –> cell shrinks
  • Isotonic plasma –> no net water shift –> cell volume remains unchanged

Question 7

Osmoreceptors

• Osmoreceptors
• Central osmoreceptors
  
  • Function
  • Location
  • Main osmoreceptor
  • Special group of structures
• Peripheral osmoreceptors
  
  • Function
  • Location
    *

Answer 7

• Osmoreceptors
  
  • Sense changes in plasma tonicity b/c we don’t have water sensors
    
    • Senses water imbalance since many clinical disorders can arise as a consequence of water excess or deficit
  • Activate homeostatic response to small changes in TBW
• Central osmoreceptors
  
  • Sense changes in plasma tonicity
  • Located in the CNS
  • Organum vasculosum of lamina terminalis (OVLT)
    
    • Main CNS osmoreceptor
    • Part of circumventricular organs
  • Circumventricular organs
    
    • Lack BBB & are in direct contact w/ the ECF & plasma
    • Readily sense minimal changes in its composition (e.g. changes in plasma tonicity)
• Peripheral osmoreceptors
  
  • Anticipate osmotic loads
    
    • Sense osmotic loads in food & trigger a response before actual changes in plasma tonicity occur
  • Located in peripheral structures
    
    • Pharynx
    • Esophagus
    • GI tract
    • Portal vein
    • Splanchnic mesentery

Question 8

Homeostatic response to TBW deficit

Answer 8

• Decrease TBW
  
  • Water is continuously lost in sweat, stool, etc.
  • If not replaced by drinking water, plasma tonicity will increase
• Osmoreceptors in the OVLT sense increased plasma tonicity
  
  • Stimulates thirst
    
    • Drives drinking behavior
    • Increases water intake
  • Stimulates ADH release by the posterior pituitary
    
    • ADH –> kidneys
    • Increases water permeability of principal cells in the collecting duct
    • Increased water reabsorption –> decreased urine volume & increased urine osmolality –> concentrated urine
• Increased thirst + increased water reabsorption in the kidney –> increased TBW back to normal –> decreased plasma tonicity back to normal

Question 9

Homeostatic response to TBW excess

Answer 9

• Increase TBW
  
  • Drink water –> water is distributed throughout the body
  • Amt of solute doesn’t change
  • Excess water –> dilute solutes –> decrease plasma tonicity
• Osmoreceptors in the OVLT sense decreased plasma tonicity
  
  • Inhibits thirst
    
    • Suppresses water drinking
    • Decreases water intake
  • Inhibits ADH release by the posterior pituitary
    
    • Decreased ADH delivery to kidneys
    • Decreased water permeability of principal cells in the collecting duct
    • Decreased water reabsorption –> increased urine volume & decreased urine osmolality –> diluted urine
• Decreased thirst + decreaed water reabsorption in the kidney –> decreased TBW back to normal –> increased plasma tonicity back to normal

Question 10

Antidiuretic hormone (ADH) / vasopressin

• ADH synthesis
• ADH storage
• ADH release vs. plasma tonicity
• ADH release vs. effective arterial blood volume (EABV)
  
  • EABV
  • Baroreceptors
  • Increase EABV –>
  • Decrease EABV –>
• Set point for ADH release

Answer 10

• ADH synthesis
  
  • Supraoptic & paraventricular nuclei in the hypothalamus
• ADH storage
  
  • ADH is transported down axons from the hypothalamus to the posterior hypophysis where its stored in nerve terminals
• ADH release vs. plasma tonicity
  
  • Increased plasma tonicity –> ADH release into the circulation
    
    • Plasma osmolality threshold: 280-285 mOsm/kg
  • Decreased plasma tonicity –> inhibits ADH release
• ADH release vs. effective arterial blood volume (EABV)
  
  • EABV
    
    • Arterial blood volume that effectively perfuses organs
    • Can’t be directly measured
      
      • Inferred from other physiological measurements (renin, aldo, urine Na, etc.)
  • Baroreceptors
    
    • Stretch-sensitive receptors in carotid & aortic sinus sense changes in EABV
    • Potent stimulus for ADH release even when plasma tonicity is decreased
  • Increase EABV –> neural impulses inhibit ADH release
  • Decrease EABV –> decrease discharge rate of stretch receptors –> ADH release
• Set point for ADH release
  
  • As blood volume decreases (ex. hemorrhage), rates of ADH secretion increase
  • Set poitn for ADH release shifts to a lower plasma osmolality

Question 11

ADH effect on distant organs

• ADH effect on aquaporins
• Main determinant of water flow through principal cells
• ADH effect on Na/K/2Cl
• ADH effect on urea
• ADH effect on blood vessels

Answer 11

• ADH effect on aquaporins
  
  • ADH binds to V2 receptors in the basolateral membrane of princiapl cells in the CD
    
    • Receptor is coupled to adenylylcyclase through G stimulatory protein (Gs)
  • Bindings increases intracellular cAMP –> activates protein kinase A (PKA) –> increases # of aquaporin 2 water (AQP2) channels in the apical membrane of principal cells
    
    • Allows water to move from tubules into principal cells
  • Water exits princiapl cells via AQP3 & AQP4 channels on the basolateral membrane
    
    • Not dependent on ADH
• Main determinant of water flow through principal cells
  
  • Hyeprtonic medullary interstitium
  • Water: tubules –> principal cells –> medullary interstitium by osmosis
    
    • Driven by high tonicity of the renal medulla
• ADH effect on Na/K/2Cl
  
  • ADH increases Na/K/2Cl activity in the TkAL
  • Increases NaCl transport into the medullary interstitium
  • Contributes to medullayr ypertonicity
• ADH effect on urea
  
  • ADH increases expression of urea transporters (UTA1) –> increases permeability of the inner medullary CD to urea
  • ADH increases transport of urea into medullary interstitium & contribues to medullary hyeprtonicity
• ADH effect on blood vessels
  
  • ADH binds to V1 receptors in smooth muscl ecells –> vasoconstriction

Question 12

Thirst

• Originates in…
• Triggered by…
• Thirst vs. age

Answer 12

• Originates in thirst centers int eh brain
• Triggered by an increase in plasma tonicity of as little as 2-3%
  
  • Plasma osmolality threshold = 295 mOsm/kg
• Ability to feel thirsty decrease w/ age

Question 13

Renal water handling: absence vs. presence of ADH

Answer 13

Question 14

Renal water handling: proximal tubule

• GFR
• PT water reabsorption
• PT permeability to water
• Accumulation of fluid & solutes within the renal interstitium
• Osmolality of reabsorbed fluid

Answer 14

• GFR = 125 ml plasma / min (93% = water)
• PT reabsorbes 65-80% of filtered water
  
  • PT reabsorbs Na & other solutes from tubular fluid into lateral intercellular spaces
  • Decreases the osmolality of tubular fluid
  • Increases the osmolality of hte lateral intercellular space
• PT is highly permeable to water
  
  • Expresses AQP1 channels in the apical & basolateral membranes
  • Water is reabsorbed transcellularly by osmosis due to higher osmolality of fluid in the lateral intercellular space 9renal interstitium) than tubular fluid
  • Some water is also reabsorbed paracellularly
• Accumulation of fluid & solutes within the renal interstitium
  
  • Increases hydrostatic pressure in this compartment
  • Forces fluid & solutes into peritubular capillaries
• Osmolality of reabsorbed fluid
  
  • Reabsorbed fluid is iso-osmotic to plasma

Question 15

Renal water handling: proximal tubule

• Net water reabsorption force in the renal interstitium
• P_c
• During hypovolemia
• π_c

Answer 15

• Net water reabsorption force in the renal interstitium
  
  • Filtration = K_f [(P_c - P_i) - (π_c - π_i)]
  • K_f = filtration coefficient
  • P_c = peritubular capillary hydrostatic pressure
  • P_i = renal interstitium hydrostatic pressure
  • π_c = peritubular capillary oncotic pressure
  • π_i = renal itnerstitium oncotic pressure
• P_c
  
  • Determined by arteiral BP & vasuclar resistance in AffAs & EffAs
  • Increase arterial BP –> increase P_c –> decrease water reabsorption in PT
  • Increase vascular resistance in AffAs & EffAs –> decrease P_c –> increase water reabsorption in PT
• During hypovolemia
  
  • Decrease arterial BP –> decrease P_c
  • Release AII –> AffA & EffA constriction –> decrease P_c
  • Net effect: increase water reabsorption in Pt
• π_c
  
  • Determiend by serum albumin conc & FF
  • Increase serum albumin –> increase π_c –> increase water reabsorption in PT
  • Increase FF –> more plasma filtered through glomerulus –> more concentrated albumin –> increase water reabsorption in PT

Question 16

Normal hydrostatic & oncotic forces that determine water reabsorption by peritubular capillaries

• Normal hydrostatic pressure in peritubular capillaries vs. renal interstitium
• Normal oncotic pressure in peritubular capillaries vs. renal interstitium
• Net result

Answer 16

• Normal hydrostatic pressure in peritubular capillaries vs. renal interstitium
  
  • Peritubular capillaries: 13 mmHg
  • Renal interstitium: 6 mmHg
  • Net result: hydrostatic pressure gradient of 7 mmHg opposes water reabsorption
• Normal oncotic pressure in peritubular capillaries vs. renal interstitium
  
  • Peritubular capillaries: 32 mmHg
  • Renal interstitium: 15 mmHg
  • Net result: oncotic pressure gradient of 17 mmHg favors water reabsorption
• Net result
  
  • Net oncotic forces that favor reabsorption (17 mmHg) - net hydrostatic forces that oppose water reabsorption (7 mmHg) = net water reabsorption (10 mmHg)

Question 17

Renal water handling: water permeability

• LOH
  
  • TDL
  • TnAL
  • TkAL
• DCT
• CD

Answer 17

• LOH
  
  • TDL: has AQP1 & reabsorbs 15% of filtered water​
    
    • NaCl transporter: absent
    • NaCl permeability: no
    • Osmolality: increase
  • TnAL: lacks AQP1 & is impermeable to water
    
    • NaCl transporter: Cl channel, Na channel?
    • NaCl permeability: yes
    • Osmolality: decrease
  • TkAL: lacks AQP1 & is impermeable to water
    
    • NaCl transporter: Na/K/2Cl co-transporter
    • NaCl permeability: yes
    • Osomlality: decrease
• DCT
  
  • Lacks AQP1 & is impermeable to water
• CD
  
  • Segments: cortical, outer medullayr, & inner medullary CD
  • Absence of ADH: impermeable to water
  • Presence of ADH: permeable to water

Question 18

Countercurrent multiplication system

• Corticopapillary osmotic gradient
• Histological structure responsible for generating the corticopapillary osmotic gradient
• 4 steps in the countercurrent multiplication process
  
  • Step 1: rest
  • Step 2: TnAl & TkAL NaCl transport
  • Step 3: TDL water transport
  • Step 4: additional fluid transport
• Net effect

Answer 18

• Corticopapillary osmotic gradient
  
  • Gradient of osmolarity in the interstitial fluid from the cortex to the tip of the papilla
  • Interstitial osmolarity increases from cortex –> outer medulla –> inner medulla –> papilla
• Histological structure responsible for generating the corticopapillary osmotic gradient
  
  • LOH
• 4 steps in the countercurrent multiplication process
  
  • Step 1
    
    • Tubular fluid in the LOH & medullary interstitum are isotonic (osmolarity = 300 mOsm/L)
  • Step 2
    
    • TnAL & TkAL transport NaCl from tubule –> medullary interstitium until interstitium is 200 mOsm/L (more concentrated than in tubule)
      
      • TnAL: passive process
        
        • Cl transported transcellularly via Cl channel & paracellularly via following Na
        • NaCl –> down conc gradient
        • Urea: inner medullary CD –> medullary interstitium
          
          • Reduces inner medullary interstitial NaCl conc –> establishes gradient
      • TkAL: active process
        
        • Via Na/K/2Cl transporter
        • Na –> down conc gradient from Na/K ATPase
    • Water impermeability –> salt leaves w/o water osmotically following
  • Step 3
    
    • Water follows the osmotic gradient out of the TDL until the osmolarities in the TDL & medullary interstitium become equal (400 mOsm/L)
    • TDL is impermeable to NaCl
  • Step 4
    
    • Additional fluid: PT (osmolarity = 300 mosm/L) –> TDL
    • Causes hyperosmotic fluid (400 mOsm/L): TDL –> TnAL & TkAL
• Net effect
  
  • Add more solute to medulla –> increase conc gradient –> increase medullary interstitium osmolarity to 1200 mOsm/L
  • Gradually trap solutes in medulla

Question 19

Urea recycling

• Urea recyling contributes to…
• Urea contributes to…
• Plasma urea filration & reabsorption under normal GFR
• Urea reabsorption in the PT
• Urea conc in the TDL
• Urea conc in the TnAL
• Urea conc in the TkAL & DCT
• Urea conc int he CCD, OMCD, & IMCD in the presence of ADH
• Cycle continuation

Answer 19

• Urea recyling contributes to…
  
  • Generation of the corticopapillary osmotic gradient
• Urea contributes to…
  
  • 50% of the medullary interstitium osmolality when hte kidney forms max concentrated urine in the presence of ADH
  • Esp true in the IMCD where osmolality reaches 1200 mOsm/L
• Plasma urea filration & reabsorption under normal GFR
  
  • All plasma urea is filtered
• Urea reabsorption in the PT
  
  • 50% is reabsorbed
• Urea conc in the TDL
  
  • Conc increases due to water reabsorption & urea secretion into the TDL via UT-A2 urea transporters
• Urea conc in the TnAL
  
  • Conc increases due to urea secretion into the TnAL
• Urea conc in the TkAL & DCT
  
  • Unchanged b/c tubules are impermeable to water
• Urea conc int he CCD, OMCD, & IMCD in the presence of ADH
  
  • CCD & OMCD are permeable to water but impermeable to urea
    
    • Urea conc increases due to water reabsorption
  • IMCD is permeable to urea
    
    • High urea conc when fluid reaches IMCD
    • Urea is tranpsored out via UT-A1 urea transporters
    • Favors urea diffusion into the medullayr interstitium
• Cycle continuation
  
  • A moderate share of the urea that moves into the interstitium eventually diffuses into the DTL and ATL,

Question 20

Countercurrent exchanger

• Purpose
• Histological structure responsible for the countercurrent exchanger
• Blood flow
• Energy: active vs. passive process
• Osmolality
  
  • Blood entering TDL
  • As blood descends…
  • Bend of vasa recta
  • As blood ascends…

Answer 20

• Purpose
  
  • Maintain the medullayr gradient by mitigating washout
• Histological structure responsible for the countercurrent exchanger
  
  • Vasa recta: capillaries that serve the medulla
  • Branch off EffA of juxtamedullary nephrons
  • Follow the LOH
• Blood flow
  
  • RBF = 20% * CO
  • Medulla receives 5% of total RBF
  • Blood flow through the vasa recta is slow & has a low oxygen conc
• Energy: active vs. passive process
  
  • Purely passive so no energy is spent
  • Contrasts countercurrent multiplication: energy is spent
• Osmolality
  
  • Blood entering TDL: 300 mOsm/L
  • As blood descends, it’s exposed to interstitial fluid w/ increased osmolality
    
    • Capillaries are freely permeable to water & solutes, so small solutes (ex. NaCl, urea) diffuse from the medulla –> descending capillary limb
    • Allows blood to equilibrate osmotically
  • Bend of vasa recta: osmolality = interstitial fluid = 1200 mOsm/L
    
    • Hairpin config doesn’t allow medullary gradient to be washed out by solute leaving & water coming
  • As blood ascends the TnAL & TkAL, blood is exposed to interstitial fluid w/ decreasing osmolality
    
    • Solutes diffuse out into the interstitium & water diffuses into the TALs
    • Blood in the ascending limb equilibrates w/ surrounding interstitial fluid

Question 21

Renal water handling during TBW deficit

• Main job of kidneys during TBW deficit
• PT
• TDL
• TnAL
• TkAL
• DCT
• CD

Answer 21

• Main job of kidneys during TBW deficit
  
  • Produce concentrated urine to maximize water reabsorption & preserve water balance
• PT
  
  • Osmolality of glomerular filtrate = blood (300 mOsm/L0
    
    • Osmolarity remains at 300 mOsm/L b/c water is reabsorbed in proportion to solutes (iso-osmotic)
  • TBW deficit + total body Na deficit (hypovolemia): increase % of water reabsorbed (90%)
• TDL
  
  • Permeable to water, impermeable to NaCl
  • Water is reabsorbed following the osmotic gradient of th ehypertonic medulla
  • As water –> medulla, tubular fluid osmolality increases & equilibrates w/ the osmolality of the medulla at the hairpin of the LOH (1200 mOsm/L)
• TnAL
  
  • Impermeable to water so no osmotic equilibrium
  • Permeable to NaCl: passive process
    
    • NaCl conc in the medullayr interstitium has been diluted by water from the TDL
    • NaCl conc in TnAL > medulla
    • NaCl moves passivley down conc gradient –> decrease TnAL osmolality
• TkAL (aka medullayr diluting segment, aka concentrating segment)
  
  • Impermeable to water
  • Permeable to NaCl: active process
    
    • NaCl is reabsorbed down its conc gradient into the medulla via the N/K/2Cl co-transporter
      
      • Gradient is produced by Na/K ATPase actively pumping Na out of the cell
      • ADh stimulates Na/K/2CL to contribute to the increasing gradient
    • osmolality of fluid leaving this segment = 100 mOsm/L
• DCT (aka cortical diluting segment)
  
  • Impermeable to water
  • Permeable to NaCl
  • Osmolality of tubular fluid decreases to 80 mOsm/L
• CD
  
  • Permeable to water only in the presence of ADH
    
    • As tubular fluids flow down, it’s exposed to interstitial fluid w/ increasingly higher osmolality (corticopapillary osmotic gradient)
    • Water will be reabsorbed until tubular fluid equilibrates osmotically w/ surrounding medullary interstitial fluid
    • Final urine osmolality at the tip of the papilla = 1200 mOsm/L
  • ADH also increases urea permeability in the IMCD to facilitate urea transport
    
    • Urea contributes to the medullayr gradient in the inner medulla

Question 22

Renal water handling during TBW excess

• Main job of kidneys during TBW excess
• PT
• TDL
• TnAL
• TkAL
• DCT
• CD

Answer 22

• Main job of kidneys during TBW deficit
  
  • Produce diluted urine to maximize water excretion & preserve water balance
• PT
  
  • Osmolality of glomerular filtrate = blood (300 mOsm/L0
    
    • Osmolarity remains at 300 mOsm/L b/c water is reabsorbed in proportion to solutes (iso-osmotic)
  • TBW deficit + total body Na deficit (hypovolemia): decrease % of water reabsorbed (65%)
• TDL
  
  • Permeable to water, impermeable to NaCl
  • Water is reabsorbed following the osmotic gradient of the hypertonic medulla
  • As water –> medulla, tubular fluid osmolality increases & equilibrates w/ the osmolality of the medulla at the hairpin of the LOH (600 mOsm/L)
    
    • Lower than in TBW deficit
• TnAL
  
  • Impermeable to water so no osmotic equilibrium
  • Permeable to NaCl: passive process
    
    • NaCl conc in the medullary interstitium has been diluted by water from the TDL
    • NaCl conc in TnAL > medulla
    • NaCl moves passivley down conc gradient –> decrease TnAL osmolality
• TkAL (aka medullary diluting segment, aka concentrating segment)
  
  • Impermeable to water
  • Permeable to NaCl: active process
    
    • NaCl is reabsorbed down its conc gradient into the medulla via the N/K/2Cl co-transporter
      
      • Gradient is produced by Na/K ATPase actively pumping Na out of the cell
      • ADh stimulates Na/K/2CL to contribute to the increasing gradient
    • Osmolality of fluid leaving this segment = 120 mOsm/L
      
      • Higher than in TBW deficit b/c dilution step is diminished w/o ADH due to lack of N/K/2Cl stimulation
• DCT (aka cortical diluting segment)
  
  • Impermeable to water
  • Permeable to NaCl
  • Osmolality of tubular fluid decreases to 100 mOsm/L
    
    • Higher than in TBW deficit
• CD
  
  • Imermeable to water in the absence of ADH
    
    • As tubular fluids flow down, no osmotic equilibration is possible
    • NaCl continues to get reabsorbed
    • Urine osmolality decreases to 50 mOsm/L
  • ADH can’t increase urea permeability in the IMCD
    
    • Urea doesn’t contribute to the medullary gradient
  • Final urine osmolality at the tip of the papilla = 600 mOsm/L
    
    • Lower than in TBW deficit

Question 23

Assessment of water balance

• Urine osmolality (UOsm)
  
  • Definition
  • Normal vs. abnormal ranges
• Urine specific gravity (USG)
  
  • Definition
  • Normal vs. abnormal ranges
  • USG vs. UOsm
  • Plasma USG & UOsm

Answer 23

• Urine osmolality (UOsm)
  
  • # of particles in urine / kg of water volume
  • Normal range: 50-1200 mOsm/kg
    
    • UOsm < 100 –> max diluted urine + absent ADH –> TBW excess
    • UOsm > 600-800 –> concentrated urine + present ADH –> TBW deficit
• Urine specific gravity (USG)
  
  • Ratio of density of urine w/ density of an equal volume of water
    
    • Proportional to the MW & # of particles in sol’n
  • Normal range: 1.005 - 1.035
    
    • Every 30 mOsm/kg increment in UOsm corresponds to an increase in USG of 0.001
    • USG > 1.030 –> concentrated urine –> TBW deficit
    • USG < 1.010 –> diluted urine –> TBW excess
  • Every 30 mOsm/kg increment in UOsm corresponds to an increase in USG of 0.001
  • Plasma: 1% heavier than water –> USG = 1.010 –> UOsm = 300 mOsm/kg

Question 24

Assessment of water balance

• Electrolyte-free water clearance (C_eH2O)
• C_eH2O equation
• Urine/plasma electrolyte ratio
  
  • Definition
  • (U_Na + U_K) / P_Na > 1
    
    • C_eH2O
    • Free water
  • (U_Na + U_K) / P_Na = 1
    
    • C_eH2O
    • Free water
  • (U_Na + U_K) / P_Na < 1
    
    • C_eH2O
    • Free water
• Under pathological circumstance

Answer 24

• Electrolyte-free water clearance (C_eH2O)
  
  • Amt of solute-free water excreted by kidneys in 24 hr
  • Assessment of water balance
• C_eH2O equation
  
  • C_eH2O = V * { 1 - [ (U_Na + U_k) / P_Na ] }
  • C_eH2O = electroyle-free water clearance
  • V = urine volume in 24 hr
  • U_Na = urine Na conc
  • U_K = urine K conc
  • P_Na = plasma/serum Na conc
• Urine/plasma electrolyte ratio
  
  • Used to predict electrolyte-free water clearance if info about urine volume (V) is unavailable
  • (U_Na + U_K) / P_Na > 1
    
    • C_eH2O: negative
    • Free water: retained
  • (U_Na + U_K) / P_Na = 1
    
    • C_eH2O: zero
    • Free water: neither retained nor excreted
  • (U_Na + U_K) / P_Na < 1
    
    • C_eH2O: positive
    • Free water: excreted
• Under pathological circumstances
  
  • Homeostatic mechs that maintain water balance fail
  • TBW deficit & excess produce persistent change sin plasma tonicity
  • Changes can be assessed by measuring serum osmolality & serum Na conc