Body Fluid Osmolarity

Question 1

T or F. a change in TBW is uniformly distributed in different body fluid compartments resulting in uniform change in fluid osmolarity in different compartments

Answer 1

T. Because cell membranes are highly permeable to water,So an excessive water intake would increase TBW resulting in a decrease in body fluid osmolarity in different compartments and vice versa

Question 2

How does the kidney respond to a decrease in fluid osmolarity?

Answer 2

by increasing water excretion in the urine.

Question 3

How does the kidney respond to a change in fluid osmolarity?

Answer 3

This is a centrally regulated process. ADH secreted by the pituitary gland regulates water reabsorption in kidney. Thirst center regulates water intake.

Question 4

What is the normal intake/production of water daily?

Answer 4

Normal daily water intake is about 2000 ml (1500 drinking and 500 food) and 400 ml is produced in the body during metabolic processes.

Question 5

What is the normal distribution of water output daily?

Answer 5

urine-1500mlbreathing-400mlskin-400ml (burn can drastically increase)feces-100ml

Question 6

Does the kidney have a high capacity to excrete water?

Answer 6

Yes, Excessive water driniking or lack of ADH may increase GFR by 10% which is equal to 18 L/day.

Question 7

Eqn for plasma osmolarity

Answer 7

2[Na+] + glucose concentration in mg/dl divided by 18 + BUN in mg/dl divided by 2.8.normal is ~285mOsmNa 137, glucose 100, and BUN 15

Question 8

Changes in osmolarity is sensed by what?

Answer 8

osmoreceptors. The Osmoreceptors on supraoptic and paraventricular nuclei of the hypothalamus are stimulated by an increase in body fluid osmolarity. Increase in osmolarity also stimulates osmoreceptors in the thirst center I the hypothalamus. The result is change in behavior encouragig to drink more water.

Question 9

What does activation of the supraoptic and paraventricular nuclei of the hypothalamus cause?

Answer 9

Activation at the cell body of supraoptic nerves transmits signal to the nerve ending that is located in the posterior pituitary gland. The final cellular signal in the nerve ending is increase in intracellular calcium. Elevated intracellular calcium stimulates membrane fusion of ADH containing vesicles resulting in exocytosis of ADH into ECF.

Question 10

What does ADH do?

Answer 10

ADH acts on the CD epithelial cells and increases water reabsorption.Increase in water reabsorption corrects the osmolarity back to normal.

Question 11

What is the composition of ADH?

Answer 11

small peptide consisting of 9 amino acids with a MW of 1100 daltons.

Question 12

T or F. The basolateral membranes of the CD epithelial cells have the receptors for vasopressin

Answer 12

T.

Question 13

How is ADH released from the pituitary transported to the kidney?

Answer 13

By circulation. It binds to vasopressin receptors on the BL membrane and activates the intracellular signaling. It first activates the adenylate cyclase that converts ATP into cAMP.

Question 14

What does increased cAMP in the CD epithelial cells stimulate?

Answer 14

cAMP activates protein kinase A which phosphorylates vesicles containing aquaporin-2 in their membranes and makes them fuse to plasma membrane on the luminal side, thus increases water permeability of the cells.

Question 15

How quick is this whole process?

Answer 15

This is a rapid process, takes less than 10 min to increase water permeability once the plasma ADH level is increased

Question 16

What are the types of vasopressin receptors?

Answer 16

There are 3 types of vasopressin receptors, V1, V2 and V3. It is the V2 receptors on the basolateral membrane that is involved in cAMP production and aquaporin translocation to luminal membrane.

Question 17

What do V1 and V3 do?

Answer 17

V1 and V3 receptors are G-protein coiupled receptors. V1 receptors seem to present in the luminal membranes, but its function is unclear at this point.

Question 18

What happens to ADH once it functions?

Answer 18

ADH released by stimulation of hypothalamus is rapidly degraded in the PT and liver, thus avoiding sustained presence of high plasma ADH. Rapid degradation help bring the ADH level back to normal.

Question 19

Does increase in plasma osmolarity lead to concentrated or diluted urine?

Answer 19

concentrated. Make sure you know howUrinary osmolarity can go as high as 1200 mOM.

Question 20

Describe the relationship between plasma AVP (y) and plasma osmolality (x).

Answer 20

up to pOsm of 270, AVP is negligible. Above 270 mOsM osmolarity ADH level increases proportionally to reach maximum of 18 pM at 290 mOsM plasma osmolarity. Above this plasma osmolarity, AVP levels will not increase any more.

Question 21

In addition to plasma osmolarity, ADH secretion is also regulated by plasma volume. How?

Answer 21

A decrease in ECFV by 1.5 L (from normal) has only a little effect on ADH level. But, further decrease in ECFV increases plasma ADH concentration, which can be as high as 50 pg/ml. Therefore, the threshold for ADH secretion by reduction in ECFV is very high.

Question 22

Greater than 10-15% decrease in ECFV is required to have a strong increase in plasma ADH.

Answer 22

Second, a 25% decrease in ECFV can increase plasma ADH level to 50 pg/ml, which is almost 3 fold higher than the highest concentration achieved by osmolarity changes.

Question 23

Can osmolarity and volume be reduced at the same time?

Answer 23

Yes, A clinical condition that may reflect such a situation is of severe decline in ECFV due severe diarrhea, but with reduced plasma osmolarity due to loss of salts in diarrhea. Based on osmolarity there should reduced plasma ADH causing diuresis. But, that would result in further reduction of volume. On the other hand, reduction of plasma volume should increase plasma ADH and increase water reabsorption. So, which effect prevails?Under condition of severe loss of ECFV its effect on ADH release overrides osmolarity effect on ADH secretion. In other words, it does not matter what the osmolarity is at low ECFV, the AVP level rises high.

Question 24

How does excessive vomiting lead to hypoatremia?

Answer 24

Assume the lid loss in vomit is isotonic.The ECFV depletion (but not osmolarity because we assume no change) is large enough to stimulate ADH release.ADH indcues concentration of urine and dilution of plasma.Therefore body water is conserved and the ECFV is increased.The result is reduced osmolarity and hyponatremia

Question 25

What are some clinical signs of hyponatremia?

Answer 25

lethargy, hyporeflexia and mental confusion

Question 26

Treatment for persistent vomiting?

Answer 26

infusion of isotonic saline.

Question 27

A common symptom of decreased ability to concentrate urine is what?

Answer 27

A common symptom of decreased ability to concentrate urine is nocturia, that is frequent urination during night

Question 28

The ability of kidneys to dilute or concentrate urine depends on what?

Answer 28

the rate at which they excrete water in relation to solute.So, to assess the ability of kidney to concentrate or dilute urine requires us to first quantitate the rate of excretion of solute. The parameter used for this is osmolar clearance

Question 29

What is the eqn for osmolar clearance?

Answer 29

Cosm= UF*(Uosm/Posm)

Question 30

What is normal osmolar clearance?

Answer 30

2 ml/min +- 0.5Represents the rate at which solute is removed from plasma and excreted in urine

Question 31

What is water clearance?

Answer 31

Water clearance is how much water is cleared in urine at a given time. The difference between osmolar clearance and water clearance is the “free water clearance.

Question 32

Eqn for free water clearance.

Answer 32

Ch20= UF-Cosm So if urine osmolarity is less than plasma osmolarity, there will be a positive free water clearance, that is dilution of urine and plasma osmolarity increasesOn the other hand, if urine osmolarity is greater than plasma osmolarity, there will be a negative free water clearance, which means urine is being concentrated and reduction of plasma osmolarity

Question 33

Here is a numerical example of free water clearance under condition of hypo-osmolar plasma

Answer 33

Assume plasma is dilute: 270 mosml/L (plsma AVP is undetectable) and RPF is 0.69 L/minMass osmolar flow is 0.69 x 270 = 186.3 mOsmol/minAssume urine is dilute: 50 mOsml/L and urine flow is 12 ml/minMass osmolar flow is 0.012 x 50 = 0.6 mOsm/minRenal venous flow:RPF = 690-12 = 678 ml/minOsmolar flow = 186.3-0.6 = 185.7 mOsm/minVenous plasma osmolarity = 185.7/0.678 = 274 mOsM that is plasma osmolarity is increased by 4 mOsMThe free water clearance is 12 ml/min of UF times (1 minus 50 mOsm/L of urine osmolarity divided by 270 mOsm/L plasma osmolarity); 9.78 ml/min.

Question 34

Here is a numerical example of free water clearance under condition of hyper-osmolar plasma

Answer 34

Assume plasma is hyperosmolar: 300 mosml/L (plsma AVP is high) and RPF is 0.69 L/minMass osmolar flow is 0.69 x 300 = 207 mOsm/minAssume urine is concentrated: 1200 mosml/L and urine flow is 0.5 ml/minMass osmolar flow is 0.0005 x 1200 = 0.6 mOsm/minRenal venous flow:RPF = 690-0.5 = 689.5 ml/minOsmolar flow = 207-0.6 = 206.4mOsm/minVenous plasma osmolarity -= 206.4/0.6895 = 299.3 mOsM that is decrease by 0.7 mOsMThe free water clearance is 0.5 ml/min of UF times 1 minus 1200 mOsm/L of urine osmolarity divided by 300 mOsm/L plasma osmolarity; -1.5 ml/min.Human kidney is more efficient in clearing water than conservation

Question 35

Renal medullary osmolarity is high surrounding the LOH and there is an osmolarity gradient from the cortical end to the papillary end. What is the significance?

Answer 35

Due to the osmotic gradient between the TF and medullary IS, water and NaCl are reabsorbed which then to carried to blood by the vasa recta.

Question 36

How is the hyperosmolarity gradient is developed and maintained in the medulla?

Answer 36

The permeability characteristics of different segments of DT play important role in this.Thin descending limb is highly water permeable, but impermeable to NaClThin ascending limb is impermeable to water. It is permeable to NaCl, but there is no active transport mechanism for it.Thick ascending limb is also impermeable to water but NaCl is absorbed by active transport mechanism.The DCT and CD are permeable to water depending on ADH level and Na is transported by active transport mechanism. The CD in the inner medulla is also highly permeable to urea in addition to being permeable to water depending on ADH level and Na is transported by active transport mechanism.

Question 37

Features of kidney responsible for development of medullary hyperosmolarity

Answer 37

1. Special anatomical arrangement of loop of Henle and vasa recta and peritubular capillaries. Loop like arrangement of LOH and vasa recta2. Active transport of Na+ and co-transport of K+ and Cl- out of thick ascending limb into medullary ISF Capable of creating 200 mOsm gradient between tubule and ISF3. Active transport of Na+ out of collecting duct into ISF4. Passive diffusion of urea from inner medullary collecting duct into medullary ISF5. Diffusion of only small amounts of water from medullary tubules into medullary interstitium

Question 38

Let us say in step 1, the TF and ISF are isoosmolar that is 300 mOsM all over.In step 2, the active transport mechanism in the thick ascending limb of LOH creates an osmolarity gradient with 200 mOsM TF and 400 mOsM ISF.In step 3, water is absorbed in the thin descending limb due to the osmotic gradient created by the active of Na, concentrating the TDL.

Answer 38

In step 4, as the fluid in the thin descending limb flows downwards an osmolarity gradient is created, as it becomes more concentrated In Step 5, as the fluid from the descending limb flows upwards into the ascending limb the active transport of Na creates an new gradient between TF and ISF.In step 6, water is transported in the descending limb to match the new osmolarity gradient. Repeating the steps 4-6 results in development of a stable osmolarity gradient.

Question 39

Does urea play an important role in maintenance of medullary hyperosmolarity?

Answer 39

Yes, it contributes to at least 40% of medullary ISF hyperosmolarity.

Question 40

What segments are permeable for reabsorption of urea?

Answer 40

The thin limbs of LOH are only slightly permeable to urea. The thick ascending limb, the DCT and the cortical CD are impermeable to urea. So urea is concentrated by the time it reaches the inner medullary CD, which has very high permeability to urea.

Question 41

So how is urea absorbed into the medullary ISF?

Answer 41

by simple diffusion. As the permeability of thin limbs of LOH to urea is low, a high urea concentration is maintained in the inner medullary ISF, which contributes to hyperosmolarity.

Question 42

Why do the medullary capillaries not wash out the medullary hyperosmolarity?

Answer 42

First, the medullary blood flow is low. Only 1-2% of renal blood flow reaches inner medullary region. The flow rate is only 50 ml/min.Second, due to the loop structure of the vasa recta, it serves in counter current exchange. The plasma osmolarity in the descending vasa recta does increase similar to the medullary ISF osmolarity gradient. But, when the blood flows upwards in the ascending vasa recta the plasma osmolarity drops to normal osmolarity. Therefore, there no net clearance of medullary hyperosmolarity.

Question 43

What does diabetes insipidus result in?

Answer 43

High rates of production of dilute urine NOTE: there are two types- central and nephrogenic

Question 44

What is central DI?

Answer 44

Pituitary gland fails to release AVP - rare congenitalPatients get dehydrated very quickly

Question 45

What is nephrogenic DI?

Answer 45

Collecting ducts do not respond to AVP

Question 46

Causes of nephrogenic DI?

Answer 46

-V2 receptor mutation-Aquaporin-2 mutation-Drugs: lithium, tetracycline

Question 47

What is polydipsia?

Answer 47

Psychiatric condition characterized by obsession of water drinking leading to hyponatraemia (water intoxication) and potentially coma and death

Question 48

How does nicotine affect ADH?

Answer 48

increases it

Question 49

How does alcohol affect ADH?

Answer 49

decreases it- plasma osmolarity will increase BUT it is freely permeable through the plasma membrane so it won’t increase it