Water Balance & Hydration Status

Question 1

How much of the body is made up of water? What are the 2 compartments?

Answer 1

TBW = 60%

1. ECF (33%) - 25% intravascular, 75% interstitial
2. ICF = 66%

Question 2

What is the difference between osmolality and osmolarity?

Answer 2

OSMOLALITY - [solute] per kg of SOLVENT (plasma/serum), mOsm/kg (solution with an osmolality of 1.0 = 1 osmole of solute added to 1 kg (1 L) of water)

OSMOLARITY - [solute] per L of SOLUTION mOsm/L (solution with an osmolarity of 1.0 = 1 osmole of solute with water added to make 1 L)

Question 3

How is osmolality measured? What equation is used to estimate it? What are the normal values in dogs, cats, horses/cows?

Answer 3

freezing point depression osmometry, which measures all of the osmoles in plasma

mOsm/kg = 2[Na + K (mmol/L)] + [glucose (mg/dL)]/18 + [BUN (mg/dL)]/3

• DOG = 210-310 mOsm/kg
• CAT = 290-300 mOsm/kg
• HORSE/COW = 270-300 mOsm/kg

Question 4

What is diuresis? What are the 2 types?

Answer 4

urine flow is greater than normal (> 1-2 mL/kg/hr in dogs and cats)

1. OSMOTIC: increased urine flow caused by excessive amounts of impermeant solutes within the renal tubules (Na, glucose from DM, mannitol), causing the urine osmolality to approach plasma osmolality
2. WATER: increased urine flow caused by decreased reabsorption of free water, causing urine osmolality to drop below plasma osmolality (DI)

Question 5

What is specific gravity? What 2 things does it depend on? How does it relate to osmolality?

Answer 5

ratio of weight of a volume of liquid to the weight of an equal volume of distilled water

1. number of particles present
2. molecular weight of those particles

estimate of osmolality —> linear relationship

Question 6

What are the 2 methods of maintaining blood volume and body fluid tonicity?

Answer 6

1. ADH/vasopressin control water balance (osmolality, [Na])
2. aldosterone controls sodium and ECF volume

Question 7

What 4 things does water balance depend on? What does it require?

Answer 7

1. adequate intake
2. renal and GI function
3. losses in sweat and respiration
4. neural control

FUNCTIONAL KIDNEY - adequate delivery of tubular fluid (plasma flow, GFR, isoosmotic resorption of Na and water in PT), ascending loop of Henle, CDs impermeable to water

Question 8

What physical sensors regulate water balance? How do they respond to changes in osmolality?

Answer 8

osmoreceptors in the hypothalamus

• HYPEROSMOLALITY (low body water): osmoreceptors shrink and stimulate ADH release, which increases water reabsorption via the kidney and stimulates the thirst response
• HYPOOSMOLALITY (excess body water): osmoreceptors swell and inhibit ADH release, which increases renal water excretion

Question 9

How does the renin-angiotensin-aldosterone system affect ADH secretion?

Answer 9

stimulates ADH release if needed for hypovolemic state regardless of sodium concentration

Question 10

What is the primary regulator of blood volume? How does water concentration affect the concentration of it?

Answer 10

sodium [Na] = mmol (# Na molecules in plasma) / L (water in plasma)

• increased water = decreased [Na]
• decreased water = increased [Na]

Question 11

How is blood volume regulated? What 3 hormones are involved? What are the major outcomes?

Answer 11

sensing atrial stretching and renal perfusion pressure

1. renin, angiotensin II, aldosterone
2. sympathetic nervous system
3. atrial natriuretic peptide (ANP)

urine Na retention or excretion

Question 12

How does the kidney affect blood volume?

Answer 12

• renal Na resorption = water follows = blood volume expands
• renal Na excretion = water follows = blood volume contracts

Question 13

What are the 4 major water components in the ECF compartment?

Answer 13

1. intravascular (-volemia): blood volume
2. intercellular fluid
3. transcellular (third spaces): pleural, peritoneal, pericardial
4. GI

Question 14

What does TBW volume determine?

Answer 14

hydration status - controlled by water intake (thirst) and renal output

Question 15

Where are electrolytes most commonly measured in? What organs take part in maintaining their concentrations?

Answer 15

serum —> may not completely reflect balance of electrolytes in the body, especially for intracellular electrolytes

GIT and kidneys

Question 16

What are the most common electrolytes found in the ICF and ECF?

Answer 16

ICF: potassium*, calcium, phosphorus, magnesium

ECF: sodium (renal conservation of water), chloride (secretory fluids)

Question 17

What ions are coupled with the movement of chloride?

Answer 17

SODIUM = same direction for electroneutrality

BICARBONATE = opposite direction

Question 18

How is potassium affected by acid-base imbalances?

Answer 18

exchanged between ICF and ECF

Question 19

What solutes mostly affect osmolality of the ECF? What does it influence?

Answer 19

electrolytes (Na+, K+), proteins, glucose, urea

changes in ECF osmolality affects water shifts between ECF and ICF

Question 20

How do measured and calculated osmolality compare?

Answer 20

MEASURED = accounts for all osmoles in the blood

CALCULATED = represents osmoles reported in the chemistry panel

Question 21

What are the most common causes of water shifts between ICF and ECF? How do they cause this?

Answer 21

• hypernatremia
• hyperglycemia
• ketoacidosis
• uremia
• exogenous toxins (ethylene glycol)

changes plasma osmolality

Question 22

What causes plasma hyperosmolality without fluid shifts? What is an example? What clinical signs are associated?

Answer 22

increased plasma concentration of ineffective solutes causing the intracellular osmolality = extracellular osmolality

uremia - urea is freely filterable across cell membranes

no clinical signs

Question 23

What does plasma hyperosmolality cause? What are 2 common causes? What clinical signs are associated?

Answer 23

increased plasma concentration of effective solutes, where the intracellular osmolality is less, so the cell becomes dehydrated and loses water

hypernatremia, severe hyperglycemia (DM)

those manifested of cerebral cellular volume - neurologic changes associated to cellular dehydration, depression, stupor, coma, CNS deficits, seizures

Question 24

What does plasma hypoosmolality cause? What is a common cause? What clinical signs are associated?

Answer 24

increased plasma concentration of water, where intracellular osmolality is higher, so the cell swells with water

hyponatremia

cerebral edema and cell lysis - lethargy, weakness, altered mentation, obtundation, seizures, death

Question 25

What is the osmolar gap? What is the normal value? What is happening when it is elevated?

Answer 25

measured osmolality (ALL osmoles) compared to calculated osmolality (osmoles in BIOCHEM)

10 mOsm/kg

> 10 mOsm/kg = presence of osmolar substances NOT included in the osmolality calculation, like ethylene glycol, mannitol, ethanol, methanol, or radiographic contrast

Question 26

What is dehydration? What 4 clinical signs are associated?

Answer 26

fluid loss exceeds fluid intake, where TBW decreases

1. increased skin tent
2. increased CRT
3. tacky MM
4. retracted eyes

Question 27

What 5 clinicopathological parameters are observed in dehydrated patients?

Answer 27

1. erythrocytosis
2. (pre-renal) azotemia
3. hyperproteinemia
4. hypersthenuria
5. electrolyte abnormalities

Question 28

What is overhydration? How can patients be hypovolemic at the same time?

Answer 28

increased TBW with accumulation of fluid in extracellular or third spaces

effusions, in GIT (rumen)

Question 29

How is dehydration classified? What are the 3 types?

Answer 29

type of fluid loss and remaining tonicity of fluids (confirm dehydration, then look at plasma concentration)

1. hypertonic - water loss > Na loss = Na increased
2. isotonic - water loss = Na loss = Na normal
3. hypotonic - water loss < Na loss = Na loss

Question 30

What is hypertonic dehydration? What are the 5 main differentials?

Answer 30

water loss is in excess of electrolyte loss, causing plasma [Na] and osmolality to increase —> water shifts from ICF to ECF

1. diabetes insipidus
2. diabetes mellitus
3. osmotic diuresis
4. osmotic diarrhea
5. water deprivation

Question 31

What is isotonic dehydration? What are the 2 main differentials?

Answer 31

water loss is equivalent to electrolyte loss, causing plasma [Na] and osmolality to remain the same —> no shift between compartments, but ECF volume decreases

1. renal disease
2. diarrhea

Question 32

What is hypotonic dehydration? What are the 4 main differentials?

Answer 32

electrolyte loss is greater than water loss, causing plasma [Na] and osmolality to decrease —> water shifts from ECF to ICF, causing volume depletion

1. secretory diarrhea
2. vomiting
3. 3rd space loss
4. heat stress and sweating in horses - Cl- losses are greater than Na+ losses

Question 33

What 3 problems are associated with hypotonic dehydration?

Answer 33

1. fluid shifts from vasculatory into cells, causing vascular volume to decrease and cells swell —> edema when Na < 115-120 mEq/L
2. osmoreceptors are not stimulated and ADH is not released (stimulated by increased osmolality and decreased plasma volume)
3. medullary washout - increased urine flow rate resulting in impaired reabsorption of Na, Cl and urea

Question 34

What is another cause of medullary washout other than hypotonic dehydration?

Answer 34

increased medullary blood flow in the vasa recta flushes out solutes accumulating and creatin hypertonicity in medulla caused by hypokalemia and hypercalcemia

Question 35

What are common causes of overhydration? What 3 conditions does this typically lead to?

Answer 35

• iatrogenic fluid overload from IV administration with inappropriate elimination
• heart failure
• renal obstruction
• oliguria/anuria from renal failure

1. cardiovascular overload
2. pulmonary edema
3. generalized edema