Electrolyte Disorders 👩🏼‍🔬

Question 1

What are the 6 measured electrolytes?

Answer 1

1. sodium
2. potassium
3. (chloride)
4. (bicarbonate)
5. urea
6. creatinine

Question 2

What are the estimated electrolytes in the body?

Answer 2

water

Question 3

Why are abnormal electrolytes so clinically important?

Answer 3

1. it can be a primary disease state
2. it can be a secondary consequence of many diseases
3. iatrogenic problems are common

Question 4

What are the 4 main important functions of electrolytes?

Answer 4

1. maintenance of cellular homeostasis
2. cardiovascular physiology - BP
3. renal physiology - GFR
4. electrophysiology - heart & CNS

Question 5

What are the most common clinical examples of electrolyte disorders?

Answer 5

1. haemorrhage
2. poor intake in the elderly
3. diabetes insipidus
4. diabetes mellitus
5. diuretic therapy
6. endocrine disorders involving ADH, aldosterone

Question 6

What five interconnecting concepts are measured in the lab?

What is the main one that is measured?

Answer 6

1. concentrations
2. compartments
3. contents
4. volumes
5. rates of gain and loss

In the lab, concentration is measured

The other factors are deduced

Question 7

What are the missing components of this important concept?

Answer 7

Question 8

What is the normal intracellular fluid (ICF) and extracellular fluid (ECF) volume?

Answer 8

ICF - 23 L

ECF - plasma + interstitial 19 L

Question 9

What is normal cellular sodium concentration?

How can a change in the body affect this?

Answer 9

Normal Na conc is 140 mmol/L

Normally the system is maintained in equilibrium

changing any factor causes a new steady state to be reached

Question 10

How does decreasing the volume of fluid in the body affect ECF, ICF and Na concentration?

Answer 10

Decreasing the volume will raise the concentration of any solute

ICF - 20L

ECF - plasma + interstitial 18 L

Na - 148 mmol/L

Question 12

How does increasing the excretion of a solute affect solute concentration?

Answer 12

Increasing excretion decreases solute concentration

Question 13

Fill in the body fluid distribution table

Answer 13

Question 14

How does haemorrhage affect electrolyte concentrations?

Answer 14

it leads to loss of isotonic solutions

Question 15

If 2 L of isotonic fluid is lost from the body, how does this affect ECF, ICF and [Na]?

Why?

Answer 15

ECF = plasma and interstitial 17 L

ICF = 23 L

Na - 140 mmol/L

the loss is from the ECF ONLY

there is no change in [Na} and no fluid redistribution

Question 16

What is the difference between isotonic and hypotonic?

Answer 16

an isotonic solution has the same particulate concentration as the blood

a hypotonic solution is less concentrated than the blood

Question 17

What tends to lead to loss of hypotonic solutions?

Answer 17

dehydration

Question 18

How would loss of 3L of hypotonic fluid affect ECF, ICF and [Na]?

Why?

Answer 18

ECF = plasma + interstitial 18 L

ICF = 21 L

[Na] = 148 mmol/L

Greater loss from ICF than ECF

Small increase in [Na]

Fluid redistribution between ECF and ICF

Question 19

How can isotonic solutions be gained?

Answer 19

through administration of saline

Question 20

How does gain of 2L of isotonic fluid through saline drip affect ECF, ICF and [Na]?

Answer 20

ECF = plasma + interstitial 21 L

ICF = 23 L

[Na] = 140 mmol/L

Gain is to ECF ONLY

There is no change in [Na] and no fluid redistribution

Question 21

How may hypotonic solutions be gained?

Answer 21

through giving water

Question 22

What would happen to ECF, ICF and [Na} if there was gain of 3L of hypotonic fluid?

Answer 22

ECF = plasma + interstitial 20L

ICF - 25L

[Na] = 133 mmol/L

greater gain to ICF than to ECF

small decrease in [Na}

fluid redistribution between ECF and ICF

Question 23

What are examples of physiological compensatory mechanisms?

Answer 23

1. thirst
2. ADH
3. renin/angiotensin system

Question 24

What are examples of therapeutic compensatory mechanisms?

Answer 24

1. intravenous therapy
2. diuretics
3. dialysis

Question 25

Where is ADH produced and when is it released?

What effects does it have?

Answer 25

it is produced by the median eminence

it increases when osmolality rises

it decreases renal water loss and increases thirst

Question 26

What is the median eminence?

Answer 26

a part of the hypothalamus from which regulatory hormones are released

Question 27

What are the 2 simple tests to ascertain ADH status?

What do the results show?

Answer 27

measure plasma & urine osmolality:

if urine > plasma, this suggests that ADH is active

measure plasma & urine urea:

if urine is much greater than plasma, this suggests water retention

Question 28

What activates the renin-angiotensin system?

What does it cause?

Answer 28

it is activated by reduced IVV caused by Na depletion or haemorrhage

it causes renal Na retention

Question 29

What is the simple test to ascertain renin-angiotensin status?

Answer 29

measure plasma and urine [Na]

if urine [Na] < 10 mmol/L, this suggests that RAAS is active

Question 30

What will happen to ECF, ICF and [Na] if 2L of isotonic fluid loss is replaced by isotonic and hypotonic fluids?

Answer 30

isotonic fluid:

ECF = plasma + interstitial 19L

ICF = 23 L

Na = 140 mmol/L

This is NORMAL - no change in [Na] and no fluid redistribution

hypotonic fluid:

ECF = plasma + interstitial 18 L

ICF = 24 L

[Na] = 132 mmol/L

There is a fall in [Na] and fluid redistribution

Question 31

What will happen to ECF, ICF and [Na] if loss of 3 L of hypotonic fluid is replaced by isotonic and hypotonic fluid?

Answer 31

isotonic fluid:

ECF = plasma + interstitial 21L

ICF = 21L

[Na] = 146 mmol/L

[Na] is slightly increased but there is NO fluid redistribution

hypotonic fluid:

ECF = plasma + interstitial 19L

ICF = 23L

[Na] = 140 mmol/L

[Na is restored and there is fluid redistribution

Question 32

What 2 factors can lead to hyponatraemia?

Answer 32

• too little Na in ECF
• excess water in ECF

Question 33

What 2 factors can lead to hypernatraemia?

Answer 33

• too little water in ECF
• too much Na in ECF

Question 34

What 2 factors can lead to dehydration?

Answer 34

• water deficiency
• fluid (Na and water) depletion

Question 35

Fill in the blanks in the tree for diagnosing hyponatraemia

Answer 35

Question 36

How will the following features change in hyponatraemia due to diuretics?

Answer 36

Question 37

How are the following factors changed in hyponatraemia due to Syndrome of inappropriate antidiuretic hormone secretion (SIADH)?

Answer 37

Question 38

How are the following factors changed in hypernatraemia due to decreased water intake?

Answer 38

Question 39

How do the following factors change in hypernatraemia due to osmotic diuresis?

Answer 39

Question 40

What is the potassium reference range?

Which values are dangerous and why?

Answer 40

3.6 - 5.0 mmol/L

Values < 3.0 or > 6.0 are potentially dangerous

They can cause cardiac conduction defects or abnormal neuromuscular excitability

Question 41

How is potassium measured?

How is this used to calculate total body potassium?

Answer 41

serum potassium concentration is measured

this is a small proportion of the total potassium in the plasma

total body potassium is determined by total cell mass

Question 42

What conditions can significantly affect plasma [K] and why?

Answer 42

1. acidosis
2. insulin/glucose therapy
3. adrenaline
4. rapid cellular incorportation - TPN, leukaemia

This is because exchange between ICF and ECF significantly affects plasma [K]

Question 43

Fill in the potassium distribution table

Answer 43

Question 44

What is the effect of K+ redistribution?

Answer 44

Question 45

What is the relationship between K+ and H+ ions?

Answer 45

They exchange across the cell membrane

They both bind to negatively charged proteins (e.g. Hb)

Question 46

How do changes in pH affect the K+ and H+ equilibrium?

Answer 46

acidosis:

potassium moves out of cells, leading to hyperkalaemia

alkalosis:

potassium moves into cells, leading to hypokalaemia

Question 47

What is the movement of H+ and K+ like in acidosis?

Answer 47

H+ moves into cells

K+ moves out of cells

this leads to hyperkalaemia

Question 48

What are the 5 causes of hyperkalaemia?

Answer 48

1. artefactual
2. renal
3. acidosis (intracellular exchange)
4. mineralocorticoid dysfunction
5. cell death

Question 49

What are examples of artefactual causes of hyperkalaemia?

Answer 49

1. delay in sample analysis
2. haemolysis
3. drug therapy - excess intake

Question 50

What are examples of renal and ‘cell death’ causes of hyperkalaemia?

Answer 50

renal:

1. acute renal failure
2. chronic renal failure

cell death:

1. cytotoxic therapy

Question 51

What are examples of mineralocorticoid dysfunction causes of hyperkalaemia?

Answer 51

1. adrenocortical failure
2. mineralocorticoid resistance - e.g. spironolactone

Question 52

What are the 5 treatments for hyperkalaemia?

Answer 52

1. correct acidosis if this is the cause
2. stop unnecessary supplements/intake
3. give glucose and insulin to drive K into cells
4. ion exchange resins encourage GIT K binding
5. short and long-term dialysis

Question 53

What are the 4 causes of potassium depletion?

Answer 53

1. low intake
2. increased urine loss
3. gastrointestinal losses
4. hypokalaemia without depletion

Question 54

What may cause increased urine loss leading to potassium depletion?

Answer 54

1. diuretics/osmotic diuresis
2. tubular dysfunction
3. mineralocorticoid excess

Question 55

What may cause gastrointestinal losses leading to potassium depletion?

Answer 55

1. vomiting
2. diarrhoea
3. fistulae

Question 56

What may cause hypokalaemia without depletion?

Answer 56

1. alkalosis
2. insulin/glucose therapy

Question 57

What concentration must there be for it to be classified as potassium depletion?

Answer 57

< 2.5 mmol/L

Question 58

What are the effects of potassium depletion due to acute changes in ICF/ECF ratios?

Answer 58

neuromuscular changes:

1. lethargy
2. muscle weakness
3. heart arrhythmias

Question 59

what are the effects of potassium depletion due to chronic losses from the ICF?

Answer 59

neuromuscular:

• lethargy
• muscle weakness
• heart arrhythmias

kidney

• polyuria
• alkalosis due to increase in renal bicarbonate production

also affects vasculature and the gut

Question 60

How may potassium depletion be detected when taking a history from a patient?

Answer 60

1. diarrhoea, vomiting, drugs (diuretics, digoxin)
2. symptoms of lethargy/weakness
3. cardiac arrthymias

Question 61

What electrolyte tests would be done in potassium depletion and what results obtained?

Answer 61

1. hypokalaemia
2. alkalosis due to raised bicarbonate

Question 62

How can potassium depletion be prevented?

Answer 62

through giving adequate supplementation

Question 63

How can potassium depletion be treated through replacement of deficit?

Answer 63

oral:

46 mmol/day + diet

IV

< 20 mmol/L

Question 64

In what conditions should plasma potassium be monitored regularly?

Answer 64

1. diuretic therapy
2. digoxin use
3. compromised renal function
4. in support of IV resuscitation

Question 65

How will the following factors be changed in hypernatraemia due to aldosterone?

Answer 65