Sodium/Water Balance Issues

Question 1

In the 2013 guidelines NICE recommend the following requirements for maintenance fluids (water) ?

Answer 1

25-30 ml/kg/day of water

Question 2

In the 2013 guidelines NICE recommend the following requirements for maintenance fluids (electrolytes) ?

Answer 2

approximately 1 mmol/kg/day of potassium, sodium and chloride

Question 3

In the 2013 guidelines NICE recommend the following requirements for maintenance fluids (glucose) ?

Answer 3

approximately 50-100 g/day of glucose to limit starvation ketosis

Question 4

for a 80kg patient, for a 24 hour period how much maintenence water and potassium would you prescribe?

Answer 4

2 litres of water

80mmol potassium

Question 5

For the first 24 hours NICE recommend the following (fluid therapy?)

Answer 5

When prescribing for routine maintenance alone, consider using 25-30 ml/kg/day sodium chloride 0.18% in 4% glucose with 27 mmol/l potassium on day 1 (there are other regimens to achieve this).

Question 6

The amount of fluid patients require obviously varies according to their recent and past medical history.

Answer 6

true

Question 7

Who would require more fluid? Who would require less?

Answer 7

a patient who is post-op and is having significant losses from drains will require more fluid whereas a patient with heart failure should be given less fluid to avoid precipitating pulmonary oedema.

Question 8

electrolyte concentrations (in millimoles/litre) of plasma

Answer 8

Na+ 135-145
Cl- 98-105
K+ 3.5-5
HCO3- 22-28
Glucose

Question 9

electrolyte concentrations (in millimoles/litre) of 0.9% saline

Answer 9

Na+ 154

Cl- 154

Question 10

electrolyte concentrations (in millimoles/litre) of 5% glucose

Answer 10

Glucose 50g

Question 11

electrolyte concentrations (in millimoles/litre) of 0.18% saline with 4% glucose

Answer 11

Na+ 30
Cl- 30
Glucose 40g

Question 12

electrolyte concentrations (in millimoles/litre) of Hartmann’s

Answer 12

Na+ 131
Cl- 111
K+ 5
HCO3- 29

Question 13

0.9% saline

if large volumes are used there is an increased risk of

Answer 13

hyperchloraemic metabolic acidosis

Question 14

Hartmann’s should not be used in?

Answer 14

contains potassium and therefore should not be used in patients with hyperkalaemia

Question 15

Which solutions are not reccomended for surgical patients?

Answer 15

5% dextrose and dextrose/saline combinations

Question 16

excessive administration of normal saline and many oliguric postoperative patients can lead to what? Why?

Answer 16

hyperchloraemic acidosis

With a greater understanding of this potential complication, the use of electrolyte balanced solutions (Ringers lactate/ Hartmans) is now favoured over normal saline

Question 17

guidance for post op fluids?

Answer 17

Fluids given should be documented clearly and easily available
Assess the patient’s fluid status when they leave theatre
If a patient is haemodynamically stable and euvolaemic, aim to restart oral fluid intake as soon as possible

Question 18

When should post op patients fluid status be reviewed?

Answer 18

urinary sodium is < 20

Question 19

If a post op patient is oedematous, what should be treated first?

Answer 19

hypovolaemia if present should be treated first. This should then be followed by a negative balance of sodium and water, monitored using urine Na excretion levels.

Question 20

What is used in caution in spetic patients and why?

Answer 20

Solutions such as Dextran 70 should be used in caution in patients with sepsis as there is a risk of developing acute renal injury.

Question 21

What is the water deprivation test?

Answer 21

The water deprivation test is designed to help evaluate patients who have polydipsia.

Method
prevent patient drinking water
ask the patient to empty their bladder
hourly urine and plasma osmolalities

Question 22

What would you see in water deprivation test for Normal?

Answer 22

Starting plasma osm. Normal
Final urine osm. >600
Urine osm. post-DDAVP >600

Question 23

What would you see in water deprivation test for Psychogenic polydipsia?

Answer 23

Starting plasma osm. Low
Final urine osm. >400
Urine osm. post-DDAVP >400

Question 24

What would you see in water deprivation test for Cranial DI?

Answer 24

Starting plasma osm. High
Final urine osm. <300
Urine osm. post-DDAVP >600

Question 25

What would you see in water deprivation test for Nephrogenic DI?

Answer 25

Starting plasma osm. High
Final urine osm. <300
Urine osm. post-DDAVP <300

Question 26

Diabetes insipidus (DI) is a condition characterised by

Answer 26

either a decreased secretion of antidiuretic hormone (ADH) from the pituitary (cranial DI) or an insensitivity to antidiuretic hormone (nephrogenic DI).

Question 27

Causes of cranial DI

Answer 27

idiopathic
post head injury
pituitary surgery
craniopharyngiomas
histiocytosis X
DIDMOAD is the association of cranial Diabetes Insipidus, Diabetes Mellitus, Optic Atrophy and Deafness (also known as Wolfram's syndrome)
haemochromatosis

Question 28

Causes of nephrogenic DI

Answer 28

Genetic
Electrolyte abnormalities
lithium
demeclocycline
tubulo-interstitial disease:

Question 29

Why does lithium cause nephrogenic DI

Answer 29

lithium desensitizes the kidney’s ability to respond to ADH in the collecting ducts

Question 30

Which electrolyte abnormalities cause nephrogenic DI?

Answer 30

hypercalcaemia, hypokalaemia

Question 31

What genetic mutations cause nephrogenic DI?

Answer 31

the more common form affects the vasopression (ADH) receptor, the less common form results from a mutation in the gene that encodes the aquaporin 2 channel

Question 32

Features of DI

Answer 32

polyuria

polydipsia

Question 33

Investigation DI

Answer 33

high plasma osmolality, low urine osmolality
a urine osmolality of >700 mOsm/kg excludes diabetes insipidus
water deprivation test

Question 34

Mx nephrogenic diabetes insipidus

Answer 34

thiazides, low salt/protein diet

Question 35

mx - central diabetes insipidus

Answer 35

can be treated with desmopressin

Question 36

What is SIADH?

Answer 36

The syndrome of inappropriate ADH secretion (SIADH) is characterised by hyponatraemia secondary to the dilutional effects of excessive water retention.

Question 37

Causes of SIADH - Malignancy

Answer 37

small cell lung cancer

also: pancreas, prostate

Question 38

Causes of SIADH - Neurological

Answer 38

stroke
subarachnoid haemorrhage
subdural haemorrhage
meningitis/encephalitis/abscess

Question 39

Causes of SIADH - Infections

Answer 39

tuberculosis

pneumonia

Question 40

Causes of SIADH - Drugs

Answer 40

sulfonylureas, *reported with glimepiride and glipizide.
SSRIs, tricyclics
carbamazepine
vincristine
cyclophosphamide

Question 41

Causes of SIADH - other

Answer 41

positive end-expiratory pressure (PEEP)

porphyrias

Question 42

Management SIADH?

Answer 42

correction must be done slowly to avoid precipitating central pontine myelinolysis
fluid restriction
demeclocycline: reduces the responsiveness of the collecting tubule cells to ADH
ADH (vasopressin) receptor antagonists have been developed

Question 43

Hyponatraemia may be caused by

Answer 43

water excess or sodium depletion

Question 44

Causes of pseudohyponatraemia include

Answer 44

hyperlipidaemia (increase in serum volume) or a taking blood from a drip arm

Question 45

What aid making a diagnosis in hyponatraemia

Answer 45

Urinary sodium and osmolarity levels

Question 46

Urinary sodium > 20 mmol/l causes in hypovolemic patient?

Answer 46

Sodium depletion, renal loss (patient often hypovolaemic)
diuretics: thiazides, loop diuretics
Addison’s disease
diuretic stage of renal failure

Question 47

Urinary sodium > 20 mmol/l causes in euvolemic patient?

Answer 47

SIADH (urine osmolality > 500 mmol/kg)

hypothyroidism

Question 48

Urinary sodium < 20 mmol/l causes

Answer 48

Sodium depletion, extra-renal loss
diarrhoea, vomiting, sweating
burns, adenoma of rectum

Water excess (patient often hypervolaemic and oedematous)
secondary hyperaldosteronism: heart failure, liver cirrhosis
nephrotic syndrome
IV dextrose
psychogenic polydipsia

Question 49

Management of hyponatremia complicated and primarily based around the following parameters

Answer 49

Duration of hyponatremia: is it acute or chronic?
Severity of hyponatremia: what is the sodium level?
Symptoms: is the patient symptomatic?

Question 50

Acute hyponatremia:

Develops over a period of

Answer 50

less than 48 hours

Question 51

Acute hyponatremia usually develops due to

Answer 51

excessive fluid intake, either parenteral or oral. Common examples include post-operative parenteral fluids and athletes.

Question 52

Acute hyponatremia usually has mild sx

Answer 52

false severe

Question 53

What is chronic hyponatraemia?

Answer 53

If the duration is unknown or it is present for more than 48 hours.
Symptoms are usually less severe than acute.

Question 54

Describe mild hyponatraemia?

Answer 54

Serum Na+: 130-134 mmol/l

Sx: Non-specific symptoms such headache, lethargy, nausea, vomiting, dizziness, confusion, and muscle cramps

Question 55

Describe moderate hyponatraemia?

Answer 55

Serum Na+: 120-129 mmol/l

Sx: Same as mild

Question 56

Describe severe hyponatraemia?

Answer 56

Serum Na+: Less than 120 mmol/l

Sx: Seizures, coma, and respiratory arrest

Question 57

Mx mild hyponatraemia?

Answer 57

Fluid restriction (less than 800 mL/day)
Loop diuretics

Question 58

Mx moderate hyponatraemia?

Answer 58

Hypertonic saline in first 3-4 hours to increase Na+ >120 mmol/l
Rest is the same as mild

Question 59

Mx severe hyponatraemia?

Answer 59

Bolus of hypertonic saline until symptom resolution

With or without conivaptan

Question 60

Fluids intake should be less than urine output in the following patients?

Answer 60

Oedematous states like heart failure and cirrhosis
SIADH
Renal failure
Psychogenic polydipsia

Question 61

How do Vasopressin/ADH receptor antagonists (conivaptan) work

Answer 61

These act on V1 and V2 receptors. The V1 receptors cause vasoconstriction while the V2 receptors results in selective water diuresis, sparing the electrolytes.

Question 62

Vasopressin/ADH receptor antagonists (conivaptan) should be avoided in

Answer 62

patients who have hypovolemic hyponatremia.

Question 63

Vasopression/ADH receptor antagonists make you thirsty

Answer 63

true

Vasopression/ADH receptor antagonists can stimulate the thirst receptors leading to the desire to drink free water.

Question 64

Vasopression/ADH receptor antagonists should be avoided in

Answer 64

hepatotoxic in patients with underlying liver disease.

Question 65

Complication of Vasopression/ADH receptor antagonists

Answer 65

Osmotic demyelination syndrome (central pontine myelinolysis)
can occur due to over-correction of severe hyponatremia
to avoid this, Na+ levels are only raised by 4 to 6 mmol/l in a 24-hour period
symptoms usually occur after 2 days and are usually irreversible: dysarthria, dysphagia, paraparesis or quadriparesis, seizures, confusion, and coma
patients are awake but are unable to move or verbally communicate, also called ‘Locked-in syndrome’

Question 66

Causes of HYPERnatraemia

Answer 66

dehydration
osmotic diuresis e.g. hyperosmolar non-ketotic diabetic coma
diabetes insipidus
excess IV saline

Question 67

Hypernatraemia should be corrected with great caution.

Answer 67

true

Question 68

Describe effect of lowering sodium on the brain

Answer 68

Although brain tissue can lose sodium and potassium rapidly, lowering of other osmolytes (and importantly water) occurs at a slower rate, predisposing to cerebral oedema, resulting in seizures, coma and death

Question 69

NICE or Royal College of Physicians at present, it is generally accepted that a rate of no greater than ? correction is appropriate in hypernatraemia

Answer 69

0.5 mmol/hour

Question 70

Hyperosmolar hyperglycaemic state (HHS) is?

Answer 70

is a medical emergency which is extremely difficult to manage and has a significant associated mortality. Hyperglycaemia results in osmotic diuresis, severe dehydration, and electrolyte deficiencies

Question 71

HHS typically presents in

Answer 71

the elderly with type 2 diabetes mellitus (T2DM), however the incidence in younger adults is increasing. It can be the initial presentation of T2DM.

Question 72

It is extremely important to differentiate HHS from

Answer 72

HHS from diabetic ketoacidosis (DKA) as the management is different

Question 73

Firstline for HHS is insulin?

Answer 73

false

treatment of HHS with insulin (e.g. as part of a DKA protocol) can result in adverse outcomes

Question 74

Which unit are HHS pts usually managed in?

Answer 74

The first 24 hours of treatment is very labour intensive so these patients are best managed in either a medical high dependency unit.

Question 75

DKA or HHS higher mortality?

Answer 75

HHS has a higher mortality than DKA

Question 76

HHS complications

Answer 76

vascular complications such as myocardial infarction, stroke or peripheral arterial thrombosis. Seizures, cerebral oedema and central pontine myelinolysis (CPM) are uncommon but documented complications of HHS.

Question 77

Timeframe HHS or DKA?

Answer 77

DKA presents within hours of onset

HHS comes on over many days - therefore dehydration and metabolic disturbances are more extreme.

Question 78

Pathophysiology of HHS?

Answer 78

Hyperglycaemia results in osmotic diuresis with associated loss of sodium and potassium
Severe volume depletion results in a significant raised serum osmolarity (typically > than 320 mosmol/kg), resulting in hyperviscosity of blood.
Despite these severe electrolyte losses and total body volume depletion, the typical patient with HHS, may not look as dehydrated as they are, because hypertonicity leads to preservation of intravascular volume.

Question 79

Clincial features of HHS?

Answer 79

General: fatigue, lethargy, nausea and vomiting
Neurological: altered level of consciousness, headaches, papilloedema, weakness
Haematological: hyperviscosity (may result in myocardial infarctions, stroke and peripheral arterial thrombosis)
Cardiovascular: dehydration, hypotension, tachycardia

Question 80

Diagnosis of HHS?

Answer 80

1. Hypovolaemia
2. Marked Hyperglycaemia (>30 mmol/L) without significant ketonaemia or acidosis
3. Significantly raised serum osmolarity (> 320 mosmol/kg)
   Note: A precise definition of HHS does not exist, however the above 3 criteria are helpful in distinguishing between HHS and DKA. It is also important to remember that a mixed HHS / DKA picture can occur.

Question 81

The goals of management of HHS can be summarised as follows?

Answer 81

1. Normalise the osmolality (gradually)
2. Replace fluid and electrolyte losses
3. Normalise blood glucose (gradually)

Question 82

Fluid replacement in HHS?

Answer 82

Caution is needed

Intravenous (IV) 0.9% sodium chloride solution is the first line fluid for restoring total body fluid.

If the serum osmolarity is not declining despite positive balance with 0.9% sodium chloride, then the fluid should be switched to 0.45% sodium chloride solution which is more hypotonic relative to the HHS patients serum osmolarity

Question 83

Fluid losses in HHS are estimated to be

Answer 83

between 100 - 220 ml/kg (e.g. 10-22 litres in an individual weighing 100 kg).

Question 84

In HHS The rate of rehydration will be determined by assessing the combination of initial severity and any pre-existing co-morbidities (e.g. heart failure and chronic kidney disease). Caution is needed, particularly in ?

Answer 84

elderly, where too rapid rehydration may precipitate heart failure but insufficient may fail to reverse an acute kidney injury.

Question 85

isotonic 0.9% sodium chloride solution is already relatively hypotonic/hypertonic compared to the serum in someone with HHS?

Answer 85

hypotonic compared to the serum in someone with HHS. Therefore in most cases it is very effective at restoring normal serum osmolarity.

Question 86

In HHS IV fluid replacement should aim to achieve

Answer 86

positive balance of 3-6 litres by 12 hours and the remaining replacement of estimated fluid losses within the next 12 hours.

Question 87

in HHS Existing guidelines encourage vigorous initial fluid replacement and this alone (without insulin) will result in

Answer 87

a gradual decline in plasma glucose and serum osmolarity. A rapid decline is potentially harmful (see below) therefore insulin should NOT be used in the first instance unless there is significant ketonaemia or acidosis

Question 88

In HHS The aim of treatment should be

Answer 88

replace approximately 50% of estimated fluid loss within the first 12 hours and the remainder in the following 12 hours. However this is just a guide, and clinical judgement should be applied, particularly in patient with co-morbidities such as heart failure and chronic kidney disease (which may limit the speed of correction).

Question 89

Rapid changes of serum osmolarity are dangerous and can result in

Answer 89

cardiovascular collapse and central pontine myelinolysis (CPM).

Question 90

Guidelines suggest that what should me monitored hourly in HHS Monitoring response to treatment

Answer 90

serum osmolarity, sodium and glucose levels

Question 91

In HHS Fluid replacement alone (without insulin) will gradually lower blood glucose which will reduce osmolality

Answer 91

true

Question 92

Describe the physiological effect of reduction of serum osmolarity in HHS

Answer 92

will cause a shift of water into the intracellular space.
This inevitably results in a rise in serum sodium (a fall in blood glucose of 5.5 mmol/L will result in a 2.4 mmol/L rise in sodium). This is not necessarily an indication to give hypotonic solutions. If the inevitable rise in serum Na+ is much greater than 2.4 mmol/L for each 5.5 mmol/L fall in blood glucose this would suggest insufficient fluid replacement. Rising sodium is only a concern if the osmolality is NOT declining concurrently.

Question 93

In HHS A safe rate of fall of plasma glucose of? safe target?

Answer 93

4 and 6 mmol/hr is recommended

A target blood glucose of between 10 and 15 mmol/L is a reasonable goal.

Question 94

In HHS: The rate of fall of plasma sodium should not exceed

Answer 94

10 mmol/L in 24 hours.

Question 95

Complete normalisation of electrolytes and osmolality may take up to

Answer 95

72 hrs

Question 96

In HHS Fluid replacement alone with 0.9% sodium chloride solution will result in a gradual decline of blood glucose and osmolarity

Answer 96

true
most patients with HHS are insulin sensitive (e.g. it usually occurs in T2DM), administration of insulin can result in a rapid decline of serum glucose and thus osmolarity.

A steep decline in serum osmolarity may also precipitate CPM.

Question 97

In HHS insulin treatment prior to adequate fluid replacement may result in?

Answer 97

cardiovascular collapse as the water moves out of the intravascular space, with a resulting decline in intravascular volume.

Question 98

In HHS Measurement of ? is essential for determining if insulin is required. How does this affect mx

Answer 98

ketones

If significant ketonaemia is present (3β-hydroxy butyrate is more than 1 mmol/L) this indicates relative hypoinsulinaemia and insulin should be started at time zero (e.g. mixed DKA / HHS picture). The recommended insulin dose is a fixed rate intravenous insulin infusion given at 0.05 units per kg per hour.
If significant ketonaemia is not present (3β-hydroxy butyrate is less than 1 mmol/L) then do NOT start insulin.

Question 99

Patients with HHS are potassium what? How should this be mx

Answer 99

Deplete but less acidotic than those with DKA so potassium shifts are less pronounced
Hyperkalaemia can be present with acute kidney injury
Patients on diuretics may be profoundly hypokalaemic
Potassium should be replaced or omitted as required