Assessment of kidney function using blood tests

Question 1

What kidney tests can be done in the lab?

Answer 1

U&E request gives serum concentrations of:

• Creatinine – Reference Interval higher in males than females
• Urea
• Sodium
• Potassium
• e-GFR calculated using serum creatinine concentration

Urine

• Albumin:Creatinine ratio (ACR)
• Protein:Creatinine ratio (PCR)
• Plus a range of supporting assays for Acute Kidney Injury (AKI) or Chronic Kidney Disease (CKD)

Question 2

What is the rate of kidney blood flow?

Answer 2

1500mL/min

Question 3

What is the equation for GFR?

Answer 3

GFR = (U x V)/S = ml/min

U = Urine concentration mmol/l

V = Urine flow rate ml/min

S = Serum concentration mmol/l

Question 4

What does measurement of glomerular filtration require?

Answer 4

•A substance that is filtered and then neither absorbed or secreted in the renal tubules

24h urine collection and a blood sample

Question 5

Why use creatinine for GFR?

Answer 5

• Derived from creatine in muscle
• Serum concentrations relatively stable
• 24 h urine output is also stable day to day
• No absorption and very little secretion in renal tubules
• Simple to measure

Question 6

What causes variations in creatinine?

Answer 6

But variation in serum concentrations and 24h urine output by:

• Age
• Sex – male > female
• Lean body mass – ethnic origin
• Effect of Diet

Question 7

How are creatinine variations overcome?

Answer 7

GFR related to body surface area – so standardise to a given body surface area

This allows:

• Comparison against a general standard
• Staging of renal disease
• Monitoring of change in renal filtration – individual or cohort
• Chosen standard = 1.73m2

Question 8

What is the equation for eGFR?

Answer 8

MDRD equation as calculated in the laboratory computer:

eGFR = 175 x (serum creatinine)-1.154 x (age)-0.203 x (0.742 if female) x (1.21 if Afro-Caribbean)

This allows for variation by age, sex and ethnic origin

Age – decreasing GFR with age but largely offset by reducing muscle mass with age

MDRD = Modification of Diet in Renal Disease

Question 9

Answer 9

• Very high plasma glucose – causes an osmotic diuresis leading to loss of water and sodium
• Vomiting – adding to his fluid loss
• Loss of salt and water – causes volume depletion leading to impaired renal function and also dehydration
• Failure of glucose metabolism leads to keto-acidosis – 3-OH butyrate
• Acidosis – plasma 3-OH butyrate and bicarbonate – lead to increased serum concentrations of potassium and phosphate
• Renal impairment – leads to potassium and phosphate accumulation and enhances the acidosis

Question 10

What tests indicate dehydration?

Answer 10

Dehydration is very likely if the serum urea:creatinine ratio is greater than 100

NB – both measurements need to be in mmol/l

Some authors have used 80 as a cut-off

The mechanism is the passive re-absorption of urea in the nephron especially at low flow rates

Serum protein concentrations may also be elevated

Question 11

What tests indicate AKI?

Answer 11

• a rise in serum creatinine of 26 µmol/L or greater within 48h,
• a 50% or greater rise in serum creatinine known or presumed to have occurred within the past 7 days,
• a fall in urine output to less than 0.5 mL/kg/hr for more than 6 hours for adults and more than 8 hours in children or young people,
• a 25% or greater fall in eGFR in children and young people < 18y

Question 12

What is the AKI alert system?

Answer 12

These Alerts are calculated by the lab computer:

• AKI stage 1 is a rise of >1.5x baseline level, or of >26μmol/L within 48h
• AKI stage 2 is a rise of>2x baseline
• AKI stage 3 is a rise of>3x baseline or a rise of >1.5 baseline to >354μmol/L

Question 13

What are the causes of AKI?

Answer 13

Question 14

• Very elevated serum creatinine
• AKI Alert level 3
• Very raised serum CRP concentration
• Marked proteinuria – not just albumin – indicates marked glomerular damage
• Anaemia with a raised WBC
• Negative Anti-streptolysin O titre – not post-streptococcal
• Raised Anti-GBM antibody – GBM = glomerular basement membrane

Answer 14

This is Goodpasture’s syndrome – an important diagnosis as it requires treatment by plasma exchange to remove the antibody

Question 15

Answer 15

This man was a body-builder

• High muscle mass
• High protein intake
• Strenuous muscle activity
• Pressing heavy weights

•

Note – mild hypokalaemia is not uncommon in body-builders

Question 16

Write the equation for the origins of creatinine

Answer 16

Question 17

Answer 17

Note – AKI although both serum creatinine results are within the reference interval

Also he is dehydrated and has evidence of a septic condition – raised serum CRP

Question 18

What are the causes of CKD?

Answer 18

• Hypertension
• Diabetes – T2DM>T1DM
• Hyperlipidaemia
• Recurrent renal infections
• Chronic glomerulonephritis – IgA nephritis
• Systemic disease – systemic lupus, multiple myeloma
• Genetic - polycystic kidney, Alport syndrome
• Chronic obstruction – prostatic hypertrophy, renal calculi, reflux
• Medication – NSAIDs, lithium

Question 19

wHAT IS ACR – Albumin:Creatinine Ratio?

Answer 19

Proteinuria is a common finding in renal disease

Normally large proteins are retained by the glomerulus and only small proteins such as amylase are filtered.

A small amount of albumin is normally filtered but metabolised in the proximal tubule. However at larger loads due to glomerular damage more albumin escapes into the urine.

Measurement as a ratio with creatinine allows use of a random urine sample rather than a timed collectio

Question 20

What are the metabolic features of stage 2 and 3 CKD?

Answer 20

Question 21

What are the metabolic features of stage 4 and 5 CKD?

Answer 21

Question 22

• Very raised serum urea and creatinine concentrations
• Hyperkalaemia and acidosis
• Low e-GFR
• Significant albuminuria
• Hypocalcaemia with hyperphosphataemia and raised serum PTH concentration and alkaline phosphatase activity
• Hypertriglyceridaemia
• Anaemia with low transferrin saturation and borderline low serum ferritin

Answer 22

Advanced CKD

Question 23

What are the interventions in CKD?

Answer 23

Question 24

What are the interventions in CKD?

Answer 24

Question 25

What is the role of the lab in diagnosing CKD?

Answer 25

• Serum and urine light chains – myeloma
• Glycated Hb – diabetic control
• Antibody tests – ANA, ANCA, anti-GBM
• Biopsy - histology

Question 26

What is the role of the lab in diagnosing AKI?

Answer 26

• Plasma lactate – prognostic indicator
• Infection – serum procalcitonin, CRP, WBC, blood culture
• Autoimmune causes

Question 27

How is renal dialysis monitored?

Answer 27

Pre- and Post-Dialysis samples to:

• Show the effectiveness of dialysis
• Indicate the required frequency of dialysis
• Determine the need for other interventions:
• Diet
• Supplements
• Phosphate binders
• Calcimimetic drugs
• Lipid lowering agents
• Iron supplements/erthropoietin

Question 28

How are renal transplant patients monitored?

Answer 28

• Serum creatinine – transplant function
• e-GFR
• ACR or PCR – potential damage to the transplanted kidney
• Measuring anti-rejection drugs
• Ciclosporin
• Tacrolimus, Sirolimus
• Checking for any tubular dysfunction

Monitoring as for CKD 3

Question 29

How is an indivduals GFR calculated when needed?

Answer 29

Remember MDRD and CKD-Epi are linked to a standard body surface area.

The real GFR of an individual is required

• To determine the dose of renally excreted drugs that are potentially toxic
• Monitoring dialysis and transplant patients

Here the Cockroft and Gault calculation is used

Question 30

What are the 3 types of renal tubular disorders?

Answer 30

• Renal tubular acidosis
• Fanconi Syndrome
• Diabetes Insipidus

Question 31

What would you do next?

What is the likely diagnosis and treatment?

Answer 31

Early morning urine pH. This will be greater than 5.5 in Type 1 (distal) Renal Tubular Acidosis with hypokalaemia

Treatment to reduce the risk of nephrocalcinosis/renal stone formation:

potassium citrate, sodium bicarbonate, thiazide diuretics

Question 32

24 h urine collection showed elevated concentrations of amino-acids, calcium and phosphate

Fractional excretion of phosphate:

(Urine phosphate x Serum creatinine)/(Serum phosphate x Urine creatinine)

(24.3 x 0.065)/(0.72 x 7.2) = 30.5%

>20% indicates excessive loss

Answer 32

This is Fanconi Syndrome – the condition may be either congenital or acquired

Question 33

Answer 33

Diabetes insipidus

Question 34

What condition causes each result?

Answer 34