Clinical Biochemistry Flashcards

Question 1

Q

define accuracy

Answer

A

closeness to the true value

Question 2

Q

define precision

Answer

A

reproducibility of agreement with each other for multiple trials

Question 3

Q

define true value

Answer

A

standard or reference of a known or theoretical value

Question 4

Q

what results show in a blood sample that has been haemolysed?

Answer

A

collected too vigorously
red cells have been broken down
artificially high level of potassium

Question 5

Q

describe how a false negative occurs

Answer

A

there is a proportion of the diseased population, where for the result of the test, fall into the reference range

Question 6

Q

define sensitivity

Answer

A

true positive / true positive + false negative

Question 7

Q

define specificity

Answer

A

true negative / true negative + false positive

Question 8

Q

what factors affect reference ranges and results?

Answer

A

age
gender
diet
pregnancy
sample handling
sample type
time of day/month/year
weight
fasting
posture
sample collection procedure

Question 9

Q

where is calcium distributed in the body?

Answer

A

99% in bone
1% in plasma
of that, 50-60% is bound to plasma proteins
remainder is ionised (active, required for nerve conduction and muscle contraction)

Question 10

Q

what affects plasma calcium concentration?

Answer

A

alteration in protein levels
vitamin D
parathyroid hormone
renal function
prolonged tourniquet application (increases protein levels)
reduced/increased by 0.02mmol for each g albumin falls below/above 40

Question 11

Q

what is the role of parathyroid hormone?

Answer

A

released when Ca levels fall
increases renal reabsorption of Ca and excretion of PO4
stimulates osteoclasts, increases bone reabsorption and increases Ca released from bone
increases vitamin D synthesis

Question 12

Q

describe vitamin D metabolism

Answer

A

UV light converts cholesterol to vitamin D3
hydroxylated at 25 site in the liver
converted from vitamin D to 1,25 vitamin D (active form) in the kidneys

Question 13

Q

what are the causes of hypercalcaemia?

Answer

A

PTH excess
vitamin D excess (ingestion, sarcoid)
increased Ca intake (milk-alkali syndrome in PUD)
thiazide diuretics
bony metastases in malignancy
PTH-secreting tumours
haematological malignancy
thyrotoxicosis
addison's disease
familial hypocalcuric hypercalcaemia

Question 14

Q

what are the signs and symptoms of hypercalcaemia?

Answer

A

malaise
depression
polydipsia
polyuria
abdominal pain (renal stones)
features of underlying disease (malignancy, sarcoid)
low PO4 and high Ca (excess PTH)
high PO4 and Ca (excess vitamin D)
high ALP (bone disease, haematological malignancy)
renal function
CXR (sarcoid)
plasma protein electrophoresis (myeloma)
urinary calcium

Question 15

Q

what is the management of hypercalcaemia?

Answer

A

rehydration (orally, normal saline 4-6L over 24hrs)
monitor urine output
loop diuretic (furosemide)
monitor K levels if lots of excretion
bisphosphonates (bind Ca to prevent if being released from bone)
hydrocortisone (in myeloma or sarcoid)

Question 16

Q

what are the causes of hypocalcaemia?

Answer

A

not corrected for albumin
renal failure (increased PO4 and vitamin D may not be converted to the active form)
hypoparathyroidism
vitamin D deficiency
hypomagnesaemia
bisphosphonates

Question 17

Q

what are the symptoms and signs of hypocalcaemia?

Answer

A

neuromuscular irritability
tetany
positive Chvostek’s sign (tap on facial nerve and spasm of facial muscle)
positive Trousseau’s sign (inflation of BP cuff causes wrist flexion and finger extension)
QT prolongation

Question 18

Q

what is the management of hypocalcaemia?

Answer

A

oral calcium
milk
vitamin D
IV calcium gluconate (severe cases)

Question 19

Q

describe the storage and uses of PO4

Answer

A

85% stored in bone within cells
required for ATP
important constituent of cell membranes and nucleic acid

Question 20

Q

what are the causes of hypophosphataemia?

Answer

A

poor diet, reduced intake
reduced absorption (malnutrition, vitamin D deficiency)
increased shift into cells (respiratory alkalosis, insulin, glucose, amino acids)
increased urinary excretion (excessive PTH, renal tubular defects)

Question 21

Q

what are the clinical features of hypophosphataemia?

Answer

A

refeeding syndrome, post IV, enteral or normal feeding
alcohol abuse
asymptomatic
rhabdomyolysis
cardiomyopathy
renal failure
impaired RBC function
impaired white cell function (susceptible to infection)
reduced phagocytosis

Question 22

Q

what is the treatment of hypophosphataemia?

Answer

A

milk
oral supplements
IV dipotassium hydrogen phosphate over 12hr and once in 24hr (too much causes calcium deposits in tissues)

Question 23

Q

what are the causes of hyperphosphataemia?

Answer

A

renal failure
cellular phosphate leak
cell breakdown (rhabdomyolysis or tumour lysis)

Question 24

Q

describe the storage of magnesium

Answer

A

67% in bone

31% intracellular

Question 25

Q

what are the causes of hypomagnesaemia?

Answer

A

poor intake
malabsorption
increased losses (renal or GI)
diarrhoea or fistula (losses of gut fluid)
refeeding syndrome
alcohol abuse/withdrawal
increase in amount of fluid lost in the loop of henle

Question 26

Q

what are the symptoms and signs of hypomagnesaemia?

Answer

A

similar to hypocalcaemia
tetany
Chovstek’s sign
neuromuscular problems

Question 27

Q

what is the treatment of hypomagnesaemia?

Answer

A

oral or IV magnesium

30mmol in first 24hrs then 20mmol in each 24hr period after that (IV)

Question 28

Q

where is ALP found?

Answer

A

liver
bone
intestines
placenta

Question 29

Q

what are the causes of high ALP?

Answer

A

bone growth
pregnancy (placenta)
bone fracture healing
bony metastases
Paget’s disease (excessive bone growth and abnormal bone remodelling)
hyperparathyroidism (osteoclasts stimulated to release Ca)
obstructive jaundice

Question 30

Q

describe osteoporosis

Answer

A

Ca, PO4 and ALP normal
asymptomatic
usually found in a DEXA scan if there are no fractures

Question 31

Q

describe osteomalacia

Answer

A

defective bone mineralisation (similar to rickets)
low Ca and PO4 and high ALP
usually due to low vitamin D

Question 32

Q

describe Paget’s disease

Answer

A

abnormal bone remodelling due to increased ALP
normal Ca and PO4
usually elderly

Question 33

Q

describe bony metastases

Answer

A

high Ca and ALP, normal or high PO4

Question 34

Q

describe myeloma

Answer

A

Ca alone high

ALP usually normal

Question 35

Q

describe primary hyperparathyroidism

Answer

A

adenoma on parathyroid gland causing excess PTH
high Ca (hypercalcaemia), ALP and low/normal PO4

Question 36

Q

define tumour markers

Answer

A

molecules which indicate the presence of a cancer or provide information of the likely future behaviour of a cancer

Question 37

Q

what are the use of tumour markers?

Answer

A

detect cancer in asymptomatic patients
differentiate between malignant and benign tumours
post-surgery to detect the amount that was removed
detect recurrence
predict how a tumour responds/has responded to treatment

Question 38

Q

what are the categories for the ideal tumour marker?

Answer

A

high PPV and NPV
highly sensitive and specific
inexpensive
simple
circulating level correlates with amount of tumour
acceptable to subjects

Question 39

Q

describe some non-specific markers involved in detecting malignancy

Answer

A

hyponatraemia - indicates SIADH secondary to NSCLC
LDH - haematological malignancy
ALP - bony metastases, bone malignancy
total protein - multiple myeloma, Waldenstrom’s macroglobulinaemia
ferritin - renal cell carcinoma, leukaemia, hepatocellular carcinoma

Question 40

Q

define oncofetal antigens

Answer

A

present in cells in early development

reactivated in more undifferentiated cancer cells

Question 41

Q

describe 2 types of oncofetal antigens and what they look for

Answer

A

AFP - hepatocellular carcinoma, ovarian and testicular tumours
carcinoembryonic antigen - colorectal carcinoma

Question 42

Q

describe some hormones that are used as tumour markers

Answer

A

HCG - choriocarcinoma, testicular tumours, trophoblastic tumours
metanephrines - pheochromocytoma
calcitonin - medullary carcinoma of thyroid
IGF1 - pituitary malignancy

Question 43

Q

describe some glycoproteins that are used as tumour markers

Answer

A

CA19-9 - pancreatic tumours
CA125 - ovarian, breast, pancreatic and lung tumours
can be increased in benign conditions

Question 44

Q

describe some enzymes that are used as tumour markers

Answer

A

PSA - prostate cancer, other prostatic conditions

neurone-specific enolase - SCLC, neuroendocrine tumours

Question 45

Q

describe some cell components/antigens used as tumour markers

Answer

A

SCC antigen - gynae, head and neck and lung tumours
immunoglobulins - multiple myeloma
CEA - breast, pancreatic, ovarian, lung, stomach, colon and prostate cancer

Question 46

Q

what markers are produced by a multiple myeloma?

Answer

A

heavy and light immunoglobulin chains (detected as a paraprotein band)
Bence Jones protein (urine)
free light chains
beta-2 microglobulin (measures mass of tumour present)

Question 47

Q

what markers are produced by ovarian cancer?

Answer

A

CA125
inhibin
HCG
AFP
carcinoembryonic antigen

Question 48

Q

what markers are produced by carcinoid tumours?

Answer

A

serotonin
S-hydroxytryptamine
catecholamines
chromogranin A

Question 49

Q

what are the causes of PSA increase?

Answer

A

prostate tumour
BPH
needle biopsy
prostatitis
urinary retention

rises occur rapidly and can take several days to return to normal

Question 50

Q

with what symptoms should CA125 be measured for ovarian cancer?

Answer

A

abdominal distension
loss of appetite
abdominal pain
new onset irritable bowel syndrome
>50

measured along with a pelvic US

Question 51

Q

what are the causes of CA125 increase?

Answer

A

ovarian, pancreatic, lung, breast, uterus, cervix and GI tract tumours
pancreatitis
peritonitis
hyperthyroidism
PID
ascites, HF, pleural effusion (fluid accumulation)

Question 52

Q

what patients should have an AFP test?

Answer

A

those known to have hep B and C-related cirrhosis

Question 53

Q

what are HCG and AFP used to detect?

Answer

A

non-seminoma type testicular germ cell tumours

follow-up to detect recurrence

Question 54

Q

what are HCG and LDH used to detect?

Answer

A

pure seminoma tumours

Question 55

Q

what are the causes of an AFP increase?

Answer

A

hepatocellular carcinoma
ovarian tumour
testicular tumour
cirrhosis
hepatitis
ataxia telangiectasis
pregnancy

Question 56

Q

what are the causes of a HCG increase?

Answer

A

pregnancy
marijuana use
choriocarcinoma
trophoblastic tumour
testicular tumour

Question 57

Q

what affects the reference range of CEA?

Answer

A

smoking
other tumours
IBD
pancreatitis
liver disease

Question 58

Q

what are the causes of CA19-9 increase?

Answer

A

pancreatic, colorectal, lung, liver and ovarian cancers
pneumonia
hepatobiliary disease
renal failure

Question 59

Q

name some examples of lipids

Answer

A

fats
steroids
fatty acids
fat soluble vitamins (K, E and A)
phospholipids

Question 60

Q

what are the functions of lipids?

Answer

A

maintain the structure of cell membranes
store energy
hormone synthesis
signalling

Question 61

Q

what are the functions of cholesterol?

Answer

A

hormone production (cortisol and sex hormone synthesis)
main component of cell membranes
vitamin D synthesis
bile acid synthesis (role in digestion)

Question 62

Q

what is the function of triglycerides?

Answer

A

efficiency way of storing and transferring energy

Question 63

Q

describe lipoproteins

Answer

A

required for lipid transportation in the circulation

contain apolipoproteins - made in the liver, bind to receptors, allow transportation

Question 64

Q

what is the function of chylomicrons?

Answer

A

transport triglycerides (mainly dietary)

Answer 65

A

transport triglycerides from the liver to other tissues

Answer 66

A

allow the transfer of different cholesterol fractions between different lipoprotein particles
co-factors for some of the enzymes used in cholesterol metabolism
bind to receptors in the cells
allow lipids to be taken up into cells

Answer 67

A

dietary
hepatic
tissue to liver (reverse cholesterol)

Answer 68

A

mainly via chylomicrons
can go directly to cells if required (muscle, fat)
can go to liver to be processed and stored

Answer 69

A

the liver exports some of these stored triglycerides and moves them to the various tissues as required
the fraction that remain are transported back to the liver for further processing

Answer 70

A

via HDL
cholesterol can go back to the liver and be removed from the circulation
doesn’t contribute to atheroma

Answer 71

A

the extent of reverse cholesterol transport

low - increased risk of atherosclerosis

Answer 72

A

an idea of the total number of atherogenic particles

high - increased risk of cardiovascular disease

Answer 73

A

genetic links

FHx of premature cardiovascular disease

Answer 74

A

very low/absent alpha lipoprotein or apolipoprotein A
no mechanism for clearing cholesterol from the circulation
cholesterol deposited in tissues
enlarged orange tonsils (cholesterol deposits)

Answer 75

A

friedewald-levy-fredrickson formula
= TC - HDL C - (TG/2.2) mol/L
not valid for very high triglycerides

Answer 76

A

LDL, IDL, VLDL, Lp a

= total cholesterol - HDL

Answer 77

A

hypothyroidism
nephrotic syndrome
ciclosporin
cholestasis
anorexia nervosa

Answer 78

A

malabsorption
liver disease
malnutrition

Answer 79

A

exercise
moderate amounts of alcohol
oestrogen

Answer 80

A

smoking
metabolic syndrome
T2DM
malnutrition
anabolic steroids
systemically unwell

Answer 81

A

obesity
diabetes
hepatitis
alcohol
renal disease
protease inhibitors
retinoid acid-based treatments

Answer 82

A

autosomal dominant
associated with high coronary mortality
50% of men will have an MI <50 and 30% of women will have an MI <60
high lipid levels in children
tendon xanthoma
premature corneal arcus
xanthelasma

problem with Apo B on the LDL particle or the LDL receptor on the cell

Answer 83

A

abnormality in the apo E receptors
apo E2 binds poorly to receptors and results in cholesterol not being removed as effectively from the circulation
1/170 are homozygous E2/E2

Answer 84

A

cholesterol and triglycerides are numerically similar
increased cardiovascular risk
responds well to fibrates

Answer 85

A

reduced eGFR
known cardiovascular risk
T1DM
>40
FH
mental health disorders
inflammatory conditions (RA)

Answer 86

A

fat should be <30% of calorie intake, saturated fat <7%
5x fruit and vegetable portions
high amount of whole green foods
2x fish/week, 1x oily
4-5x non-salted nuts or seeds/week
150mins moderate or 75mins vigorous intensity exercise

Answer 87

A

primary prevention - atorvastatin 20mg
secondary prevention - atorvastatin 80mg
aim for >40% reduction in non-HDL cholesterol

fat soluble - simvastatin, atorvastatin
water soluble - pravastatin, fluvastatin, rosuvastatin

Answer 88

A

obesity
DM
alcohol excess
metabolic syndrome
renal failure
protease inhibitors
isotretoin
second generation antipsychotics (phenothiazines)
primary dyslipidaemia

Answer 89

A

cardiovascular risk
raised cholesterol
pancreatitis

Answer 90

A

low fat diet (10% fat)
diabetes control
avoid alcohol
fibrates
statins
fish oils

Answer 91

A

statins 1st line
if triglycerides remain >5.6mmol/L then use fibrates
fish oils (omacor 4g/day)

Answer 92

A

produced by myocardial cells
released into the circulation in high concentration whenever myocardial cells are under stress or excess stretch
pro-BNP -> pre-pro-BNP

Answer 93

A

promotes vasodilation
increased urinary Na retention, reducing the circulating blood volume
promotes myocyte growth
worse prognosis

Answer 94

A

if ECG and BNP are both normal

Answer 95

A

heart failure
LV failure following MI
assess prognosis in elderly, PE, general population
monitor treatment

Answer 96

A

synthesis of proteins
detoxification (metabolism and elimination of waste)
metabolises proteins to ammonia
storage of glycogen and can replenish glucose when needed

Answer 97

A

red blood cells are broken down into haem and globin
haem metabolised by haem oxygenase to produce iron and biliverdin
biliverdin is reduced by biliverdin reductase to produce bilirubin

Answer 98

A

initially binds to albumin (unconjugated) because it is insoluble and can’t pass into urine alone

Answer 99

A

transported to hepatocytes
binds to ligandin
this allows it to be transferred to the endoplasmic reticulum and undergoes conjugation
via UPD glucuronosyltransferase
it becomes bilirubin diglucoronide (soluble)

Answer 100

A

conjugated bilirubin goes into the bile via the gallbladder and bile duct
passes into the intestine
degraded by intestinal bacteria to urobilinogen (colourless)
passes through the intestine and is converted to stercobilin (brown)
exerted into faeces
some is bilirubin and urobilinogen is reabsorbed by the portal vein
passes back into the liver and goes into the systemic circulation
some urobilinogen passes through the kidneys (some becomes oxidised to urobilin (yellow)) and is excreted

Answer 101

A

haemolysis (along with raised AST, LDH and reticulocyte count and decreased haptoglobin)
problem with liver uptake of bilirubin from the circulation)
physiological neonatal jaundice (babies have an increased erythrocyte load and reduced ligandin)
gilbert syndrome (AD, reduced glucuronosyltransferase)
crigler-najaar syndrome (AR, two forms, more severe form of Gilbert syndrome)

Answer 102

A

allow digestive enzymes pass through a duct to the intestine
trypsin
chymotrypsin
elastase
lipase
amylase

Answer 103

A

the small intestine produces cholecystokinin and secretin

Answer 104

A

causes gallbladder contraction
empties bile into the duodenum
allows digestion of fats
stimulate the production of alkaline fluid and pancreatic enzymes

Answer 105

A

acute pancreatitis
pancreatic insufficiency (chronic pancreatitis, cystic fibrosis - chronic ongoing inflammation)
pancreatic cancer

Answer 106

A

acute abdominal pain, relieved by leaning forward
shock, 3rd space fluid loss
acutely unwell
mortality 5-10%
amylase (pancreas and salivary glands)
lipase (more specific for pancreas)
CT - oedema and inflammation surrounding pancreas

Answer 107

A

gallstones
ERCP
hypertriglyceridaemia (fat obstruct pancreatic blood flow, >10mmol/L)
alcohol excess
viral
drugs

Answer 108

A

mumps
calculi of salivary ducts
CKD (reduced amylase excretion)
duodenal ulcer perforation
ruptured AAA
DKA
acute pancreatitis

Answer 109

A

increased age
increased LDH (cell breakdown)
increased urea (kidney dysfunction, multiple organ failure)
increased WCC
increased blood glucose
reduced albumin (negative acute phase reactant)
reduced Ca (auto-digestion of mesenteric fat)

Answer 110

A

removal of some necrotic areas of pancreas
chronic pancreatitis
cystic fibrosis

malabsorption (anaemia, weight loss, diarrhoea, steatorrhoea)
abdominal discomfort
osteomalacia
low Ca
low vitamin D
hyperglycaemic (check plasma glucose and HbA1c)
low faecal elastase (pancreatic dysfunction)

Answer 111

A

CEA

CA19-9

Answer 112

A

produce other hormones; insulin or glucagon

better prognosis

Answer 113

A

ensure that there are constant levels of the drug in plasma
avoid toxicity
identify non-compliance

Answer 114

A

lithium
vancomycin, aminoglycosides
cyclosporin, tacromilus, mycophenolate

digoxin
theophylline, caffeine (given in COPD and asthma)
anti-epileptics (phenytoin, phenobarbitone, carbamazepine, sodium valproate)

Answer 115

A

clinical response (BP)
INR/PT - warfarin
renal function - ACEi, diuretics, NSAIDs
potassium - spironolactone
liver function - statins
urinary protein - pencillamine, gold (for RA, can cause nephrotic syndrome)

Answer 116

A

treatment of bipolar disorder

diabetes insipidus
renal function
thyroid function

Answer 117

A

ototoxicity (auditory nerve)

nephrotoxicity

Answer 118

A

nephrotoxicity

careful when used in immunosuppression of kidneys

Answer 119

A

converted to a toxic metabolite
usually inactivated by conjugation with glutathione
glutathione becomes depleted when an excess of paracetamol is taken
NABQI binds to sulphhydryl-containing groups on liver cell membranes, causing liver necrosis

Answer 120

A

acetylcysteine
replaces glutathione and mops up toxic metabolite
most effective within the first 8hrs
measure INR and creatinine

Answer 121

A

history of alcohol abuse

taking drugs that may induce liver enzymes (phenytoin)

Answer 122

A

vomiting
sweating
tinnitus
blurred vision
respiratory alkalosis (adults)
metabolic acidosis
renal failure

Answer 123

A

mild - oral fluids
vomiting - IV fluids
potassium monitoring, require supplements
oral activated charcoal (50g 4hrly)
alkalinisation (1L 1.26% NaCl over 2hrs, maintain urinary pH>7.5, allows salicylate to be excreted in the urine)
severe - haemodialysis (persistent acidosis, falling consciousness, levels >1000mg/L)

Answer 124

A

depressed consciousness
hypoglycaemia (children)

fluids
monitoring
ensure airway is open in vomiting
glucose if required

Answer 125

A

benzodiazepines - flumazenil in respiratory depression
detection tests
do not provide the levels of drug (not useful in someone who’s already taking them)
monitoring
treat symptomatically

Answer 126

A

abdominal pain
anaemia
bone marrow suppression
peripheral neuropathy (mononeuropathy)

Answer 127

A

remove from source (occupational exposure)
chelation therapy (Ca EDTA or penicillamine)
monitoring of lead levels

Answer 128

A

abdominal pain (gastric erosion)
nausea
hypotension
hepatic injury

Answer 129

A

chelation therapy (desferrioxamine)
increases excretion
prevents toxic effects
monitoring

Answer 130

A

methanol produces formate and ethylene glycol produces glycolate
cause severe metabolic acidosis
liver and kidney toxicity
blindness

Answer 131

A

ethanol
prevents metabolisation and formation of toxic metabolites
severe cases - haemodialysis

Answer 132

A

contains iron
provides an oxygen store
released into the blood during muscle damage
filtered by the glomerulus

Answer 133

A

damage and blockage of the renal tubules
AKI
brown/tea coloured urine (blockage of tubules)
CK increase

Answer 134

A

creatinine kinase
aspartate aminotransferase
lactate dehydrogenase

Answer 135

A

used in ATP regeneration
composed of 2 subunits (M or B)
main type in skeletal - CK-MM
main type in cardiac - CK-MB

Answer 136

A

cardiac muscle damage

Answer 137

A

liver dysfunction
skeletal or cardiac muscle dysfunction
haemolysed sample

Answer 138

A

increased cell breakdown or an increased number of cells

tumour growth - leukaemia and lymphoma

Answer 139

A

rises after 4-9 hours
more cardiac-specific (can be affected by other muscle)
should return to baseline after 48-72 hours
second rise in CK-MB = second event

Answer 140

A

muscle pain
no rise in CK
no severe muscle tenderness

Answer 141

A

mild increase in CK

increased muscle breakdown

Answer 142

A

rapid muscle breakdown
CK increase (5-10x upper limit of normal)

Answer 143

A

increase in CK and myoglobin
monitor urea, creatinine, GFR (AKI)
increase in potassium phosphate (electrolyte release)
cardiac arrhythmias (K)
metabolic acidosis (AKI, organic acids released from muscle, ischaemia of muscle causing lactic acidosis
hypocalcaemia (falls initially then rises as muscles recover)

Answer 144

A

crush syndrome (excess alcohol)
ischaemia
seizure (rapid tonic-clonic muscle contraction)
inflammation
autoimmune disorders (polymyositis or dermatomyositis)
hypothyroidism (mild increase in CK)
hypo/hyperadrenalism
hypo/hyperkalaemia, hypocalcaemia, hypohosphataemia, hypomagnesaemia
statins (myalgia, not rhabdomyolysis)
ecstasy, cocaine
muscular dystrophies (CK increase)
malignant hyperpyrexia
fatty oxidation defects
mitochondrial disorders
paraneoplastic syndrome

Answer 145

A

troponin C - binds to Ca, allows muscle contraction
troponin I - inhibitory
troponin T - anchors the tropomyosin complex

Answer 146

A

large increase
put o 7 days to return to baseline
may be difficult to detect re-infarction

Answer 147

A

ischaemia
myocarditis (viral or autoimmune)
post-cardiac surgery
aortic dissection
cardiomyopathy
acutely unwell, cardiac strain (ICU)
PE
SAH
stroke (other cerebral cause)
CKD
sepsis
severe exertion (marathon

Answer 148

A

secreted by atrial and ventricular myocytes when the heart is under strain
cause natriuresis (loss of Na and water) and relaxation of smooth muscle
increase in acute/chronic heart failure, age, female

Answer 149

A

diagnosing heart failure (rule out test)
screening for left ventricular function in those with IHD
risk stratification/prognosis

Answer 150

A

proceed to echocardiography (most likely due to HF)

Answer 151

A

measure BNP

if high, refer to echocardiography

Answer 152

A

PE
septic shock
liver cirrhosis
kidney injury
COPD with cor pulmonale
acutely ill from SAH or stroke
AF
IHD
hyperthyroidism

Answer 153

A

60% of the body weight is water
2/3s is intracellular fluid and 1/3 is extracellular fluid
of the extracellular fluid - 1/4 is in the vasculature, 3/4 is interstitial fluid

Answer 154

A

potassium

Answer 155

A

by the regulation of salt and water
volume receptors respond to changes in the intravascular volume via the kidneys
osmoreceptors respond to changes in the composition of plasma via thirst and water reabsorption

Answer 156

A

volume receptor in the left atrium
causes Na to be lost in the urine via natriuresis
reduces the amount of angiotensin and aldosterone, reducing the amount of Na reabsorbed

Answer 157

A

increased renin secretion

angiotensin, aldosterone and sodium reabsorption

Answer 158

A

thirst stimulation when osmolarity is increased

when osmolarity is increased, dehydration occurs and ADH is released from the posterior pituitary, preventing diuresis

Answer 159

A

hypertriglyceridaemia

hyperproteinaemia

Answer 160

A

non-ketotic hyperosmolar coma

diabetic ketoacidosis

Answer 161

A

water moves into cells
cerebral oedema
this results in nausea, headache, malaise, seizures, coma

Answer 162

A

congestive cardiac failure
cirrhosis
nephrotic syndrome

urinary Na <20 (without diuretics)
reduced albumin (cirrhosis and nephrotic syndrome)
increased urinary protein (nephrotic syndrome)

Answer 163

A

GI loss; diarrhoea, vomiting, fistula (low urinary Na)
renal loss; obstruction, (thiazide) diuretics, hyperglycaemia (high urinary Na)

skin turgor reduction, dry tongue, postural hypotension, tachycardia

Answer 164

A

addison’s (synacthen test)
hypothyroidism
SIADH

Answer 165

A

water retention when it is not necessary
plasma becomes diluted, plasma osmolarity falls and a concentrated urine is produced
high urinary Na

Answer 166

A

pain
nausea
carbamazpeine
SSRI (sertraline, lustral)
paraneoplastic syndrome (most commonly small cell carcinoma of the lung)

Answer 167

A

slowly corrected Na by 1-2 mmol/hr
not more than 12 mmol in 24hrs
faster - brain shrinkage and cerebral haemorrhage
treat underlying cause
Na depletion - oral or IV Na
SIADH - fluid restriction (1L/24hrs)
not responding/require Na correction rapidly - demeclocycline (causes nephrogenic diabetes insipidus, blocks ADH action)
aquaporin receptor antagonists - block Na reabsorption

Answer 168

A

dermal loss; burns, sweating, fever
GI loss; vomiting, diarrhoea, fistula
renal loss; diuresis (loop diuretics), AKI, CKD, PKD, hyperosmolar non-ketotic coma

Answer 169

A

iatrogenic
excess hypertonic saline administered
antibiotic infusions of a very high Na content

Answer 170

A

diabetes insipidus (polyuria, polydipsia)
fever (water loss in excess of salt)
mechanical ventilation (insensible fluid loss in excess of Na)

Answer 171

A

ADH deficiency; not enough being produced or posterior pituitary damage

Answer 172

A

tumour of pituitary
sarcoid (can infiltrate the pituitary)
ADH resistance (action blocked by the kidneys)

confirmation by water deprivation test (check urine, plasma osmolarity and fluid output)

Answer 173

A

treat the underlying cause
fluid replacement (hypovolaemic or euvolaemic)
correct Na 1-2 mmol/hr, 10-12 mmol/24hrs

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Clinical Biochemistry Flashcards

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