CASE 7

Question 1

at what 2 main sites do diuretics work?

Answer 1

loop of henle and DCT

Question 2

what part of the nephron is impermeable to water?

Answer 2

ascending limb of LoH

Question 3

name a loop diuretic

Answer 3

furosemide

Question 4

how do loop diuretics work?

Answer 4

• block the NaKCl transporter in the thick ascending limb of the loop of Henle and inhibit chloride reabsorption
• this thus prevents Na+ reabsorption — so less water is reabsorbed via osmosis
• results in increased loss of salt and water
• high loss of fluid

Question 5

when are loop diuretics used?

Answer 5

pulmonary oedema, HF, renal insufficiency, or resistant hypertension

Question 6

unwanted effects of loop diuretics

Answer 6

hypotension, hypovolaemia, hypokalaemia, metabolic alkalosis

Question 7

name a thiazide diuretic

Answer 7

indapamide

Question 8

how do thiazide diuretics work?

Answer 8

• inhibit the NaCl transporter in the distal convoluted tubule (DCT), preventing the removal of Na+ and Cl- from the tubular fluid, along with the water that would have travelled with the ions to maintain osmolarity
• has a vasodilator action — BP falls initially due to renal action, reduced blood volume stimulates renin secretion which limits the effect on BP, vasodilation maintains the antihypertensive effect

Question 9

when are thiazide diuretics given?

Answer 9

given as an add one when other drugs are not efficient on their own — potentiates the effect of other drugs

Question 10

unwanted effects of thiazide diuretics

Answer 10

more frequent urination, hypokalaemia, erectile dysfunction

Question 11

what is spironolactone an example of?

Answer 11

potassium sparing diuretic

Question 12

how do K sparing diuretics work?

Answer 12

blocks the mineralocorticoid receptor, preventing the action of aldosterone, thereby causing increased excretion of Na+ and water, while preventing K+ ions in the circulation

Question 13

what part of the nephron does aldosterone work at?

Answer 13

DCT and collecting duct

Question 14

when are K sparing diuretics used?

Answer 14

in treatment of HF, hyperaldosteronism, resistant HT (especially w low renin)

Question 15

what do K sparing diuretics prevent when given with a loop pr thiazide diuretic?

Answer 15

hypokalaemia

Question 16

unwanted effects of K sparing diuretics

Answer 16

potentially fatal hyperkalaemia, GI upset, gynaecomastia, menstrual disorders and testicular atrophy due to actions at other steroid receptors

Question 17

K sparing diuretics prevent action of ______ on kidney, (stimulate aldosterone release), resulting in vasodilation and reduced plasma volume

Answer 17

angiotensin 2

Question 18

what is mannitol?

Answer 18

osmotic diuretic

Question 19

what do osmotic diuretics do?

Answer 19

• work in the late PCT and the descending loop of Henle
• promotes water excretion without increasing the loss of electrolytes

Question 20

unwanted effects of osmotic diuretics

Answer 20

acute hypovolaemia

Question 21

All diuretics can disturb the plasma electrolyte balance, with ___ a particular concern. Diuretics can also cause loss of ______ function as a consequence of hypovolaemia. For these reasons, serum ________ and _________ levels are monitored during treatment.

Answer 21

All diuretics can disturb the plasma electrolyte balance, with K+ a particular concern. Diuretics can also cause loss of renal function as a consequence of hypovolaemia. For these reasons, serum electrolyte and creatinine levels are monitored during treatment.

Question 22

what type of diuretics are more likely to cause hypokalaemia?

Answer 22

loop

Question 23

why are thiazide and thiazide-like diuretics safer than loop?

Answer 23

dont cause such profound salt and water loss

Question 24

what diuretics work at the NCC in the distal tubule?

Answer 24

thiazide eg. indapamide

Question 25

what diuretics work at the NKCC co-transporter in the loop of henle?

Answer 25

loop. eg furosemide

Question 26

what does urine analysis look for?

Answer 26

proteinuria, albuminuria, haemoglobinuria, haematuria, WBC, glucose

Question 27

what is GFR?

Answer 27

= glomerular filtration rate

• rate in millilitres per minute at which substances in plasma are filtered throguh the glomerulus ie. the clearance of a substance from the blood

Question 28

what is normal GFR for an adult male?

Answer 28

90 to 120 ml per min

Question 29

according to the Kidney Disease Improving Global Outcomes (KDIGO), what are the stages of chronic kidney disease in terms of GFR?

Answer 29

• Stage 1 GFR greater than 90 ml/min/1.73 m²
• Stage 2 GFR-between 60 to 89 ml/min/1.73 m²
• Stage 3a GFR 45 to 59 ml/min/1.73 m²
• Stage 3b GFR 30 to 44 ml/min/1.73 m²
• Stage 4 GFR of 15 to 29 ml/min/1.73 m²
• Stage 5-GFR less than 15 ml/min/1.73 m² (end-stage renal disease)

Question 30

what are normal albumin levels in urine?

Answer 30

very little — less than 30mg/g — anything above this may mean you have kidney disease, even if your GFR number is above 60

Question 31

what levels of albumin:creatinine ratio are normal, show microalbuminuria and albuminuria?

Answer 31

<30 is normal, 30-300 is microalbuminuria, above 300 is albuminuria

Question 32

what are the divisions of the nephron and what happens at each?

Answer 32

• glomerulus — filtration (provides a size and charge barrier - large or negatively charged molecules are repelled)
• proximal convoluted tubule — selective reabsorption of water, ions, and all organ nutrients
• descending limb of loop of Henle — selective reabsorption of water
• ascending limb of loop of Henle — selective reabsorption of Na+ and Cl-
• distal convoluted tubule — secretion of ions, acids, drugs, toxins / variable reabsorption of water, Na+ and Ca++
• collecting tubule — variable reabsorption of water and reabsorption/secretion of Na+, K+, H+ and HCO3-

Question 33

what is the first stage of RAAS?

Answer 33

release of renin

Question 34

where is renin released from?

Answer 34

granular cells of the renal juxtaglomerular apparatus (JGA)

Question 35

what 3 things stimulate renin release?

Answer 35

1. reduced Na+ delivery to the DCT detected by macula densa cells
2. reduced perfusion pressure in the kidneys detected by baroreceptors in the afferent arteriole
3. sympathetic stimulation of the JGA via B1 adrenoreceptors

Question 36

what is the release of renin inhibited by?

Answer 36

atrial natriuretic peptide (ANP) = released by stretched atria in response to increases in BP

Question 37

angiotensinogen is a precursor produced by the ______ and cleaved by renin to form __________

Answer 37

• liver
• angiotensin I

Question 38

how is angiotensin I converted to angiotensin II?

Answer 38

converted to angiotensin II by angiotensin converting enzyme (ACE

Question 39

where does most of the angiotensin I to II converison occur and why?

Answer 39

occurs mainly in the lungs where ACE is produced by vascular endothelial cells, although ACE is generated in smaller quantities within the renal epithelium

Question 40

what does angiotensin II bind to?

Answer 40

it binds to 1 of 2 G-protein coupled receptors; the AT1 and AT2 receptors (most actions occur via the AT1 receptor)

Question 41

affect of angiotensin II on: arterioles

Answer 41

vasoconstriction

Question 42

affect of angiotensin II on: kidney

Answer 42

stimulates Na+ reabsorption

Question 43

affect of angiotensin II on: sympathetic nervous system

Answer 43

increased release of NA

Question 44

affect of angiotensin II on: adrenal cortex

Answer 44

stimulates release of aldosterone

Question 45

affect of angiotensin II on: hypothalamus

Answer 45

increases thirst sensation and stimulates anti-diuretic hormone (ADH) release

Question 46

what are the cardiovascular effects of angiotensin II?

Answer 46

• acts on AT1 receptors found in the endothelium of arteries throughout the circulation to cause vasoconstriction
• this signalling occurs via a Gq protein, to activate phospholipase C and subsequently increase intracellular calcium
• the net effect of this is an increase in total peripheral resistance and therefore BP

Question 47

what are the neural effects of angiotensin II?

Answer 47

• acts at the hypothalamus to stimulate the sensation of thirst, resulting in an increase in fluid composition
• this helps to raise the circulating volume and in turn BP
• also increases the secretion of ADH from the posterior pituitary gland — resulting in the production of more concentrated urine to reduce the loss of fluid from urination
• stimulates the SNS to increase the release of NA resulting in an increase in cardiac output, vasoconstriction of arterioles, release of renin

Question 48

what effect does angiotensin II have on the renal artery and afferent arteriole and how?

Answer 48

• vasoconstriction
• voltage-gated Ca++ channels open and allow an influx of Ca++

Question 49

what effect does angiotensin II have on the efferent arteriole and how?

Answer 49

• vasoconstriction — greater than the afferent arteriole
• activation of AT1 receptor

Question 50

what effect does angiotensin II have on mesangial cells and how?

Answer 50

• contraction, leading to a decreased filtration area
• activation of Gq receptors and opening of voltage-gated Ca++ channels

Question 51

what effect does angiotensin II have on the PCT and how?

Answer 51

• increased Na+ reabsorption
• increased Na+/H+ antiporter activity and adjustment of the starling forces in the peritubular capillaries to increase paracellular reabsorption

Question 52

angiotensin II is also an important factor in _______________, which helps to maintain a stable glomerular filtration rate. the local release of ___________, which results in a preferential vasodilation to the afferent arteriole in the glomerulus, is also vital to this process.

Answer 52

• tubuloglomerular feedback
• prostaglandins

Question 53

where is aldosterone released from?

Answer 53

zona glomerulosa of the adrenal cortex

Question 54

what does aldosterone do?

Answer 54

acts on the principal cells of the collecting ducts by increasing the expression of apical epithelial Na+ channels (ENaC) to reabsorb urinary sodium. the activity of the basolateral NaK ATPase is increased

• this causes the additional Na+ reabsorbed through ENaC to be pumped int the blood by NaK pump. in exchange, K+ is moved from the blood into the principal cell of the nephron, this K+ then exits the cell into the renal tubule to be excreted in urine
• as a result, aldosterone causes reduced levels of K+ in blood

Question 55

what is the overall affect of the RAAS system?

Answer 55

causes water and salt retention. effective circulating volume increases. perfusion of the JGA increases

Question 56

what is ramipril?

Answer 56

ACE inhibitor

Question 57

what do ACE inhibitors do and when are they used?

Answer 57

• used in the treatment of hypertension and HF
• inhibit the action of ACE and so reduce the levels of angiotensin II — reduces the activity of RAAS
• decreased arteriolar resistance
• decreased arteriolar vasoconstriction
• decreased cardiac output
• reduced K+ excretion in the kidneys

these actions help to looser BP in HT patients and also help to improve outcomes in conditions such as HF

Question 58

what are typical SEs of ACEI?

Answer 58

• dry cough
• hyperkalaemia
• headache
• dizziness
• fatigue
• renal impairment
• rarely angioedema

Question 59

what are the 2 most important prognostic factors in chronic kidney disease?

Answer 59

hypertension and proteinuria

Question 60

what are 3 the main hormones made by the kidneys?

Answer 60

vitamin D, erythropoietin and renin

Question 61

diabetic nephropathy:

the early stages cause an elevated _____ with enlarged kidneys but the principal feature of diabetic nephropathy is _________. This develops insidiously, starting as intermittent microalbuminuria before progressing to constant proteinuria and occasionally_____________ (= loss of protien eg. proteinurea, hyperalbuminurea)

Answer 61

• GFR
• proteinuria
• nephrotic syndrome

Question 62

what is the leading cause of end stage renal failure in the developed world?

Answer 62

diabetic nephropathy

Question 63

albuminuria persistency means increased risk of developing what?

Answer 63

heart attack

Question 64

what are the 5 stages of injury in diabetic nephropathy?

Answer 64

1. hyperfiltration
2. microalbuminuria
3. macroalbuminuria
4. proteinuria
5. declining renal function

Question 65

describe the pathology of nephropathy

Answer 65

1. hyperglycaemia causes glycosylation of glomerular proteins
2. thickening of glomerular basement membrane
3. mesangial expansion
4. nodular sclerosis
5. advanced renal sclerosis

Question 66

what are areas of nodular glomerulosclerosis referred to as?

Answer 66

Kimmelstiel-Wilson lesions

Question 67

how is diabetic nephropathy treated?

Answer 67

aims of treatment = glycaemic control, BP control (these drugs help delay the progression of kidney diseases by blocking RAAS) — ACEI, ARBs (losartan), Renin-inhibitors (aliskiren) — delay progression because they lower BP which lowers the GFR

secondary treatments = lipid lowering, reduce other CV risks

Question 68

peritoneal dialysis vs haemodialysis

Answer 68

Question 69

sepsis treatment

Answer 69

• antibiotics
• fluid added to veins
• vasopressors — narrow blood vessels and help increase BP
• may need surgery to remove infected tissue

Question 70

hyperkalaemia treatment

Answer 70

• IV calcium to ameliorate cardiac toxicity
• identify and remove sources of K+ i taken
• enhance K+ uptake by cells to decrease the serum conc — IV glucose and insulin infusions
• IV insulin can cause hypoglycaemia - patients with acute kidney injury and chronic kidney disease are especially susceptible - sufficient dextrose in the treatment regimen can minimise the risk
• correct metabolic acidosis with sodium bicarbonate
• increase K+ excretion from the body — IV saline accompanied by a loop diuretic such as furosemide
• emergency dialysis for those with potentially lethal hyperkalaemia

Question 71

what is pyelonephritis?

Answer 71

kidney infection

• usually starts in bladder and moves upstream to one or both kidneys
• the usual organisms are the same for lower UTI = Escherichia coli, Klebsiella spp, Proteus spp, Enterococcus spp
• repeated attacks of acute pyelonephritis can lead to chronic pyelonephritis, which involes destruction and scarring of renal tissue due to repeated inflammation

Question 72

symptoms of pyelonephritis

Answer 72

> unilateral or bilateral loin pain, suprapubic pain or back pain
fever
malaise/nausea/vomiting/anorexia/diarrhoea can occur
may or may not be lower UTI symptoms with frequency, dysuria, gross haematuria or hesitancy
pain on firm palpation of one or both kidneys

Question 73

Answer 73

Question 74

if you have a GFR over 60, and no albumin…..

Answer 74

you do NOT have ckd

Question 75

what type of anaemia can you get in ckd and why?

Answer 75

normocytic — due to decrease in erythropoietin production

Question 76

what gives you a metabolic acidosis?

Answer 76

sepsis

Question 77

which diuretics cause metabolic alkalosis/acidosis as an adverse side effect?

Answer 77

thiazide and loop —> metabolic alkalosis

K+ sparing —> metabolic acidosis

Question 78

what type of diuretic can cause hyperglycaemia in diabetes as an unwanted side effect?

Answer 78

thiazide

Question 79

what drug type reduce diuretic efficacy? how?

Answer 79

NSAIDs — by inhibiting prostaglandin synthesis

Question 80

what can corticosteroids enhance when using thiazide or loop diuretics?

Answer 80

hypokalaemia

Question 81

what can ACE inhibitors potentiate when using K+ sparing diuretics?

Answer 81

hyperkalaemia

Question 82

what kind of diuretics cause gynecomastia and gastric problems (inc peptic ulcers)?

Answer 82

K+ sparing

Question 83

why do K+ sparing diuretics cause gynacomastia?

Answer 83

aldosterone antagonism