S3 L1 Hypertension and Heart Failure

Question 1

What is blood pressure?

Answer 1

Driving force to perfuse organ with blood (force per unit area acting on vessels)
- Pressure needed to drive blood out of the heart- requires a pressure gradient

Question 2

What are some of the features of BP?

Answer 2

Not uniform throughout the body 
- Gravity has an impact 
Measure systolic and diastolic pressure 
Cyclical 
Physiologically regulated variable → changes

Question 3

What affect the BP?

Answer 3

Mean Arterial Pressure (MAP)= Cardiac output (CO) x total peripheral resistance (TPR)
TRP also called systemic vascular resistance

Question 4

How can the mean arterial pressure be calculated?

Answer 4

Diastolic blood pressure + ((systolic blood pressure - diastolic blood pressure)/ 3)
Time in systolic blood pressure is much smaller

Question 5

How is the blood pressure regulated?

Answer 5

Autonomic sympathetic pathway and renin angiotensin-aldosterone system (RAAS)
Plus autacoid including bradykinin and NO (vasodilation)- action from the endothelium on vascular smooth muscle

Question 6

How does the sympathetic activity regulate BP?

Answer 6

Decrease in BP
- ↑Activation of β1 adrenoreceptors on the heart → CO
- ↑ Activation of α1 adreno receptors on smooth muscle → ↑venous return
- ↑ Activation of β1 adrenoreceptor on kidney → ↑peripheral resistance and ↑renin release
Increase in Blood pressure

Question 7

How does the renal blood flow regulate BP?

Answer 7

Decrease BP
↓ Renal blood flow → ↓ GFR → ↑Na+, H2O retention → ↑Blood volume → ↑CO → ↑BP
AND
↓ Renal blood flow→ ↑Renin → ↑Angiotensin II → ↑Aldosterone → ↑Sodium, water retention → ↑BV → ↑CO → ↑BP

Question 8

How are resistance and increased mean arterial pressure related?

Answer 8

Resistance to flow = 8nL / πr^4
Radius of vessel main determinant of flow
Small change in radius = big change in resistance

Question 9

How does the radius change?

Answer 9

Smooth muscle tone changes total peripheral resistance

Vasoconstriction causes ↑peripheral resistance require ↑BP to drive blood through systemic circulation to maintain CO

Question 10

What is the pathophysiology of hypertension?

Answer 10

1. Elevated blood pressure (essential/primary/idiopathic) still not completely understood
2. Leads to vascular changes including remodelling, thickening and hypertrophy
3. Increased vasoactive substances including ET-1 (endothelin-1), NA (noradrenaline) and AngII (angiotensin II)
4. Vascular remodelling also occurs as a direct result of local salt sensitivity
5. Hyperinsulinemia and hyperglycaemia lead to endothelial dysfunction and increased ROS - NO signalling reduced

Question 11

What is the end results of hypertension?

Answer 11

1. Permanent and maintained medial hypertrophy of vasculature with ↑↑TPR and ↓Compliance of vessels
2. Results in end organ damage (renal, peripheral vascular disease, aneurysm, vascular dementia and retinal disease)
3. Hypertensive heart disease- LVH → dilated cardiac failure
4. Increased morbidity and mortality

Question 12

Why should we treat hypertension?

Answer 12

Silent killer- often asymptomatic

Increases the risk of other diseases such a coronary heart disease, stroke

Question 13

How is hypertension defined?

Answer 13

Labile, age, sex and population differences make it difficult to define
Elevation in blood pressure that is associated with an increase in risk of some harm
Significant to cause end organ damage
An elevated blood pressure that treated will do more good than harm

Question 14

What is the NICE definition of hypertension?

Answer 14

140/90 mmHg= hypertension

Approx >40% population in England

Question 15

What are the different types of hypertension?

Answer 15

Essential/ primary/ idiopathic - 90% of cases
Other 10%
- Secondary hypertension (secondary to another disease)
- Pre hypertension
- Isolated systolic/diastolic hypertension
- White coat/ clinic (real phenomenon- elevated BP in GP or hospital settings)

Question 16

How is hypertension diagnosed?

Answer 16

• Screening the at risk population
• Increasing public awareness of risk factors
• Appropriate lifestyle changes to limit risk- no immediate gain presence a challenge- don’t see or feel change so difficult to believe changes are working
• Reliable measurements based on clinical guidelines
• Regular monitoring and refinement of medication
• SILENT KILLER

Question 17

How should a BP be obtained?

Answer 17

• Sitting, relaxed and arm is supported
• Both arms >15mmHg difference repeat measurement and use arm with higher reading
• Measurements over period of visits +/- Ambulatory BP measurement (ABPM) or Home BP measurement (HBPM)
• Emergency treatment required (>180 SBP or 120 DBP + clinical signs)
• CVD risk and end organ damage should be assessed whilst waiting for hypertension confirmation
• Aim- target BP and reduced CVD risk

Question 18

What is the target BP?

Answer 18

140/90 <80 year old including type II diabetes
150/90 >80 year old
135/85 type 1 diabetes

Question 19

What are the different stages of hypertension?

Answer 19

120/80 mmHg 'desired' minimise CVD risk 
Stage 1
- Clinical BP 140/90 - 159/99 mmHg and subsequent ABPM daytime/ HBPM average blood pressure ranging from 135/85 mmHg to 149/94 mmHg
Stage 2
- Clinical BP 160/100 - 180/120 mmHg
- ABPM/HBPM 150/95mmHg or higher 
Stage 3
- Clinical systolic BP of 180mmHg or higher OR clinical diastolic BP of 120mmHg or higher

Question 20

What is prehypertension?

Answer 20

Slippery slop to hypertension >120/80 <140/90 mmHg

Question 21

How can you prevent progression of hypertension?

Answer 21

1. Promotion of regular exercise
2. Modified healthy/balance diet
3. Reduction in stress and increased relaxation
4. Limited/ reduced alcohol intake
5. Discourage excessive caffeine consumption
6. Smoking cessation
7. Reduction in dietary sodium
   - All contribute to CVD risk reduction
   These should be promoted to all patient groups not just pre pharmacological groups

Question 22

What are the classes of drugs that are used to treat hypertension?

Answer 22

Angiotensin converting enzyme inhibitors (ACEi)
Angiotensin (AT1) receptor blockers (ARBs)
Calcium channel blockers (CCBs)
Diuretics- thiazide and thiazide-like
Other agents

Question 23

What is ACE?

Answer 23

Angiotensin converting enzyme
Found on the luminal surface of capillary endothelial cells, predominantly in the lungs
Catalyses the conversion of AngI to AngII (active vasoconstrictor)

Question 24

What is angiotensin II?

Answer 24

Afford action through AT1 (and AT2 receptors)
AT1 receptor subtype typical of classic angiotensin II action
- Vasoconstriction
- Stimulation of aldosterone (DCT)
- Cardiac and vascular muscle cell growth
- Vasopressin (ADH) release from posterior pituitary
BP↑ through combination of vasoconstriction and ↑circulating blood volume

Question 25

What do ACEi do?

Answer 25

Limit the conversion of AngI to AngII by inhibiting ACE
Reduction in AngII activity
- Vasodilation ↓peripheral resistance → ↓afterload
- Reduction in aldosterone release ↑Na+ and H2O excretion
- Reduce vasopressin (ADH) release (↑H2O excretion)
- Reduce cell growth and proliferation
All can contribute to antihypertensive effects
AngII can also be produced from AngI independently of ACE via Chymases (additional pathway)

Question 26

What are some of the common ACEi?

Answer 26

‘-pril’

1. Lisinopril
2. Ramipril

Question 27

What are the adverse effects of ACEi?

Answer 27

Hypotension
Dry cough (10-15% bradykinin association)
Hyperkalaemia (low aldosterone ↑K+)
Cause or worsen renal failure (especially renal artery stenosis where constriction of efferent arterioles are needed)
Angioedema (more common in Afro-Caribbean patients)

Question 28

What are the warning/contraindications of using ACEi?

Answer 28

• Renal artery stenosis
• AKD
• Pregnancy
• CKD- cation
• Idiopathic angioedema

Question 29

What are the important drug interactions of ACEi?

Answer 29

↑K+ drugs
NSAIDs
Other antihypertensive agents

Question 30

How do ACEi affect bradykinin?

Answer 30

ACE also needed for bradykinin breakdown into peptide fragments
Use of ACEi potentiate bradykinin
- Vasodilation via NOS/NO and PGI2
→ ACEi vasodilation in low-renin hypertensives

Question 31

What are the Angiotensin receptors blockers (ARB)?

Answer 31

‘-sartan’
Candesartan
Losartan

Question 32

Where are the main mechanisms of action of ARBs?

Answer 32

AT1 and AT2 receptors
AT1 are important in relation to cardiovascular regulation
Confusing nomenclature- AngII blockers - block angiotensin II, AT1-receptors blockers- act at T1 receptor or ARBs
No affect on bradykinin as act further down in the pathway - less effective in low-renin hypertensive patients dry cough and angioedema much less likely

Question 33

What are the adverse effects of ARBs?

Answer 33

Hypotension
Hyperkalaemia (low aldosterone ↑K+)
Cause or worsen renal failure

Question 34

What are the warnings/contraindications of ARBs?

Answer 34

Renal artery stenosis
AKD
Pregnancy
CKD

Question 35

What are the important drug interactions of ARBs?

Answer 35

↑K+ drugs

NSAIDs

Question 36

Which are more effective the ACEi or ARBs?

Answer 36

ARBs- Directly targeting AT1 receptors
More effective at inhibiting AngII mediated vasoconstriction than ACEi
(chymase production AngII- block further downstream in the pathway)

Question 37

How do ARBs work?

Answer 37

Bind to AT1 receptor preventing AngII binding
Prevents:
- Arterial vasoconstriction
- Tubular Na+, Cl- and H20 reabsorption and K+ excretion
- Aldosterone release from adrenal cortex
- Posterior pituitary gland ADH release

Question 38

What are L-type calcium channels

Answer 38

• Stimulated → Allow inward flux of Ca2+ ions into cells- VOCC→ calcium induced calcium release from SR → Contraction
• On smooth muscles cells and cardiac myocytes plus SA and AV node
• Calcium initiate smooth muscle contraction

Question 39

How do calcium channel blockers work?

Answer 39

Bind to LTCC/VOCC inhibit influx of Ca2+
Inhibit Ca2+ initiated smooth muscle contraction
Different CCB bind to different subunit (α1)
Different selectivity for vascular smooth muscle or myocardium

Question 40

What are the classes of calcium channel blockers?

Answer 40

Dihydropyridines

Non-dihydropyridines → Phenylalkylamines and benzothiazapines

Question 41

What are the dihydropyridines?

Answer 41

Selective for peripheral vasculature
Little chronotropic or inotropic effects
Used in hypertension
Primary choice in low renin patients

Question 42

What do the non-dihydropyridines do?

Answer 42

Phenylalkyamines- depress SA node and slow AV node conduction, negative inotrophy
Benzothiazapines- In the middle, some cardiac effects, some peripheral vasculature effects

Question 43

What are some of the dihydropyridine CCB?

Answer 43

‘-ipine’
Amlodipine - longer half life
Nifedipine
Nimodipine - selective for cerebral vasculature

Question 44

What are the adverse effects of dihydropyridine CCBs?

Answer 44

Ankle swelling, flushing, headaches → vasodilation

Palpitations → compensatory tachycardia

Question 45

What are the contraindications of dihydropyridine CCBs?

Answer 45

Unstable angina, severe aortic stenosis

Question 46

What are the drug-drug interactions?

Answer 46

Used with simvastatin → Increases the effects of simvastatin so reduced dose maybe necessary

Question 47

What are the phenylalkylamines used for?

Answer 47

Class IV anti-arrhythmic agent/ prolongs the action potential/ effective refractory period
Less peripheral vasodilation
More action on cardiac tissue- negative chronotropic and inotropic effects
Treat: Arrhythmias, angina, sometime hypertension

Question 48

How do the phenylalkylamines have an effect on cardiac tissue?

Answer 48

?

Question 49

What are the adverse effects of phenylalkylamines?

Answer 49

Constipation
Bradycardia
Heart block
Cardiac failure

Question 50

What are the contraindications of phenylalkylamines?

Answer 50

Poor LV function - use with caution

AV nodal conduction delay

Question 51

What are the important drug-drug interactions of phenylalkylamines?

Answer 51

β-blockers

Other antihypertensives and antiarrhythmic agents

Question 52

What is the benzothiazapine

Answer 52

Diltiazem

Question 53

What is the benzothiazapine?

Answer 53

Diltiazem

Question 54

How do the thiazide and thiazide-like diuretics work?

Answer 54

Inhibit the Na+/Cl- cotransporter in the DCT
↓Na+ and H2O reabsorption
(RAAS compensated with time- further down tubule increase Na+ uptake through ENaC)
Also helps cause vasodilation

Question 55

What are some of the thiazide ad thiazide-like diuretics?

Answer 55

Thiazide- bendroflumethiazide

Thiazide like- indapamide

Question 56

What are the adverse effects of thiazide and thiazide like diuretics?

Answer 56

Hypokalaema 
Hyponatraemia 
Hyperuricemia (gout) - competition at OATs
Arrhythmias 
↑glucose 
↑cholesterol ad triacylglyceride

Question 57

What are the contraindications of thiazide and thiazide-like diuretics?

Answer 57

Hypokalaemia
Hyponatraemia
Gout

Question 58

What are the important drug-drug interactions with thiazide and thiazide like diuretics?

Answer 58

NSAIDs

↓K+ such as loop diuretics

Question 59

How is primary hypertension treated?

Answer 59

Step 1 → ACEi or ARB or CCB
Step 2 → Add on ACEi or ARB or CCB (depending on what’s already been prescribed) or thiazide-like diuretic
Step 3 → Combination of all of them (ACEi or ARB and CCB and thiazide-like diuretic)
Step 4 → Confirm resistant hypertension - add in spironolactone, α blocker or β blocker

Question 60

How do you decide what to give in step 1?

Answer 60

Hypertension w/o type 2 diabetes

• Age 55 or + or black African or African-Caribbean family origin → CCB
• Age <55 and not black African or African-Caribbean family origin → ACEi or ARB

Question 61

How are patients with hypertension and type 2 diabetes treated?

Answer 61

ACEi or ARB
Help to ↓diabetic nephropathy and CKD with proteinuria by dilation of efferent glomerular arteriole → ↓pressure in the glomerulus
Two pronged approach
1- ↓peripheral vascular resistance → ↓BP
2- Dilation of efferent glomerular arteriole → ↓glomerular pressure

Question 62

What things should be considered in Step 4 for resistant hypertension before adding another drug?

Answer 62

Need to consider patient adherence, compliance, check drugs are being taken in the correct way

Question 63

What is spironolactone?

Answer 63

Aldosterone receptor antagonist
- Aldosterone mineralocorticoid released from the adrenal cortex
Adverse effects→ hyerkalaemia, gynaecomastia (males develop breast tissue)
Contraindications→ hyperkalaemia and Addisons (too little cortisol and aldosterone
Drug-drug interactions→ ↑K+ drugs, pregnancy

Question 64

What is considered instead of spironolactone in pregnancy?

Answer 64

Labetalol - reduced sympathetic outflow

Question 65

What are beta adrenoreceptor blockers?

Answer 65

• Decrease sympathetic tone by blocking NA and reducing myocardial contraction → ↓CO
• ↓Renin secretion β1

Question 66

What are the adverse effects of beta blockers?

Answer 66

Bronchospasm
Heart block
Raynaud’s
Lethargy
Impotence
Mask tachycardia- sign of insulin induced hypoglycaemia
- think about β1 (heart) and β2 (lungs) selectivity when considering side effects

Question 67

What are the contraindications of beta blockers?

Answer 67

Asthma, COPD, haemodynamic instability, hepatic failure

Question 68

What are the important drug-drug interactions with beta blockers?

Answer 68

Non-dihydropyridine CCBs verapamila and diltiazem causes asystole (heart stops)

Question 69

What are examples of the β-adrenoreceptor blockers?

Answer 69

‘-lol’
Labetalol
Bisoprolol
Metoprolol

Question 70

What are the α-adrenoreceptor blockers?

Answer 70

Selective antagonists of α1 adrenoreceptors
Reduce peripheral vascular resistance
- Also affect urinary tract → bladder neck and prostate- benign prostatic hyperplasia
Relatively safe in renal disease

Question 71

What are the adverse effects of α-blockers?

Answer 71

Postural hypotension
Dizziness
Syncope
Headache and fatigue

Question 72

What are the contraindications of α-blockers?

Answer 72

Postural hypotension

Question 73

What are the important drug-drug interaction of α-blockers?

Answer 73

Dihydropyridine CCB - oedema

Question 74

What is an example of α-blocker?

Answer 74

‘-osin’

Doxazosin

Question 75

What is heart failure?

Answer 75

Abnormality in cardiac function which is responsible for the failure of the heart to pump blood at a rate commensurate with the requirements of metabolising tissue
- Reduced CO

Question 76

What can affect the CO?

Answer 76

CO= HR x SV
Varies in response to physiological and pathological factors
- Preload- filling pressure
- Afterload- load the ventricle must eject
- Contractility
- Heart Rate

Question 77

What are the characteristic symptoms of HF?

Answer 77

Exercise intolerance
Dyspnoea
Fatigue (swelling)

Question 78

What is meant by the self perpetuating spiral of HF?

Answer 78

Phsyiological neurohormonal response attempts to compensate
Eventually will cause further pathology
1. Compromised cardiac function
2 ↓Arterial BP
3. Baroreceptor reflex
4. ↑Sympathetic outflow → α1- vasoconstriction and β1- ↑renin
5. ↑renin → ↑AngII → ↑aldosterone and vasoconstriction → Na+ retention → Intravascular volume expansion → ↑preload → ↑myocardial demand
6. Vasoconstriction → ↑afterload → ↑myocardial demand
7. Worsening HF

Question 79

How if HF managed?

Answer 79

• Usually caused by LV systolic dysfunction and associated LV ejection fraction (<45%)
• Correct underlying cause
• Non pharmacological management- ↓ salt intake, liquid retention - 1.5L- keep BP ↓ - ↓pressure on heart
• Addition of diuretic plus other therapeutic agents

Question 80

What are the aims of HF treatment?

Answer 80

• Reduction in symptoms (dyspnoea, fatigue, oedema)
• Managed ↑exercise tolerance
• Address arrhythmias, hyperlipidaemia and diabetes
• ↑quality of life and slow morbidity

Question 81

What treatments would you give?

Answer 81

1- Furosemide - loop diuretic → reduced BP and signs of volume overload
2- Lisinopril/ Ramipril - ACEi, Spironolactone- mineralocorticoid receptor antagonist (if symptoms continue), candesartan/losartan- ARB → reduce sympathetic output, vasodilation, reduced Na+ and H2O water retention, ↑bradykinin
3- Bisoprolol - β-blocker → Reduce remodelling and ↑systolic function

Question 82

When would spironolactone be used to treat HF?

Answer 82

Refractory hyperaldosteronism occurs

- Aldosterone escape- excessive RAAS despite ACEi and ARB and diuretic

Question 83

When are β-blockers used?

Answer 83

Counterintuitively 
Negative inotropic effect 
Reduce contractions- slow the heart 
- reduce damage caused by sympathetic activity 
- reduce β1 activity of renin 
- limit remodelling of cardiac tissue