Session 11- Heart failure

Question 1

What are the three key factors in determining stroke volume?

Answer 1

• Preload
• Afterload
• Contractility

Question 2

What are the two major groups of heart failure?

Answer 2

• Systolic dysfunction -> Decreased ejection fraction due to an abnormality of ventricular emptying
• Diastolic dysfunction -> Abnormalities of diastolic relaxation

Question 3

What are the two main causes of systolic dysfunction?

Answer 3

• Impaired myocardial contractility

- Excessive afterload

Question 4

What effect can loss of contractility have on myocytes?

Answer 4

• Destruction of myocytes
• Abnormal myocyte function
• Fibrosis

Question 5

How does afterload cause a decreased ejection fraction?

Answer 5

-Increased resistance to flow

Question 6

What effect does systolic dysfunction have on SV?

Answer 6

-Decreases it

Question 7

Why does the end diastolic volume increase in systolic dysfunction?

Answer 7

-Decreased ejection fraction -> Larger end systolic volume -> normal venous return added to increased ESV -> Increased end diastolic volume

Question 8

If the EDV is increased in systolic dysfunction, why does this not increase SV?

Answer 8

-The initial problem of decreased contractility/increased afterload is still present

Question 9

Why does pulmonary congestion and oedema occur in left systolic dysfunction?

Answer 9

-Increased EDV -> Increased pressure in LV -> increased pressure in LA -> increased pressure in pulmonary veins and capillaries -> increased hydrostatic capillary pressure -> transudate moves into pulmonary interstitium ->Pulmonary oedema and congestion

Question 10

What are the common causes of diastolic dysfunction?

Answer 10

• Impaired diastolic dysfunction haha

- Increased stiffness of ventricular wall

Question 11

What type of injury would cause impaired relaxation and stiffness?

Answer 11

-Acute myocardial infarction leading to fibrosis and scar tissue

Question 12

Why is the RV susceptible to damage caused by sudden increases in afterload?

Answer 12

-Thin walled chamber which is used to pumping blood against a low pulmonary vascular resistance

Question 13

What is the most common cause of RHF?

Answer 13

-LHF which increases pulmonary resistance and thus the af-terload of- the RV

Question 14

Besides LHF, what is the most common cause of isolated RHF?

Answer 14

-Increased afterload due to diseases of the lung parenchyma or pulmonary vasculature eg lung disease, pulmonary hypertension, valvular disease

Question 15

What effects and why does RHF directly have effect on the systemic system? (not compensatory mechanisms)

Answer 15

-Increased pressure in RV due to high afterload -> increased pressure in RA and congestion due to higher pressure in RV -> congestion of systemic veins -> increased hydrostatic pressure causes oedema -> hepatomegaly as first organ back and liver becomes saturated with blood -> possible ascites due to increased hydrostatic pressure

Question 16

How does starlings law participate in compensatory mechanisms of systolic dysfunction LHF? What are its limitations?

Answer 16

• Decreased ejection fraction -> SV decreased -> normal venous return adds to increased ESV -> increased end diastolic volume -> causes the heart to contract harder as preload is greater increasing SV
• In severe HF with a great decrease in contractility of the heart, the heart cannot eject anymore blood than the maximum it can, despite increasing EDV

Question 17

What are the three main compensatory neurohormonal mechanisms activated in response to decreased CO?

Answer 17

• The sympathetic nervous system
• Renin-Angiotensin-Aldosterone System
• Increased ADH

Question 18

What effect do compensatory mechanisms have on vascular resistance and why?

Answer 18

-Increase vascular resistance in order to maintain arterial bloodf-low and thus perfusion to the tissues as bp=COxTPR and if CO is decreased then TPR needs to be raised

Question 19

What is compensatory heart failure?

Answer 19

-When the fall in SV, however decreased CO is counteracted by an increase in HR and an increase in TPR through compensatory mechanisms, so the impairment is asymptommatic or mild

Question 20

What overall effect do compensatory mechanisms have on sodium and water retention and why does this occur?

Answer 20

-Increase Na and H2O retention in order to increase blood volume and thus increase BP and also increase SV through starling’s law of filling of the heart

Question 21

What two organs sense a fall in CO and how?

Answer 21

• Brain through baroreceptors in carotid sinus and aortic arch
• Kidney through juxtaglomerular apparatus

Question 22

What leads to the activation of SNS after a fall in CO?

Answer 22

• Baroreceptors in carotid sinus and aortic arch detect fall in CO and decrease their firing rate to the medulla
• Causes an increase in sympathetic outflow and diminish in parasympathetic

Question 23

What are the immediate consequences of increasing SNS in LHF?

Answer 23

• Increase in HR
• Increase in ventricular contractility
• Vasoconstriction of vessels through af-adrenoreceptors

Question 24

What is the reason for activating the SNS in LHF?

Answer 24

• Counteract fall in CO by increasing HR and force

- Increase TPR through vasoconstriction to maintain bp

Question 25

Why is venoconstriction helpful in HF?

Answer 25

-Less capacitance in veins -> higher venous return to heart -> f-rank starlings law

Question 26

What mediates the RAAS?

Answer 26

-Release of renin

Question 27

Where is renin secreted from?

Answer 27

-Juxtaglomerular cells of the kidney

Question 28

What causes secretion of renin?

Answer 28

• Decreased renal artery perfusion pressure secondary to low CO
• Direct stimulation of JGA by SNS through b2-adrenoreceptors

Question 29

What is the function of renin?

Answer 29

-Cleaves circulating angiotensinogen to angiotensin I

Question 30

What happens to angiotensin I when synthesised?

Answer 30

-Rapidly converted to angiotensin II through proteolytic cleavage by ACE

Question 31

What are the main functions of angiotensin II?

Answer 31

• Vasoconstrictor which increases TPR to maintain bp
• Increase intravascular volume through stimulating thirst receptors in hypothalamas and stimulating the adrenal cortex to increase aldosterone secretion to increase Na retention by the kidney and thus increase water reabsorption

Question 32

Where does aldosterone promote sodium reabsorption?

Answer 32

-Distal convoluted tubule

Question 33

What is the benefit of increasing intravascular volume in LHF?

Answer 33

-Maintain bp and increase CO through starlings law

Question 34

Where is ADH (vasopressin) secreted from?

Answer 34

-Posterior pituitary

Question 35

What causes increased ADH secretion in HF?

Answer 35

-Baroreceptors detect fall in BP and relay to brain

Question 36

Why is increased secretion of ADH beneficial in HF?

Answer 36

• Increases thirst
• Increases aquaporin channels means increased water retention
• Increased blood volume
• Maintains BP and starlings law increases CO

Question 37

What are the consequences of chronic activation of RAAS?

Answer 37

-Increasing intravascular volume -> initially increases EDV which tries to increase SV, however this increases pressure in chambers causing the pressure in the previous system to increase leading to oedema
ie in LHF, increased pulmonary capillary hydrostatic pressure = oedema
in RHF, increased systemic congestion and hydrostatic pressure leading to peripheral oedema and hepatosplenomegaly and ascites

Question 38

What causes activation of brain and kidney compensatory mechanisms in RHF?

Answer 38

-Decreased ejection fraction from RV -> decreased pulmonary flowf-> decreased filling of LV -> decreased CO f-> fall in bp detected by baroreceptors causing activation of SNS and ADH secretion -> reduced flow to JGA causes activation of RAAS, in addition to SNS acting on b-adrenoreceptors

Question 39

What effect does chronic activation of SNS have in LHF?

Answer 39

• Chronic vasoconstriction increases the afterload which the already failing left ventricle has to contract against, may therefore decrease SV further
• Increased HR increases metabolic demand of heart which can further reduce contractility
• Continuous exposure to NA results in downregulation of b-adrenoreceptors and upregulation of inhibitory g-proteins resulting in a negative inotropic response

Question 40

What are the two types of natriuretic peptide?

Answer 40

• Atrial natriuretic peptide

- B-type natriuretic peptide

Question 41

What causes the release of ANP?

Answer 41

-Atrial distention

Question 42

When is BNP produced?

Answer 42

-When ventricular myocardium is subjected to haemodynamic stress eg in heart failure or MI

Question 43

What are the functions of natriuretic peptides?

Answer 43

Ultimately oppose compensatory mechanisms

• Excretion of Na and water
• Vasodilation
• Inhibition of renin secretion
• Antagonists of angiotensin effects on aldosterone and ADH

Question 44

What are possible causes of impairment of ventricular dysfunction in HF?

Answer 44

• Loss of myocytes from cellular necrosis (Ischaemic heart disease MI/CAD)
• Impaired function of living myocytes through mechanical wall stress resulting in dilation of the wall leading to mechanical and electrical uncoupling
• Impaired function of myocytes through altered expression of contracile proteins by inflammatory cytokines

Question 45

What are the common factors which precipitate compensated or asymptomatic HF to develop into a clinical manifestation?

Answer 45

• Increased metabolic demand and thus cardiac workload eg fever, infection, anaemia, exercise
• Increasing preload -> diet high in Na, excess fluid
• Increasing afterload -> hypertension
• Conditions which impair contractility -> MI, negative inotropic meds

Question 46

How would a tachyarrhythmia precipitate HF?

Answer 46

-Decreased diastolic ventricular filling and increased myocardial O2 demand

Question 47

What is the most common clinical manifestation of LHF?

Answer 47

-Breathlessness on exertion

Question 48

What causes breathlessness in LHF?

Answer 48

• Pulmonary oedema results in reduced pulmonary compliance due to compression of the walls of the bronchi and alveoli, increasing the resistance to airflow, and the reduction in the available number of- alveoli
• Reduced blood flow to overworked respiratory muscles lead to atrophy

Question 49

What effect does HF have on skeletal muscle?

Answer 49

• Decreased CO -> decreased tissue perfusion -> atrophy of skeletal muscle including diaphragm
• Fatigue and weakness

Question 50

Why would HF cause dulled mental status?

Answer 50

-Decreased cerebral perfusion

Question 51

Why would HF cause impaired urine output?

Answer 51

-Decreased renal perfusion -> high pressure not maintained and needed for glomerular filtration

Question 52

Why would nocturia happen in HF?

Answer 52

-Bloodflow to kidney re-established when supine, promoting renal perfusion and diuresis

Question 53

Why does hepatomegaly occur in RHF?

Answer 53

-Liver becomes engorged with blood

Question 54

Why does nausea and anorexia occur in RHF?

Answer 54

-Oedema within the gastrointestinal tract

Question 55

Why would a patient with RHF gain weight despite having a decreased appetite?

Answer 55

-Accumulation of interstitial fluid due to systemic congestion and RAAS/ADH

Question 56

Why do pateints with severe HF appear cachexia?

Answer 56

-Poor appetite and metabolic demands of increased effort in breathing

Question 57

Why would a patient appear diaphoretic?

Answer 57

-Sweating due to increased SNS-> activation of sweat glands

Question 58

Why are the extremities of patients with uncompensated LHF often cool?

Answer 58

-Chronic vasoconstriction of the peripheries

Question 59

Why can sinus tachycardia occur in HF?

Answer 59

-Increased sympathetic NS

Question 60

Why does crackling in the lungs occur with HF?

Answer 60

-Pulmonary oedema -> air bubbling through fluid

Question 61

Why can wheezing occur in HF?

Answer 61

-Narrowed airways due to oedema

Question 62

What are causes of increased afterload which can precipitate LHF?

Answer 62

• Hypertension
• Atheroscleosis
• Aortic stenosis
• Hypertension

Question 63

What are causes of increased preload which can precipirate LHF?

Answer 63

• Mitral regurgitation

- Aortic regurgitation

Question 64

What is heart failure?

Answer 64

-The inability of the heart to pump blood at a sufficient rate to meet the metabolic demands of the body

Question 65

What is high-output HF?

Answer 65

-The demand of- the body outweighs the hearts ability

Question 66

Briefly describe the classes of HF

Answer 66

• Class i-> asymptommatic
• Class ii-> Slight limitation to physical activity
• Class iii-> Marked limitation of physical activity
• Class ivf-> inability to carryout physical activity without symptoms, possible symptoms at rest

Question 67

How is the pulmonary and systemic vascular congestion treated in HF?

Answer 67

• Fluid restriction
• Dietary Na restriction
• Diuretics

Question 68

What groups of drugs are used to increase CO and tissue perfusion?

Answer 68

-Vasodilators and positive inotropic drugs

Question 69

Describe the structural changes in the heart after an MI

Answer 69

• Necrosis and scarring
• Heart remodels around scar as it is thin and weak
• Heart becomes asymmetrically dilated

Question 70

Why is the mitral valve effected in systolic dysfunction?

Answer 70

-LV becomes dilated and the valve becomes incompetent as it does not close tightly

Question 71

Describe the structural changes which occur in the heart in diastolic and systolic HF

Answer 71

• Heart undergoes hypertrophy due to increased workload

- Overtime the muscle wears which results in dilation and thinning in a symmetrical manner

Question 72

Why does contraction become uncoordinated and abnormal in HF?

Answer 72

• Muscle damage results in loss of muscle and dilation
• This decreases mechanical and electrical coupling resulting in uncoordinated contraction
• ECM increases in collagen and myocardial fibre orientation slips

Question 73

What receptor does Aii cause the compensatory mechanisms through?

Answer 73

-AT1R

Question 74

What is the effect of- angiotensin II acting on AT2R?

Answer 74

-Increased nitric oxide production which is a vasodilator

Question 75

List some signs and symptoms of LHF

Answer 75

• Breathlessness (dyspnoea)
• Fatigue
• Tachycardia
• Cardiomegaly (displaced apex beat)
• Functional murmur of mitral regurgitation
• Peripheral oedema
• Basal pulmonary crackles

Question 76

What are the signs and symptoms of RHF?

Answer 76

• Fatigue
• Dyspnoea
• Anorexia and nausea
• High JVP
• Hepatomegaly and ascites
• Pitting odema

Question 77

List the common pharmacological treatments of HF

Answer 77

• Diuretics -> reduce blood volume
• ACE inhibitors -> inhibit angiotensin ii -> decrease blood vol and vasoconstriction
• Nitrates -> vasodilator to reduce afterload
• B-blockers -> decrease HR and f-orce of- contraction to decrease metabolic demand

Question 78

What is the known side effect of an ACE inhibitor?

Answer 78

-Dry cough due to blocked effect of bradykinin