Heart failure topic

Question 1

Definition of heart failure

Answer 1

Heart failure is a complex clinical syndrome of symptoms and signs that suggest the efficiency of the heart as a pump is impaired
- Having heart failure means that for some reason, your heart is
not pumping blood around the body as well as it used to.

Question 2

How does blood flow through the heart?

Answer 2

• Oxygen-poor blood from the body returns to the right atrium of the heart. Blood from the upper body returns through the superior vena cava. Blood from the lower body returns through the inferior vena cava.
• As the atrium is filled with blood, it contracts, the tricuspid valve opens and blood is pumped into the right ventricle
• When the right ventricle is filled, the tricuspid valve closes to prevent backflow of blood into the atrium.
• The right ventricle contracts, pulmonary valve opens and blood is pumped into the pulmonary artery and into your lungs
• The pulmonary valve closes to prevent backflow into the ventricles
• Oxygen rich blood from the lungs returns through the pulmonary veins to the left atrium of the heart. As the left atrium is filled with blood, it contracts, the mitral valve opens and blood is pumped into the left ventricle of your heart.
• This happens at the same time as the right atrium pumps blood into the right ventricle on the other side of the heart.
• As the left ventricle is full, the mitral valve closes, the left ventricle contracts and the aortic valve opens, the left ventricle contracts and oxygen- rich blood is pumped to the aorta to reach all parts of the body.
• This happens at the same time as the right ventricle pumps blood into the pulmonary artery on the other side of the heart.
• The aortic valve closes to prevent backflow back into the heart.
• Meanwhile the atria have filled with blood and the cycle repeats again.

Question 3

What are the causes of heart failure?

Answer 3

• ischaemic heart disease
• hypertension
• valve disease
• diabetes
• cardiomyopathies
• alcohol, drugs and pregnancy

Question 4

what does ejection fraction mean?

Answer 4

a measure of how well the heart is pumping. a measure of the amount of blood pumped out of the ventricle compared to the total amount of blood in the ventricle each time that the heart contracts

Question 5

what does a low ejection fraction mean?

Answer 5

the lower the ejection fraction, the worse the pumping ability of the heart. a normal EJ is around 60-70%. a person with HF their EJ is around 30%

Question 6

what does left ventricular systolic dysfunction mean

Answer 6

the heart contracts in the systole mode of the heart and if this is impaired, then this will be associated with reduced ejection fraction and reduced emptying of the heart.

Question 7

what is heart failure with preserved ejection fraction

Answer 7

– Impaired LV relaxation (diastolic)
– Preserved ejection fraction- impaired relaxation of the heart itself. So when you measure the ejection fraction of the heart it will appear normal
• Common in HTN particularly in the elderly (females) and other comorbidities such as AF, chronic obstructive airways disease, diabetes etc
• In these patients they may have all the signs and symptoms of heart failure but when you measure their ejection fraction, it is within normal range. This is known as heat failure with preserved ejection fraction

Question 8

what are the precipitants of heart failure

Answer 8

•	Non- compliance *
–	Medication- diuretics to manage the fluid overload, they may have stopped taking their disease modifying agents in patients with HfrEF
–	Fluid intake
•	Infection
–	E.g. Chest ( HR and demand on heart)
•	Arrhythmias
–	Tachyarrhythmia's (e.g. AF) –loss of atrial component to cardiac output
–	Bradyarrhythmias – rate too slow to provide enough cardiac output
•	XS Etoh / fluid
–	Fluid / Cardiomyopathy
•	Anaemia 
•	Check thyroid and renal function

Question 9

what are the signs of HF

Answer 9

•	Hypotension
•	Cold peripheries
•	Raised JVP
•	3rd heart sound
•	Lung crackles/ wheeze
•	Fluid retention
–	L-lung- becomes congested 
–	R-peripheral /ascites

Question 10

Definition of heart failure

Answer 10

the inability of the heart to meet the circulatory demands.
OR
The ability to do so only at abnormally high cardiac filling pressures. If you increase the amount of blood returning to the heart then the stroke volume and the cardiac output will increase. However for a given stroke volume, a failing heart requires much more blood to be returned to the ventricles than a healthy heart.

Question 11

what are the two classifications of heart failure

Answer 11

HFPED stands for heart failure with preserved with ejection fraction and HFREF stands for heart failure with reduced ejection fraction

Question 12

what is heart failure with preserved ejection fraction?

Answer 12

In patients who have heart failure with preserved ejection fraction have a normal ejection fraction range between 60-70%. they have heart failure because the volume of the ventricles is reduced. This is because the left ventricles muscles cells have become larger and there is marked fibrosis.
because the chamber the left ventricle is smaller the ventricle will hold less blood even though the ejection fraction is preserved

Question 13

what is heart failure with reduced ejection fraction?

Answer 13

with reduced fraction, the cross section of the ventricles is different. the ventricles are enlarged because lots of blood returning to the ventricles. but there is a dysfunction in the ability of the heart to contract . therefore there is less than 35% of blood returning to the ventricles

Question 14

what factors predisposes people to have reduced ejection fraction

Answer 14

being male, having a heart attack previously, having cardiac problems

Question 15

what factors predisposes people to have preserved ejection fraction

Answer 15

aging, prolonged untreated high blood pressure and diabetes

Question 16

what is the frank starling curve?

Answer 16

describes how the heart is able to move blood through the body in a regulated way by pumping out as much blood as it receives.
the law states that increased filling of the ventricles results in a greater contraction force and therefore a higher cardiac output
in Hf the mechanism fails as the ventricles is filled with blood to the point where the heart muscles contractions become less efficient.

Question 17

describe the intrinsic mechanism

Answer 17

This mechanism is important in allowing the heart to increase stroke volume in response to an increase in diastolic volume is based around the sensitivity of this protein Troponin C to calcium Muscles require calcium to contract and the calcium is involved in the contractile process because it binds to troponin C and when they bind, it pulls the protein tropomyosin out of the way because there is a change in troponin C and it pulls the myosin binding site out of the way
The actin and the myosin can interact and the muscle can contract

Calcium binding causes a confirmation or change which pulls tropomyosin away from the myosin binding site
As we increase the diastolic volume, troponin c is able to move this tropomyosin protein at increasingly lower concentrations of calcium. So by stretching the muscle fibres, sensitises troponin c to calcium. At far lower concentrations of intracellular calcium, the tropomyosin will be removed allowing contraction to occur.
- The whole process is sensitised by blood returning and stretching the ventricles

ANOTHER EXPLANTION
• At rest, when end-diastolic volume is relatively low, there is very little stretch on the muscle fibres in the ventricle and therefore sarcomere length is relatively short and has a high degree of overlap of the myosin and actin filaments in the heart myocytes
• If this heart muscle cell wanted to contract, it can only move a relatively small distance
• As we increase stroke volume, sarcomere length increases and we have a much larger distance that the muscle fibres can contract over
• The more blood that returns to the heart, the more it stretches the sarcomere and therefore the more contraction is possible, allowing the heart to pump out the same amount of blood that enters the heart
• Eventually, these muscle fibres get stretched far too much and therefore the degree of the overlap of the actin and the myosin will not be optimal and you will start to damage the fibres and they will start to lose their efficiency – so the stroke volume will eventually start to decline

ANOTHER EXPLANATION
At the beginning of the cardiac contraction cycle, calcium ions enter cardiomyocytes via L-type calcium channels, leading to further calcium release from the sarcoplasmic reticulum (SR). High concentrations of Ca2+ causes calcium binding to Troponin C, moving Troponin I out of the way of the actin-myosin binding site, allowing for an interaction between the two. The interaction between actin & myosin leads to force generation (muscle contraction). When the conc of Ca2+ drops, troponin returns to its standard conformation.

Actin-myosin filaments stretch when the heart fills with blood. The more these fibres stretch, the contraction of the heart becomes stronger, increasing stroke volume. However, if the fibres stretch too far, they break, and the heart fails to contract. With greater stretch of the fibres, Troponin becomes more sensitive to calcium; his means a smaller concentration of calcium illicit a response. the length of contraction & relaxation is longer, but the force of contraction is reduced. This means that the volume of blood that fills the right ventricle increases, but the stroke volume decreases. This leads to accumulation of blood, increasing the risk of thrombosis, pulmonary congestion a transient ischaemic event (TIA).

Question 18

Describe extrinsic mechanism?

Answer 18

RAS, sympathetic nervous system and natriuretic system

Question 19

Sign and symptoms of heart failure?

Answer 19

• Elevated pulmonary capillary wedge pressure is a marker to see how well gaseous exchange occurs.
• Crackles due to fluid build-up in the lungs.
• Wheezing and capillaries can be ruptured In the lung leading to blood in the sputum
• The patient is likely to be breathing faster than normal because of the lack of oxygen into the body. They can become restless and confused because of poor perfusion to the brain.
• They may have a faster heart rate than normal because the heart is beating harder because body is not getting the oxygen and nutrients it needs and also because the cardiac output is reduced and this will activate the barro receptors to drive the sympathetic system to cause tachycardia.

Question 20

causes of heart failure

Answer 20

• acute MI and associated cardiovascular risk factors (obesity, diabetes, cigarette smoking)
• hypertension
• valve disease
• cardiomyopathies (genetic)
• toxins (alcohol, cytotoxic; doxorubicin)
• viruses/bacteria (e.g. viral myocarditis HIV and SLE; systemic lupus erythematosus)
• Arrhythmias (AF)
• Right-sided failure: Chronic pulmonary problems (anything that will increase pulmonary blood pressure). If there is not enough oxygen in a tissue because of a mucus in the airway or because of a tumour, this will disrupt gaseous exchange. The bloods vessels in the airway clamp off or constrict so the blood supply to that damaged are is reduced and blood going to the lungs is redistributed to parts of the lung that are healthy and where gas exchange is happening naturally. But because you have constricted some parts of the vasculature, there is an increase in blood pressure in the lungs leading to damage to the RHS of the heart.

Question 21

how do you measure raised JVP

Answer 21

Vertical height from the sternal angle to the top of the pulsating column of blood in the internal jugular vein. 45 degrees. Measuring how high that jugular venous pulse is above the sternal angle. Around 6 cm in healthy and in HF is about 4cm

Question 22

what are the initial steps to diagnose HF?

Answer 22

signs and symptoms

• 2D doppler Echocardiography (ejection fraction <35%)
• raised JVP
• BNP levels >100pg/ml suggests heart failure. Levels >400pg/ml poor prognosis

Question 23

describe the sympathetic response to heart failure?

Answer 23

in the face of reduced cardiac output, the arterial baroreceptors located in the aortic arch and carotid sinus will sense changes in the blood pressure, leading to a release in norepinephrine and adrenaline that in turn stimulate the beta-1 receptors located in the SA node, myocardium and the ventricular conduction. stimulation of these receptors increases the heart rate and cardiac contractility leading to a greater stroke volume. when the heart rate and the stroke volume increase, the cardiac output will also increase to maintain adequate blood pressure and therefore perfusion of vital organs

Question 24

Describe the activation of renin angiotensin aldosterone system?

Answer 24

• In addition to the Renin-angiotensin system also gets activated when there is a decrease in cardiac output.
• Cardiac output is reduced which leads to a reduction in renal blood flow(barro-receptors in the renal artery) which will stimulate the release of renin from the juxtaglomerular cells.
• Renin will start to activate the RAS which leads to the production of angiotensin 2
• Angiotensin 2 can constrict veins through the action on the AT-1 receptors which is linked to the production of IP3 on the smooth muscles which drives calcium release which will cause the muscles to contract and the veins to constrict. This will increase preload and increase stroke volume and cardiac output.
• The RAS system through the actions of angiotensin 2 on the adrenal gland will release aldosterone. Aldosterone works on the distal convoluted tubules cells to increase the expression of ENaC in the luminal membrane and sodium-potassium ATPase in the apical membrane and as a consequence there is more salt and water retention.
• This will increase blood volume which will increase venous return and increase cardiac output
• Angiotensin 2 will also increase blood pressure by constricting arteries in the same way it constricts veins through the activation of AT-1 receptors and this will increase after load
• The direct effects of aldosterone and angiotensin and the effects of increased after load will lead to the remodelling of the heart by increasing the size of the heart muscle fibres and also there is an increase in the connective tissue that is present in the heart. This remodelling makes the heart less efficient.

Question 25

How does beta blockers work for the treatment of HF?

Answer 25

works by binding to the beta-1 receptors in the heart and blocking the action of norepinephrine therefore reducing heart rate and contractility thereby decreasing cardiac output and blood pressure. a decreased heart rate allows diastolic filling time so the stroke volume is not reduced.
- also via blocking the beta-1 receptors of the renal juxtaglomerular complex, certain beta blockers can also decrease the renin secretion, therefore reducing the severity of angiotensin 2 induced vasoconstriction as well as aldosterone

Question 26

Name 3 beta blockers used to treat HF

Answer 26

Bisoprolol , carvedilol, and metoprolol

Question 27

Describe how ACE inhibitors is used o treat HF?

Answer 27

drugs in this class selectively inhibits the angiotensin- converting enzyme which reduces angiotensin 2 production and its effect on vasoconstriction as well as ADH and aldosterone secretion.
in addition ACE inhibitors increases the levels of vasoactive peptide called bradykinin which is a vasodilator which is normally degraded by ACE. so when ACE inhibitor occurs while angiotensin levels drops bradykinin levels increases. as a result the blood vessels becomes dilated and total peripheral resistance reduces and blood pressure also decreases. this means the total effort for the the heart to pump blood around the body decreases.

Question 28

name 3 ACE inhibitors used to treat HF?

Answer 28

Ramapril, Lisinopril, Fosinopril, Captropril, Quinapril, Enalapril

Question 29

Describe how Angiotensin receptor blockers is used in the treatment of HF?

Answer 29

works in the same way as angiotensin pathway however instead of blocking the enzyme that drives angiotensin 2 production, ARBs work by binding to AT1 receptors located on vascular smooth muscle as well as other tissues such as heart directly blocking actions of angiotensin 2. as a result the effects are similar to ACE inhibitors by less vasoconstriction, less ADH and aldosterone secretion which will reduce the total peripheral resistance and therefore blood pressure is reduced.
because ARBs do not inhibit ACE they do not cause the bradykinin levels to increase

Question 30

name 3 ARBs for the treatment of heart failure

Answer 30

Losartan, Candesartan, Valsartan, Telmisartan

Question 31

describe how angiotensin receptor - neprilysin works for the treatment of HF?

Answer 31

despite being treated with ACE or ARBS many patients will continue to suffer with HF. As a result, increasing the beneficial natriuretic peptides may be good. neprilysin is an enzyme that degrades several endogenous vasoactive peptides including ANP, BNP and CNP. therefore terminating their positive actions, angiotensin receptor - neprilysin inhibitor simply combines angiotensin receptor blocker and neprilysin inhibitor to simultaneously block angiotensin 2 and inhibiting neprilysin enzyme therefore preventing the breakdown of natriuretic peptides

Question 32

name 2 angiotensin receptor neprilysin inhibitor used for the treatment of HF?

Answer 32

Valsartan and cubitril

Question 33

describe how loop diuretics is used in the treatment of HF?

Answer 33

in order to relieve symptoms of HF of volume overload loop diuretics are used. used to treat pulmonary congestion and peripheral oedema. it does this by inhibiting the luminal sodium-potassium-chloride transporter located in the thick ascending loop of henle where about 20-30% of the filtered sodium is managed. loop diuretics manages the reabsorption at a much greater proportion of sodium. the sodium is then excreted with the water that follows leading in a big decrease in plasma volume, cardiac overload and oxygen demand

Question 34

name 3 loop diuretics used for the treatment of HF?

Answer 34

furosemide, bumetanide and torsemide

Question 35

describe how Digoxin is used in the treatment of HF?

Answer 35

works by increasing the contractility of the cardiac muscle cells. does this by inhibiting the sodium potassium ATPase pump in cardiac muscle. this is responsible for moving sodium ions out of the cell and bringing potassium ions into the cell. as a result of this inhibition, when the sodium ions increase, the sodium-calcium exchanger pushes the excess sodium ions out while bringing additional calcium ions in. this causes an increase in the intracellular calcium which is available in the contractile proteins, therefore increasing the force of contraction and increasing cardiac output

Question 36

describe other treatments used in HF?

Answer 36

Ivabradine: Revise this from last year. Ivabradine is a HCN channel blocker and works by blocking the funny current so it reduces the frequency on the action potential in the SA node so reduces cardiac output. The slower frequency allows for more filling time of the ventricles and therefore cardiac output can hopefully be maintained. Used in patients where their heart rate is high.

Question 37

what are the symptoms when using digoxin for the treatment of HF?

Answer 37

• arrhythmias- bradycardia but if the levels of digoxin in the body is too high, then that increase in calcium ions inside of the cell causes late after depolarisation which can lead to tachycardia
• heart block

Question 38

describe the natriuretic peptide mechanism

Answer 38

• The natriuretic peptides are released in order to help the heart survive. The stimulus that causes their release is an increase in blood pressure. An increase in preload and increase in the volume of blood in the ventricles and how much the ventricles are being stretched
• When the RAS and the sympathetic system are activated, a lot of blood is returning to the heart and so there will be a lot of stretch in the ventricle walls.
• the natriuretic peptides are designed to prevent the walls of the ventricles from being overstretched.
• They work by dilating veins causing salt and water excretion. They are going to decrease pre load so they will decrease cardiac output. They also dilate arteries.
• Useful to reverse the modelling effects of the overstretching of the heart.
• These kick in under conditions of a natural stretch of the ventricles. Designed as a protective mechanism. Will only occur when the RAS and sympathetic system are overactive.

Question 39

what is remodelling

Answer 39

• When the muscle cells are becoming bigger. Occurs through the Renin-angiotensin aldosterone system.
• The muscle fibres increase inside and therefore decreases the volume of the ventricles so reduced cardiac output.
• The increased in size doesn’t match an increase in blood supply to these cells so the heart wouldn’t receive an efficient blood supply
• Fibrosis ( the laying down of lots of connective tissues and therefore the heart becomes less efficient in its ability to contract and relax and pump blood forward.
• As chamber of the heart muscle decreases the amount if blood volume that can pump through because there is a decreased volume of blood allowed to get through. This is also an issue for connective tissue

Question 40

what are some of the problems with prolonged compensation?

Answer 40

starlings law
desensitisation of beta receptors to reduce cAMP
• Increased angiotensin secretion leads to increased afterload can drive remodelling of the heart.
• Abnormally high levels of Noradrenaline /Adrenaline causes increases in heart rate (catecholamines) leads to arrhythmias
• Myocardial hypertrophy-

Question 41

what does starling law state

Answer 41

starling law (overstretch leads to loss of function)- if we increase activity in the RAS and sympathetic system more blood will be returning to the heart (good thing for shorty term ) however overtime stretches muscle fibres leads to loss of function.

Question 42

how does desensitisation of beta receptors cause problems

Answer 42

• Desensitisation of beta receptors (beta-1) to reduce cAMP. If you challenge them with adrenaline or noradrenaline. The receptor will be removed from the membrane and taken to the cell and so adrenaline and noradrenaline wouldn’t have anything to target. Similar mechanism if you keep taking inhaler you will desensitize the beta receptors because you are pumping adrenaline and noradrenaline.

Question 43

how does abnormally high levels of adrenaline and noradrenaline cause problems to the heart

Answer 43

• Abnormally high levels of Noradrenaline /Adrenaline causes increases in heart rate (catecholamines) leads to arrhythmias. Can cause ectopic beats through the actions of adrenaline on ion channels in the muscle cells. The muscle cells will be damaged and so there may be problems with the electrical signals so will be strange as pacemaker activity may increase. Increase in angiotensin and adrenaline and noradrenaline can increase the after load. Increasing after load makes the heart having to pump blood out into the systemic circulation and this can cause remodelling. Can also be caused from the direct effects of angiotensin and aldosterone of the heart

Question 44

what is myocardial hypertrophy and how does it affect the heart?

Answer 44

• Myocardial hypertrophy- cells becomes larger
– Make heart stiffer
– Muscle growth can decrease chamber size and so reduces volume of blood.

Question 45

what are the side effects of loop diuretics?

Answer 45

• Dehydration- by weight loss
• hypotension
• hypokalaemia- potassium loss
• hypomagnesaemia
• hyperuricaemia and gout- uric acid build up

Question 46

what are the side effects of ACE inhibitors?

Answer 46

• hypotension (6%)
• hyperkalaemia (6%) their ability to cause a diuresis means that there is a retention of potassium in the body. Can cause problems of arrhythmias and brain problems and cardiac tissue
• cough (40%)
• dizziness (50%) as it reduces blood pressure
• raised serum creatinine (0.2%) ace inhibitor will decrease kidney function. Need to monitor renal function.

Question 47

why do you add an ARB?

Answer 47

• ACE inhibitor therapy can lead to breakthrough due to increases in renin production and therefore Ang I.
• Other enzymes that convert Ang I to Ang II (chymase)
• If you block ACE and you stop producing/reduce the production of angiotensin 2, then the body notices by thinking you are not producing enough angiotensin 2 therefore the body will stimulate the production of renin to produce more angiotensin 1. Because ACE inhibitors are competitive antagonist, you can outcompete the inhibitor for the ACE enzyme with angiotensin 1. So get a delay in angiotensin 2 production

Question 48

what are the side effects of beta blockers?

Answer 48

• hypotension
• bradycardia
• peripheral vasoconstriction
• impotence
• bronchospasm
• Inverse agonists have negative efficacy

Question 49

Describe how vasodilators are used in the treatment of HF?

Answer 49

when a patient is intolerant to ACE/ARB which is usually due to renal impairment so the blood pressure can be controlled by vasodilators. isosorbide dinitrate releases nitric oxide into the vascular smooth muscle cells that activates GC, an enzyme that catalyses the formation of cGMP from GTP. increased intracellular cGMP which cause a chain reaction that decreases the calcium concentration and because calcium drives contraction this decrease will cause the SMC to relax and hence vasodilation.

Question 50

MoA of HYDRALAZINE?

Answer 50

is a vasodilator and works on the vascular smooth muscle which includes the stimulation of NO release from the vascular endothelium stimulating. cGMP production and decreasing calcium concentration, opening the potassium channels and inhibition of calcium ions release from the sarcoplasmic reticulum which all contribute to muscle relaxation and vasodilation.

Question 51

describe how aldosterone antagonist work for the treatment of HF?

Answer 51

they work by competitively blocking and binding of aldosterone to the mineral corticoid receptor therefore decreasing the reabsorption of sodium and water as well as decreasing the excretion of potassium leading to cardioprotective effects. these drugs are referred to as potassium sparing diuretics. examples includes Epierenone and spironolactone

Question 52

what is the role of spironolactone?

Answer 52

• added into conventional therapy
• attenuates aldosterone effect (Why needed)? Can drive cardiovascular remodelling so by blocking out aldosterone results in reducing hypertrophy of muscles fibres and reduces fibrosis. Also reduces some changes in ion channels that are expressed in a a failing heart.
• only small doses required

Question 53

what are the side effects of spironolactone

Answer 53

hyperkalaemia

• Gynaecomastia- male breast tissue development

Question 54

MoA of Ivabradine?

Answer 54

Ivabradine is a HCN channel blocker and works by blocking the funny current so it reduces the frequency on the action potential in the SA node so reduces cardiac output. The slower frequency allows for more filling time of the ventricles and therefore cardiac output can hopefully be maintained. Used in patients where their heart rate is high.

Question 55

Why is bioavailability of oral solution likely to be less than that of oral tablet?

Answer 55

• Due to the tablet dissolving slower than oral solution so therefore don’t get a high C max. there is a slow release with tablet. Because we have a higher C max with oral solution, you therefore get more metabolism and quicker excretion of our drug which results in a slightly lower bioavailability

Question 56

What if bioavailability of oral tablet was less than that of oral solution, what might cause this?

Answer 56

• Not all of the drug is being absorbed and therefore we get less drug into the bloodstream and therefore the bioavailability is lower
• If the tablet is compressed too hard it might not dissolve

Question 57

• When a drug in solution is injected intravenously it has good bioavailability but when it is taken orally (still in solution) the bioavailability is reduced.
• Why might this be the case?

Answer 57

When given IV form, the bioavailability is always 100% and when given orally there will be some degradation in the stomach or in the GI tract and not all of the drug might be dissolved or some of the drug may stay in the GI tract.

• Might get first pass metabolism, therefore removing some of the drug then that’s not available in the plasma for bioavailability.
• Not all the dosage form may have dissolved and so doesn’t get all absorbed

Question 58

Measurement of biopharmaceutical properties

Answer 58

1. Release of drug from its dosage form (dissolution)
2. Stability in physiological fluids
3. Permeability
4. Partition coefficients; Cell culture techniques; Tissue techniques; Perfusion studies
5. Pre-systemic metabolism- some happens in the gut wall

Question 59

BCS Class Boundaries

Answer 59

• Solubility:
– A drug substance is considered highly soluble when the highest dose strength is soluble in 250 mL or less of water over a pH range of 1–7.5 at 37 °C
• Permeability:
– A drug substance is considered highly permeable when the extent of absorption in humans is greater than 90% of an administered dose, based on mass-balance or compared with an intravenous reference dose
• Dissolution:
– A drug product is considered rapidly dissolving when 85% or more of the labelled amount of drug substance dissolves within 30 min using USP Apparatus 1 or 2 in a volume of 900 mL or less of buffer solutions

Question 60

Effect of disease on bioavailability: Chronic Heart Failure

Answer 60

•	CHF patients
–	Lower Cmax
–	Longer Tmax
–	CHF leads to a decreased ability to transport drug into urine compared to healthy subjects
–	Likely reasons
–	Delayed gastric emptying
–	Decreased GI motility
–	Decreased renal function
–	Bowel wall oedema associated with CHF

Question 61

thiazide diuretics

Answer 61

– Only used alone in v mild HF (usually for hypertension)
– Ineffective in poor renal function (eGFR <30ml/min)
– Monitor potassium, sodium, magnesium, calcium
– May exacerbate diabetes and gout
– Metolazone (discontinued /NP only)
– Alone is a weak diuretic
– Very potent when combined with loop

Question 62

what is capillary exchange

Answer 62

• The movement is driven by hydrostatic pressure and the osmotic pressure (pressure exerted by proteins that are present in the blood which will act to try and hold onto the fluid and stop it from leaving the capillary)
• If hydrostatic pressure is increased in the venous end then less fluid is going to be reabsorbed and less is going to be taken back into the capillary and the fluid that remains in the intracellular space and eventually gets into the alveoli is what causes pulmonary congestion, impaired gaseous exchange and difficulty breathing and shortness of breath.

Question 63

what are the signs and symptoms on the RHS for heart failure?

Answer 63

ascities
nocturia
pitting oedema
raised JVP

Question 64

what happens on the RHS of the heart in heart failure?

Answer 64

• if the RHS of the heart has failed , then blood returning to the heart will pull in the right ventricle, not much blood will be removed and more blood returns, pressure increases in the right ventricle which increases pressure in the right atrium, increases pressure in the vena cava that bring blood from the areas of the body above the heart (superior vena cava) and areas below the heart (inferior vena cava). Because of that build up in pressure in the heart, there is an increase I pressure in the capillaries in the abdomen which can cause ascites, nocturia, pitting oedema, and raised JVP.