Cardiovascular System

Question 1

What are the two circuits of the cardiovascular system?

Answer 1

Pulmonary and systemic

Question 2

What are the differences in resistance and pressure between the pulmonary and systemic circuit?

Answer 2

Pulmonary: Medium resistance and medium pressure
Systemic: High resistance and high pressure

Question 3

What is special about the the liver?

Answer 3

It has a dual supply of blood. One supply is from the gut via the hepatic portal vein. One supply is from the systemic arteries.

Question 4

What percentage of blood volume is in each of the pulmonary circuit, heart and systemic circuit?

Answer 4

Pulmonary: 9%
Heart: 7%
Systemic: 84%

Question 5

Where does most blood sit?

Answer 5

In the systemic veins

Question 6

Why is an outlet valve essential for a ventricle?

Answer 6

When the ventricle is filling, it prevents arterial blood from returning to the pump.

Question 7

Why is an inlet valve necessary?

Answer 7

To prevent high-pressure blood in the pumping chamber from returning to the veins.

Question 8

What are the two phases that ventricles undergo?

Answer 8

Filling phase

Ejection phase

Question 9

What is an atrium? What is its purpose?

Answer 9

A reservoir upstream of the pump. During the ejection phase, it accumulates venous blood which can enter the ventricle quickly during the filling phase.

Question 10

Why is it advantageous for the inlet and outlet of the ventricle lie close together?

Answer 10

The walls of the pumping chamber can shorten in length as well as in width.

Question 11

How does an appendage (auricle) improve the heart?

Answer 11

Increases the capacity of the atrium.

Question 12

How are the two ventricles separated?

Answer 12

Anterior and posterior interventricular sulcus

Question 13

What is the heart’s job?

Answer 13

To repressurise blood.

Question 14

What are the peak pressures of the left and right atrium and ventricle?

Answer 14

Right atrium: 5 mmHg
Left atrium: 8 mmHg
Right ventricle: 27 mmHg
Left ventricle: 120 mmHg

Question 15

What are the names of the valves between the left atrium and ventricle and the right atrium and ventricle?

Answer 15

Left atrium and ventricle: Mitral/bicuspid valve

Right atrium and ventricle: Tricuspid valve

Question 16

What is below each valve to hold it in place?

Answer 16

Chordae tedineae

Papillary muscle

Question 17

Are atria effective pumps?

Answer 17

NO

Question 18

What type of tissue are valves made from?

Answer 18

Fibrous connective tissue

Question 19

What are the Chordae tendineae?

Answer 19

Tendinous cords which tether the atrioventricular valves, thus preventing them from bursting upwards into the atrium during systole.

Question 20

What is another name for atrioventricular valves?

Answer 20

Ventricular inlet valves

Question 21

What forms the core of the heart?

Answer 21

The left ventricle

Question 22

What are the open ends of the ventricles each subdivided into?

Answer 22

An inlet and outlet.

Question 23

What must be the diameter of the inlets? Why is this?

Answer 23

Must be of a large diameter in order to admit blood at low pressure

Question 24

Why do the outlets have a small diameter?

Answer 24

Blood leaves the ventricles at high pressure

Question 25

What are the names of the inlet and outlet valves?

Answer 25

Inlet: triscuspid (right) and mitral/bicuspid (left)
Outlet: pulmonary (right) and aortic (left)

Question 26

What shape is the pathway taken by blood through the ventricles?

Answer 26

Y-shaped

Question 27

What is the ratio of the peak pressure of the LV:RV? Compare this to the ratio of the wall thickness.

Answer 27

5: 1
3: 1

Question 28

How many cusps does the pulmonary valve have?

Answer 28

3

Question 29

How are outlet valves sometimes described?

Answer 29

Semilunar

Question 30

What is the difference between the appearance of the aortic and pulmonary valves?

Answer 30

We would see the openings of the coronary artieries near the aortic valve.

Question 31

What is the structure of inlet valves?

Answer 31

Cusps are flat flaps with their free edges restrained by cords.

Question 32

Describe the structure of outlet valves.

Answer 32

Shaped like a small pocket and lack cords.

Question 33

What happens when the outlet valves are inflated with blood?

Answer 33

They gain strength from the 3D shape.

Question 34

When are the outlet valves in the open position?

Answer 34

Ventricular ejection

Question 35

What word do we use to describe the lack of energy required for outlet valve opening and closure?

Answer 35

Passive

Question 36

When is the outlet valve in the closed position? Why does it close?

Answer 36

Ventricular filling - The pressure of blood trying to re-enter the ventricle forces the free edges of the cusps tightly together. The superior lip is then pressed against the neighbouring valve leaflets.

Question 37

In what direction does the apex of the heart point?

Answer 37

Inferiorly, anteriorly and to the left

Question 38

What proportion of the mass of the heart lies to the right of the midline of the body?

Answer 38

One third

Question 39

What is the right border of the heart mainly formed by?

Answer 39

The right atrium

Question 40

What is the inferior border of the heart mainly formed by?

Answer 40

The right ventricle

Question 41

What is the left border of the heart mainly formed by?

Answer 41

The left ventricle

Question 42

What is the heart enclosed in?

Answer 42

A double walled bag - pericardium

Question 43

What are the inner and outer walls of the pericardium made of?

Answer 43

A single layer of squamous mesothelial cells.

Question 44

Where are the two walls of the pericardium continuous?

Answer 44

Where the great vessels enter and leave the heart.

Question 45

What are the names of the two walls that the pericardium is made up of?

Answer 45

Inner: visceral pericardium
Outer: parietal pericardium

Question 46

What is another name for the visceral pericardium?

Answer 46

Epicardium

Question 47

What is found within the pericardial space?

Answer 47

Serous fluid

Question 48

What is the purpose of the serous fluid?

Answer 48

Allows the parietal and visceral surfaces to slide without friction as the heart beats.

Question 49

What are the layers of the pericardium?

Answer 49

Fibrous Pericardium
Parietal pericardium
Pericardial space
Visceral pericardium

Question 50

What are the layers of the heart wall?

Answer 50

Epicardium
Myocardium (cardiac muscle)
Endocardium
Inside ventricle (blood)

Question 51

Which layer of the heart wall and the pericardium overlap?

Answer 51

Epicardium/visceral pericardium

Question 52

What are the functions of the fibrous skeleton?

Answer 52

Supports and anchors the valve leaflets to the heart wall and acts as electrical insulation.

Question 53

How fast is the conduction from the SA node to the atrial muscles? What is the result of this?

Answer 53

0.5 m/s (slow)

Atrial contraction

Question 54

What occurs when the electrical impulse reaches the AV node? What is the speed of conduction through the AV node?

Answer 54

0.05 m/s

100 ms delay

Question 55

How fast is the conduction from the AV bundle to the Purkinje fibres? What is the result of this?

Answer 55

5 m/s

Even contraction of ventricle - systole

Question 56

How is the right side of the heart different to the left?

Answer 56

It is similar but pressures are much lower.

Question 57

What are the steps of the cardiac cycle?

Answer 57

Ventricular filling, atrial contraction, isovolumetric ventricular contraction (systole), ventricular ejection, isovolumetric ventricular relaxation

Question 58

When does ventricular filling begin? What happens during this phase?

Answer 58

Phase commences as pressure in the ventricle drops below that in the atrium. The mitral valve opens quietly and blood enters the ventricle. The ventricle will fill to about 80% of its capacity during this phase. Diastole

Question 59

Which phase is the longest phase and takes up half the cycle?

Answer 59

Ventricular filling

Question 60

What occurs during atrial contraction? What is this stimulated by?

Answer 60

The left atrium contracts to complete the filling of the ventricle. Stimulated by SA node

Question 61

Why is the atrial pressure small?

Answer 61

1) Muscle layer is thin
2) There are no valves where the pulmonary veins enter the atrium and therefore nothing to prevent backflow into the veins.

Question 62

What happens to our atria as we get older? Does this affect us very much?

Answer 62

Atria flutter instead of contracting. No significant effect because a small amount of blood is topped up in the atria.

Question 63

What happens during isovolumetric ventricular contraction?

Answer 63

Systole. The ventricle begins to contract. Blood within it lifts backwards towards the atrium and the mitral valve closes. Ventricular pressure is still below that in the aorta so the aortic valve remains closed.

Question 64

What is the first heart sound caused by?

Answer 64

When the blood within the ventricle lifts backwards towards the atrium and the mitral valve closes during isovolumetric ventricular contraction.

Question 65

During what phases is the ventricle isolated from the rest of the circulation for a brief period, with its inlet and outlet valves closed?

Answer 65

During isovolumetric ventricular contraction (systole) and relaxation

Question 66

What is the first heart sound called?

Answer 66

Lub sound

Question 67

Compare the pressure differences between the atria, ventricles, and arteries during ventricular contraction.

Answer 67

Atrial pressure is less than ventricle pressure (increasing), which is less that arterial pressure.

Question 68

What happens during ventricular ejection?

Answer 68

Systole continues, but now ventricular pressure exceeds aortic pressure and the aortic valve cusps open quietly. Blood leaves the ventricle.

Question 69

Why does the pressure in the ventricle and aorta continue to rise steeply during ventricular ejection until later.

Answer 69

Blood is ejected into the aorta faster than it can run-off into the distributing arteries. Later in the phase, the rate of ejection falls below the rate of run-off and aortic and ventricular pressures level-off and then begin to decrease.

Question 70

What happens during isovolumetric ventricular relaxation?

Answer 70

The ventricle relaxes. As it does so, ventricular pressure drops suddenly, flow reverses in the aorta and the aortic valve closes as blood tries to reenter the ventricle.

Question 71

What causes the second heart sound?

Answer 71

When flow reverses in the aorta and the aortic valve closes as blood tries to re-enter the ventricle during ventricular relaxation.

Question 72

What is the name of the second heart sound?

Answer 72

Dub sound

Question 73

Why is the dub sound higher pitched than the lub sound?

Answer 73

The valve closes over a smaller hole.

Question 74

How long do ventricular contraction and releaxation last for?

Answer 74

0.05 s

Question 75

Compare the pressure between the atria, ventricles and arteries during ventricular relaxation.

Answer 75

Atrial pressure is less that ventricular pressure (decreasing), which is less than arterial pressure

Question 76

Why are there two dub sounds?

Answer 76

Aortic valve closes just before the pulmonary. Blood tries to return into the LV faster than to the RV.

Question 77

What is the conduction pathway of the heart?

Answer 77

SA node -> Atrial muscle -> AV node -> AV bundle -> Purkinje fibres

Question 78

What are elastic arteries? What do they do during systole and diastole? What does this result in?

Answer 78

Very large arteries which have elastic walls. They expand during systole to store the bolus of blood leaving the ventricle. During diastole, they push blood out into the arterial tree by elastic recoil.They smooth out the pulsatile flow of blood leaving the ventricles.

Question 79

What is the structure of elastic arteries?

Answer 79

Many thin sheets of elastin in the middle tunic.

Question 80

What is the size of elastic arteries?

Answer 80

Finger sized

Question 81

What is the size of muscular arteries?

Answer 81

Pencil -> pin

Question 82

What are the functions of muscular arteries?

Answer 82

Distribute blood around the body at high pressure (and lungs at medium pressure).

Question 83

How is rate of blood flow adjusted by muscular arteries?

Answer 83

By using smooth muscle to vary the radius of the vessel.

Question 84

What is flow proportional to in the muscular arteries? What does this imply?

Answer 84

The fourth power of radius

A small change in radius has a large effect on flow rate.

Question 85

What is the structure of muscular arteries?

Answer 85

Many layers of circular smooth muscle wrapped around the vessel in the middle tunic.

Question 86

What are the three layers of muscular artery walls?

Answer 86

Tunica externa
Tunica media
Tunica interna (intima)

Question 87

What is the size of arterioles?

Answer 87

Hair sized

Question 88

What is the function of arterioles?

Answer 88

Controls blood flow into capillary beds.

Question 89

What is special about arteriole walls?

Answer 89

They have a thicker muscular wall relative to their size than any other blood vessel.

Question 90

Where are arterioles found in the body?

Answer 90

In the circulation where the greatest pressure drop occurs, where there is the greatest resistance to flow.

Question 91

What does the degree of constriction of arterioles throughout the body determine?

Answer 91

Total peripheral resistance, which in turn affects mean arterial blood pressure.

Question 92

What is the structure of arterioles?

Answer 92

Between one to three layers of circular smooth muscle wrapped around the vessel in the middle tunic.

Question 93

What do arteries often travel alongside?

Answer 93

Their companion veins.

Question 94

What are the differences between artery and vein walls?

Answer 94

Arteries have much bigger walls but a smaller lumen.

Question 95

How large are capillaries?

Answer 95

Size of a red blood cell

Question 96

What are the functions of capillaries to the thinness of their walls?

Answer 96

Allows exchange of gases, nutrients and wastes between blood and the surrounding tissue fluid.

Question 97

Is blood flow fast or slow through capillaries? What does this allow for?

Answer 97

Slow

Allows time for exchange to occur

Question 98

Capillaries are ______ vessels. ______ escapes but not ___ ______ _____.

Answer 98

Leaky
Plasma
Red blood cells

Question 99

How is most of the lost plasma immediately recovered?

Answer 99

Due to the osmotic gradient

Question 100

What is the structure of capillaries?

Answer 100

Diameter just wide enough to admit one RBC. Capillary walls is a single layer of endothelium with an external basement membrane.

Question 101

What is not present in capillary walls?

Answer 101

Smooth muscle (so no ability to adjust diameter) 
Connective tissue

Question 102

What is another name for tissue fluid?

Answer 102

Interstitial fluid

Question 103

What drives tissue fluid out of capillaries?

Answer 103

Hydrostatic pressure

Question 104

What type of tissue are WBC’s?

Answer 104

Connective tissue

Question 105

What are venules?

Answer 105

Low-pressure vessels which drain capillary beds.

Question 106

Where do white blood cells leave the blood circulation? When do they leave? What do they then do?

Answer 106

Venules
During infection and inflammation
To attack bacteria in the tissue alongside.

Question 107

Compare the structures of small and large venules?

Answer 107

Small venules: endothelium, connective tissue.

Larger venules: endothelium, connective tissue, single layer of smooth muscle.

Question 108

What is the function of veins?

Answer 108

Drain blood back to the atria, except portal veins which drain blood to another capillary bed.

Question 109

Describe the walls of veins.

Answer 109

Thin and soft. They stretch easily (compliant) Similar to a muscular artery but much thinner walled for their size. Have much less muscle and connective tissue.

Question 110

A small change in venous blood pressure results in a ________ change in venous volume.

Answer 110

Larger

Question 111

What do veins act as?

Answer 111

A reservoir which stores blood.

Question 112

What percentage of blood volume occurs in systemic veins and venules?

Answer 112

64%

Question 113

What percentage of blood volume occurs in systemic arteries and arterioles?

Answer 113

13%

Question 114

Why are there valves in larger veins?

Answer 114

They prevent backflow. As muscles alongside the vein alternately contract and relax during walking, the system acts as a venous pump which returns blood to the atrium.

Question 115

Where do coronary arteries arise from?

Answer 115

From the aorta just downstream from the aortic valve

Question 116

What do muscle coronary arteries supply?

Answer 116

Supply the muscle of the heart (myocardium)

Question 117

When does significant obstruction to blood flow through a coronary artery occur?

Answer 117

When it is narrowed to about 20% of its normal cross section by atheroma.

Question 118

What is ischaemia?

Answer 118

When the myocardium supplied by the diseased coronary artery runs low on oxygen (especially during exercise).

Question 119

What is angina?

Answer 119

Chest pain

Question 120

What does severe ischaemia result in?

Answer 120

Infarction (death) of a local area of the myocardium.

Question 121

What are anastomoses?

Answer 121

Artery-to-artery junctions

Question 122

How can the heart adjust to ischaemia?

Answer 122

Anastomoses between small penetrating branches of the main coronary arteries widen slowly so that an ischaemic area of muscle can be supplied by a distant artery.

Question 123

What is deoxygenated blood from the myocardium drained by?

Answer 123

Cardiac veins

Question 124

Where do cardiac veins return blood to?

Answer 124

Right atrium

Question 125

What is meant by idiopathic?

Answer 125

Unidentifiable cause

Question 126

The cause of dilated cardiomyopathy is _________, but is probably a _______ __________ in many cases?

Answer 126

Unidentified

viral infection

Question 127

What are infected muscle fibres attacked by? What happens after they are attacked?

Answer 127

Lymphocytes

Many die, others are left weakened and slow to contract. Makes muscle fibres longer.

Question 128

What is meant by dilated cardiomyopathy?

Answer 128

Heart muscle disease

Question 129

Which ventricle is most affected in dilated cardiomyopathy?

Answer 129

Left ventricle most affected because of high pressure. It dilates - chamber enlarged, wall thickness normal or slightly increased.

Question 130

What happens to the fibrous ring supporting mitral valve during dilated cardiomyopathy? How does this cause mitral regurgitation

Answer 130

It stretches so that mitral valve flaps no longer meet during systole, causing mitral regurgitation.

Question 131

After LV dilatation, what happens to the ratio of wall thickness between the left and right ventricle?

Answer 131

Remains the same at 3:1

Question 132

What is the dilatation of the ventricle due to? What happens during systole?

Answer 132

The lengthening of cardiac muscle fibres.

During systole, blood regurgitates from the left ventricle to the left atrium.

Question 133

What is the Law of LaPlace?

Answer 133

Pressure is inversely proportional to radius

Question 134

What is the dilatation of the left ventricle known as?

Answer 134

Mitral incompetence

Question 135

Which heart sound is affected by mitral regurgitation?

Answer 135

The first heart sound is longer

Question 136

What is different about the mitral regurgitation cardiac cycle?

Answer 136

Lower max pressure reached by ventricles

Greater pressure reached by atrium as ventricles filled.

Question 137

What happens to the ventricle between S1 and S2?

Answer 137

Ejection

Question 138

What happens to the ventricle between S2 and S1?

Answer 138

Filling

Question 139

Why does a problem on the left (systemic) side of the heart cause symptoms in the right (pulmonary) circuit?

Answer 139

To maintain CO, LV must pump a greater volume. In order to fill the ventricle, LA works harder, so LA pressure increases. Pulmonary venous pressure increases, pulmonary capillary pressure increases, and this leads to increased capillary leakage.

Question 140

What are the consequences of increased capillary leakage?

Answer 140

Lungs get heavier, wetter, and more rigid. Breathing requires more muscular work. This is called Dyspnoea.

Question 141

What is Dyspnoea?

Answer 141

Discomfort during breathing, consciousness of laboured breathing.

Question 142

What is the cycle of mitral regurgitation?

Answer 142

LV dilatation -> Mitral valve ring stretches -> Increased mitral regurgitation -> Volume load on LV -> LV dilatation

Question 143

How can mitral regurgitation be treated?

Answer 143

Valve replacement or heart replacement

Question 144

What function does the heart serve?

Answer 144

To supply based on demand

Question 145

What does the cardiac cycle include?

Answer 145

All events associated with one heart beat, forcing areas of high pressure to low pressure.

Question 146

Which receptors can notify the body that demand will increase?

Answer 146

Proprioreceptors which detect movement.

Question 147

What is the equation for cardiac output?

Answer 147

CO = heart rate x stroke volume

Question 148

What units is heart rate measured in?

Answer 148

Beats per minute

Question 149

What units is stroke volume measured in?

Answer 149

mL

Question 150

What is stroke volume?

Answer 150

The volume of blood ejected in one cycle of the heart.

Question 151

What is the average stroke volume of humans?

Answer 151

70mL

Question 152

What is meant by cardiac output?

Answer 152

The volume of blood ejected into the aorta by the left ventricle per minute

Question 153

What are the units of cardiac output?

Answer 153

mL per minute

Question 154

What is cardiac output at rest?

Answer 154

4-7 litres per minute

Question 155

What is cardiac output also equal to? What does this imply?

Answer 155

Total blood volume

So, per minute, total blood volume is ejected. Thus the heart is a high-flowing system. Allows rapid filtering of blood.

Question 156

What percentage of the cardiac output does the kidney get at rest?

Answer 156

20%

Question 157

What is meant by venous return?

Answer 157

The volume of blood returning to the heart from the vasculature every minute and is linked to cardiac output.

Question 158

What is meant by cardiac reserve?

Answer 158

The maximum ability to supply. It refers to the difference between the resting rate at which the heart pumps blood and the max capacity for pumping blood.

Question 159

What can proprioreceptors detect? What do they do?

Answer 159

Movement. Tell the body that demand will increase.

Question 160

What occurs during heart failure?

Answer 160

Ability to increase cardiac output is reduced. Demand of tissues remains the same but supply is reduced. Cardiac reserve decreases.

Question 161

What 3 things is stroke volume affected by?

Answer 161

1) Preload stretch
2) Contractility
3) After load

Question 162

What is meant by preload stretch?

Answer 162

Stretch on the left ventricle before it contracts

Question 163

What is another word for contractility?

Answer 163

Inotrophy

Question 164

What is meant by contractility?

Answer 164

Forcefulness of contractility

Question 165

What is another word for heart rate?

Answer 165

Chronotrophy

Question 166

What ions have an excitatory or inhibitory effect on contractility?

Answer 166

Ca2+: positive

K+: Negative

Question 167

What is meant by after load?

Answer 167

Pressure the heart has to work against for LV to eject blood into the aorta.

Question 168

What is the Frank-Starling Law?

Answer 168

An increase in filling pressure leads to both an increase in end diastolic value and an increase in the subsequent stroke volume. This response can be explained by the ability of the cardiac muscle to respond to increased stretch with a more forceful contraction. Thus the energy of the contraction of the ventricle is a function of the initial length of the muscle fibers comprising its walls.

Question 169

What gives rise to blood pressure?

Answer 169

After load

Question 170

What are the two mechanisms by which the stroke volume is regulated?

Answer 170

1) Intrinsic regulation of the forc e of contraction governed by the degree of stretch of the myocardial fibre at the end of diastole.
2) Extrinsic regulation, which is determined by the activity of the autonomic nervous system and the circulating level of various hormones.

Question 171

What is a consequence of Starling’s Law?

Answer 171

The heart automatically adjusts its output to match its venous return.

Question 172

What determines blood pressure?

Answer 172

After load

Question 173

What is the pumping action of the heart achieved by?

Answer 173

The mechanical work of the myocardium.

Question 174

What must happen for mechanical work to be performed?

Answer 174

A load must be moved through a distance.

Question 175

For a 3D system, what is work equal to?

Answer 175

The change in pressure times the change in volume, so that the work performed by the heart each time it beats is given by the area of the pressure-volume curve for ventricular contraction. - Stroke Work

Question 176

Why is it necessary to construct a graph of ventricular pressure against volume to determine the stroke work accurately?

Answer 176

Ventricular pressure varies during the ejection phase of the cardiac cycle.

Question 177

Why does the pressure fall at first while the ventricle is filling? What happens after this?

Answer 177

Due to the suction effects of the relaxing muscle.

Later, it starts to rise passively as volume increases.

Question 178

What gives rise to the first steep rise in the pressure volume graph?

Answer 178

The pressure rises steeply, but since the aortic valve is closed, there is no change in volume. This is isovolumetric contraction.

Question 179

What happens after volumetric contraction with regard to the pressure-volume graph?

Answer 179

Aortic valve opens and blood is ejected from the ventricle.

Question 180

What happens after ejection with regard to the pressure-volume graph?

Answer 180

The valve closes again and isovolumetric relaxation occurs.

Question 181

What often causes stroke volume to increase?

Answer 181

The presence of a positive inotropic agent. The agent promotes the influx of Ca2+ during cardiac action potentials, which strengthens the force of the subsequent muscle fibre contraction (contractility).

Question 182

What often causes the stroke volume to decrease?

Answer 182

Negative inotropic agent. The agent promotes the influx of K+, which reduces the contractility.

Question 183

What is meant by ejection fraction?

Answer 183

The percentage of blood pumped out of a filled ventricle during each cycle. There is always a volume of blood that remains in the lungs.

Question 184

What can damage to the SA node result in?

Answer 184

Less regularity

Question 185

What is the SA node? What does it exhibit?

Answer 185

Pacemake

Autorhythmicity

Question 186

What is excitation initiated by?

Answer 186

Specialised cells in the SA node.

Question 187

Where is the SA node found?

Answer 187

It lies close to the point of entry of the great veins into the right atrium.

Question 188

What happens after excitation?

Answer 188

A wave of depolarisation is conducted throughout the myocardium.

Question 189

What does an ECG measure?

Answer 189

The electrical activity being produced by the heart.

Question 190

What value of voltage is produced by the electrical activity of the heart?

Answer 190

1-2mV

Question 191

Why is the electrical activity of the heart able to spread throughout the body?

Answer 191

Because water is an electrical conductor and the body is made up of mostly water.

Question 192

What is electrical activity controlling?

Answer 192

Contractile activity: Making sure fibres contract at the right time.

Question 193

What is ventricular arythmia

Answer 193

Lack of rhythmicity in the coordinated contraction.

Question 194

How can arythmia be reverted?

Answer 194

Giving the person a shock using defibrillators.

Question 195

What happens in atrial arythmia?

Answer 195

Atria are not contracting in a coordinated fashion.

Question 196

The heart has an inherent ______ _______ like ability.

Answer 196

Pace maker

Question 197

What is the inherent rate of the heart?

Answer 197

90-100 bpm

Question 198

What is the inherent ability of the heart due to?

Answer 198

SA node - special group of cells with an autorhythmicity.

Question 199

If the SA node is damaged, what can replace it?

Answer 199

The AV node

Question 200

How does ht ewave of depolarisation travel through the heart?

Answer 200

It sweeps over the surface of the heart, reaching different parts at different times and thus causing contraction at different times.

Question 201

What do we measure using an ECG?

Answer 201

The wave front of electrical acitivity sweeping across the heart surface.

Question 202

What do we record using an ECG?

Answer 202

The way the electrical activity is getting to different parts of the heart.

Question 203

Why are different ECG’s slightly different?

Answer 203

Electrodes are placed on different spots. This takes a picture of one angle of the heart. The different pictures taken by the leads shows different parts of the heart.

Question 204

What do the letters on an ECG refer to?

Answer 204

Different stages of the cardiac cycle

Question 205

What does the P wave stand for?

Answer 205

Relates to the wavefront activating and causing depolarisation of the atria

Question 206

What does the Q wave represent?

Answer 206

Depolarisation of ventricles

Question 207

What does the T wave represent?

Answer 207

Repolarisation of ventricles to get ready for the next cycle.

Question 208

What gives rise to the QRS complex?

Answer 208

Depolarisation of ventricular contractile fibers produces the QRS complex.

Question 209

What does an enlargement of the P wave indicate?

Answer 209

Enlargement of the atria. Higher preload

Question 210

What does enlargement of the R wave indicate?

Answer 210

Enlargement of ventricles

Question 211

What happens in heart failure?

Answer 211

There is more stretch on the wall. There may be a portion that is damaged. Other myocytes respond to heart failure by enlargement. Unlike other muscles, which get larger when exercised, heart muscles get larger in a non-beneficial way (hypertrophy).

Question 212

The electrical activity moves through the heart on a _________

Answer 212

Trajectory

Question 213

The build up of plaque in coronary vessels can lead to what?

Answer 213

Causes a blockage, reducing the diameter and resulting in transient ischaemia which can lead to angina (the pain associated with the lack of blood supply).

Question 214

What is angiography?

Answer 214

Injecting a dye into the vessels and looking at it with an xray to detect blockages.

Question 215

What are some ways to treat blocked vessels?

Answer 215

Bypass using leg vein

Stent

Question 216

Describe the action potential of a ventricular contractile fiber.

Answer 216

1) Initially, negative resting membrane potential. Rapid depolarisation due to Na+ inflow when voltage-gated fast Na+ channels open.
2) Plateau (maintained depolarisation) due to Ca2+ inflow when voltage-gated slow Ca2+ channels open and K+ outflow when some K+ channels open. Cannot have another heartbeat during this refractory period.
3) Repolarisation due to closure of Ca2+ channels and K+ outflow when additional voltage-gated K+ channels open.

Question 217

Compare the heart rate of a human dog, rabbit and rat. Now compare their blood pressures.

Answer 217

Human: 60 bpm
dog: 90 bpm
Rabbit: 150 bpm
Rat: 300bpm
Blood pressure is pretty much the same in every mammalian species. However, rats have a much smaller, so to generate the same pressure, they must beat much faster.

Question 218

What is the intrinsic rate of the SA node? Why is our resting heart rate different?

Answer 218

90 bpm

It is driven by the autonomic nervous system

Question 219

What are the two branches of the autonomic nervous system?

Answer 219

Parasympathetic and sympathetic

Question 220

Where do parasympathetic nerves start?

Answer 220

In the brain stem

Question 221

What is meant by the auto part of autonomic nervous system? What does this mean for control of the heart rate?

Answer 221

Not under conscious control. Cannot control your heart rate.

Question 222

Where is the medulla situated? What does it control?

Answer 222

At the back of the brain under the cerebellum.

Critical region involved in cardiovascular and respiratory control.

Question 223

What is the vagus nerve? What does it come alongside?

Answer 223

A group of cells in the medulla form a nerve axon (parasympathetic) which is called the vagus. Comes down alongside the carotid artery.

Question 224

How thick is the vagus nerve?

Answer 224

4-5mm in diameter

Question 225

Where does the vagus nerve lead to? What does it release there and what effect does this have on the heart rate?

Answer 225

The SA node and releases the neurotransmitter acetylcholine. This then decreases heart rate.

Question 226

Why is the resting heart rate lower than the intrinsic rate of the SA node?

Answer 226

The vagus nerve reduces heart rate by releasing acetylcholine when nerve impulses are sent in the autonomic nervous system.

Question 227

What is the effect of exercise on vagal activity?

Answer 227

The proprioreceptors which sense movement in joints sends signals to the medulla which decreases vagal activity, which leads to an increase in heart.

Question 228

What type of relationship exists between vagal activity and heart rate?

Answer 228

Inverse

Question 229

What is the predominant role of the vagus? What may be another role of the vagus?

Answer 229

Regulating heart rate. May have minor role on stroke volume.

Question 230

What is another factor that can cause an increase in heart rate?

Answer 230

Mental stress

Question 231

The central nervous system and cardiovascular system work together to ensure that you have the ___________________________________

Answer 231

Optimum heart rate for the current situation

Question 232

Where do sympathetic nerves travel?

Answer 232

Go down the spinal cord and then goes out at different segments. Some of the segments go to the coronary vessels and myocardium of the heart.

Question 233

How does sympathetic activity affect the heart?

Answer 233

Increases the heart rate and stroke volume and thus increases cardiac output. Contractility and inotropy

Question 234

What inputs does the sympathetic nervous system receive?

Answer 234

Proprioreceptors, oxygen levels, temperature, blood pressure, blood volume

Question 235

What is excitation of the heart initiated by? What occurs after this?

Answer 235

Specialised cells in the sinoatrial node. A wave of depolarisation is then conducted throughout the myocardium.

Question 236

Where is the sinoatrial node found?

Answer 236

It lies close to the point of entry of the great veins into the right atrium.

Question 237

Is the resting potential of the SA node stable or unstable?

Answer 237

Unstable

Question 238

What does the membrane potential between successive action potentials show? What happens when threshold is reached?

Answer 238

A progressive depolarisation

An action potential is triggered to initiate a heartbeat.

Question 239

Do the myocytes of the atria, ventricles, and conducting system have action potentials with the same or different characteristics? Describe similarities and differences.

Answer 239

Different
Although they cary in duration, they all show a fast initial upstroke followed by a plateau phase of depolarisation prior to repolarisation.

Question 240

What is the plateau phase of cardiac muscle contraction due to?

Answer 240

The inward movement of calcium ions.

Question 241

What does the calcium influx that occurs during the plateau phase of the action potential ensure?

Answer 241

That the action potential lasts almost as long as the contraction of the cell. Because the muscle is refractory both during and shortly after the passage of the action potential, the long plateau phase ensures the unidirectional excitation of the myocardium.

Question 242

When does repolarisation of the myocardial cells occur?

Answer 242

When the voltage dependent calcium channels inactivate.

Question 243

Describe a typical ECG and how it correlates with atrial and ventricular systole.

Answer 243

1) P wave: depolarisation of atrial contractile fibers
2) Flat region: atrial systole (contraction)
3) QRS complex: Depolarisation of ventricular contractile fibers produces QRS complex.
4) Flat region: ventricular systole (contraction)
5) T wave: repolarisation of ventricular contractile fibres
6) Flat region: ventricular diastole (relaxation)

Question 244

What gives rise to the P-Q interval, the S-T segment and the Q-T interval?

Answer 244

P-Q interval: Beginning of P wave and the flat region after it.
S-T segment: Flat region between QRS complex and T wave.
Q-T interval: The beginning of the QRS complex to the end of the T wave.

Question 245

What are the two inputs to the cardiovascular center in the brain? Give examples for each.

Answer 245

From higher brain centers: cerebral cortex, limbic system, and hypothalamus.
From sensory receptors: proprioreceptors ( Monitor movements), chemoreceptors (monitor blood chemistry), baroreceptors (monitor blood pressure).

Question 246

What are the two outputs of the cardiovascular (CV) center and give examples of how it affects the heart.

Answer 246

1) Cardiac accelerator nerves (sympathetic)
- Increased rate of spontaneous depolarisation in SA node (and AV node), which increases heart rate.
- Increased contractility of atria and ventricles, which increases stroke volume.
2) Vagus (X) nerves (parasympathetic)
- Decreased rate of spontaneous depolarisation in SA node (and AV node), which decreases heart rate.

Question 247

Describe the factors that increase stroke volume.

Answer 247

• Increased preload
• Increased contractility
• Decreased afterload

Question 248

How can preload be increased? What are the consequences?

Answer 248

• Increase end-diastolic volume (stretches the heart).

- Within limits, cardiac muscle fibres contract more forcefully with stretching (Frank-Starling law)

Question 249

How can contractility be increased? What are the consequences of this?

Answer 249

• Positive inotropic agents such as increased sympathetic stimulation: catecholamines, glucagon, or thyroid hormones in the blood lead to increased Ca2+ in extracellular fluid.
• These agents increase force of contraction at all physiological levels of stretch.

Question 250

How can afterload be decreased? What are the consequences of this?

Answer 250

• Decreased arterial blood pressure during diastole.

- Semilunar valves open sooner when blood pressure in aorta and pulmonary artery is lower.

Question 251

Describe the factors that increase heart rate.

Answer 251

Nervous sustem : Cardiovascular center in medulla oblongata receives input from cerebral cortex, limbic system, proprioreceptors, baroreceptors, and chemoreceptors. Leads to increased sympathetic and decreased parasympathetic stimulation.
Chemicals: catecholamine or thyroid hormones in the blood moderate increase in extracellular Ca2+
Other: Infants and senior citizens, females, low physical fitness, increased body temperature.

Question 252

Define afterload

Answer 252

The pressure the LV has to work against in order to eject blood into the aorta

Question 253

What is another name for blood pressure?

Answer 253

Arterial pressure

Question 254

What is arterial pressure?

Answer 254

The pressure in the arteries

Question 255

What causes arterial pressure?

Answer 255

The heart pushing against the aortic valve.

Question 256

What do the two numbers used to describe blood pressure relate to?

Answer 256

Systolic over diastolic

Question 257

What is the incidence of hypertension in NZ?

Answer 257

10-40%

Question 258

What blood pressure is used to define hypertension?

Answer 258

140 over 90

Question 259

What is the impact of having high blood pressure on the heart and on blood vessels?

Answer 259

• Makes the heart have to work harder because the afterload is higher so there is a decrease in efficiency. Over a number of years, heart failure will occur and the ejection fraction will decline. Breathlessness and venous congestion will result.
• Tortuosity, bends and plaque buildup can occur in small vessels. These are weak points that hypertension can cause bursts in (stroke)

Question 260

Is the increase in heart muscle size beneficial?

Answer 260

NO

Question 261

What are the risk factors for hypertension?

Answer 261

Smoking, alcohol, overweight, no exercise as well as genetic factors.

Question 262

What is happening when a cuff is placed on the arm when measuring blood pressure? What is listened for?

Answer 262

Occluding all blood flow into and out of the arm so there is zero blood supply.
When a small amount of blood is allowed to flow when the valve is just released, turbulent flow can be heard. This gives the systolic value. The valve is wound down until silence is heard. This is because flow in tubes that is laminar (non-turbulent) is silent. This is the diastolic value.

Question 263

What is the majority of the 5 L of blood in the body situated?

Answer 263

The major veins

Question 264

When we are measuring pressure with a cuff, what are we measuring?

Answer 264

The pressure in the arteries

Question 265

Does blood pressure change when we exercise?

Answer 265

Yes, but to a small extent.

Question 266

What do we see happening to the pressure and pulsatility when we move from the arteries to the arterioles? Why?

Answer 266

A big reduction in pressure. The pulsatility of the wave decreases. This is because they don’t have as much connective tissue and a good amount of smooth muscle, which contracts.

Question 267

What do the arterioles act as?

Answer 267

A shock absorber or dampening force

Question 268

How does the smooth muscle affect the arterioles? How does this affect the pressure?

Answer 268

Changes the radius of the blood vessel, which affects the resistance. (Inverse square law)
Reduces the pressure.

Question 269

What is the approximate pressure in the capillaries?

Answer 269

35 mmHg

Question 270

What happens to the blood pressure in the arterial end of capillaries? Why?

Answer 270

Pressure falls because substances leak out.

Question 271

When we get to the venules, what is the blood pressure and what happens there?

Answer 271

20 mmHg

We reabsorb the waste products.

Question 272

What can pressure in the superior vena cava reach?

Answer 272

Around zero

Question 273

Does flow rate change despite the change in pressure?

Answer 273

NO

Flow in = Flow out

Question 274

What does blood pressure drive?

Answer 274

Exchange

Question 275

Is the pressure across mammalian species the same? What is the exception?

Answer 275

YES

Giraffes

Question 276

What substances cause negative forceful filtration in the capillaries? Does it vary across the capillary bed?

Answer 276

Substances that are not easily filtered due to their molecular weight. They only pass through special secretory process and therefore restrain other things from being pushed out. This is the same across the capillary bed.

Question 277

What opposes the blood hydrostatic pressure? What contributes to it?

Answer 277

Blood colloid osmotic pressure

Contributed to by substances that cannot be easily filtered.

Question 278

What is the interstitial hydrostatic pressure in most regions of the body? Where is it different?

Answer 278

0 mmHg

Kidneys

Question 279

What is the pressure that drives filtration?

Answer 279

Net filtration pressure: 10mmHg

Question 280

What is the system that drains most of the interstitial fluid?

Answer 280

Lymphatic system

Question 281

In the venous end of the capillary, what is the same and different about the pressure?

Answer 281

All pressure values are the same except for the blood hydrostatic pressure, which goes from 35 to 16 mmHg.

Question 282

What is the pressure in the venule end compared to the arterial end of the capillary? What does this serve to do?

Answer 282

-9 in the venule end vs +10 in the arterial end.

This sucks substances back into the capillary.

Question 283

If blood pressure stays low for a very long period of time?

Answer 283

A lower net filtration pressure. Stuff is not being pushed out so cells are not getting the nutrients and oxygen for normal metabolism to occur.

Question 284

What occurs when the pressure goes up? When can this occur?

Answer 284

More filtration due to increase of net filtration pressure.
Standing still for a long time: great hydrostatic pressure in the ankles and feet, leads to higher force driving fluid out of capillaries. Less net reabsorption occurs. This leads to a edema (swollen ankles) occurring.

Question 285

What vessels provide the major resistance to flow?

Answer 285

Arterioles

Question 286

What is total peripheral resistance (TPR)?

Answer 286

The sum of all the resistances provided by all the vessels around the body.

Question 287

What equation relates blood pressure, cardiac output, and total peripheral resistance?

Answer 287

Blood pressure = Cardiac output x Total peripheral resistance

Question 288

Why doesn’t pressure in the arterial system go to zero?

Answer 288

Because we have peripheral resistance

Question 289

How do we regulate total peripheral resistance?

Answer 289

By regulating the diameter of arterioles. Vasoconstriction or vasodilation.
E.g. hot day leads to vasodilation of arterioles.

Question 290

How is the vascular supply to different organs arranged?
What does this mean for the pressure entering each organ?
What would be the result if they were arranged in series?

Answer 290

In parallel
All organs receive the same pressure going into them. This is useful for exchange.
The organ at the end would receive very little pressure.

Question 291

What happens to the blood flow to organs (kidneys) when running a marathon?

Answer 291

Reduces by vasoconstrictions.

Exercising muscles require more oxygen so blood vessels supplying skeletal muscles vasodilate.

Question 292

If we start with 4 L/min of cardiac output, how much goes to each of 4 organs?

Answer 292

1 L/min

Question 293

What does vasoconstriction occur in?

Answer 293

Arterioles

Question 294

During vasoconstriciton and vasodilation, does blood pressure change radically?

Answer 294

NO

Question 295

Why is stability in blood pressure what we are after?

Answer 295

For driving exchange

Question 296

What do we regulate to maintain blood pressure?

Answer 296

Cardiac output (heart rate and stroke volume) and total peripheral resistance.

Question 297

Why does blood pressure get higher as we age?

Answer 297

Arterioles get stiffer and less responsive due to less smooth muscle, thicker walls and plaque build up, leading to greater total peripheral resistance.

Question 298

What does vasoconstriction of peripheral blood vessels due to cold temperatures result in?

Answer 298

Brings in blood flow and reduces heat loss.

Question 299

What factors lead to vasodilation?

Answer 299

Heat

Alcohol

Question 300

What is the approximate reduciton in blood pressure due to gravity when going from lying to standing?

Answer 300

15 mmHg

Question 301

What is decrease in blood pressure sensed by?

Answer 301

Baroreceptors (pressure receptor) in the arterial system.

Question 302

Where are baroreceptors found?

Answer 302

Carotid artery divides into the external and internal carotid artery under the jaw and in this region, there is a nerve that travels down and the nerve goes across this region. Blood vessel forms a sinus in this region which is a swelling. This is a baroreceptor afferent nerve which terminates in the artery. Baroreceptors are found in the carotid sinus and arch of the aorta.

Question 303

What is an afferent nerve?

Answer 303

Takes information from the periphery to CNS.

Question 304

What are baroreceptors sensitive to?

Answer 304

Stretch

Question 305

When blood pressure decreases, for example when we go from lying to standing, what is the response?

Answer 305

Baroreceptors fire less -> CNS -> Decrease in vagal nerve firing -> Increase in heart rate
CNS -> Increase in cardiac sympathetic nervous activity -> Increase in heart rate and stroke volume
CNS -> Increase in sympathetic nerve activity -> Vasoconstriction -> Increase in total peripheral resistance
Increase in CO and TPR leads to increase in BP

Question 306

Why are arterioles able to respond to blood pressure?

Answer 306

Every arteriole has a sympathetic nerve going to it. This sympathetic innervation changes the diameter.

Question 307

What is the difference in blood pressure and heart rate/SNA over a 24 hour period?

Answer 307

BP: very little variation

HR + SNA: much variation

Question 308

What does the cardiovascular system use to stabilise blood pressure?

Answer 308

Heart rate and sympathetic nerve activity

Question 309

Why does exercise help raise low blood pressure?

Answer 309

Skeletal muscles help pump blood back to the heart.

Question 310

How often do baroreceptors sense changes in pressure?

Answer 310

Every heart beat

Question 311

What happens if blood pressure and blood volume decrease due to haemorrhage or blood loss?

Answer 311

Same processes occur as decrease in BP due to do standing from lying, but stronger. Blood flow to kidney reduces profoundly due to vasoconstriction so filtration is curtailed. It is difficult to maintain filtration, and some may need dialysis for extreme cases.

Question 312

How long does the cardiovascular system take to recover from haemorrhage or blood loss?

Answer 312

20 min

Question 313

Where does the sympathetic nerve activity go to especially? What effect does it have there?

Answer 313

The kidneys: regulates vasoconstriction

Question 314

What are cardiac pulmonary receptors?

Answer 314

Receptors that are located around the veins as they come back to the heart. Superior and inferior vena cava.
Sense venous pressure.

Question 315

Is pressure in the veins near the heart high or low? Give an approximate value.

Answer 315

Low

2-5 mmHg

Question 316

What percentage of blood volume is in the veins?

Answer 316

60%

Question 317

What senses venous pressure?

Answer 317

Nerve endings in the veins near the heart

Question 318

Why is venous pressure able to go negative?

Answer 318

Due to the pleural cavity

Question 319

When central venous pressure decreases, what happens?

Answer 319

Goes to central nervous system -> Increase SNA -> Increase SV and HR -> Increase BP

Question 320

What is the collective name for the cardiovascular system’s attempt to restore blood pressure?

Answer 320

Compensation

Question 321

What happens as a result of increased blood volume (e.g. due to drinking a lot of water)?

Answer 321

Increase in central venous pressure (Small - 5 mmHg) -> Sensed by cardiac pulmonary receptors -> Decrease in cardiac sympathetic nerve activity -> decrease heart rate and stroke volume
Also decrease in sympathetic nerve activity of kidney -> Vasodilation -> Increase renal filtration -> Increase urine output

Question 322

What happens between the nerve endings of the sympathetic nervous system and the smooth muscle of arterioles?

Answer 322

Noradrenaline is released as a neurotransmitter, which acts on alpha receptors to cause vasoconstriction.

Question 323

How can high blood pressure be treated?

Answer 323

Block the receptors for vasoconstriction to bring down the heart rate and stroke volume.

Question 324

What is cardiovascular disease?

Answer 324

The name for the group of disorders of the heart and blood vessels

Question 325

List the cardiovascular diseases.

Answer 325

Hypertension (High BP)
Coronary heart disease (Heart attack)
Cerebrovascular disease (Stroke)
Peripheral vascular disease
Heart failure
Rheumatic heart disease
Congenital heart disease
Cardiomyopathies