Normal structure & Function

Question 1

Main function of Heart?

Answer 1

Pump blood to all organs and tissues in body

Question 2

Bloods role?

Answer 2

Oxygen and nutrients to tissues and removes waste products

Question 3

Prime function of right heart?

Answer 3

Via the pulmonary trunk drives the low pressure pulmonary circulation

Question 4

Prime function of left heart?

Answer 4

Via the aorta drives high pressure systemic circulation

Question 5

How many pumps does heart have?

Answer 5

Two

Question 6

High pressure pump?

Answer 6

On the left side. Forces blood to flow to other tissues around body and then back to the heart

Question 7

Low pressure pump?

Answer 7

On the right side. Forces blood to flow to the lungs and back to the heart.

Question 8

Blood circulates body via?

Answer 8

Arteries

Question 9

Blood returns to the heart via?

Answer 9

Veins

Question 10

Features of Arteries?

Answer 10

The walls of larger central arteries are elastic and recoil to help propel blood
The walls of smaller arteries and arterioles are much more muscular and are mainly responsible for peripheral resistance to blood flow.

Question 11

Features of veins?

Answer 11

Thin walls and easily distensible- act as a major reservoir of blood
Larger veins have valves that support unidirectional blood flow- important during standing and exercise

Question 12

Capillaries structure and function?

Answer 12

Tiny vessels forming a network linking arterial and venous blood flow. In this gases and nutrients or waste are exchanged at a cellular level

Question 13

Capillary walls?

Answer 13

Thin single layer of endothelial cells
Permeable to small molecules facilitating exchange of hormones, fluid and nutrients, electrolytes etc between interstitial fluid and blood.

Question 14

What does the lymphatic system do?

Answer 14

It comprises of a network of thin walled vessels which enable excess interstitial fluid to return to the circulation

Question 15

Where does the heart lie?

Answer 15

Lies in the chest cavity, deep to the sternum within the rib cage, between the lungs, superior to the diaphragm in the mediastinum.

Question 16

Where is the base of your heart?

Answer 16

Closer to the head than the apex

Question 17

Describe the position of the apex of the heart?

Answer 17

Lowest most lateral point of heart

5th left intercostal space just medial to the mid-clavicular line

Question 18

4 reasons it is clinically important to know the location of the heart?

Answer 18

• It directs you to where you could normally find the apex beat
• Indicates listening areas on chest wall for where you could best hear heart sounds and murmurs
• Helps you know were best to place electrodes when recording a trace of hearts electrical activity
• Helps you know where to put pressure in CPR

CAME-
CPR
Apex
Murmurs & heart sounds 
ECG- electrodes

Question 19

Coronary Sulcus

Answer 19

Groove on the external surface of the heart that separates atria from ventricles

Question 20

What do superior and inferior vena cavae do?

Answer 20

Drain blood from upper and lower parts of the body into the right atrium

Question 21

What does aorta do?

Answer 21

Carries oxygenated blood from left ventricle to body

Question 22

What do pulmonary arteries do?

Answer 22

Carry systemic venous blood from the right ventricle to the lungs

Question 23

Where do the left and right coronary arteries rise from?

Answer 23

Root of the aorta just above the aortic valve, and lie within the coronary sulcus

Question 24

Why is the left ventricular wall thicker than the right?

Answer 24

Pumps blood against high pressure in the systemic circulation, whereas RV pumps blood into low pressure pulmonary circulation

Question 25

What are valves in heart for?

Answer 25

To maintain unidirectional blood flow between chambers and between chambers and vessels

Question 26

How many pair of valves does heart have?

Answer 26

2- atrioventricular and semilunar

Question 27

AV valves?

Answer 27

Atrioventricular valves
Located between atria and ventricles
Right side AV valve has 3 cusps and is called tricuspid
Left side valve has 2 cusps and is called mitral valve

Question 28

SL valves?

Answer 28

Semilunar valves
Located within aortic and pulmonary trunk

Valve cusps are half moon shaped

They are called the aortic and pulmonary valves

Question 29

Cardiac skeleton?

Answer 29

Consists of strong fibrous framework that prevents main components of heart pulling themselves apart during contraction. Heart valves are also anchored by this.

Question 30

Were does drainage of the lymphatic system occur?

Answer 30

Right and left subclavian veins

Question 31

What empties into the coronary sinus?

Answer 31

Large veins that drain myocardium which converge towards the coronary sulcus

Question 32

How many veins drain blood from the lungs into the left atrium?

Answer 32

4

Question 33

What does cardiac skeleton consist of?

Answer 33

Strong central framework of fibrous rings(annuli) that surround heart valves giving attachment to valve cusps and muscle fibers of heart chambers

Question 34

How many layers of tissue is the heart composed of?

Answer 34

3-
epicardium
myocardium
endocardium

Question 35

Epicardium description?

Answer 35

serous membrane of simple squamous epithelium overlaying loose connective tissue and fat
Forms smooth outer surface of the heart

Question 36

Myocardium description?

Answer 36

Thick middle layer of cardiac muscle cells responsible for contracting ability of heart

Question 37

Endocardium description?

Answer 37

Simple squamous epithelium overlaying a layer of connective tissue which allows blood to flow easily through the heart chambers

Question 38

Factors which affect blood flow through the body?

Answer 38

Pressure difference
Resistance within vessels
Viscosity of blood

Question 39

Why is blood flow required?

Answer 39

To supply nutrients to and remove metabolic waste products from the cells of the body.

Question 40

When will blood flow through a vessel?

Answer 40

When a pressure difference exists between the 2 ends of the vessel- larger pressure is driving force so blood moves away from it

Question 41

What is resistance?

Answer 41

Measure of how difficult it is for fluid to flow along a vessel
Frictional forces also exist within the fluid itself depending on it’s level of viscosity

Question 42

What is blood viscosity affected by?

Answer 42

Haematocrit (volume of blood with red blood cells)- RBCs exert frictional drag on eachother and against vessel wall

Question 43

What conditions could a patient with low blood velocity and high blood viscosity have?

Answer 43

Increased risk of thrombotic tendencies
which would equal vascular complications such as
-Coronary thrombosis
-Myocardial infarction

Question 44

Describe laminar flow?

Answer 44

Blood flowing in an organized streamlined pattern

Question 45

What does laminar flow refer to?

Answer 45

Fluid moving along a vessel behaves as if it has many concentric layers
Little mixing between layers
Fluid next to vessel wall experience lowest velocity of flow
Central blood has greatest velocity
This creates a pressure gradient

Question 46

What is blood flow (Q)within the cardiovascular system determined by?

Answer 46

Head of pressure developed by the heart (P1-P2)

Resistance to flow encountered within the vessels (R)

Question 47

Resistance to blood flow equation?

Answer 47

Q=[(P1-P2) / R]

Question 48

In systemic circulation which of the following represents the driving pressure and which the exit pressure. Mean pressure in right atrium and mean pressure in ascending aorta.

Answer 48

Mean pressure in ascending aorta is P1 (driving pressure)

Mean pressure in right atrium is P2 (exit pressure)

Question 49

What equation describes all factors that influence flow through a vessel?

Answer 49

Poiseuille equation

Question 50

What is resistance to flow through a vessel affected by?

Answer 50

Length (L)
Inner radius (R)
Viscosity (n) of a fluid flowing through a vessel

Question 51

What is blood flow primarily affected by?

Answer 51

Changes in the radius of blood vessels

Question 52

What is vascular tone a result of?

Answer 52

Balance between constrictor and dilator influences

Question 53

What is vasomotor tone?

Answer 53

During resting conditions a continuous low frequency sympathetic discharge from the vasomotor center in the medulla oblongata to the peripheral vessels (arterioles) maintains these vessels in a partially constricted state.

Question 54

When does vasodilation commonly occur?

Answer 54

Following increased skeletal muscle metabolism (exercise) to increase blood flow and oxygen delivery to the muscles

Question 55

What are initial electrical impulses in the heart generated by?

Answer 55

SA node

Question 56

Initial electrical heart impulse?

Answer 56

SA node generates APs which spread through the atrial wall to the AV node

Question 57

The AV nodes role?

Answer 57

Propagation of an AP through the AV nodal region is very slow and imposes a delay of excitation between atria and ventricles. This delay allows time for atria to empty contents into ventricles before ventricular contraction begins.

Question 58

Where does impulse travel to from AV node?

Answer 58

Bundle of His (AV bundle)

Question 59

What happens after the AV node receives AP?

Answer 59

AP passes through bundles of His and branches into ventricular muscle
Bundle branches terminate in purkinje fibers transferring potential to ordinary cardiac muscles = rapid simultaneous excitation of all ventricular muscle cells

Question 60

When does a cardiac muscle fibre contract?

Answer 60

When an action potential is transmitted along its plasma membrane

Question 61

How many types of cardiac myocytes and their names?

Answer 61

2 types 
ventricular myocyte (non-pacemaker)
Pacemaker myocyte

Question 62

Resting phase of myocyte AP?

Answer 62

Transient depolarization of a cell followed by repolarisation as a result of movement of ions across its cell membrane via ion channels
At rest membrane has a low permeability to Na+ and Ca++ and a high permeability to K+.

Question 63

Depolarization of myocyte AP?

Answer 63

Increased Membrane permeability to Na+
-This is caused by rapid transient entry of Na+ through voltage- gated Na+ channels into the myocyte

Simultaneously membrane potential to K+ falls causing membrane potential to move away from the K+ equilibrium potential and towards the Na+ equilibrium potential (+60mV) = rapid upstroke on graph

Question 64

Plateau phase of myocyte AP?

Answer 64

Increased membrane potential to Ca++
-membrane permeability to Na+ returns to its resting value due to inactivation of Na+ channels and membrane potential decays slowly (over 0.25secs)= plateau phase

Question 65

What is plateau phase primarily due to ?

Answer 65

Slow influx of Ca++ via long lasting voltage gated Ca++ channels (L type) which activate relatively slowly until membrane potential reaches 40mV= increased permeability to Ca++- vital for muscle contraction

Question 66

What is Ca++ entry into the cell vital for during the plateau phase of an AP?

Answer 66

Muscle contraction

Question 67

Repolarization phase of myocyte AP?

Answer 67

Increased membrane permeability to K+
-At the end of plateau the voltage gated K+ channels open causing an increased permeability to K+ while Ca++ permeability decreases
Membrane potential returns to its resting level.

Question 68

Membrane permeabilities in each stage of an AP?

Answer 68

Resting phase- Membrane permeable to K+
Depolarization phase- Increased Na+ permeability
Plateau phase- Increased membrane permeability to Ca++
Repolarization phase- Increased membrane permeability to K+

Question 69

When is an action potential initiated?

Answer 69

When the membrane is depolarized to threshold potential

Question 70

What will understanding the characteristics of pacemaker APs help you understand?

Answer 70

Origins of cardiac arrhythmias and treatment used to control them

Question 71

What do pacemaker cells make up?

Answer 71

SA node

Question 72

Resting phase of a pacemaker potential membrane potential?

Answer 72

Less negative than that of ventricular muscle fibers (it is around -55->-60mv)

Question 73

What happens in the resting phase of a pacemaker AP?

Answer 73

• A progressive decrease in K+ membrane permeability results in fewer K+ moving out of the cells
• Slight increase in Na+ permeability results in a slow influx of Na+ (funny current) contributing towards depolarization
• Around this time a small rise in Ca++ conductance into cell via T type Ca++ channels which open very briefly causing membrane potential to rise very gradually towards threshold potential (-40mV)—-This unstable resting potential is called pacemaker potential

Question 74

Threshold potential for pacemaker AP?

Answer 74

-40mV

Question 75

What is pacemaker potential?

Answer 75

Membrane potential gradually rising towards threshold potential due to a small rise in Ca++ conductance into cells via T type Ca++ channels opening very briefly.

Question 76

Depolarization of pacemaker AP?

Answer 76

As potential reaches threshold potential many (L type) slow long lasting Ca++ channels begin to open and the slow influx of Ca++ into the cell is primarily responsible for this phase.

Question 77

Repolarization phase of pacemaker AP?

Answer 77

Voltage gated Ca++ (L type) channels become inactivated together with the opening of a large number of voltage gated K+ channels - causing diffusion of K+ out of fibers

Question 78

Hyperpolarization of pacemaker AP?

Answer 78

K+ channels remain open for a few ?/10 of a second carrying a great XS of K+ ions out of fibre and resulting in an XS negativity inside the fibre. This = hyperpolarization (-55mv–>-60mv)

Question 79

Hyperpolarization membrane potential?

Answer 79

-55mv–>-60mv

Question 80

What does an excessive HR mean for cardiac filling?

Answer 80

Insufficient time to do it properly

Question 81

Consequences of excessive HR?

Answer 81

Decreased CO

Possible death

Question 82

What protects against insufficient cardiac filling?

Answer 82

Refractory period of cardiac myocyte

Question 83

Explain what the refractory period is?

Answer 83

The refractory period of the heart is the interval of time during which a normal cardiac impulse cannot re-excite an already excited area of cardiac muscle. The normal refractory period of the ventricle lasts from 250 to 300 milliseconds. This corresponds to the duration of the action potential.
There is an additional relative refractory period of about 50 milliseconds during which the muscle is more difficult than normal to excite, but nevertheless can be excited.

The long refractory period ensures that cardiac muscle contraction and relaxation are almost complete before the next action potential is initiated. Thus tetanic contraction is prevented in cardiac muscle.

Question 84

What is recorded in an ECG?

Answer 84

The coordinated rhythmical stimulation of the heart by the cardiac conduction system.

Question 85

What equipment is used in an ECG?

Answer 85

Electrodes

Question 86

What conditions are ECGs used to diagnose?

Answer 86

Myocardial Infarctions
Arrhthymias
Ventricular Hypertrophy

Question 87

What is an arrhthymia?

Answer 87

Variation from the normal rhythm of the heart beat

Question 88

What is ventricular hypertrophy?

Answer 88

Abnormal enlargement of the ventricular muscle cells of the heart

Question 89

How many leads in an ECG?

Answer 89

12

Question 90

What is an ECG?

Answer 90

Summation of all of the hearts electrical activity

Question 91

What is the P wave of an ECG?

Answer 91

Caused by atrial depolarization

Question 92

What does a P wave usually look like?

Answer 92

Contour is usually 
Positive
Smooth 
Uniform size
Less than 0.12secs

Question 93

What does the QRS complex represent?

Answer 93

Time taken for depolarization of ventricles

Question 94

What does the QRS complex look like?

Answer 94

R wave= dominant, looks like spike

Duration= 0.04-0.12secs)

Question 95

What is the T wave of an ECG represent?

Answer 95

Ventricular repolarization

Question 96

What does a T wave look like in an ECG?

Answer 96

Normally positive

Question 97

What is the PR interval?

Answer 97

Portion of the ECG wave from the beginning of the P wave to the beginning of the QRS complex (onset of ventricular depolarization)

Question 98

Duration of PR interval?

Answer 98

0.12->0.2secs

Question 99

Where is the QT interval?

Answer 99

Extends from the start of the QRS complex to the end of the T wave

Question 100

What is the QT interval?

Answer 100

Represents time between start of ventricular depolarization and the end of ventricular repolarization

Question 101

What is the QT interval dependent on?

Answer 101

Heart rate

Varies inversely with heart rate

Question 102

What does the ST segment represent?

Answer 102

Period from the end of ventricular depolarization to the beginning of ventricular repolarization

Question 103

What does intrinsic regulation of the heart depend on?

Answer 103

Depends on normal functional characteristics of heart and not hormonal or neural regulation

Question 104

What law is the main intrinsic mechanism set out in?

Answer 104

Starlings law

Question 105

What is venous return?

Answer 105

The amount of blood flowing into the right atrium from veins during diastole.

Question 106

Relationship between Venous return and end diastolic volume?

Answer 106

As venous return increases so too does end diastolic volume

Question 107

Relationship between EDV and stretch of ventricular walls?

Answer 107

Greater the EDV

Greater the stretch of ventricular walls

Question 108

What is the pre-load?

Answer 108

The extent to which the ventricular walls are stretched

Question 109

What does it mean that cardiac muscle exhibits a “length versus tension” relationship?

Answer 109

Increased preload causes cardiac muscle fibres to increase with larger force and produce greater STROKE VOLUME

Question 110

Cardiac output equation?

Answer 110

CO= HR x SV

Question 111

What does

a) increased preload
b) decreased preload cause?

Answer 111

a) Increased CO

b) Decreased CO

Question 112

What is Starlings law of the heart referring to?

Answer 112

Relationship between preload and stroke volume

Describes relationship between changes in pumping effectiveness of heart and changes in preload

Question 113

Relatively small changes in preload do not effect pumping effectiveness of heart. True or false?

Answer 113

False ]Relatively small changes can have a great affect on pumping effectiveness

Question 114

What is after load?

Answer 114

The resistance that contracting ventricles must overcome in order to propel blood downstream from the heart
(into pulmonary arteries from right ventricle and into aorta from left ventricle)

Question 115

Ventricular function is relatively insensitive to small changes in after load. True or False

Answer 115

True

Question 116

What does extrinsic control of the heart involve?

Answer 116

Hormonal control mechanisms

Neural control mechanism

Question 117

What is neural regulation through?

Answer 117

Parasympathetic and sympathetic mechanisms

Question 118

What is hormonal regulation through?

Answer 118

Adrenaline and noradrenaline secreted by adrenal medulla

Question 119

Define parasympathetic?

Answer 119

Part of the autonomic nervous system -which is the portion of the nervous system concerned with regulation of activity of cardiac muscle, smooth muscle and glands