Cardiovascular System

Question 1

The CVS operates via 2 systems:

Answer 1

1. Systemic
2. Pulmonary

*united by heat

Question 2

There is high pressure within the:

Answer 2

Left ventricle
Aorta
Systemic capillaries
Systemic circuit

Question 3

There is low pressure within the:

Answer 3

Systemic capillaries
Right atrium
Right ventricle
Pulmonary circulation
Left atrium
Left ventricle

Question 4

Blood pressure is calculated by…

Answer 4

Pressure = Force/Area

Question 5

Flow is calculated by…

Answer 5

Flow = (Pressure1 - Pressure2) / Resistance

Question 6

Primary functions of the cardiovascular system?

Answer 6

Delivery of O2 to tissues and cells
Removal of by-products and CO2
Enables metabolism, growth and repair by delivering necessary components to specific parts of the body

Question 7

Intercalated discs:

Answer 7

Interlocking of adjacent cardiomyocytes

Question 8

Desmosomes:

Answer 8

Provide strength and anchor membranes together

Question 9

Gap Junctions:

Answer 9

Allow for signalling with movement of ions between cells

Question 10

Functional syncytium:

Answer 10

A single unit of electrically-coupled cardiomyoctes

*There are no gap junctions between atrial and ventricular cells.

Question 11

Atrial and ventricular cells are separated by….

Answer 11

Non-conductive fibrous tissue that surrounds the AV valves

Question 12

Purkinje fibres:

Answer 12

Modified muscle cells which contract depolarisation more rapidly than muscle cells

Found within ventricular walls and Bundle of His

Question 13

The AV node generates primary action potentials for heart contractility. T/F

Answer 13

False, SA node

Question 14

The rate of AP production is limited by ____

Answer 14

how fast Na+ leaks through HCN channels

Question 15

HCN channels:

Answer 15

Hyperpolarization-activated cyclic nucleotide–gated channels

Question 16

The AV node generates…

Answer 16

~40-60 AP/min

Question 17

Ectopic beats:

Answer 17

When conduction to the ventricles causes spontaneously contraction out of sync with the atria.

Question 18

Ventricular myocytes have no capacity for generating action potentials and their resting membrane potential rests at a stable level until an action potential from arrives from the bundle of His. T/F

Answer 18

True

Question 19

Ventricular myocytes have no capacity for generating action potentials and their resting membrane potential rests at a stable level until an action potential from arrives from the bundle of His.

This initiates the…

Answer 19

Ventricular action potential –> increase in Ca2+ entry –> contraction of the myocyte.

1. Fast Na+channels open, rapidly depolarising the cell.
2. This opens L-type Ca2+>channels, as in SA node cells. This Ca2+entry initiates contraction.
3. Voltage-gated K+channels open as the Na+and Ca2+begin to close, causing hyperpolarisation and bringing the membrane potential back to its resting level

Question 20

The ECG measures…

Answer 20

the electrical activity that reaches the skin surface, initiated by a cardiac impulse

Question 21

Atrial repolarisation is shown on the ECG. T/F

Answer 21

False

Question 22

Contraction:

Answer 22

Sysole

Question 23

Relaxation:

Answer 23

Diastole

Question 24

Lead ll describes the positioning of…

Answer 24

1 lead on the right arm

1 lead on the left leg

Question 25

P wave:

Answer 25

Atrial depolarisation –> contraction –> systole

• Small wave, because the atria has small muscle mass

Always positive in lead ll during sinus

Question 26

QRS complex:

Answer 26

Depolarisation of the ventricles. –> contraction –> systole

• The electrical wave generated by the left ventricle is larger than the right

A short QRS complex shoes rapid depolarisation of ventricle (desirable)

Question 27

Isovolumic contraction:

Answer 27

Closing of AV valves within a build-up of pressure ((Q)RS complex)

Question 28

The AV node functions to…

Answer 28

Delay impulse speed

Question 29

At what point in the ECG does arterial pressure increase?

Answer 29

R corresponds to innervation of the purkinje fibres.

–> depolarisation of the ventricles, –> contraction and thus increase arterial blood volume/pressure.

Question 30

At what point in the ECG does arterial pressure increase?

Answer 30

T corresponds to repolarisation of the ventricle, –> decrease in arterial blood volume, –> increase in arterial volume.

Question 31

Describe the movement of the electrical signal from the pacemaker to the purkinje fibres.

Answer 31

The electrical wave moves from the SA node to the internodal tracts –> small increase (P) on the ECG.
Arriving at the AV node there is a small delay on the ECG (PR interval).
The wave then travels to the bundle of HIS causing a small decrease on the ECG (Q).

After this the wave travels through the purkinje fibres, –> increase in ECG voltage (R), followed by a decrease as the purkinji fibes depolarise the top of the ventricle (S).

Question 32

Blood pressure is highest during…

Answer 32

Systole

Question 33

Hypertension is characterized by a bpm of…

Answer 33

140/90mmHg

Question 34

Atherosclerosis:

Answer 34

If the blood vessel has a tear, –> WBC will coagulate around the tear; fat, cholesterol, and other substance can attach to the tear and cause a plague that stiffens the arterial wall.

If the tear ruptures, a blood clot can form and block the flow of oxygen –> heart attack or stroke

Question 35

Angioplasty:

Answer 35

Widening of clogged blood vessels

Question 36

Resistance is dependant on:

Answer 36

blood viscosity;
number or erythrocytes,
vessel length
diameter

Question 37

Poiseulles Law:

Answer 37

The flow of Newtonian fluids for no turbulence

Question 38

Central venous pressure:

Answer 38

Difference in arterial pressure and venous pressure

Question 39

Total peripheral resistance:

Answer 39

Resistance across the whole systemic circuit

Question 40

Cardiac suction occurs when the _____

Answer 40

atrial cavity enlarges during ventricular contraction (atrialpressure < 0mmHg)

Question 41

Altering MAP:

Answer 41

Increasing cardiac output –> incr. Volume of blood in aorta

Increasing total peripheral resistance –> vasocontraction

Question 42

If stroke volume, mean arterial pressure, and heart rate are known, it is possible to determine which of the following?

Answer 42

• Total peripheral resistance

- Cardiac output

Question 43

Arteries offer low resistance. T/F

Answer 43

True, due to the large radii

Question 44

Conducting arteries:

Answer 44

Arteries close to the heart; largest diameter

Question 45

Disturbing arteries:

Answer 45

More muscular arteries (less elastin in tunica intima and more smooth muscle inthe tunica media)

Question 46

Arterioles have a larger tunica ___

Answer 46

Media

Question 47

Elastic arteries contain

Answer 47

Fibers for elasticity

Question 48

Intrinsic Control of Vascular Tone:

Answer 48

Alters the radii of arterioles within a tissue through chemical or physical influences:

Question 49

Nitric oxide and histamines initiate:

Answer 49

Vasodilation

Question 50

Endothelin initiates:

Answer 50

Vasoconstriction

Question 51

Myogenic receptors respond to:

Answer 51

Stretch

Question 52

Extrinsic control of vascular tone is via the

Answer 52

the endocrine or nervous system

Question 53

The sympatheticnervous system (SNS) releasesnoradrenalinewhich acts on:

Answer 53

α-1adrenoreceptors to inducevasoconstriction

Question 54

The SNS releasesadrenaline(from the adrenal medulla) which acts on:

Answer 54

β-2adrenoreceptors to inducevasodilation –> heart and skeletal muscle perfusion.

Question 55

There is no direct parasympatheticnervous system innervation of blood vessels;

Answer 55

Acetylcholine(ACh) is released onto the vascular endothelium –> nitric oxide is release–> local vasodilation)

Question 56

Extrinsic control: Angiotensin & Vasopressin initiate

Answer 56

Vasoconstriction

Question 57

Extrinsic control: Atrial Natriuretic Peptide & Bradykinin initiate

Answer 57

Vasodilation

Question 58

Question: Why doesn’t arterial pressure drop to 0 mmHg in arteries during diastole?

Answer 58

• It is due to the elastic properties of the arterial walls –> driving force for blood flow during diastole.

Question 59

The elastic recoil of the vascular wall functions to:

Answer 59

maintain the pressure gradient that drives the blood through the arterial system.

Question 60

What would occur ifartery walls were rigid and unable to expand and recoil?

Answer 60

Their resistance to blood flow would greatly increase –> blood pressure would rise to even higher levels, –> require the heart to pump harder to increase the volume of blood expelled by each pump (the stroke volume) and maintain adequate pressure and flow.

Question 61

Why do muscular arteries need to be muscular? What can affect the radii of muscular arteries?

Answer 61

To allow for active constriction and relaxation based on the needs of the body.
For example, the autonomic nervous system can release noradrenaline, to induce vasoconstriction. This decreases the radii of muscular arteries, –> during the fight or flight response.

Question 62

An adult has been diagnosed with endothelial dysfunction.

What are the likely future complications, if the condition is not managed correctly?

Answer 62

• Endothelial dysfunction can lead to atherosclerosis. First blood pressure may become more difficult to manage as blood vessels are no longer elastic enough to adapt to increased pressures. Artery wall can thick as the vessel attempts to heal itself, forming plague from blood clots. This could eventually lead to heart attacks and strokes.

Question 63

Capillaries consist of a…

Answer 63

Venous and arterial end

Question 64

Net hydrostatic pressure at the arterial end:

Answer 64

33mmHg out

Question 65

Net hydrostatic pressure at the venous end:

Answer 65

13mmHg out

Question 66

Net oncotic pressure at the arterial end:

Answer 66

20mmHg in

Question 67

Net oncotic pressure at the venous end:

Answer 67

20mmHg in

Question 68

Net filtration pressure at arterial end:

Answer 68

+13mmHg out

Question 69

Net filtration pressure at venous end:

Answer 69

-7mmHg in

Question 70

Precapillary spincters:

Answer 70

Control blood flow through capillary spincters

Squeeze down to inhibit blood flow –> blood flows through to the thoroughfare channel

Question 71

Thereare two opposing important forces driving fluid movement across the endothelial cells:

Answer 71

hydrostatic pressureand oncotic pressure

Question 72

Oncotic pressure:

Answer 72

a form of osmotic pressure induced by proteins, notably albumin, in a blood vessel’s plasma

Question 73

Met-arteriole:

Answer 73

Smooth muscle within the wall

Question 74

True capillaries extend all throughout the individual cells. T/F

Answer 74

True

Question 75

Which of the following components exerts the highest net hydrostatic pressure to promote movement into the capillaries?

Answer 75

Proteins

Question 76

What substances are reabsorbed in the venous end of capillaries?

Answer 76

Carbon dioxide and waste

Question 77

i) How do nutrients such as oxygen move out of the capillaries into tissue?
ii) How do the arterial and venous sections of the capillaries function in capillary exchange?

Answer 77

As blood is pumped into the arteries it exerts a greater force out of the capillaries than force going in (Arterial section).

–> This allows fluid to exit the capillaries through spaces between cells.
Small molecules of nutrients such as oxygen are able to leave the capillary.

During the venous section, the force from being pumped into the capillary has decreased.

Here the concentration proteins i.e. albumin, and low concentration of gasses and small molecules attracts fluid back into the capillary i.e. C02 and waste

Question 78

Compare and contrast the function of smooth muscle in muscular arteries, and pre-capillary sphincters.

Answer 78

Their function is similar. Capillaries do not have smooth muscle covering it (as it needs to be thin for nutrient exchange), it instead has pre-capillary muscular sphincters to regulate amount of blood flow depending on the body’s needs.

Question 79

Capillary walls are 2 cells thick. T/F

Answer 79

False, 1 cell thick

Question 80

Hormones are circulated via the….

Answer 80

Lymphatic system

Question 81

Lymphatic cells are made of…

Answer 81

Endothelium, anchored by collagen filaments

Question 82

The valves open when…

Answer 82

When pressure in the interstitial space is greater than within the capillary

Question 83

Trunks of the lymph system:

Answer 83

• Lumbar (2)
• Broncho-mediastinum (2)
• Subclavian (2)
• Jugular (2)
• Intestinal

Question 84

Thoracic duct includes _____ and drains into the ____

Answer 84

All excl. Right side of head and arm

–> left jugular and left subclavian vein

Question 85

Right lymphatic duct includes ____ and drains ____

Answer 85

Right side of head and arm

–> jugular & subclavian vein

Question 86

Lymphoid organs diffuse lymph tissue, within the GI, respiratory patch, and intestinal wall via the _____

Answer 86

Peyers patches

Question 87

When an infection gets in a tissue:

Answer 87

1. lymphatic capillary 2. lymph node
2. Detected by a dendritic cell
3. Sample lymph and present antigens to B-cell to make anti-bodies 5. plasma cell
4. exit lymph node

Question 88

Antibodies are generated in the…

Answer 88

White pulp of the spleen

Question 89

The red pulp is responsible for…

Answer 89

Recycling old RBCs

Question 90

Lymph ducts terminate in small, blind-ended capillaries. T/F

Answer 90

True

Question 91

Reduced plasma proteins reduces…

Answer 91

Oncotic pressure in plasma

i.e. renal disease or cirrohis

Question 92

Increased venous pressure initiates…

Answer 92

Greater hydrostatic pressure in plasma

i.e. heart failure

Question 93

Increased permeability of capillary walls causes:

Answer 93

plasma proteinsto move into interstitial fluid
–> increasingoncotic pressure in interstitial space
–>fluid retention

i.e. local inflammation

Question 94

Increased blood in veins causes a(n)

Answer 94

Increased hydrostatic pressure in plasma

–> filtration

Question 95

Blockage of lymph vessels causes

Answer 95

A reduction in lymphatic drainage –> accumulation of interstitial fluid in tissues

i.e. surgical removal of lymph nodes in cancer

Question 96

Pleural effusion:

Answer 96

Oedema accumulation in the lungs

Question 97

Pericardial effusion:

Answer 97

Oedema accumulation in the heart

Question 98

Peritoneum effusion/Ascites:

Answer 98

Oedema accumulation in the abdomen

Question 99

Peripheral oedema:

Answer 99

Oedema accumulation in the lower-limb

Question 100

Transudate:

Answer 100

Low in protein and cellular content

• Incr. Hydrostatic pressure
• Decr. Osmotic pressure

Question 101

Excaudate:

Answer 101

High in protein and cellular content

• Inflammatory response
• Lymphatic obstruction

Question 102

SPECgrav:

Answer 102

measuring of density of fluid; transudate or exudate?

Question 103

An excess of instititual fluid causes….

Answer 103

1. Incr. distance between blood and cells
2. Decr. rate of diffusion
3. Inadequate nutrient supply

Question 104

Directcontributors to movement of fluid through the lymphatic system

Answer 104

• Smooth muscle
• Skeletal muscle
• Arterial pulse

Question 105

Veins have low resistance to blood flow, however they are more compliment than arteries. T/F

Answer 105

True

Question 106

The venous system is a reservoir for blood. T/F

Answer 106

True

Question 107

Venous return:

Answer 107

The volume of blood entering theatriumeach minute; stabilised and regulated by veins.

Question 108

End diastolic volume:

Answer 108

Amount of blood in ventricles prior to contaction

Question 109

End diastolic volume
Stroke volume
Cardiac output
are all dependant on…

Answer 109

Venous return

Question 110

Venous pressure is highest in ___

and lowest in ___

Answer 110

Venules

Vena-cava and right ventricle

Question 111

Venous return is affected by:

Answer 111

Skeletal muscles
Sympathetic nerve activity
Respiratory activity

Question 112

Inspiration initiates…

Answer 112

1. Pulls diaphragm down
2. Decr. intrapleural pressure
3. Lungs expand
4. Incr systemic venous return

Question 113

Inspiration decreases ___

and increases ___

Answer 113

Decr. BP

Incr. HR

Question 114

The paradoxical fall in pressure is explained by…

Answer 114

When the vagual tone is reduced, the HR increases

Question 115

Expiration initiates…

Answer 115

1. Relaxation of diaphragm
2. Incr. in intrapeural pressure
3. Deflating of lungs
4. Decr. in venous return
5. Compression of pulmonary vessels

Question 116

Expiration decreases ___ and increases ___

Answer 116

Increases BP, decreases HR

Question 117

Exhalation ___ venous return

Answer 117

Decreases

Question 118

Which is one explanation for an increase in heart rate, when moving from a lying to a standing position?

Answer 118

Venous return

Question 119

How does inhaling increase venous return?

Answer 119

During inhalation, the diaphragm moves down, –> decreasing thoracic pressure.
–> decreased right atrial pressure, facilitating venous return.

The downwards movement of the diaphragm also increases pressure on the abdomen, squeezes blood up towards the heart.

Question 120

How does exhaling decrease venous return?

Answer 120

During exhalation, the diaphragm moves up,

• -> increasing thoracic pressure.
• -> This in turn results in increased right atrial pressure, decreasing venous return.

Question 121

The heart rate depends primarily on the balance between sympathetic and parasympatheric nerve impulses. T/F

Answer 121

True

Question 122

The vagual tone has a dominant effect at rest:

Answer 122

The SA node exhibits spontaneous pacemaker activity with an intrinsic rhythm of about 100-110 bpm. But normal HR is only about 60-70 bpm, which indicates thatvagal (parasympathetic) tone has a dominant influence at rest.

Question 123

To achieve a high HR, vagual tone must be

Answer 123

decreased

Question 124

Parasympathetic preganglionic fibres originate from the dorsal motor nucleus of the vagus nerve and synapse on…

Answer 124

parasympathetic ganglia within the heart –> release acetylcholine on muscarinic receptors on the SA Node, atrial muscle and AV node.

Question 125

It has been found that a natural compound decreases heart rate when inhaled.
Which of the following may be potential reasons why the natural compound decreases the heart rate?

Answer 125

• Decr. Sympathetic output

- Incr. Parasympathetic output

Question 126

A patient undergoing septic shock, characterised by severe vasodilation, and subsequent inability for nutrients such as oxygen to reach areas of the body where it is needed.
Which hormones should be administered to help the patient?

Answer 126

• Noradrenaline should be used to increase vasoconstriction and increase heart rate to help compensate for the vasodilation.

Question 127

A patient with a blockage in the pulmonary artery, due to complications regarding deep vein thrombosis, exhibits symptoms of tachycardia and hyperventilation.
Explain why the patient is suffering these symptoms.

Answer 127

Blockage of the pulmonary artery causes the inability for oxygen to be taken from the lungs and distributed to the organs. This hypoxemia (low oxygen in blood) is one reason heart rate is increased.

Question 128

Stroke volume is calculated by:

Answer 128

End Diastolic Volume - End Systolic Volume

Question 129

Pre-load:

Answer 129

• Myocardial sarcomere length prior to contraction
• Ventricular filling
• Ventricular and pericardial compliance
• Wall thickness;

*Hypertrophy decreases pre-load

Question 130

After-load

Answer 130

• Force that ventricles must contract to eject blood.
• Sum of all elastic and kinetic forces
• Resistance or impendence

Question 131

Contractility (inotropy)

Answer 131

• All other factors that are responsible for changes in myocardial performance

Question 132

Contractility is inhibited by:

Answer 132

Ca2+ and beta-blockers, high concentrations of K+ and Na+

Question 133

Positive chronotrophic agents:

Answer 133

Incr. production of sympathetic neurotransmitters

Noradrenaline
Adrenaline

Question 134

Noradrenaline and adrenaline synapse on

Answer 134

β1 anderoceptors, incr. HR

Question 135

An increase of Ca2+ will likely…

Answer 135

Increase heart contractility

Question 136

Negitive chronotrophic agents:

Answer 136

Increase production of parasympathetic neurotransmitters

Decr. HR

Question 137

PSNS incr. production of acetylcholine, to act on muscurinic2 receptors, to…

Answer 137

Decr. HR

Question 138

A lack of Ca2+ and K+ will ____ heart contractility

Answer 138

Decrease

Question 139

Bradycardia is characterized by a HR of:

Answer 139

<60bpm

Question 140

Tachycardia is characterized by a HR of

Answer 140

> 100bpm

Question 141

Frank Starling law:

Answer 141

The strength of cardiac contraction is dependant on initial fibre length

Question 142

Frank Starling dictates that,

Answer 142

↑ tension is a result of ↑ length
and;
↑ contractilityis proportional to ↑ end-diastolic volume (EDV).

Question 143

Which of the following is consistent with the Frank Starling law?

Answer 143

• An increase in venous return increases stroke volume and cardiac output
• The length tension relationship of muscle fibres and contractility

Question 144

i) The longer the sarcomere the greater the contraction, why is this?
ii) It is possible for sarcomeres to be too long, resulting in decreased contraction, why is this?

Answer 144

The rationale for long sarcomeres and increased contractility is due to increased surface area –> greater calcium sensitivity.

However, sarcomeres that are too long there is less overlap of the thin and thick filaments.

Question 145

Short term Mean Arterial Pressure is determined by

Answer 145

Cardiac Output

Question 146

Long term Mean Arterial Pressure is determined by:

Answer 146

Arterial blood volume and arterial compliance

Question 147

Low blood flow –>

Answer 147

organ failure, shock and death

Question 148

High blood flow –>

Answer 148

extra load causes tissue damage –> cardiac, vascular and renal failure –> shock and death

Question 149

The cardiovascular control center is located within the:

Answer 149

Medulla oblongata

Question 150

The cardiovascular control center receives…

Answer 150

afferent impulses from baroreceptors; and efferent outputs via the ANS

Question 151

Cardioaccelerator centres:

Answer 151

• Stimulate cardiac cells by regulating heart rate and stoke volume.
• SNS activation

Question 152

Cardioinhibitory centres

Answer 152

• Decreases cardiac output and HR

- PNS; vagus nerve

Question 153

Vasomotor centres

Answer 153

• Control vascular tone of smooth muscles within tunica media (arteries, arterioles, veins)
• SNS; noradrenaline –> vasoconstriction

Question 154

Afferent Input is via the:

Answer 154

Cortex, limbic system, hypothalamus, and sensory receptors; baroreceptor, chemoreception, and proprioception

Question 155

Blood pressure is monitored by:

Answer 155

High pressure baroreceptors

Question 156

Baroreceptors regulate short-term control of blood pressure via;

Answer 156

High pressure arterial baroreceptors
and;
Low pressure volume receptors

Question 157

High pressure arterial baroreceptors are located within the

Answer 157

Carotid sinus and aortic arch

Question 158

Low pressure volume receptors are located within the…

Answer 158

Atria
ventricles
pulmonary vasculature

Question 159

Distension depends on…

Answer 159

Venous return

Question 160

The afferent neural pathway from stretch receptors are via the ____ nerve –> Nucleus Tractus Solitarius (NTS)

Answer 160

vagus

Question 161

MAP is controlled via a

Answer 161

Negitive feedback loop

Question 162

Primary function of the baroreceptor reflex is to:

Answer 162

Minimize variations in systemic arterial blood pressure;
whether these variations are caused by postural changes of the animal, excitement, diurnal rhythm, or even spontaneous fluctuations of unknown origin.

Question 163

Arterial baroreceptor afferents innervate:

Answer 163

carotid sinuses, aortic arch and the right carotid artery

-right subclavian artery juncture.

Question 164

Cardiopulmonary baroreceptors innervate

Answer 164

Veno-atrial juncture, Atria,

Ventricles and Pulmonary vasculature.

Question 165

The baroreflexes modulate:

Answer 165

paraSNA and SNA to numerous organ systems and vasopressin (AVP) release.

Question 166

The primary function of the baroreceptor reflex is control of short term, minimisation of blood pressure changes. T/F

Answer 166

True

Question 167

Baroreceptor reflex dysfunction or failure is a rare disorder.
What would be some of the symptoms/consequences of baroreceptor reflex dysfunction disorder?

Answer 167

• Increases blood pressure variability both in the short term, as well as chronically.
• Innocuous changes such as excitement, diurnal rhythm and postural changes can induce large fluctuations in blood pressure.

Chronically it can also increase incidence of hypertension.

Question 168

Bainbridge Reflex:

Answer 168

Ensures cardiac output is proportional to effective circulating volume.

–> It is a counter-balance reflex to the baroreceptor reflex in the control of heart rate.

Question 169

Low pressure baroreceptors trigger tachycardia…

Answer 169

Located within the atria and pulmonary artery
- Distension depends on venous return
- Renin-Angiotensin System
Regulate cardiac output

Question 170

Chemoreceptor Reflex:

Answer 170

Regulate ventilation and cardiac output

Located in the medulla oblongata and, sense low brain pH, which –> high arterial carbon dioxide pressure.

Question 171

CNS: Ischaemic Response

Answer 171

• When blood-flow to the brain is compromised; emergency pressure control –> preserves blood-flow to the brain
• Does not become active until systolic blood pressure < 60 mmHg and is
• Most effective around a systolic pressure of 15 to 20 mmHg.

Question 172

An increase of HR may be due to:

Answer 172

• Activation of the Bainbridge reflex
• Stimulation of atrial baroreceptors
• Stretching of atrium

Question 173

A patient arrives at the emergency after a car crash, where he received a serious blow to the head.
What are the three symptoms to watch for in the patient, and how are the symptoms related to one another?

Answer 173

• After a head injury it is possible the brain will swell up
  –> increases inter-cranial pressure and triggers the Cushing reflex.
  If this increases above that of mean arterial blood pressure, then this could lead to a lack of blood flow to the brain as blood vessels in the brain become compressed by the pressure.

To compensate for this the body increases sympathetic activity in order to increase arterial pressure, resulting in the first symptom- hypertension. However, this hypertension (high blood pressure) triggers baroreceptors which up-regulate the parasympathetic nervous system, –> decreasing heart rate (bradycardia). This hypertension along with inter-cranial pressure presses on the respiratory centre in the cerebellum, causing irregular breathing.

Question 174

Blood pressure =

Answer 174

(Stroke Volume * Heart Rate) * Peripheral Resistance

Question 175

There is no known cause of Primary Hypertension. T/F

Answer 175

True

Question 176

Primary hypertension is characterized by:

Answer 176

High blood volume,
high resistance
incr. In pressure

Question 177

Explain the physiology of hypertension:

Answer 177

When a person has hypertension their baroreceptors begin to maintain the blood pressure at a higher range. This is caused to the baroreceptors being reset to maintain this higher range.
- Acute resetting of baroreceptor pressure-activity relationship to higher mean pressures in hypertension

Question 178

A man dies from a stroke. During autopsy it was found that the walls of his left ventricle has enlarged and thickened.

i) How could hypertension have contributed to the enlargement and thickening of the left ventricle?
ii) How could hypertension have contributed to the patient’s stroke?

Answer 178

• Left ventricular hypertrophy can occur due to chronic hypertension, as the body attempts to increase the strength of the heart to provide organs with nutrients.

If this man had chronic hypertension, then it is possible that this could also be the cause of the stroke. With increased blood pressure, shear stress increases and can cause damage to blood vessels. This damage, over time could form plaques, and restrict bloodflow. A plaque could have developed in the man’s brain, causing stroke.

Question 179

The best place to measure venous return is at the:

Answer 179

Right atrium

Question 180

Venous return fluctuates with…

Answer 180

Respiration

Question 181

Cardiac output is not influenced by reflexes. T/F

Answer 181

False. Reflexes alter CO

Question 182

There is less resistance and pressure within the

Answer 182

Pulmonary circuit, because its shorter

Question 183

Vasoconstriction enhances

Answer 183

Vasoconstriction

Question 184

Factors affecting venous return:

Answer 184

1. Valves
2. Contraction of skeletal muscle
3. Respiration
4. Post-ganglionic noradrenaline
5. Cardiac suction

Question 185

Frank starling refers to the

Answer 185

Intrinsic input-output mechanism

Question 186

The ischemic response:

Answer 186

Maintains blood flow to the brain and heart ONLY

Incr. in HR
Decr. in BP

1. Vasodilation of arteries
2. Decr. in MAP
3. Hypoxia to CVS
4. Big sympathetic release
5. Last ditch effort to stay alive

Question 187

An excess in fluids will cause an _____

Answer 187

Incr. in BP

Question 188

The bainbridge reflex prevents…

Answer 188

Damming of blood in veins, atria, and pulmonary circuit

Question 189

An increased Total Peripheral Resistance will lead to…

Answer 189

An increase in MAP

Question 190

decreased sympathetic activity gives an increase in MAP. T/F

Answer 190

False

Question 191

Positive chronotrophic agents:

Answer 191

• Increased temperature at SA node
• Sympathetic nervous system input to SA node
• Increased plasma Ca2+
• Adrenaline

Question 192

Increased plasma K+ is a positive chronotrophic agent. T/F

Answer 192

False

Question 193

____ inhibits venous return

Answer 193

Gravity

Question 194

Inspiration inhibits venous return. T/F

Answer 194

False

Question 195

Vasoconstriction inhibits venous return. T/F

Answer 195

False

Question 196

enlargement of the right atrium during contraction of the right ventricle inhibits venous return. T/F

Answer 196

False

Question 197

The cerebral reflex involves…

Answer 197

Low blood perfusion of cardiovascular centre

Question 198

Baroreceptors in the carotid sinus are…

Answer 198

At an appropriate position to protect the brain from changes in pressure

Question 199

Baroreceptors in the carotid sinus monitor the volume of blood in the carotid arteries. T/F

Answer 199

False

Question 200

Collectivly,
Increased venous pressure
Local inflammation resulting in ancreased capillary permeability
Surgical removal of lymph nodes and;
Reduced plasma protein concentrations can cause…

Answer 200

Oedema