control of heartrate

Question 1

how is cardiac output measured

Answer 1

cardiac output = heart rate (bpm) x stroke volume (cm3min-1 or dm3min-1)

Question 2

define myogenic

Answer 2

contraction is initiated from WITHIN the muscle itself (without receiving external nerve impulses)

Question 3

give the steps of how to control heart rate

Answer 3

• sinoatrial node is in wall of right atrium (commonly known as pacemaker)
• wave of electrical excitation spreads out from SAN across both atria causing them to contract
• atrioventricular septum prevents wave crossing to ventricles
• wave of excitation enters the atrioventricular node (AVN)
• AVN after a short delay conveys a wave of electrical excitation between ventricles along the purkyne tissue which collectively makes up the bundle of his
• bundle of his conducts the electrical wave through the atrioventricular septum to base of ventricle where bundle of his branches into smaller purkyne tissue
• wave of excitation is released from purkyne tissue, causing ventricles to contract quickly at the same time from the bottom of the heart upwards

Question 4

Describe the autonomic nervous system

Answer 4

The autonomic nervous system controls the involuntary activities of internal muscles and glands. It has two branches sympathetic (stimulates effectors and speeds up responses) and parasympathetic (inhibits effectors and slows responses)

Question 5

Explain the role of chemical receptors in the control of heart rate

Answer 5

Chemoreceptors in wall of carotid arteries and aorta are sensitive to changes in pH of blood that occur as a result of changes in carbon dioxide concentration (carbon dioxide lowers pH)

Chemoreceptors detect lowered pH and increase frequency of impulses to centre in medulla oblongata that increases heart rate

Centre increases frequency of impulses via sympathetic nervous system to SAN which increases rate of nerve impulses and therefore heart rate

Increased blood flow increases carbon dioxide removed by lungs and therefore carbon dioxide concentration and pH of blood is reduced

The change is detected by the chemoreceptors and impulses via the sympathetic nervous system decrease, decreasing heart rate

Question 6

Explain the role of pressure receptors in the control of heart rate

Answer 6

Pressure receptors in the walls of the carotid artery and aorta detect high blood pressure and transmit more impulses to the centre in the medulla oblongata that decreases heart rate

Centre sends impulses via the parasympathetic nervous system to the SAN which decreases heart rate

Pressure receptors in the walls of the carotid artery and aorta detect low blood pressure and transmit more impulses to the centre in the medulla oblongata that increases heart rate

Centre sends impulses via the sympathetic nervous system to the SAN which increases heart rate

Question 7

why is the delay between the AVN sending a wave of electrical excitation between the ventricles important?

Answer 7

the delay is important as it allows the flow of blood from atrium to ventricles

this ensures atria are fully empty before ventricles contract

Question 8

why is it important that the wave of excitation causes ventricles to contract at the same time from the bottom of the heart upwards

Answer 8

helps with flow of blood as heart contracts as it pushes blood upwards out of the heart

Question 9

where are the chemoreceptors in the heart

Answer 9

in the aorta, carotid arteries, medulla

Question 10

what do chemoreceptors in the heart respond to

Answer 10

changes in blood glucose concentration and pH

Question 11

where are the baroreceptors located in the heart

Answer 11

in aorta and carotid arteries

Question 12

what do the baroreceptors in the heart respond to

Answer 12

high or low blood pressure