Module 1 - cardiovascular system

Question 1

How many circuits does the cardiovascular
system have?

Answer 1

Pulmonary and systemic

Question 2

Which system has the highest pressure?

Answer 2

Systemic

Question 3

How many chambers does the heart have?

Answer 3

Two atria & two ventricles

Question 4

Which chamber is the most muscular?

Answer 4

Left ventricle

Question 5

How many valves does the heart have?

Answer 5

2 x atrioventricular valves (tricuspid and bicuspid)
2 x semilunar valves (pulmonary and aortic)

Question 6

Why are valves important?

Answer 6

To prevent backflow of blood

Question 7

describe the functions of the cardiovascular system

Answer 7

TRANSPORT SYSTEM
* oxygen and nutrients to cells
* wastesincluding CO2
* hormones (endocrine)
HOMEOSTASIS
* body temperature by redistributing blood
* pH levels in blood & interstitial fluid
* blood volume/blood pressure
PROTECTION
* white blood cells (WBC) immune response

Question 8

what are the major structures of the cardiovascular system?

Answer 8

1. BLOOD: fluid connective tissue that is transported in the cardiovascular system
2. HEART: muscular organ that pumps blood through blood vessels to all body parts
3. BLOOD VESSELS:
   - Arteries:
   - Capillaries:
   - Veins:
   carry blood AWAY from the heart
   exchange of gases, nutrients & waste products between blood & tissues
   return blood TOWARD the heart

Question 9

what is the septum of the heart?

Answer 9

dividing wall between the right and left sides of the heart.

Question 10

what is the heart surrounded by?

Answer 10

pericardium

Question 11

what is the pericardium and the various layers within the pericardium?

Answer 11

The pericardium:
* maintains the hearts position
* prevents heart from overfilling
* outer fibrous pericardium
* inner serous pericardium
* parietal layer of serous
pericardium
* visceral layer of serous
pericardium
The pericardial cavity is between
the 2 serous layers (fluid)

Question 12

describe what the coronary arteries do and where they are

Answer 12

-are the arterial blood vessels of coronary circulation, which transport oxygenated blood to the heart muscle.
-The heart requires a continuous supply of oxygen to function and survive, much like any other tissue or organ of the body.
-wrap around the entire heart.

Question 13

Anatomical differences between the right and left ventricles

Answer 13

The left ventricle has thicker walls than the right because it needs to pump blood to most of the body while the right ventricle pumps blood only to the lungs.

Question 14

where and how does blood enter the heart?

Answer 14

Deoxygenated venous blood from
the peripheral organs and tissues
enters the right atrium through the
superior and inferior vena cava
* This blood then enters the right
ventricle via the tricuspid valve

Question 15

location of the tricuspid valve

Answer 15

the right side of the heart. Another
name right atrioventricular
valve.

Question 16

location and function of the bicuspid valve

Answer 16

The left side of the heart. Another name mitral valve or left atrioventricular valve.

works better on the high-pressure side because, with only two sides to the valve, the muscles and ligaments are able to spring back from the high pressure on the left side of the heart.

Question 17

describe the papillary muscles

Answer 17

located in the ventricles of the heart. They attach to the cusps of the atrioventricular valves (also known as the mitral and tricuspid valves) via the chordae tendineae and contract to prevent inversion or prolapse of these valves during ventricular contraction.

Question 18

function and location of semilunar valves

Answer 18

(aortic and pulmonary valve): situated between the aorta and the left ventricle and between the pulmonary artery and the right ventricle. These valves permit blood to be forced into the arteries but prevent backflow from the arteries into the ventricles

do not have chordae tendineae that attach to papillary muscles

Question 19

what is the direction of blood flow through the hear

Answer 19

unidirectional flow
-The blood MUST flow through each
circuit before returning to the heart.

Question 20

what are the two circuits in the heart?

Answer 20

1. systemic circulation (high pressure)
2. pulmonary circulation (low pressure)

Question 21

describe blood flow in the systemic circulation

Answer 21

blood flows in parallel through many different organs and tissues (i.e., it is ‘shared’ between these organs and tissues)

◼ High O2 in the arteries
◼ Low O2 in the veins

~84% of blood in body

Question 22

describe blood flow in the pulmonary circulation

Answer 22

all the blood flows only through the lungs

◼ Low O2 in the arteries
◼ High O2 in the veins

~16% of blood in body

Question 23

what are the components of the heart in order of blood flow

Answer 23

Atria -> Ventricles -> Arteries -> Arterioles -> Capillaries -> Venules ->
Veins

Question 24

function of atria

Answer 24

receive blood returning to the heart from the veins (RA = deoxygenated, LA = oxygenated) Contraction fills ventricles

Question 25

function of ventricles

Answer 25

their contraction generates the
pressure to drive the flow of blood (RV = pulmonary, LV = systemic)

Question 26

function of arteries and arteries in the heart/ cardiovascular system

Answer 26

conduct blood to organs and tissues with little loss of pressure.

Pulmonary artery: Takes deoxygenated blood from the heart to the lungs

Aorta: carries oxygenated blood to
peripheral organs

Question 27

function of arterioles

Answer 27

smallest arteries branch into arterioles. Control resistance to flow, thus, the distribution of flow to different organs and tissues.

Question 28

function of capillaries

Answer 28

main site where substances are
exchanged between the blood and cell of the body.

Question 29

function of venules

Answer 29

collect blood from the capillaries.

Question 30

function of veins and veins in the heart/ cardiovascular system

Answer 30

return blood to the heart

Superior vena cava: return deoxygenated blood from the systemic circulation to the right atrium of the heart. It receives venous return from the upper half of the body

Inferior vena cava: return deoxygenated blood from the systemic circulation to the right atrium of the heart. It receives venous return from the lower half of the body

Pulmonary veins: Brings oxygenated blood from the lungs to the heart

Question 31

blood flow through the heart

Answer 31

Deoxygenated venous blood
from the peripheral organs and
tissues enter the right atrium
through the superior and
inferior vena cava

This blood then enters the right
ventricle via the tricuspid valve

From the right ventricle blood is
pumped to the pulmonary artery
via the pulmonary valve to blood
vessels in the left and right lungs

Lungs remove Co2 and add O2 to
the blood

Oxygenated blood enters the left atrium via the pulmonary vein

Blood then enters the left ventricle
through the mitral valve (bicuspid valve)

Left ventricle ejects blood to the aorta via the aortic valve

Aorta distributes blood into
various organs in the body

Question 32

explain the diastole and systole phases of the heart

Answer 32

Diastole and systole are two phases of the cardiac cycle. They occur as the heart beats, pumping blood through a system of blood vessels that carry blood to every part of the body.

Systole = when the heart contracts to pump blood out.

Diastole = when the heart relaxes after contraction (filling).

Question 33

describe the cardiac cycle and events within each step of the cycle

Answer 33

the cycle of contraction and relaxation

Remember
❑ Blood always flows from a region of high pressure to a lower pressure.
❑ Heart valves are either open or shut depending on the relative pressures on either side of the valve.

a) atrial systole begins: (upper 2 chambers) atrial contraction forces a small amount of additional blood into relaxed ventricles (atrial systole + ventricular diastole)

b) atrial systole ends, atrial diastole begins

c) ventricular systole - 1st phase: ventricular contraction exerts enough pressure on the blood to close AV valves but not enough to open semilunar valves

d) ventricular systole - 2nd phase: as ventricular pressure rises and exceeds pressure in the arteries the semilunar valves open and blood is ejected into blood vessels

e) ventricular diastole - early: as ventricles relax, pressure in ventricles drops; blood flows back against cusps of semilunar valves and forces them closed. Blood flows into the relaxed atria

f) ventricular diastole - late: all chambers are relaxed. ventricles fill passively.

Question 34

describe the heart sounds

Answer 34

the result blood turbulence

S1 - First heart sound “lub”: two bursts of vibrations (“turbulence”) due to sequential closure of Mitral and Tricuspid valves.
S2- Second heart sound “dub”: vibrations due to closure of aortic and pulmonary valves.
S3- Third heart sound: marks end of rapid filling phase. Due to “recoil” of blood from ventricular wall.
S4- Fourth heart sound: coincides with atrial contraction. Normally not heard. Indication of pathology involving strong atrial contraction.

Question 35

define end-diastolic volume (EDV)

Answer 35

Volume of blood in the ventricle
during relaxation and prior to ventricular contraction

Question 36

define end-systolic volume (ESV)

Answer 36

Volume of blood in the ventricle
after contraction

Question 37

define stroke volume (SV)

Answer 37

Volume of blood pumped out of each ventricle during a single contraction (volume of blood pumped per heartbeat).

Stroke volume = End diastolic volume (EDV) – end-systolic volume (ESV)

Question 38

define cardiac output

Answer 38

• Volume of blood pumped by each ventricle per minute
• Indicates blood flow through peripheral tissues

Cardiac output (CO) = Heart rate (beats/min) x stroke volume (ml/beat)

Question 39

define preload

Answer 39

= amount of stretch during diastole (diastole = when the heart is relaxing)
* More stretch of the cardiac muscle = greater force of the cardiac contraction
* Primary determinant of preload = left ventricular end diastolic volume (EDV)
* Greater the EDV, greater the cardiac contraction

Question 40

define afterload

Answer 40

= amount of resistance the heart must overcome when ejecting blood

The main determinant of afterload is resistance in the blood vessels

Question 41

explain venous return

Answer 41

= The volume of blood returning back to the heart each minute
– Increased venous return increases EDV
– Causes heart muscle to stretch (increased preload due to increased
EDV)
– As cardiac muscle stretches, the next contraction will be stronger

Question 42

describe the Frank-Starling Law

Answer 42

intrinsic property of cardiac tissue

The greater the end-diastolic volume, the greater the force of contraction during systole (within limits!)

Stretching the cardiac muscle cells produces a more optimum overlap between thick & thin filaments, leading to a stronger contraction

Question 43

what 2 things increase stroke volume

Answer 43

Frank-starling law and increased sympathetic activity

Question 44

ways that stroke volume is increased through intrinsic and extrinsic controls

Answer 44

intrinsic controls
increased venous return = increased EDV = increased strength of cardiac contraction = increased stroke volume

extrinsic controls
increased sympathetic activity (and epinephrine) = increased venous return AND = increased strength of cardiac contraction

Question 45

what are the factors that influence cardiac output?

Answer 45

increased venous return (FS law) = increased EDV = greater cardiac contraction = greater stroke volume

increased sympathetic activity = increased venous return + cardiac contractility = increased stroke volume

increased sympathetic activity = increased HR

parasympathetic = decreased HR = decreased cardiac output

Question 46

what are the two cell types of cardiac muscle cells (cardiomyocytes)

Answer 46

1. contractile:
   Almost all of the cardiac cells are contractile cardiac muscle cells (pumping activity).
2. non-contractile/ autorhythmic: pacemaker cells
   Pacemaker cells can spontaneously depolarize (auto-rhythmicity and
   intrinsic conduction system) (no neural input is required). Transplanted hearts – can cut all neural input but it still beats

Question 47

what is the composition of contractile cells?

Answer 47

Contractile cells are composed of many tubular myofibrils.

Mitochondria account for 25-35%of volume of cardiac cells
* Most of the remaining volume is occupied by myofibrils composed of typical sarcomeres

Question 48

what are myofibrils?

Answer 48

contractile units and repeating sections of sarcomeres that are
contractile units with actin (thin filaments) and myosin (thick filaments)

Question 49

what is the intercalated disk?

Answer 49

The junction between cardiac cells

Question 50

explain the contraction of cardiac muscles

Answer 50

Heart cells are electronically joined
together by gap junctions. pacemaker cells can not only initiate their own depolarization but also that of the rest of the heart

• Gap junctions tie cardiac muscle cells together to form a functional unit. Allows the wave of depolarization to travel from cell to
  cell across the heart. (Acts as a single big motor unit)
• Contraction of all cardiac myocytes
  ensures effective pumping by the
  heart

Question 51

explain excitation-contraction coupling in the cardiac muscle

Answer 51

• The process whereby an electrical stimulus is converted to a mechanical response.
• Action potentials triggered by pacemaker cells (electrical stimulus) initiate cardiac contraction (mechanical response).

Action potential travels down T tubules; causes sarcoplasmic reticulum (SR) to release Ca2+
– Ca2+ leads to binding of actin and myosin filaments leading to contraction of the cardiomyocyte.

Question 52

what are the three criteria must the heart meet for the spread of excitation

Answer 52

1. Each heart chamber must pump as a unit
2. Atria should contract together; ventricles should contract together
3. Atrial excitation & contraction must complete before ventricular contraction

Question 53

Describe the spread of excitation through the heart

Answer 53

The sinoatrial node in the right atrium is the primary pacemaker of the heart. Atrioventricular node delays impulse spread. Atrioventricular bundle conducts the impulse to the interventricular septum. AV bundle splits into L & R bundles. Connect with Purkinje fibres in the apex – contraction spreads through L & R ventricles.

another explanation:
Action potential spreads through the heart > this induces calcium release in the heart> calcium is required for actin-myosin binding in cardiac contractile cells > actin-myosin binding leads to contraction of the cell.

Question 54

describe the electrical conduction system of the heart

Answer 54

Sinoatrial (SA) Node: The process starts in the right atrium with the SA node, often referred to as the heart’s natural pacemaker. The SA node initiates an electrical signal, which causes the atria to contract. This signal spreads across both the right and left atria, causing them to contract and push blood into the ventricles.

Atrioventricular (AV) Node: The electrical signal then reaches the AV node, which is located in the lower part of the right atrium near the ventricles. The AV node is like a ‘gatekeeper’ – it slows down the electrical signal before it enters the ventricles. This slight delay allows the atria to fully empty their contents into the ventricles before ventricular contraction (systole) begins.

Bundle of His/ AV bundle: From the AV node, the electrical signal travels down a pathway called the Bundle of His. This bundle divides into right and left bundle branches along the interventricular septum, which separates the right and left ventricles.

Purkinje Fibers: The bundle branches then divide into thin, wire-like structures called Purkinje fibers. These fibers distribute the electrical signal throughout the ventricles, causing them to contract and pump blood – to the lungs from the right ventricle, and to the rest of the body from the left ventricle.

Question 55

in terms of the regulation of heart rate, describe the impacts of Sympathetic stimulation
of SA node

Answer 55

 Noradrenaline (adrenaline)
 Increases rate of closure of K+
channels and inward leak of Na+
(and Ca2+)
 Faster rate of “slow” depolarisation
 Threshold reached earlier
 Heart rate increases

Question 56

in terms of the regulation of heart rate, describe the impacts of parasympathetic stimulation
of SA node

Answer 56

 Acetylcholine (vagus nerve)
 Hyperpolarises SA node cells
 Decreases rate of closure of K+ channels and inward leak of Na+ (and Ca2+)
 Slower rate of “slow” depolarisation
 Takes longer to reach threshold
 Heart rate decreases

Question 57

what are the blood vessels in the body and what do they do

Answer 57

• Arteries: carry blood AWAY from the heart (mostly oxygenated, not always!)
• Capillaries: exchange of gases, nutrients & waste products between blood & tissues
• Veins: return blood TOWARD the heart (mostly de-oxygenated, not always!)

Question 58

Compare the walls of arteries, capillaries & veins

Answer 58

*Arteries & veins have similar 3 layers but they vary in relative thickness
* Arteries have a smaller lumen to a comparable-sized vein
*Arteries have a muscular wall, veins have scant smooth muscle
*Arteries contain elastic lamellae

Capillaries only have tunica intima

because arteries are designed to withstand higher pressures than veins

Question 59

Summarise blood vessel structure and function

Answer 59

• Arteries carry blood away from the heart.
• Arterioles distribute blood to capillary beds.
• Capillaries exchange gas, nutrients and waste between blood and tissues.
• Venules receive blood from capillaries.
• Veins return blood towards the heart.
• Arteries, arterioles, veins and venules have Tunica intima, Tunica media, Tunica externa.
• Capillaries only have tunica intima. Arteries & veins have similar 3 layers but they vary in relative thickness
• Arteries have a smaller lumen to a comparable sized vein
  *Arteries have a muscular wall, veins have scant smooth muscle
• Arteries contain elastic lamellae and their structure reflects their function.
  Arteries are designed to withstand higher pressures than veins

Question 60

describe the structure and function of capillaries

Answer 60

• Link arteries with veins
• Microscopic (<10µm diameter, 1mm long)

The exchange of materials between the blood and body can only occur
at the level of capillaries

Question 61

true or false small & medium veins contain valves

Answer 61

true, because blood only flows in the direction of the heart

Question 62

summarise pulmonary circulation

Answer 62

2 arteries, 4 veins

low pressure pump

*Right ventricle pumps into
*Pulmonary trunk
*1 left & 1 right pulmonary
artery carry oxygen-poor
(deoxygenated) blood to each
lung
*2 left & 2 right pulmonary veins
from each lung carries oxygen rich
(oxygenated) blood to the left
atrium

Question 63

summarise systemic circulation

Answer 63

All systemic arteries branch from
the aorta

DEEP VEINS:
* Usually accompany the arteries and share similar names
* Some exceptions
SUPERFICIAL VEINS:
* Located just below the skin

The body can shunt blood between the deep & superficial veins for body temperature control

Systemic blood leaves the heart through 1 artery. Returns via 3 systemic veins to the right atrium

Superior vena cava:
Receives blood from the body superior to the diaphragm (except the lungs)

Inferior vena cava:
Receives most of the blood from the body inferior to the diaphragm

Coronary sinus:
Receives blood from the heart

Question 64

Describe the three components of blood

Answer 64

55% plasma = H20 + proteins (fibrinogen) + other
1% “buffy coat” = leukocytes + platelets
44% erythrocytes

Question 65

What is the function of
blood vessels?

Answer 65

• ‘Vascular highways’ that transport blood around
  the body to meet demands:
  – Oxygen delivery
  – Nutrient delivery
  – Waste removal
  – Chemical messenger delivery (e.g. hormones)
  – Maintain body temperature

Question 66

Distribution of blood
around the body

Answer 66

• Parallel arrangement of vessels from the aorta ensures fresh blood to all organs
• Blood flow to each organ can be changed independently

Question 67

the rate at which blood flows
through the circulatory system is
dependent on…

Answer 67

– The pressure gradient (ΔP)
– The resistance to blood flow (R)
F = ΔP/R

The heart has to generate enough
pressure to overcome resistance to
blood flow

Question 68

what is the pressure gradient?

Answer 68

The difference in pressure between the two ends of a vessel, not the
absolute pressures within the vessel determines flow rate

Question 69

Resistance to blood flow is due to 3
factors….

Answer 69

– blood viscosity (η) – direct proportional
– vessel length (L)– direct proportional
– vessel radius (r) – inversely proportional

The most important of these is
radius (r)
Double the radius = increase blood flow by 16 times!

Question 70

describe blood viscosity

Answer 70

Viscosity is the resistance to flow caused by interactions among
molecules and suspended materials in a liquid. Liquids with low viscosity, such as water (viscosity 1.0), flow at low pressures.

Under normal conditions, the viscosity of blood remains stable.
Anemia, polycythemia, and other disorders that affect the hematocrit also change blood viscosity, and thus peripheral resistance.

Question 71

describe turbulence

Answer 71

High flow rates, irregular surfaces, and sudden changes in vessel
luminal diameter upset the smooth flow of blood, creating eddies and swirls. This phenomenon, called turbulence, increases resistance and slows blood flow.
* Turbulence normally occurs when blood flows between the atria
and the ventricles, and between the ventricles and the aortic and
pulmonary trunks. It also develops in large arteries, such as the aorta, when cardiac output and arterial flow rates are very high.
* However, turbulence seldom occurs in smaller vessels unless
their walls are damaged

Question 72

describe Poiseuille’s law

Answer 72

The precise relationship between flow, pressure, and resistance

Flow rate = (π/8) ΔP r4/ηL
Where P=Pressure; r= radius; viscosity= η and L= length.

Question 73

describe arteries as a pressure reservoir

Answer 73

• Elastin allows arteries to expand like a balloon & temporarily hold excess blood
• When the heart is in diastole, stretched arterial walls recoil & exert pressure on blood, ensuring continued flow even when heart is relaxed & not pumping

Question 74

how do arterioles regulate blood flow to issues?

Answer 74

Vascular smooth muscles can contract or relax:
Contraction → vasoconstriction
Relaxation → vasodilation

intrinsic controls
- control entirely within tissue or organ
- uses paracrine or properties of muscle tissue

extrinsic controls
- control from outside the tissue or organ
- uses nerves or hormones

Question 75

How is diffusion maximized in capillaries?

Answer 75

Minimal distance
* Single layer of endothelial cells
* Thin wall (1 μm) & small diameter (7 μm)
* Proximity to cells
Capillaries: sites of exchange
Maximal surface area
* High numbers (10-40 billion) =600m2
Maximal time
* Velocity is slow due to extensive
branching
Permeability
* Molecules pass between or
through endothelial cells

Question 76

how do capillaries control blood flow?

Answer 76

• Pre-capillary sphincters are smooth
  muscle cells that spiral capillaries:
  sensitive to local metabolic factors
• If metabolic activity increases,
  sphincters relax → increase flow
• If metabolic activity decreases,
  sphincters contract → flow is
  bypassed

Question 77

function of venules

Answer 77

• Blood flows from capillaries into venules
• These converge to form veins that exit the organ
• They have little tone or resistance
• Communicate with arterioles, chemically, to match inflow & outflow

Question 78

function of veins

Answer 78

Return blood toward the heart
- Large radius
- Low resistance
- Less smooth muscle with little myogenic tone
- Less elastin so little recoil

Highly compliant → huge storage
capacity therefore called capacitance vessels

Question 79

what is Mean Arterial Blood Pressure and what determines it

Answer 79

driving force for the flow of blood through organs and tissues.

◼ Mean arterial blood pressure is determined by two factors:
1) The Cardiac Output (CO), and
2) The Total Peripheral Resistance (TPR)
MAP = CO X TPR

– Pulse pressure phases out
near end of arterial tree
– Flow is non pulsatile with a
steady MAP pressure
* Heart spends more time in
diastole, so not just a simple
average of diastole and systole

Question 80

what is Total Peripheral Resistance?

Answer 80

The sum of the resistance of all of the blood vessels.
◼ Mainly determined by the arterioles.
- changes in TPR are mainly brought about by changes in the state of constriction or dilation of arterioles.

Question 81

describe systemic blood pressure

Answer 81

• Pumping action of heart generates blood flow
• Pressure results when flow is opposed by resistance
• Systemic pressure is highest in aorta and declines throughout pathway
  – Steepest drop occurs in arterioles

Question 82

what are the 2 factors that determine arterial blood pressure?

Answer 82

1. Elasticity (compliance or
   distensibility) of arteries
   close to heart
2. Volume of blood forced into
   them at any time
   Blood pressure near
   heart is pulsatile
   – Rises and falls with each
   heartbeat

Question 83

explain Systolic pressure

Answer 83

pressure exerted in aorta during ventricular contraction
– Left ventricle pumps blood into
aorta, imparting kinetic energy
that stretches aorta
– Averages 120 mm Hg in normal
adult

Question 84

explain diastolic pressure

Answer 84

lowest level of aortic pressure when the heart is at rest

Question 85

explain pulse pressure

Answer 85

difference between systolic and diastolic pressure

Question 86

what is your pulse?

Answer 86

throbbing of arteries due to
difference in pulse pressures, which
can be felt under skin

Question 87

how do you measure blood pressure?

Answer 87

Systemic arterial BP is measured indirectly by auscultatory methods using a sphygmomanometer
1. Wrap cuff around arm superior
to elbow
2. Increase pressure in the cuff until it
exceeds systolic pressure in brachial artery
3. Pressure is released slowly, and the examiner listens for sounds of Korotkoff with a stethoscope (details later)

Systolic pressure:
normally less than 120 mm Hg
– Pressure when sounds first occur as blood starts to spurt through artery

Diastolic pressure:
normally less than 80 mm Hg
– Pressure when sounds disappear because artery no longer constricted; blood flowing freely

Question 88

what the factors that affect regulation of blood pressure?

Answer 88

– Short-term regulation: neural controls
– Short-term regulation: hormonal controls
– Long-term regulation: renal controls

Question 89

what are the 2 neural mechanisms that control peripheral resistance?

Answer 89

1. MAP is maintained by altering blood vessel diameter,
   which alters resistance
   * Example: If blood volume drops, all vessels constrict
   (except those to heart and brain)
2. Can alter blood distribution to organs in response to
   specific demands

Question 90

what is the short-term neural controls of MAP?

Answer 90

Baroreceptor reflex
Cardiovascular center of medulla

Question 91

what is the main long-term control of MAP?

Answer 91

regulation of blood volume

Question 92

what is the role of the Baroreceptor Reflex?

Answer 92

◼ Provides for rapid adjustment of mean arterial blood pressure in the event of sudden disturbances.
◼ very quickly (within several seconds to minutes) compensate for any sudden changes in blood pressure.

• Carotid sinuses
  – Monitor blood flow to the brain
• Aortic arch
  – Monitor blood flow to the systemic circulation

The rate of action potential firing is proportional to arterial pressure
- if pressure rises the rate of baroreceptor firing increases
- if pressure falls rate of baroreceptor firing decreases

-> Sends information to the medullary cardiovascular center

Question 93

what is the role of the cardiovascular control center?

Answer 93

Located in the medulla oblongata
– Receives sensory info about blood pressure (baroreceptors)
– Regulates sympathetic & parasympathetic activity to heart and vessels