Cardiovascular physiology Flashcards
What is valve regurgitation
Blood leaks back into chambers; occurs when a valve does not close tightly
How are the left and right atria separated
By fibromuscular wall - Atrial (interatrial) septum
Where does the Left Atria receive blood from
Pulmonary vein
Where does the right Atria receive blood from
Superior and Inferior Vena Cava
Why does the left ventricle have a thicker muscular wall than the right ventricle
A high pressure is required to eject blood from the LV, through the aortic valve, into the aorta
Which ventricle pumps deoxygenated blood
Right ventricle
What is the cardiac afterload
The pressure the heart must eject blood against
-Left Ventricle
Afterload is relative to the aortic pressure
-Right Ventricle
Afterload is relative to that of the pulmonary artery pressure
What allows blood to flow between right atria and right ventricle
Tricuspid valve
How does blood flow from left atrium to left ventricle
Mitral (bicuspid) valve
What are papillary muscles
Muscular projections of the ventricular walls connected to valve cusps by fibrous Chordae Tendineae
Function to prevent backflow of blood and limits valve cusp movements
Why do valves not lift open when under pressure
When valves fill up with blood and close the valve, papillary muscles anchor the valve to chordae tendineae allowing the valves to remain closed under pressure preventing cusps from lifting open
What are the semilunar valves of the heart called and where are they situated
Pulmonary valve - permits blood flow between right ventricle and pulmonary artery (right)
Aortic valve - permits blood to flow between the left ventricle and aorta (left)
What forces the semilunar valves closed
The pressure difference between the artery and the ventricle
How are the heart sounds generated
Sound one -AV vales closing (LUB)
Sound two - Semilunar valves closing (DUB)
What is valve stenosis
Thickening/stiffening of valve cusps
Prevents the heart valve from opening fully; not enough blood can flow through
When might a third heart sound be heard
Due to oscillation of blood flow into the ventricle or various disease states (e.g. heart valve defect)
What are congenital heart defects
Often pulmonary / aortic valves that do not form properly during development
What is the flow of blood during the cardiac cycle
Superior/inferior Vena Cava
Right Atrium
Tricuspid valve
Right Ventricle
Pulmonary valve
Pulmonary artery
Lungs
Pulmonary veins
Left Atrium
Mitral valve
Left Ventricle
Aortic valve
Aorta
Tissues of body systems
What is systole
A phase of the cardiac cycle which involves contraction of the myocardium
ATRIAL SYSTOLE
-atrial contraction to eject blood into ventricles
VENTRICULAR SYSTOLE
-ventricular contraction to eject blood into aorta (LV) and pulmonary artery (RV)
What is Diastole
Relaxation of the myocardium which facilitates re-filling of ventricles between contractions
ATRIAL DIASTOLE
-relaxation of atrial muscle, to allow refilling (masked by ventricular systole)
VENTRICULAR DISTOLE
-ventricular relaxation
How does rapid ventricular ejection occur (blood leaves heart)
-Pressure in the ventricles exceeds pressure in the aorta and pulmonary artery
-Semi-lunar valves open and blood is ejected from LV into aorta and from RV into pulmonary artery
-Volume of blood ejected from ventricle during systole = stroke volume (SV)
What is stroke volume
The volume of blood pumped from the left ventricle per contraction
What is isovolumetric ventricular contraction
‘no change in volume’ contraction
when contracting is starting but not enough to force valves open to eject blood
What is EDV end diastolic volume
Volume of blood in the ventricle prior to contraction
What does ESV end systolic volume refer to
Volume of blood remaining in ventricle after each ejection as ventricles are not fully emptied during systole
What is the ejection fraction
The volume of blood ejected by the ventricle with each contraction, as percentage of end diastolic volume (what systole begins with)
What is cardiac output and the equation
Volume of blood ejected in one minute
Cardiac Output (CO) = Stroke Volume (SV) x Heart Rate (HR)
What percentage ejection fraction indicates a severely impaired LV
<35%
How is heart rate determined
By the rate which the cardiac pacemaker (sino-atrial node) fired action potentials to stimulate contraction of the cardiac muscle
What is the resting heart rate
60-100 bpm
What determines the rate of action potential firing and heart rate
Activity of the Autonomic nervous system
What do these terms mean:
A-Chronotropy
B-Inotropy
C-Lusitropy
D-Dromotropy
A-Increases heart rate
B-Strength of myocardial contraction
C-Rate of myocardial relaxation
D-Conduction speed in AV node
What cardiac effects does the sympathetic nervous system have
Positive chronotropy
Positive inotropy
Positive lusitropy
Positive dromotropy
What cardiac effects does the parasympathetic nervous system have
Negative Chronotropy
Negative inotropy
Negative lusitropy in atria
Negative dromotropy
Why does the parasympathetic system have these effects
Cholinergic nerves derived from the vagus nerve
Release neurotransmitter Acetylcholine (Ach)
Binds to M2 muscarinic receptors in cardiac muscle, particularly at the SA & AV nodes
Activates inhibitory G-protein
Blocking cAMP pathway and allows K+ efflux from cell
what is the membrane potential
-Potential difference between intra and extra cellular sides of the membrane
-Generated by ion gradients across the cell membrane
-Dependent on ionic gradients across membrane and ionic permeability
What is depolarisation
Potential (electrical) difference across the cell membrane becomes ‘less negative’
What is repolarisation
Potential difference across sarcolemma returns to resting Vm following depolarisation (becomes ‘more negative’)
What happens during contraction of a cardiomyocyte
-T tubules takes signal deep into cell
-Calcium induced calcium released, small influx triggers greater release of calcium
-Falls during diastole
-Calcium is removed by sodium channel or by ATPsse
-Action potential triggers the calcium induced calcium release allowing calcium to bind to contractile apparatus
What does an increase in calcium within cardiac myocyte cytosol do
Increase the force of myocardial contraction of the cell due to excitation - contraction coupling
How can the force of cardiac contraction be influenced
By the length of the heart muscle cell
Level of calcium within the cardiac myocyte cytosol
What is Starling’s Law
The force of muscle contraction increases as the muscle is stretched in response to an increased filling of the heart’s chambers.
-Heart muscle must respond to stretching in this way
-As otherwise circulation of blood would fail.
-This response is intrinsic to the heart
What is Cardiac preload
Initial stretching of cardiac myocytes to contraction indicated by ventricular end - diastolic volume because stretching of cardiac myocytes cannot be determined in intact heart muscles
The magnitude of the stretch (preload) predicts the strength of contraction
What is an echocardiogram
A type of ultrasound scan used to assess structure and function of heart at high temporal resolution (2D)
What can an echocardiogram aid detection of
Impaired cardiac contractility e.g as a results of myocardial infarction (heart attack)
Congenital heart disease; birth defects that impact cardiac function
Cardiomyopathy: enlargement of ventricular walls
Endocarditis: infection of endocardium that damages heart valves
Heart Failure: heart is unable to adequately pump blood to meet metabolic demands of the body
What is myocardial infarction
Heart attack
What is endocarditis
Infection of endocardium that damages heart valves
What happens in a doppler echocardiogram
Erythrocytes reflect ultrasound waves which are used to meassure the blood flow through the heart
What does ECG stand for
Electrocardiogram
What is the purpose of an ECG
Detects phasic change in potential difference between two electrodes
Where are the electrodes placed in an electrocardiogram
On limbs and the surface of the chest
What does bradycardia mean
Slow heart rate
What does tachycardia mean
Fast heart rate
What rhythms are detected by an ECG
Sinus rhythm
Sinus bradycardia
Atrial fibrillation
STEMI (S-T Elevated myocardial infarction)
What is the driving force for blood flow through organs
Mean arterial blood pressure
When is the arterial blood pressure greatest and lowest
On waking and sleeping
How is the arterial blood pressure measured
With a Sphygmomanometer
What is a result of the difference between systole and diastole
Pulse pressure
What is the systolic blood pressure
The pressure in the arteries (aorta) during myocardial contraction (systole)
What is the diastolic blood pressure
The pressure in arteries (aorta) during myocardial relaxation (diastole)
-when ventricles are refilling
How does control and regulation of blood pressure occur
Through rapid regulation of blood pressure
-nerves
-hormones
Long term regulation
-Blood volume
What are Baroreceptors
Mechanoreceptors that detect the degree of stretch of blood vessel walls and monitor blood pressure
Where are baroreceptors most abundant
In the aortic arch and carotid sinus
Why does mechanical stretch (circumferential stress) in arteries arise
Due to pulsatile blood flow
-directly related to blood pressure
-Increases during systole
-Gradually reducing during diastole
Where are baroreceptors found
Carotid sinus
Aortic arch
BOTH REQUIRED
How are the carotid sinus baroreceptors innervated
By the sinus nerve of Hering
How are the aortic arch baroreceptors innervated
By the aortic nerve (combines with vagus nerve)
Why are aortic arch baroreceptors less sensitive to changes in stretch than carotid sinus baroreceptors
They have a higher threshold pressure
How to identify the carotid sinus
The artery wall is thinner and contains a large number of branching nerve endings
Which cranial nerve is the sinus of Herring a branch of
IX - Glossopharyngeal nerve
What happens when baroreceptors detect a decrease in arterial pressure
There is a reduction in the action potential firing from baroreceptors
Stimulation travels along afferent neurons
To the medullary Cardiovascular Centre
Increased stimulation of sympathetic neurons to heart/arterioles/veins
Decreased stimulation of parasympathetic neurons (vagus nerve) to heart
Where is the Medullary Cardiovascular centre
In Medulla Oblongata
When the baroreceptors detect an increase in arterial pressure what occurs
Increased action potential firing from baroreceptors
Stimulation travels along afferent neurons
To the medullary Cardiovascular Centre
Decreased stimulation of sympathetic sympathetic neurons to heart/arterioles/veins
Increased stimulation of Parasympathetic neuros to heart/arterioles/veins
What is the Valsalva manoeuvre
The attempt to expire against a closed glottis
(exhaling when mouth & nose are closed)
What is the physiological response to the Valsalva manoeuvre
-Increased intrathoracic pressure
-Raising blood pressure; normal LV contraction + (1): increased baroreceptor firing
-Heart rate falls transiently - impending return of blood to heart
-Fall in CO and MAP
-As MAP decreases, HR rises and (w/TPR), stabilises blood pressure
What occurs when the glottis is re-opened after the Valsalva manoeuvre
slows fast heart rate
-Intrathoracic pressure falls
-BP falls initially
-Venous return is rapidly restored
-EDV & CO increase, raising BP
-Increased BP is sensed by baroreceptors results in reflex bradycardia (slowing of HR)
Within blood pressure regulation what does blood volume influence
Venous pressure
Venous return
End - diastolic volume
Stroke volume
Cardiac output
An increased blood volume increases arterial pressure
How does an increased arterial pressure reduce blood plasma volume
Via increasing renal excretion of salt & water
What are arterioles
Small diameter muscular walled blood vessels
What causes capillary fluid shift
Occurs due to venous dilators
Caused by reduced proximal capillary hydrostatic pressure
Most vasodilators have effects on both arteries and veins
Mechanisms that locally regulate long term blood pressure originate via:
- Renin - Angiotensin - Aldosterone System (RAAS)
-Blood vessels (myogenic or endothelial factors) - Maintenance of constant blood flow
- Blood volume and fluid regulation
What is hypertension
Clinic blood pressure of 140mmHg systolic and 90mmHg diastolic (140/90) or higher
Risk of hypertension is raised by what
Age
Cigarette smoking
High salt intake
Lack of exercise
Being overweight
Regularly drinking excess alcohol
Stress
Genetic predisposition
Family history
How common is hypertension the result of an underlying health condition or medication
1 in 20 cases
What is secondary hypertension
Hypertension as the result of an underlying health condition or taking certain medicine
What therapeutics (medication) can increase Hypertension risk
Contraceptive pill
Non-steroidal anti-inflammatory drugs (NSAIDS)
Recreational drugs
Which health conditions can raise Hypertension risk
Kidney conditions
-Chronic kidney disease
-Narrowing of arteries that supply blood to kidneys / renal hypertension
-Long-term kidney infections
-Glomerulonephritis
Diabetes
Obstructive sleep apnoea
Hormone problems
What is sleep apnoea and what does is increase the risk of
Stop breathing during sleep causing you to wake up increasing risk of hypertension
What does an under/over active thyroid cause
Hormone problems
Why are baroreceptors ineffective monitors of absolute pressure of blood in carotid arteries to the brains and only short term regulators of blood pressure
When the arterial blood pressure is elevated for prolonged periods the threshold for baroreceptor activity rises to a higher value and baroreceptor activity adapts over time and heart rate will increase at the same level
When does the resetting of baroreceptor sensitivity occur
During exercise - Maintains Cardiac output as heart rate does not fall in response to increase in BP accompanying exercise
Hypertension - Aids buffering of acute fluctuations in BP at new higher BP level
What are some damages caused by prolongs hypertension
Aneurysms in cerebral arteries
Left Ventricular hypertrophy (LVH)
Thickening of arteries
Atherosclerosis Deterioration
What is atherosclerosis deterioration
A condition where the arteries become narrowed and hardened due to build up of plaque (fats) in the artery wall.
What can atherosclerosis deterioration, Thickening of arteries and Left ventricular hypertrophy all lead to
Renal disease
Development of heart failure due to myocardial adaptation to compensate for LVH
Malignant Hypertension
Angina or myocardial infarction
Stroke
What does HMOD stand for
Hypertension-mediated organ damage
What does SCORE stand for
Systematic coronary risk evaluation
When are endogenous catecholamines released
Due to pain/stress
What is Hypotension
Systolic = 90mmHg
Diastolic = 60 mmHg
(90/60mmHg)
What is another name for postural hypotension
Orthostatic hypotension
What is postural/orthostatic hypotension
An abnormal drop in blood pressure when individuals stand up after sitting or lying down
