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Autonomic Function Tests
Prof Vajira Weerasinghe
Professor of Physiology
Available at www.slideshare.net/vajira54
Autonomic Nervous system
Objectives
Describe the physiological basis of the following autonomic function tests in relation to cardiovascular system
1. Heart rate variation during respiration
2. Heart rate variation during postural change
3. Valsalva manoeuvre (maneuver)
4. Cold pressor test
1. Heart rate variation during respiration
• The variation of heart rate with respiration is known as sinus arrhythmia
• Inspiration increases the heart rate• Expiration decreases the heart rate
• This is also called Respiratory Sinus Arrhythmia (RSA)
• This is an index of vagal control of heart rate
Sinus Arrhythmia
Explanation for sinus arrhythmia
• Due to changes in vagal control of heart rate during respiration
• Probably due to following mechanisms – Influence of respiratory centre on the vagal
control of heart rate – Influence of pulmonary stretch receptors on
the vagal control of heart rate
Heart rate variation during respiration
• Heart rate increases during inspiration due to decreased cardiac vagal activity and decreases during expiration due to increased vagal activity
• This is detected by recording the heart rate by using the electrocardiograph while the subject is breathing deeply
Deep breathing
Procedure
• Connect the ECG electrodes for recording lead II
• Ask the subject to breath deeply at a rate of six
breaths per minute for 3 cycles
(allowing 5 seconds each for inspiration and expiration)
Procedure
• Record maximum and minimum heart rate with each respiratory cycle
• Average the 3 differences
– Normal > 15 beats/min– Borderline = 11-14 beats/min– Abnormal < 10 beats/min
Procedure
• Determine the expiration to inspiration ratio (E:I ratio)
E:I ratio
• Mean of the maximum R-R intervals during deep expiration to the mean of minimum R-R intervals during deep inspiration
E:I ratio
longest RR interval (expiration)
Ratio = -------------------------------------
shortest RR interval (inspiration)
E:I = 1.2
2. Heart rate variation during postural change
• Changing posture from supine to standing leads to an increase in heart rate immediately, usually by 10-20 beats per minute
Heart rate variation during postural change
• On standing the heart rate increases until it reaches a maximum at about
– 15th beat (shortest R-R interval after standing)– after which it slows down to a stable state at about – 30th beat (longest R-R interval after standing)
Heart rate response to standing from supine
posture
30:15 ratio
• The ratio of R-R intervals corresponding to the 30th and 15th heart beat 30:15 ratio
RR interval at 30th beat• 30:15 ratio = ------------------------------
RR interval at 15th beat
• This ratio is a measure of parasympathetic response
30:15 ratio
RR interval at 30th beat
•30:15 ratio = ------------------------------
RR interval at 15th beat
•Normal > 1.04
•Borderline = 1.01-1.04
•Abnormal =<1.00
3. Valsalva Manoeuvre
• Assesses integrity of the baroreceptor reflex
• Measure of parasympathetic and sympathetic function
• It is “forced expiration against a closed glottis”
Valsalva Manoeuvre
• The Valsalva maneuver is performed by attempting to forcibly exhale while keeping the mouth and nose closed
• It increases intrathoracic pressure to as much as 80 mmHg
Procedure
• Perform the Valsalva manoeuvre (forced expiration against a closed glottis) by asking the subject to breathe forcefully into a mercury manometer and maintain a pressure of 40 mmHg for 15 seconds
• Record the ECG throughout and for 30 seconds after the procedure
Valsalva Manoeuvre
• 4 phases– Phase I– Phase II– Phase III– Phase IV
Four Phases
– Transient increase in BP which lasts for a few seconds– HR does not change much– Mechanism: increased intrathoracic pressure and mechanical
compression of great vessels due to the act of blowing
Phase I – Onset of straining
Phase II - Phase of straining• Early part – drop in BP lasting for about 4 seconds• Latter part – BP returns to normal• Heart rate rises steadily
Mechanism
• Early part– venous return decreases with compression of veins by
increased intrathoracic pressure central venous pressure decreases BP decreases
• Latter part– drop in BP in early part will stimulate baroreceptor reflex
increased sympathetic activity increased peripheral resistance increased BP ( returns to normal )
• Heart rate increase steadily throughout this phase due to vagal withdrawal in early part & sympathetic activation in latter part
Phase III - Release of straining• Transient decrease in BP lasting for a
few seconds
• Little change in heart rate
Mechanism
• Mechanical displacement of blood into pulmonary vascular bed, which was under increased intrathoracic pressure BP decreases
Phase IV – further release of strain• BP slowly increases and heart rate proportionally decreases• BP overshoots• Occurs 15-20 s after release of strain and lasts for about a
minute or more
Mechanism
• Due to increase in venous return, stroke volume and cardiac output
• With this high pressure there is no venous return since no venous blood can enter the thorax
• The blood in the lungs and heart will be expelled at a higher pressure than normal
Phases
Phase I Decrease in BP
Phase II Decrease in BP, Tachycardia
Phase III Decrease in BP
Phase IV Overshoot of BP, Bradycardia
Valsalva Ratio
• Measure of the change of heart rate that takes place during a brief period of forced expiration against a closed glottis
• Ratio of longest R-R interval during phase IV (within 20 beats of ending maneuver) to the shortest R-R interval during phase II
• Average the ratio from 3 attempts
Valsalva Ratio
Longest RR
Valsalva Ratio = -----------------------------
Shortest RR
1.4
Values
• more than 1.21 normal
• less than 1.20 abnormal
Valsalva manoeuvre
• Valsalva maneuver evaluates– 1. sympathetic adrenergic functions using the
blood pressure responses – 2. cardiovagal (parasympathetic) functions
using the heart rate responses
4. Cold pressor test
• Submerge the hand in ice cold water
• This increases – systolic pressure by about 20 mmHg – diastolic pressure by 10 mmHg
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
Veins
Arterioles
Ventricles
SA node
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (1 of 10)
Blood Pressure
Change in blood
pressure
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (2 of 10)
Blood Pressure
Carotid and aorticbaroreceptors
Change in blood
pressure
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (3 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (4 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (5 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (6 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
SA node
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (7 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
SA node
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (8 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
Ventricles
SA node
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (9 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
Arterioles
Ventricles
SA node
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Figure 15-21 (10 of 10)
Blood Pressure
Medullary cardiovascular
control center
Carotid and aorticbaroreceptors
Change in blood
pressure
Parasympatheticneurons
Sympatheticneurons
Veins
Arterioles
Ventricles
SA node
Integrating center
Stimulus
Efferent pathway
Effector
Sensor/receptor
KEY
Baroreceptor Reflex
Valsalva manoeuvre in diabetic autonomic neuropathy
Other ANS tests in CVS
• Head up tilt test (HUT)– Heart rate and BP response
• BP Response to standing • BP Response to sustained handgrip• Plasma norepinephrine measured with the subject
supine and after a period of standing provides another method of studying adrenergic function