Title: Heart Rate Variability in the Evaluation of Functional Status
1Heart Rate Variability in the Evaluation of
Functional Status
- Giedrius Varoneckas
- Institute Psychophysiology and RehabilitationVydu
no Str. 4, Palanga, Lithuaniae-mail
giedvar_at_ktl.mii.lt
2Background
- Autonomic heart rate (HR) control, measured by
means of HR variability, might be seen as
characteristic of cardiovascular function,
responsible for energetic supply of any
activities, physical, mental, or emotional - There is generally agreed, that all activities
followed by increased sympathetic influence
involves an increase of HR frequency and a
decrease of HR variability (HRV) - Such model is appropriate for the main
population, although not for all an exception
might be well-trained sportsmen with high quality
achievements
3Hypothesis
- HR frequency and HRV might be used for evaluation
of quality of work of operators mental or
physical work loads - HR frequency and HRV responses are not uniform
for all subjects - The level of HR and HRV responses and direction
of HRV changes are dependent on their baseline
level related to the subjects functional status
4Autonomic HR control goes through three main
mechanisms
- balance between of sympathetic-parasympathetic
branches of autonomic nervous system (HR
frequency and oscillatory structure) - tonic control (HR variability)
- reflex control (mainly baroreflex)
5Methods
- HR variability at rest in stationary situation
Power spectrum of RR interval sequence (Fast
Fourier analysis or autoregression analysis)
- HR response - to active orthostatic test (AOT)
- to exercise (bicycle ergometry - BE) - HR analysis using Poincare plot of RR intervals,
collected during complex of tests (sleep,
wakefulness, AOT, and BE), as a measure of
overall ability to adapt to environmental
changes internal or external
6HR analysis using power spectrum
Three main frequency components were measured
very low frequency component (VLFC),
low frequency component (LFC), high frequency
component (HFC) in absolute (ms) and relative
(percent) values for evaluation of autonomic
humoral,sympathetic-parasympathetic and
parasympathetic control, correspondingly.
7Heart rate analysis during active orthostatic
test
RR, ms
RR
?RRB
RRB
Supine Standing-up
Up-right
?RRB, s RR, s - RRB, s Maximal HR response to
active orthostatic test (AOT)
8HR response to standard physical load
9Heart rate analysis using Poincare plot
?RRr, difference on plot diagonal between
minimal (RRmin) and maximal (RRmax) RR
values ?RRt, maximal HR variability, or tonic
control level, as maximal width-difference
between of two points at parallel tangential
lines determining plot RRmin, maximal HR
frequency RRmax, HR frequency at its minimal level
?RRrt
?RRr
RRmin
RRmax
 P, square of the plot, representing overall HR
variability
10Baseline level of autonomic control at rest (in
supine) makes possible to evaluate
- balance between of P/S activation
- tonic control level, depending of P/S
interaction - reflex control level might be drawn from HR
maximal response to AOT
11Patterns of time and frequency domain HR
characteristics
12Rhythmogram patterns during quiet supine
- Well-trained
- sportsman
- Trained
- sportsman
- Sportsman
- Non-trained
- healthy subject
13HR and respiration patterns according
prevalence of vagal control
maximal influence high input normal vagal
control
14Range of the HRV patterns of healthy Ss and the
differences ofHR responses to deep
breathingenables to suspect different HR
responses to AOT, exercise, other activities,
involving changes of interplay between of P/S
control
15Rhythmogram patterns during quiet supine
- Well-trained
- sportsman
- Trained
- sportsman
- Sportsman
- Non-trained
- healthy subject
- strongly reduced HRV pattern - V ??? S ?0
- slightly increased HFC V ?? S ?inspiration
- maximal domination of HFC with dispersed
periodicity - V ?? S ? - lowering again HRV with dominating HFC
- of
strong periodicity V ? S ??
16Patterns of HR periodical structure in healthy
subject
- strongly reduced HRV pattern - V ??? S ?0
- slightly increased HFC V ?? S ? inspiration
- maximal domination of HFC with dispersed
periodicity - V ?? S ? - lowering again HRV with dominating HFC
- of
strong periodicity V ? S ??
17Patterns of HR responses to active orthostatic
test
- Well-trained sportsman
- Trained sportsman
- Sportsman
- Non-trained healthy subject
18Patterns of HR responses to standard physical load
- Well-trained sportsman
- Trained sportsman
- Sportsman
- Non-trained healthy subject
19 Correlation of HR and respiratory arrhythmia to
maximal oxygen consumption in well-trained
sportsmen
20Oxygen consumption and HR parameters in relation
to HR variability and fitness level
Vo2, maximal oxygen consumption RR1, RR
interval in supine RR2, RR interval during
standing RRB, maximal HR response to AOT
RRW1, HR during 1st load of PWC170 test RRW2,
HR during 2nd load of PWC170 test
21HR parameters at morning-time, day-time just
after training, and evening-time in sportsmen
with prevailing aerobic or anaerobic processes
22HR patterns during AOT of the same sportsman at
excellent state and overtraining
t, s
23Concluding the presented results
- HRV might be very useful for evaluation of
physical training process, however -
- the range and a direction of HR and its
variability are dependent on functional status
(e.g. fitness) of particular person and could be
evaluated in relation to its baseline level
24Sleep, being non-uniform state, due to shifts of
sleep stages, followed by the changes in
autonomic HR control, might be seen as a specific
testing condition of the latter without an use of
work load
Non-REM sleep is characterized by an increase of
parasympathetic control and a slight decrease of
sympathetic one, while REM sleep is followed by
withdrawal of parasympathetic and an increase of
sympathetic one
25Looking from the point of presented
classification of HR variability pattern at
wakefulness might be expected similar dependence
of a responses to shifts of sleep stages on
initial HR frequency and HR variability before
sleep
26RR interval, HR variability, and respiratory
arrhythmia as functions of sleep stages in
trained sportsmen and non-trained healthy
subjects
RR, s
RA, s
?RR, s
W 1 2 3 4 REM
W 1 2 3 4 REM
W 1 2 3 4 REM
27Poincare plots and power spectra of all-night HR
recording
Sportsman
Healthy subject
CAD patient
28Absolute (ms2) relative characteristics () of
power spectra of all-night HR recording
29Heart rate, stroke volume, and cardiac output as
a functions of sleep stages
RR, s
SV, ml
CO, l/min
RR,
SV,
CO,
W 1 2 3 4 REM
W 1 2 3 4 REM
W 1 2 3 4 REM
Healthy Ss
CAD Pts
30An example of HR power spectra during individual
sleep stages in a healthy Ss
31Changes of HR power spectrum components impact
during shifts of sleep stages
Healthy Ss
CAD pts - typical
CAD pts - reduced
W Stage 1
Stage 2 Stage 3 Stage 4
REM
VLFC,
LFC,
HFC,
32The restorative function of sleep towards the
cardiovascular system in trained sportsmen and
non-trained healthy Ss
Trained sportsmen
Healthy Ss
33The restorative function of sleep towards the
cardiovascular system in healthy SS and CAD pts
Healthy Ss
CAD pts
34HR variability during different testing
conditions in healthy subject and CAD pts
Â
Healthy subjects
CAD pts
35 HR variability in well-trained sportsman and
non-trained subject
well-trained sportsman non-trained subject
36HR variability in CAD patient with and without
HR restoration
with HR restoration inability to restore
37Total sleep time
Healthy Subjects Pts with HR
restoration CAD
Patients Pts showing Inability to
restore
min
min
38Sleep structure in CAD patients with
Restoration of HR control Inability
to restore HR
min
plt.05
39Sleep structure in subjects distributed
according to the HR reflex control changes
during sleep
40Concluding the last session
restoration of both P and S control of HR, as
well as hemodynamics was dependent on a level of
autonomic HR control, e.g. on the subjects
functional status at baseline level
41Conclusions
- Autonomic HR control measured by means of HR
variability at baseline level is dependent on the
subjects functional status - The responses of functional testing (physical,
mental, or sleep) depends on the baseline level
of autonomic control, i.e. HR variability pattern - Both of them, baseline autonomic control and its
modifications during individual testing
conditions might, be used for training or work
(physical or mental) process control - This is true for responses to physical work load,
reflex testing, or shifts of sleep stages, as
well as to ability to recover cardiovascular
system during sleep