Patent No. 6868345 Monitoring auditory evoked potentials
Patent No. 6868345
Monitoring auditory evoked potentials (Jensen, Mar 15, 2005)
Abstract
A method and an apparatus for extracting signals which are indicative of the level of consciousness of a patient comprises subjecting the patient to a repetitive audio stimulus, monitoring AEP produced by the patient using an autoregressive model with exogenous input, and then calculating an index (AAI), which is displayed or used otherwise,indicative of the anaesthetic depth.
Notes:
BACKGROUND
OF THE INVENTION
The present invention relates to an apparatus for extracting signals which are
indicative of the level of consciousness of a patient comprising means for monitoring
auditory evoked potentials (AEP) produced by the patient as a response to a
repetitive acoustic click stimulus, means for extracting an AEP within a few
repetitions, preferably more than 10 and less than 50 of the audio stimulus,
means for using an autoregressive model with exogenous input (ARX), and means
for calculating an index (AAI) indicative of anaesthetic.
Assessment of depth of anaesthesia is in general based on clinical observations
of physiologic parameters such as blood pressure, heart beat rate, pupil size
etc. The use of neuro-muscular blocking agents during general anaesthesia disables
the clinical signs that normally indicate consciousness. A number of incidents
exist where patients describe that they were fully conscious during the surgery,
and in the worst case had perception of pain and cardiac arrhythmias. Hence,
there is a need for a method and apparatus to assess the anaesthetic depth.
A number of investigation results have already been published, where Auditory
Evoked Potentials (AEP) are used to indicate the level of consciousness during
general anaesthesia. The AEP is a sub-component of the EEG signal, and it is
elicited by acoustic stimuli and is recorded with scalp electrodes, amplified
and analysed by a computer. The AEP is an electrical, small signal embedded
in noise from the ongoing EEG, and for this reason advanced signal processing
is necessary to extract the AEP signals. The AEP signals are traditionally extracted
by the averaging of up to 1000 repetitions of the response of the stimuli signals.
This is a very time-consuming process, which takes up to several minutes to
carry out, typically 2-3 minutes, which is excessive if the anaesthesiologist
has to use the AEP signals as a predictor of an adequate anaesthetic dose.
From international patent application no. WO 98/10701 (PCT/GB97/02435) a control
system and a method for calculating an index representation of the depth of
anaesthesia are known. The method of calculating an index indication of anaesthetic
depth is based on monitoring AEP produced by the patient and providing a signal
corresponding to the coarseness of the monitored AEP signal. The raw AEP signal
is divided into a series of sweeps or frames of a given duration, each sweep
being synchronised with the repetitive audio stimuli. A number of sweeps n are
recorded in sequence and are averaged to produce a time average sweep. The anaesthesia
index is calculated for the time-averaged sweep. Each time a new series of sweeps
is recorded, a new time-averaged sweep is determined from the most resent n
sweeps, and the anaesthesia index for that time-averaged sweep is calculated.
In this way the index is constantly updated.
It has been observed that when a patient loses consciousness, the amplitudes
of most AEP peaks are reduced and their latencies are generally also increased.
These changes occur almost simultaneously and in the same direction with all
patients. Therefore, a suitable index is one, which reflects these changes.
An empirical algorithm has been developed for calculating the index, which algorithm
is based upon the sum of the square roots of the difference between every two
successive points in the moving time-averaged sweep. This auditory evoked potential
index is given by the following equation: ##EQU1##
where x.sub.1 to x.sub.256 are the sample points of the time-averaged frame
and k is a scaling constant.
The AEP index is calculated for every filtered time-averaged sweep, and a plot
of the index against time can be generated for display and on a screen. When
the patient is awake, the index is typically in the range of 80 to 90, whereas
during anaesthesia it is typically in the range of 35 to 40.
An article in "Methods of Information in Medicine", 1996; 35: 256-260, with
the title: "Autoregressive Modeling with Exogenous Input of Middle-Latency Auditory-Evoked
Potentials to Measure Rapid Changes in Depth of Anesthesia" by E. W. Jensen,
P. Lindholm and S. W. Henneberg describe a system identification method, an
autoregressive model with exogenous input (ARX), to produce a sweep-by-sweep
estimate of the AEP. The method was clinically evaluated in 10 patients anaesthetized
with alfentanil and propofol. The time interval between propofol induction and
the time when the Na--Pa amplitude was decreased to 25% of the Initial amplitude
was measured. These measurements showed that ARX-estimated compared to MTA-estimated
AEP was significantly faster in tracing transition from consciousness to unconsciousness
during propofol induction (p<0.05).
It is the object of the invention to improve this measuring method in such a
manner that a safer result is achieved considerably more rapidly, whereby the
risk of treating a patient, e.g. by surgery, without full anaesthetization is
reduced.
The delay is reduced to about 6 seconds by using ARX modelling.
It is a second object of the invention to make the procedure for anaesthetization
more effective (time-efficient) and to reduce the staff workload.
It is a third object of the invention to produce an apparatus for continuous
monitoring of the level of consciousness, which apparatus is portable and easy
to install and operate.
This is achieved by using an apparatus as disclosed in claim 1.
Further advantageous characteristics are achieved by that which is disclosed
in the dependent claims.
With the apparatus according to the invention the possibility is achieved of
extracting the AEP with only a few repetitions, often as low as 15, which reduces
the delay to approximately 6 seconds. As the AEP is a very complex signal comprising
several peaks and troughs, it is desirable to map the AEP into a single number--an
ARX index of easy interpretation, but containing the same information as the
AEP. This is possible by following the method and by using the apparatus according
to the invention. The ARX index is typically larger than 60 when the patient
is awake, and decreases when the patient is anaesthetized; a loss of consciousness
will typically occur when the index gets below 28.
The apparatus according to the invention can operate only with three surface
electrodes, e.g. three propritary surface electrodes, the result being: Fully
updated AEP available within few seconds. Significantly faster calculating AEP
index than the traditional Moving Time Average method. Significantly faster
at tracing transition from unconsciousness and vice versa. Consistent, accurate
readings. Possible optimised display for use in operating theatre. Touch screen--easy
to operate and clean. Fully graphic display
The apparatus according to the invention monitor the level of consciousness
during general anaesthesia independently of the biological variation of the
patients with respect to tolerance and sensitivity of the anaesthetics.
The calculations according to the invention can be performed on a computer as
disclosed in claims 8 and 9.
DETAILED
DESCRIPTION OF THE PREFERRED EMBODIMENT
In FIG. 1 is schematically shown a system 1 for extracting the AEP (auditory
evoked potentials) and for calculating an index, which is indicative of the
depth of anaesthesia of a patient.
The patient 2 is subjected to repetitive sound signals, which are delivered
to the patient by headphones, earphones or the like. These sound signals are
in the form of "clicking" noise signals of short duration, approximately 1-2
ms, which are delivered to both ears of the patient, and which produces distinctive
potentials, known as AEP or auditory evoked potentials in the electroencephalographic
(EEG) response of the patient. The headphones and the equipment for producing
the sound signals, e.g. a signal generator, are not shown in FIG. 1.
Electrodes, with which EEG-signals (electroencephalographic signals) are provided,
are attached to the head of the patient 2. Three or more electrodes, e.g. scalp
electrodes, may be used. If three electrodes are used, they are attached to
the patient 2 at the following positions: A positive electrode at the middle
forehead, a reference electrode at the left forehead and a negative electrode
behind the ear, preferably in the region of the mastoid process. Other positions
may be used with similar results.
The electrodes are connected to a patient cable, which leads to an amplifier
3. This amplifier 3 is an instrumentation amplifier with a high common mode
rejection ratio (CMMR). The amplified analogue signal is digitised by an A/D-converter
(not shown) before being led to a digital processing unit 4. This digital unit
may be in the form of a personal computer (PC), in particular a single board
personal computer. The digitised signal is analysed and stored on the computer
4, which is programmed according to algorithms for extracting the AEP (auditory
evoked potentials) and according to algorithms for calculation of an index.
These methods for extracting the AEP and for calculating the index shall later
be described in further detail.
The AEP and the index are displayed on a display 6, and with an input device
5 is it possible to give instructions to the computer 4. This input device 5
may be in the form of a touch plate or a touch screen, which can be combined
with the display 6, in which way it will be possible to give instructions to
the computer by touching the display.
The extracted and calculated values of the Index and the AEP-signals can be
transmitted to external equipment (not shown) using a connection 7, which connection
may be in the form of a RS-232 connection. The external equipment may for example
be apparatus for administering drugs to the patient. Thus the system can be
used for controlling the amount of drug being delivered to the patient in relation
to the depth of anaesthesia. Other examples of external equipment are apparatus
for monitoring or for treating the patient, for example apparatus for controlling
the respiratory system.
The procedures or functions included in a method and a system, called the A-line-monitor
(AAI: A-line ARX Index), according to an embodiment of the invention is shown
in the diagram in FIG. 2
The data representing the signals from the patient is introduced to the processing
unit 4 in the form of a series of raw sweeps 11. In an embodiment of the invention
these sweeps 11 are provided at a sampling frequency of 900 Hz, and each sweep
consists of 70 samples, giving a sweep length of 80 ms. The dick stimulus used
for producing the signals was of 2 ms duration and of an intensity of 70 dB
above normal hearing level.
Each sweep is initially processed by an artifact algorithm 12 in order to decide
whether the sweep should be included for further processing. Two types of artifact
algorithms are used.
First, when artefacts are present in a sweep the amplitude of the raw data will
in general be much larger than the amplitude of normal sweeps. The amplitude,
expressed as a range of numbers, allowed of the A/D-converter, is for example
0-65534. The 95% EEG range is 15000-55000, hence if a sample is below 5000 or
above 60000 a number of subsequent samples, e.g. 400 samples are rejected.
Second, during periods after saturation of the amplifier 3 the signal will move
in to a normal range, i.e. 15000-55000. However in this period a click artifact
arising from the acoustic stimulus may be observed. Hence an algorithm that
detects the click-artifact is implemented. The mean deference of the 10 samples
before the click is calculated. If the difference between the first sample in
a sweep n and the last sample in the sweep n-1 is larger than for example five
times the previous calculated mean difference, hence a number of subsequent
samples, e.g. the next 800 samples, are rejected.
In order to improve the signal-to-noise ratio (SNR) a band pass filter 13 is
included in the system previous to the application of the moving timer average
(MTA) and the autoregressive with exogenous input (ARX) model. The filter, which
in an embodiment of the invention has a band pass from 16 to 150 Hz, may be
a fifth order Butterworth filter, which is digitally implemented.
The ARX model (autoregressive with exogenous input), with which a rapid extraction
of the AEP is facilitated, shall now be described with reference to FIG. 3,
which shows a generalised ARX model.
The ARX model is obtained by adding an exogenous input to the AR model for analysing
digital signals. Hence the ARX model is defined by the following equation:
where n is the order of the backwards coefficients (a.sub.1 . . . a.sub.n) and
m is the order of the forward coefficients (b.sub.1 . . . b.sub.m). The output
is y, u is the exogenous input and e is the error.
On FIG. 3 is shown the AR-part 22, which is driven by white noise and is defined
by the averaged EEG activity Pre-averaging may be done using 15 sweeps.
The exogenous input u to the block 23 is an AEP produced by averaging a number
of sweeps, for example the latest 256 sweeps. The output y from the ARX model
is an average of a number, preferably 15, of the latest collected sweeps consisting
of averaged EEG background activity and AEP. When the coefficients of the model
are determined, the ARX-AEP is obtained by IIR filtering of the exogenous Input
u.
With a model order of for example five, the ARX equations are the following
y.sub.6 =-a.sub.1 y.sub.5 - . . . -a.sub.5 y.sub.1 +b.sub.1 u.sub.6 + . . .
+b.sub.5 u.sub.2 +e
The error terms, e, are omitted and the equations are written on matrix form:
##EQU2##
The equation system shown above is an over determined set of linear equations.
Hence Gaussean elimination or LU-decomposition will fail to give a satisfactory
result. A very powerful way to solve an over determined system is the singular
value decomposition (SVD), which solves the problem in a least mean squares
(LMS) sense. Singularities in a matrix, which means that the matrix does not
have a full rank, often occur when the matrix is composed of data with no clear
a priori knowledge. The singularity can occur if here is an ambiguity in the
equations. This is a paradox because on the one hand the system is over determined
(more equations than unknowns) and at the same time it is undetermined because
too many equations are linear (or close to linear) combinations of each other.
SVD not only diagnoses and solves the singularity problems and produces a meaningful
numerical result but it also provides the LMS solution.
The model order is determined by considering the error function. The error function
is defined by ##EQU3##
where e(i)=y(i)=y(i)-y^(i) and N the number of samples in one sweep.
The variables y(i) and y^(i) are the real and the predicted pre-average
of a number of sweeps, for example 15 sweeps, respectively. The identification
is tested by Andersons test on whiteness of the prediction error, e. If the
prediction error is white at a confidence level of 95% the ident is accepted.
The optimal values of n and m are selected by minimising the final prediction
error (FPE) function defined by Akaike (Akaike H."Statistical predictor identification",
Ann. Inst. Statist. Math, 1970; No. 22, pp 203-217):
where n is the total number of coefficients of the ARX model.
FPE represents a need of minimising the error function and the need of limiting
the number of parameters of the ARX model.
The order of the ARX model should ideally be calculated for each sweep. This
is a very time consuming process. hence to comply with the need of fast processing
time an average model order of five for both backward- and forward coefficients
was chosen. It is obvious that another suitable number may be chosen, preferably
a number less than 10.
As shown on FIG. 2, the output from the block 15, which is the AEP achieved
by an moving time average (MTA) calculated over 256 sweeps with each sweep weighted
equally, is led to the display 6 (FIG. 1), where it may be displayed as an AEP.sub.MTA
-display 16. Further the output from the band pass filter 13, i.e. the EEG-signal,
is led to the display 6 (FIG. 1). where it may be displayed as an EEG-display
14.
The output from the block 15 is also led to the ARX model 16 together with the
output from the output from the block 17, which produces a MTA over a minor
number of sweeps, preferably 15 sweeps: The output from the ARX model 18, which
as explained above is an AEP extracted by the ARX and which is called an AEP.sub.ARX,
is also led to the display unit 6 (FIG. 1), where it may be displayed as an
AEP.sub.ARX -display 19.
In order to quantify the level of anaesthesia It is desirable to map the AEP.sub.ARX
Into an index. In order to do this, the output from the ARX model is led to
a block 20 for index calculation, the function of which shall be explained in
the following.
The index calculated by the block 20 is called the A-line ARX-index (AAI) and
may be displayed on the display unit 6 (FIG. 1), where it may be displayed as
an AAI-(AEP.sub.ARX-)index display 21. The AEP consists of several peaks. It
is generally accepted that the amplitudes of the peaks with latency 10-100 ms,
corresponding to the middle latency AEP (MLAEP), decreases when the patient
is anaesthetized and at the same time the latencies of the peaks are prolonged.
The index according to the invention preserves these two rules in order not
to lose information. Furthermore in order to achieve a reliable index the following
premises are complied with:
1. Validity for the largest number of patients possible, independent of surgery
and aesthetic drugs.
2. Good dynamics is required between awake and asleep state in order to distinguish
awareness changes from noise.
The AEP-index is calculated in a window of the AEP, which may preclude the start
and the end of the window. Preferably the window is the 20-80 ms window of the
AEP and latency and amplitude changes in the AEP is weighted equally. The 20
ms start of the window is chosen not to include BAEP (Brainstem Auditory Evoked
Potentials) and auricular muscular artefacts and the 80 ms end of the window
is chosen in order not to include LLAEP. This is because BAEP and LLAEP (Long
Latency Auditory Evoked Potentials) do not correlate well to anaesthetic depth.
The AEP index (AAI) according to the invention has shown good discrimination
between conscious and anaesthetized patients in previous studies. The AEP-index
(AAI) is defined to reflect the hypnotic level during anaesthesia. First y is
defined as: ##EQU4## where x.sub.i are the samples of a sweep, k.sub.1 are a
constant, which preferably is larger than 0.0100 and less than 0.02000, and
which in particular may be chosen to be 0.0165, and where k.sub.2 and k.sub.3
are the start and the end samples, respectively, of the summation, chosen not
to include the start and the end of the AEP window.
If the AEP window consists of 70 samples, k.sub.2 may preferably be 17, and
k.sub.3 may be 69.
The AAI-index is defined as: ##EQU5##
where k.sub.4, k.sub.5, k.sub.6, k.sub.7 and p are constants.
Preferably 0.2500<k.sub.4 <0.3000, and in a most preferred form k.sub.4
=0.2786.
Preferably 43.0000<k.sub.5 <43.5000, and in a most preferred form k.sub.5
=43.2857.
Preferably 9.1000<k.sub.6 <9.8000, and in a most preferred form k.sub.6
=9.3769.
Preferably 0.25<k.sub.7 <0.30, and in a most preferred form k.sub.7 =0.28.
Preferably 4 .ltoreq.p.ltoreq.6, and in a most preferred form p=5.
In the most preferred embodiment of the invention the ARX Index is defined as:
##EQU6##
The index is in the range of 0 to 99, where increasing value indicates elevated
level of consciousness.
The apparatus according to the invention may essentially be performed on a computer
4, e.g. a Single Board computer with 486 MHz clock frequency and provided with
programming with matching software, e.g. using the programming language Borland
Pascal, so that the algorithms or parts thereof, which are explained in the
description and disclosed in the claims, are performed in such a manner that
the desired result is achieved, i.e. calculation and display of the AAI-index
explained above. The program according to the invention is storable on any known
type of computer readable medium, so that it is easily installed in the computer
4.
Comments