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Claims  |
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We claim:
1. An improved method for controlling cuff pressure in an indirect,
non-invasive, continuous measurement of blood pressure in a finger by
using a photo-electric plethysmograph providing a pulsatile
plethysmographic signal and used with a fluid-filled pressure cuff, an
electronic control circuit having an open and closed-control loop
operation, an electric pressure valve connected to said cuff and a cuff
pressure transducer providing a cuff pressure signal, the cuff pressure
being controlled by the plethysmographic signal in closed-loop operation
by means of a servo-reference level, so that the arterial volume is
maintained at a preadjusted value, wherein the improvement includes the
steps of:
continuously changing, within a control range, for initial open loop
adjustment, the cuff pressure or the servo-reference level by means of a
control wave form provided to the electronic control circuit;
periodically detecting each peak-trough differential amplitude of the
pulsatile plethysmographic signal or cuff pressure signal;
comparing each said peak-trough differential amplitude with the preceding
peak-trough differential amplitude; and
storing the associated value of peak-trough differential amplitude in the
control range and the associated value of the cuff pressure or
servo-reference level, and using said associated value of cuff pressure or
servo-reference level at the end of the initial adjustment as the for set
value measurement of the blood pressure after initial open-loop
adjustment.
2. A method according to claim 1 further comprising, before the step of
continuously changing, the step of setting the cuff pressure to a value
between previous diastolic and systolic pressure, such that the pulsatile
plethysmographic signal is at maximum, and wherein the step of
continuously changing comprises the step of changing the cuff pressure
stepwise whereby each following pressure step increase is initiated by
termination of the current peak-trough detection of the pulsatile
plethysmographic signal.
3. A method according to claim 2 wherein the step of stepwise changing
comprises the step of changing the cuff pressure in exponentially
increasing pressure steps.
4. A method according to claim 1 further including the step of adjusting
loop amplification in closed-loop operation in inverse proportion to the
peak-trough differential amplitude in the pulsatile plethysmographic
signal in open-loop operation.
5. A method according to claim 1 further including the step, in absence of
natural intra-arterial pressure pulsations, of superposing artificial
pressure pulsations on the control wave form provided to the electronic
control circuit.
6. In a device for controlling cuff pressure in an indirect, non-invasive,
continuous measurement of blood pressure in a finger, which device
comprises a photo-electric plethysmograph providing a pulsatile
plethysmographic signal and used with a fluid-filled pressure cuff and
associated light source and light detector, an electric pressure valve
connected to the cuff, a cuff pressure transducer providing a cuff
pressure signal and an electronic control circuit having an open and
closed control-loop operation and including a differential amplifier
having a first and second inputs respectively receiving the
plethysmographic signal and a servo-reference level, the improvement
comprising:
a wave form generator which supplies a control wave form, continuously
changing in a control range, to the electronic control circuit;
two control loops of which one comprises the differential amplifier having
a feed-back circuit for the servo-reference level and the other of which
comprises a proportionate integrate-differentiate (PID) circuit, the input
of which is connected in parallel to an input of the differential
amplifier and the output of which is connected to the electric pressure
valve; and
a logic control circuit connected to said wave form generator and to said
two control loops.
7. A device according to claim 6 in which one of the two control loops is
further connected to an adjustment loop comprising a detection circuit
which detects the pulsatile plethysmograhic or cuff pressure signal and a
memory circuit which temporarily stores successive peak-trough
differential amplitudes of said pulsatile signal and the associated value
of cuff pressure or servo-reference level.
8. A device according to claim 7 further comprising a switch with open and
closed loop positions, which switch is connected at an output pole thereof
to the electric pressure valve, at a first input pole thereof for
open-loop operation to the wave form generator, and at a second input pole
thereof, for closed-loop operation, to the input of the PID circuit,
respectively, the adjustment loop having the detection circuit and memory
circuit being coupled after the control loop having the differential
amplifier.
9. A device according to claim 8 in which the detection circuit comprises a
parallel circuit of a peak detector and a trough detector, in which the
memory circuit comprises a first memory for the peak-trough differential
amplitudes and a second memory for the cuff pressure values, the device
further including a comparator circuit which compares each detected
peak-trough differential amplitude with the preceding peak-trough
differential amplitude and in case of exceeding same to store the current
differential amplitude in the first memory and the associated cuff
pressure value from the control wave form in the second memory.
10. A device according to claim 9 in which the feed-back circuit of the
differential amplifier comprises an integrator, and wherein the switch has
a further input pole, connected in open-loop operation to the second
memory, in order to supply, under control of the logic control circuit,
after cuff pressure has passed through the control range in one open-loop
operation, the cuff pressure value corresponding to the maximum
peak-trough differential amplitude to the electric pressure valve during a
time sufficient to have the differential amplifier-integrator adjust its
output signal to a time average level, after which the switch changes to
its closed-loop position.
11. A device according to claim 9 in which the output of the first memory
is also connected to control a further included divider circuit, coupled
between the output of the PID-circuit and the switch, in order to adjust
the loop amplification in the PID control loop in inverse proportion to
the peak-trough differential amplitude of the plethysmographic signal in
open-loop operation.
12. A device according to claim 9 in which the wave form generator is a
step generator and in which the peak detector and the trough detector, at
the end of each peak and trough detection respectively, supply a
ready-signal to the logic control circuit, which subsequently triggers the
step generator for the next step.
13. A device according to claim 12 in which the step generator is embodied
such that the step curve shows an exponentially increasing step.
14. A device according to claim 6 in which the wave form generator is
embodied such that it supplies a monotonically continuously increasing
control wave form.
15. A device according to claim 7 in further including pulsation generator
used in order to superpose, in the absence of natural intra-arterial
pressure pulsations, artificial pressure pulsations on the control wave
form of the wave form generator to be supplied to the input of said
switch. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The invention relates to a method for controlling the cuff pressure in the
indirect, non-invasive, continuous measurement of the blood pressure in a
finger by using a photo-electric plethysmograph in a fluid-filled pressure
cuff, an electronic control circuit and an electric pressure valve, the
cuff pressure being controlled by the plethysmographic signal in
closed-loop operation by means of a servo-reference level, so that the
arterial volume is maintained at a value to be pre-adjusted. The invention
relates, furthermore, to a device to carry out said method for the
indirect, non-invasive, continuous measurement of the blood pressure in a
finger, which device comprises a photo-electric plethysmograph in a
fluid-filled pressure cuff and associated light source and light detector,
an electric pressure valve and an electronic control circuit provided with
a differential amplifier, on the one input and the other input of which
respectively the plethysmographic signal and a servo-reference level is
supplied. Such a method and device are known from the "Zeitschrift fur die
gesammte innere Medizine und Ihre Grenzgebiete" VEB Georg Thieme, Leipzig,
Volume 31 (1976), pages 1030-1033.
In the method and device known from above periodical for the indirect,
non-invasive, continuous measurement of the blood pressure in a finger the
pressure of the fluid, e.g. air, in an inflatable cuff around the finger
is controlled by means of the signal of the photoelectric plethysmograph
and an electric control valve, controlled by a servo loop, in such a way
that at any moment the difference between a servo-reference level or
nominal value and the plethysmographic signal or real value--safe for a
servo-rest error--is zero.
Such a photo-electric plethysmograph is based on the fact that in the
chosen wave length range of the light it is, in a first approach, only
sensitive to the light absorbing and light diffusing blood in the finger
arteries, provided that the cuff pressure is sufficiently high for the
other blood vessels to be empty or nearly empty, so that the total
arterial blood volume will have to be constant. The artery-wall consists
of elastic material so that, when the intra-arterial blood pressure
changes, e.g. with the heart beat, the volume of the blood in the arteries
will change also, unless the pressure at the outside of the artery, the
extra-mural pressure, changes equally at each moment. When a pressure cuff
of the right construction and size is put correctly around the finger, the
cuff pressure will equal the extra-mural pressure so that, as a result of
the described servo-control circuit in the electronic circuit, the
intra-arterial pressure can be read at any moment from the cuff pressure,
with a determined constant rest difference or constant transmural
pressure. This constant rest difference has to be such that the cuff
pressure is always lower than or at most equal to the intra-arterial
pressure. When this is not the case, the finger arteries under the cuff
will coincide or collapse under the influence of the extra-mural pressure
being too high. In this case, it is true, the signal of the plethysmograph
is also constant, and there is also a one-to-one relation between the cuff
pressure on the one side and the intra-arterial pressure on the other
side, but resulting from the collapse of the artery the connection with
the blood pressure to the supply side is interrupted and the actual
arterial blood pressure cannot be read.
From the cited periodical an initial adjustment criterium is known from
which it is possible to set the servo-reference level or nominal value in
the control loop in such a way that the transmural pressure is zero or
practically zero without the finger arteries collapsing. The wall of the
artery is then in the unloaded state, and the diameter of the artery is
the unstretched diameter just before this artery collapses.
SUMMARY OF THE INVENTION
The object of the invention is now to give a method and a device for an
automatic initial adjustment without any manipulation of a human observer,
in such a way that a correct level of cuff pressure is guaranteed all the
time.
This object is attained by an arrangement wherein for the sake of the
initial adjustment, the cuff pressure or the servo-reference level as
pre-adjustment quantity is automatically changed continuously in the
control range by means of a control wave form to be supplied into the
electronic control circuit, that thereby the peak-trough amplitude of the
pulsatile plethysmographic signal or cuff pressure signal is detected time
and again, and compared with the preceding peak-trough amplitude, the
biggest value thereof in the control area and the associated value of the
cuff pressure or servo-reference level being stored, which value of cuff
pressure or servo-reference level at the end of the initial adjustment is
used as set value for the measurement of the blood pressure.
The device according to the invention is characterized in that the
electronic circuit further comprises a wave form generator to supply a
predetermined control wave form to the circuit; two control loops of which
one comprises the differential amplifier having a feedback circuit for the
servo-reference level and of which the other comprises a proportionate
integrate-differentiate (PID) circuit, the input of which is connected in
parallel to the input of the differential amplifier and the output of
which is connected to the electric pressure valve; and a logic control
circuit.
DETAILED DESCRIPTION OF THE DRAWINGS
The invention will be explained in detail with reference to the drawings,
in which:
FIG. 1 shows a block diagram of the device applied in the known method; and
FIGS. 2 and 3 show block diagrams of possible embodiments of the device
according to the invention applicable in the method according to the
invention.
DETAILED DESCRIPTION
The known device shown in FIG. 1 has a photo-electric plethysmograph in a
pressure cuff 1, which can be put around finger 2, and a light source 3
and light detector 4 both mounted at the inner side of the pressure cuff.
The plethysmographic or volume-changing signal outputted by the light
detector 4 is supplied via line 5b to a differential amplifier 7, to which
also an adjustment or servo-reference level is supplied from the
adjustment means 13. The output signal of the differential amplifier 7, in
closed-loop operation, is supplied to a PID-circuit 8. In open-loop
operation, i.e. open control loop, a pressure adjustment signal is
supplied to the PID circuit 8 from the manual adjustment means 11. The
output signal of the PID circuit controls the electric pressure valve or
the electro-pneumatic transducer 10 in such a way that pressurized fluid
12 e.g. gas or air, from a pressurized source is adjusted to the desired
pressure which is conveyed via line 5a to the pressure cuff 1. By means of
a pressure transducer (manometer) 6, connected to the output of the
electric pressure control valve 10, the pressure can be read or recorded.
FIG. 2 shows an embodiment of the device according to the invention, with
which the method according to the invention can be carried out. The same
reference numbers refer to those parts that correspond to the parts in
FIG. 1 with the same functions.
When pressing the start button 30, the device is placed in state a, i.e. in
position a of switch S1, by means of switching control signal 47 from the
logic control circuit 40. Hereby a control wave form from the wave form
generator 31 is supplied via switch S1 to the electric pressure valve 10,
to which also pressurized fluid 12 e.g. air, from a pressurized source 12.
Based upon the control wave form, the cuff pressure of the cuff 1 is set
to a starting pressure of e.g. 30 mm Hg. At each following trigger pulse
50 from logic control circuit 40 the next step is adjusted in the wave
form generator 31, which step for instance has a step value of 10 mm Hg.
The pulsatile plethysmographic signal is supplied via line 5b and the
amplifier 29 to the one input of a differential amplifier 32. An
integrator 35 in the feed-back circuit from the output to the other input
of differential amplifier 32 provides for the output signal of the
differential amplifier to be continuously around zero-value. The pulsatile
plethysmographic signal subsequently is supplied to a parallel circuit of
a peak detector 34 and a trough detector 33.
After detection of a trough according to the diastolic level and subsequent
detection of a peak according to the systolic level, and when, after
termination of same, a ready signal 43, 42 respectively is supplied to the
control circuit 40, the differential amplitude is supplied to a first
memory 37 via a differential circuit 39. The differential amplitude is not
stored in this differential circuit yet. Each running differential
amplitude is compared with the preceding one by means of a comparator
circuit 36. When the running differential amplitude is larger than the
preceding one, the cuff pressure control value then present (from waveform
generator 31 via switch S1) is caused to be stored in a second memory 38
by means of a control signal 44 from comparator 36. At the same time, as a
result of the control signal 44 the differential amplitude is stored in
first memory 37, and both detectors 34 and 33 are reset by the logic
control circuit 40 via the reset signals 48 and 49.
Hereafter, the control wave form of the wave form generator 31 is increased
with the step value under the influence of the control pulse 50, after
which the next trough-peak detection is carried out.
In this way, the total control pressure range between starting and final
pressure, e.g. from 30 to 200 mm Hg, is run through, while in the memory
38 that cuff pressure value is maintained, at which the difference between
trough and peak level in the plethysmographic signal is at its maximum. It
is remarked that the pulsations of the plethysmographic signal arise as a
result of the pulsating heart action, i.e. of the pulsating changes of the
volume, which must be opposed by the extramural or cuff pressure in
closed-loop operation.
After a last measurement has been effected in the open-loop position a of
switch S1, the device is subsequently put in state b, i.e. in position b
of switch S1, by a switching control signal 47 from the logic control
circuit 40. The cuff pressure now has a value at which the pulsations in
the plethysmographic signal are at maximum value. For a given period of
time, e.g. 5 seconds, which period of time is at least three times the
time constant of the circuit differential amplifier-integrator, said
differential amplifier-integrator circuit now has the opportunity to
adjust its output signal at the time average level in the plethysmographic
signal.
Hereafter the device is put into state c, i.e. in position c of the switch
S1, under the influence of the control circuit 40, whereby this action
closes the PID control loop by means of the switch S1 in position c. The
PID control loop in its responses is much faster, for example a factor 100
times, than the integrator loop, so that said PID control loop now
maintains the output signal of the differential amplifier 32 at zero,
whereby the integrator 35 does not change its output or servo-reference
level any more. The cuff pressure will follow the intra-arterial pressure
dynamically, which can be read by means of pressure transducer (manometer)
6.
The final pressure in the control-pressure range is defined by the
requirement that it has to be higher than the highest average arterial
pressure that can occur in any person. Likewise, the initial pressure in
the control pressure range is defined by the lowest pressure occurring.
Consequently, at a cuff pressure, approximately equal to the average
pressure, maximal pulsations will occur in the plethysmographic signal or
plethysmogram. In this case, the arterial volume shows a maximal variation
between the volume in the collapsed state during diastole, when the
intra-arterial pressure is smaller than the cuff pressure, and the volume
in normal open state during systole, when the intra-arterial pressure is
larger than the cuff pressure.
At low average pressure, in general a proportionate reduced pulse pressure,
i.e. the difference between systolic and diastolic pressure level, will
occur, so that at a fixed pressure step value only few measurements can be
effected for the trough peak values of the plethysmographic signal. As at
a cuff pressure above the systolic pressure no plethysmographic signal
occurs any more, and as the optimal initial adjustment pressure can only
be defined roughly and inaccurately, it is preferred to exponentially
increase the pressure steps and with these the pressure levels by small
steps at the beginning and by larger steps at the end of the control
range. This can be realized simply by a fixed potentiometer having
switchable exponential taps.
In the automatic initial adjustment described above, the pressure in
open-loop operation is changed stepwise. It is also possible to start from
a monotonically continuously increasing wave-form supplied by the wave
form generator, so that said pressure also shows a monotonically
continuous increase, either linearly in time or exponentially, or
otherwise. In this state there is no need of a control pulse 50 for the
wave form generator, as at each trough and peak detection, associated with
each pulsation of the heart action, the current cuff pressure value from
the wave form is stored.
This solution simplifies the logic control circuit 40, but has the
disadvantage that the acceleration of the method possible with a person
having a higher heart beat frequency and stepwise course is not taken into
consideration. Also the value of the cuff pressure, at which the maximal
differential amplitude in the plethysmographic signal is observed, is less
unambiguous. On the other side, in a steplike course of the wave form a
certain quantisation occurs in the pressure which also causes some
uncertainty.
Due to the fact that there is no plethysmographic signal present any more,
above the systolic level the trough and peak detectors will not be able
any more to establish a value at those pressure levels, so that the
initial adjustment cannot be finished. In order to prevent this, a
so-called watchdog timer 51 is installed which, after a defined fixed
time, e.g. 1.5 seconds or longer than the lowest pulse repetition period
of the heart, terminates state a, and subsequently realizes the transition
to state b and then to state c. At a relatively low average arterial
pressure this can even reduce the initial adjustment.
Normally the watch dog timer 51 is reset to zero at each detected pulsation
of the plethysmographic signal via the line 52. It is important that state
a is broken off only after at least at a pressure level of e.g. 100 mm Hg
another measurement has been effected in the plethysmographic signal.
Large differences in elasticity of artery wall and in normal diameter of
finger arteries can occur between different persons. This influences the
effective amplification in the servo-control loop. Also between the
pressure cuffs mutually the sensitivities of the photo-electric
plethysmographs can differ with the same effect. At too high an
amplification the servo-control loop becomes unstable. In order to prevent
this the loop amplification, via the line 46 can be adjusted by means of
the divider circuit 41 inversely proportionate to the trough-peak
amplitude in the plethysmographic signal when the control loop is open,
such as is determined in state a and is stored in memory 37.
In state a of the switch S1, i.e. in open-loop operation, a certain slight
and in general hardly objectionable distortion in the pulsating
plethysmographic signal will occur due to the presence of the integrator
35 for the continuous adjustment of the servo-reference level and
consequently of the average plethysmographic signal to zero. A refinement
of the electronic control circuit in the servo loop consists in this that
in state a the integrator 35 is accelerated very strongly, e.g. by a
factor 100, during a certain time, e.g. 50 ms. After this period the
integrator 35 is slowed down very strongly, e.g. again by a factor 100,
with respect to the normal value. Due to this the level during the first
period of e.g. 50 ms is, as it were, clamped for the rest of the period.
For this purpose the integrator 35 is provided with a switchable time
constant which can be realized simply by switching three integration
capacitors one-sidedly between earth and input of the integrator
respectively.
As observed, the above method and device make use of the heart action, in
this that the natural pulsations in the arterial pressure cause the
pulsations in the plethysmographic signal or plethysmogram. In defined
circumstances, however, it may happen during measurement of the blood
pressure in a finger that these pulsations do not occur, e.g. when the
patient is connected to a heart-lung machine. In this case the method
could not be used. This situation of failing of the pulsations can be
established automatically on the one side by means of the continuous
absence of the plethysmographic signal, but on the other side it can be
established by a human observer by setting a switch.
A plethysmographic signal can, however, be obtained by replacing the
natural intra-arterial pressure pulsations by artificially effected
pulsations. This can be realized simply by superposition of artificial
pulsations, in the states a and b of the initial adjustment, on the
determined pressure levels of the wave form generator supplied to the
cuff. This can be done by means of an additional pulse generator 53
connected to the positions a and b of the switch S1. The desired
transmural pulsations are then generated externally under control of a
control signal 45 coming from the logic circuit. In order to supply a
plethysmographic signal in the correct phase to the trough and peak
detectors and other component parts, the pulsation to be superposed has to
be supplied in counter-phase to the inputs a and b of the switch S1 as an
increasing pressure in diastole and a decreasing pressure in systole. This
required wave form of the generator 53 can for instance be obtained by
means of a simulator as described in the article "Variable heartrate
electronic simulator for some haemodynamic signals" in Med.Biol.
Engineering (1973), pages 214-216. It is, however, also sufficient to
supply a stylized wave in the form of a saw tooth having a rise time in
diastole of e.g. 600 ms and a fall time in systole of e.g. 60 ms. A
suitable amplitude is e.g. 60 mm Hg peak to peak.
The method steps described above can be carried out--apart from the
described embodiment of the electronic control circuit--also with a
microprocessor.
In the automatic initial adjustment method and device described above, the
control loop is first opened, whereby the initial adjustment pressure
range is passed through stepwise. The trough-peak amplitude of the
plethysmographic signal is determined and its maximal value is stored in a
memory 37. This adjustment is the so-called "open" adjustment method.
Another "closed" or dual initial adjustment method is possible in
principle, and is shown in FIG. 3.
One starts from a closed state, i.e. that the switch S1, not shown in FIG.
3, is in position c. The output circuit of the PID circuit 8 is connected
directly to the electric pressure valve 10 via the switch. In this dual
initial adjustment method the servo-reference level is changed, e.g.
stepwise, by the wave form generator 31, which is now connected instead of
the integrator 35. This stepwise change can be realized under influence of
the control circuit 40 by means of the control signals 50', 50" with
rising or falling steps. The detection circuit is now connected to the
output of the pressure transducer (manometer) 6 instead of to the output
of the differential amplifier 32. The output signals of the trough
detector 33 and the peak detector 34 are supplied again as a trough-peak
differential amplitude via the differential circuit 39 to the first memory
37 and to the comparator circuit 36. This means that at each detection of
the systolic and diastolic level of the pulse wave pressure, the
servo-reference level is increased stepwise via the wave form generator.
Hereby the maximal value of the trough-peak differential amplitude is
stored in the first memory 37, and that level of the wave form generator
31 is maintained in a second memory (which second memory, in this
embodiment, is part of the logic circuit 40) at which the maximal pulse
pressure amplitude occurs.
As at low servo-reference levels, pressure pulsations will not yet occur,
the watch dog timer 51 is of importance in the beginning of the initial
adjustment in order to limit the measuring time. The watch dog timer is
reset back via the liner 52 by the logic control circuit or said timer is
warned from this time generator to proceed to the following switching
step.
In this dual initial adjustment method another set of detectors 60 and 61
is used. The detector 60 serves to detect a relaxation-oscillation
phenomenon in the pressure and the detector 61 serves to detect an
uninterrupted pressure of 200 mm Hg or more for a period of e.g. one
second. If one of these detectors or both react, the initial adjustment
method is to be stopped at a level of one or two steps below the current
servo-reference level.
The relaxation-oscillation detector 60 must respond when the observed first
derivative of the cuff pressure to time (dP/dt) is bigger than a value
which can occur at best in normal pressure wave forms. A good value is
e.g. 3000 mm Hg/s or 400 kPa/s.
The step curve can have linear steps in magnitude of e.g. 2% of the full
scale value.
In this dual initial adjustment method there is really no good criterion
for the automatic adjustment of the loop amplification other than having
the loop go into oscillation, after which one has to readjust quickly.
Summarizing, the criterion for adjusting the stop of the stepwise
adjustment curve will have to be:
pulse pressure smaller than in the preceding step, or
dP/dt bigger than 3000 mm Hg/s, or
p>200 mm Hg for one second.
In all these cases the step generator must be stopped and must be adjusted
even one or two steps lower than the stop level.
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