 |
Claims  |
|
|
What is claimed as new and desired to be protected by Letters Patent is set
forth in the appended claims:
1. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
containing an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, the improvement wherein the apparatus
includes means setting the indicator in the indicator space into motion
within and relative to the indicator space during the measurement
operation performed by the apparatus.
2. The apparatus defined in claim 1, the means defining the indicator space
being an optode, the means for setting the indicator into motion
comprising a mechanical oscillatory-motion generator mechanically coupled
to the optode.
3. The apparatus defined in claim 1, including electrical- or
magnetic-field-responsive material in the indicator space operative for
setting the indicator into motion when subjected to an electrical or
magnetic field.
4. The apparatus defined in claim 1, the means defining the indicator space
being an optode, the means for setting the indicator into motion
comprising means for deforming the optode.
5. A method of optically measuring the concentration of a component of a
substance to be analyzed of the type wherein a source of monochromatic
excitation radiation is used to excite the indicator contained in an
indicator space closed off at the side thereof facing the monochromatic
radiation by a radiation-transmissive means and closed off at the side to
be brought into contact with the substance to be analyzed by a membrane
permeable to the component whose concentration is to be ascertained, the
improvement wherein the indicator is set into motion within and relative
to the indicator space during the measurement operation.
6. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
containing an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, means defining a chamber for accommodating
the substance to be analyzed and bounded by the permeable membrane, and
agitator means in the chamber operative for agitating the substance to be
analyzed.
7. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
containing an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, the improvement wherein the apparatus
includes means for setting the substance to be analyzed into convective
motion in direction parallel to the membrane to cause the substance to
travel across the membrane, the means for setting the substance to be
analyzed into motion comprising means for circulating the substance out of
and back into a chamber bounded by the permeable membrane.
8. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
obtaining an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, the improvement wherein the apparatus
includes means setting the indicator in the indicator space into motion
during the measurement operation performed by the apparatus, the permeable
membrane being provided on its rim with adhesive means operative for
detachably attaching the permeable membrane to a structure through which
the substance to be analyzed is flowing.
9. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
containing an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, the improvement wherein the apparatus
includes means setting the indicator in the indicator space into motion
during the measurement operation performed by the apparatus, the means
setting the indicator into motion comprising means setting the indicator
into motion in a direction parallel to the permeable membrane, further
including means for setting the substance to be analyzed into motion in a
direction parallel to the permeable membrane but perpendicular to the
direction of motion of the indicator.
10. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
containing an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, the improvement wherein the apparatus
includes means setting the indicator in the indicator space into motion
during the measurement operation performed by the apparatus, the means
defining the indicator space comprising a plurality of permeable-membrane
microcapsules encapsulating the indicator and additionally encapsulating
magnetic material, the means setting the indicator into motion including
magnet means operative for exerting magnetic force on the magnetic
material encapsulated within the permeable-membrane microcapsules.
11. An apparatus for the optical measurement of the concentration of a
component of a substance to be analyzed, of the type comprising a source
of monochromatic excitation radiation, means defining an indicator space
containing an indicator excited by the excitation radiation, the side of
the means defining the indicator space to be brought into contact with the
substance to be analyzed comprising a membrane permeable for the component
whose concentration is to be determined, the side of the means defining
the indicator space facing the monochromatic excitation radiation being
transmissive for the radiation, the improvement wherein the apparatus
includes means for setting the substance to be analyzed into convective
motion in direction parallel to the membrane to cause the substance to
travel across the membrane, means operative for causing two different
portions of the indicator to be differently saturated by the component
whose concentration is to be measured, and photometric means operative for
photometrically ascertaining the respective extents to which said two
different portions of the indicator are saturated by the component whose
concentration is to be measured.
12. The apparatus defined in claim 11, the photometric means including
means operative to alternatively measure the light emitted by the two
different portions of the indicator to generate a corresponding difference
signal.
13. A method of optically measuring the concentration of a component of a
substance to be analyzed of the type wherein a source of monochromatic
excitation radiation is used to excite the indicator contained in an
indicator space closed off at the side thereof facing the monochromatic
radiation by a radiation-transmissive means and closed off at the side to
be brought into contact with the substance to be analyzed by a membrane
permeable for the component whose concentration is to be ascertained, the
improvement wherein the substance to be analyzed is set into convective
motion in a direction parallel to the permeable membrane and flows across
the permeable membrane while accommodated within a chamber bounded by the
permeable membrane using agitator means located in the chamber.
14. A method of optically measuring the concentration of a component of a
substance to be analyzed of the type wherein a source of monochromatic
excitation radiation is used to excite the indicator contained in an
indicator space closed off at the side thereof facing the monochromatic
radiation by a radiation-transmissive means and closed off at the side to
be brought into contact with the substance to be analyzed by a membrane
permeable for the component whose concentration is to be ascertained, the
improvement wherein the substance to be analyzed is set into the
convective motion in a direction parallel to the permeable membrane and
flows across the permeable membrane by repeatedly circulating the
substance to be analyzed out of and then back into a chamber bounded by
the permeable membrane. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
The invention relates to the optical measurement of the concentration of a
component of interest in a substance to be analyzed, for example the
concentration of oxygen in human blood. Typically, this type of optical
measuring apparatus includes a housing provided with a monochromator which
furnishes monochromatic excitation radiation, an indicator chamber
containing an indicator through which the monochromatic excitation
radiation passes in order to excite the indicator, and a light-measuring
unit which receives the radiation emitted from the indicator in order to
determine its spectral (color or fluorescent) response to the
concentration of the component of interest. The indicator space is closed
off at the side facing the substance to be analyzed by means of a membrane
which is permeable for the component whose concentration is to be
ascertained; the indicator space is closed off at the side facing the
monochromator by means of a wall which is transmissive for the measuring
radiation.
With measuring apparatuses of this type, a difficulty results from the fact
that the layer of indicator adjoining the permeable membrane in question
comes relatively fast into combination with the component whose
concentration is to be ascertained; in contrast, the layers of the
indicator more remote from the permeable membrane are reached by the
component of interest only as the component of interest diffuses, and
relatively slowly, into these more remote layers. Accordingly, the
equilibrium state which should be reached in order that the concentration
read-out of the device be sufficiently accurate, requires a relatively
long time to be established.
SUMMARY OF THE INVENTION
It is a general object of the invention to increase the speed at which the
component whose concentration is to be ascertained becomes distributed in
the optode.
According to one concept of the invention, this is accomplished by setting
the indicator within the optode into motion. In this way, the slowly
performed diffusive distribution of the component of interest within the
indicator space is circumvented, and the speed at which a uniform or
steady distribution of the component of interest within the indicator
space becomes established is increased.
According to one concept of the invention, a mechanical oscillatory-motion
generator is mechanically coupled to the optode and is used to set the
indicator into oscillatory motion. Mechanically generated oscillatory
motion of the indicator can be achieved even in very thin and flat
optodes, particularly for example if the mechanical oscillatory-motion
generator is a generator of ultrasonic sound.
According to another concept of the invention, the fluid indicator is
provided with a material which can be set into motion by means of
electrical or magnetic oscillatory fields, to set the indicator within the
optode into oscillatory motion using such fields.
A further concept of the invention is to set the indicator within the
optode into motion by deformation of the optode itself.
Another difficulty involved in the use of an optode resides in the fact
that the layers of the substance to be analyzed (whether a gas or a
liquid) which directly adjoin the membrane permeable for the component of
interest, quickly become depleted of the component of interest, due to the
passage of the component of interest through the permeable membrane into
the indicator space. In this situation too, diffusion processes replenish
the depleted zone. However, because the diffusion processes proceed very
slowly and are proportional to the concentration gradient, it is a further
object of the invention to increase the speed at which the steady or
equilibrium value of the concentration gradient is established.
This additional object can be achieved, according to a further concept of
the invention, by setting the substance to be analyzed containing the
component of interest into convective motion. A particularly simple way of
doing this is to provide, within the chamber accommodating the substance
to be analyzed, an agitator which is magnetically driven, for example
driven by an electric motor which could be located outside the chamber.
Alternatively, the convective motion of the substance to be analyzed is
established by continually recirculating the substance to be analyzed out
of and then back into the chamber which adjoins the aforementioned
permeable membrane.
As one contemplated possibility, the chamber containing the substance to be
analyzed can be formed together with the optode into a single component,
and the substance to be analyzed in such chamber can be agitated as
described above. However, another very advantageous possibility is to use
the optode as a separate component. In that case, the indicator could be
contained between one membrane which is non-permeable for the component of
interest and another membrane which is permeable for the component of
interest; the permeable membrane would then be provided at its rim with an
adhesive layer. In this way, the substance to be analyzed (for example,
blood), can be passed through a conduit provided with an opening
corresponding to the rim configuration of the permeable membrane; to
measure the concentration of the component of interest, the permeable
membrane would be pressed into place against the aforementioned opening in
the conduit, with the adhesive layer at the rim of the permeable membrane
firmly engaging the boundary of the conduit opening, both to hold the
optode in place and to seal the connection between the optode and the
conduit. Then, the substance to be analyzed transmitted through the
conduit would flow along the permeable membrane, and the component of
interest would penetrate through the permeable membrane into the indicator
space within the optode. Using this technique, physical parameters besides
concentration can be measured, e.g., pressure, temperature, and the like,
it only being necessary to use for each such measurement an appropriate
one of the conventional indicators known in the art.
With the expedient just mentioned, it would also be possible to press the
permeable membrane directly against the skin or other tissue through
which, for example, blood is being perfused, in which case the
aforementioned adhesive at the rim of the permeable membrane serves both
to firmly seure the optode to the tissue of interest and to create a
sealing engagement between the tissue and the permeable membrane of the
optode.
According to a particularly advantageous concept of the invention, during
the measurement procedure, the indicator is set into motion within the
indicator space in a direction perpendicular to that in which the
substance to be analyzed is moving at the other side of the permeable
membrane, and most preferably both these perpendicular directions of
motion are parallel to the general plane of the permeable membrane. In
this way, the concentration gradients on both sides of the permeable
membrane are maximum and thus the speed at which the equilibrium condition
requisite for accurate and repeatable measurement is established likewise
is maximum.
According to yet another concept of the invention, in order to increase the
speed of response of the measuring apparatus, the effective surface area
of the permeable membrane relative to the volume occupied by the indicator
should be made as large as possible. An extreme increase in the ratio of
this surface area to this volume can be achieved by encapsulating the
indicator, along with magnetic particles, in microcapsules made of the
permeable-membrane material, the microcapsules having a diameter of less
than ten microns. In that event, a multitude of such indicator
microcapsules, each of which in effect constitutes a tiny optode, can be
introduced into a branch at one end of a conduit through which the
substance to be analyzed is flowing and removed from another branch of the
conduit at the other end thereof.
The very great advantage of this expedient is that the component of
interest in the substance to be analyzed, in which the microencapsulated
indicator is provided, need penetrate only a very small distance into each
indicator capsule, so that the ordinary speed of diffusion is more than
adequate to assure that all parts of the indicator are penetrated by the
component of interest very quickly. Furthermore, the inclusion of magnetic
particles in each microcapsule makes it possible to use a magnetic field
to effect motion of the indicator capsules relative to the substance to be
analyzed, e.g., either to facilitate distribution of the microcapsules
within the substance to be analyzed and/or to "steer" the indicator
microcapsules--for example to be able to introduce the indicator
microcapsules at one location in a conduit carrying the substance to be
analyzed and then remove the microcapsules, using mangetic fields, through
a branch outlet in the conduit, so that the microcapsules will not enter
the main path of travel of the substance to be analyzed.
According to a further concept of the invention, the light-measuring unit
of the device is operatively associated, in alternation, with two
different portions of the optode, in respective ones of which two
different concentrations of the component of interest are prevailing. If
the alternation is performed rapidly, the optode does not achieve
saturation with respect to the prevailing concentration value; however,
the degree of saturation actually achieved is a function of the actual
concentration of the component of interest and the effective duration of
the measurement, and this functional relationship is well understood in
the art. Because the degree of saturation achieved is in accordance with
the well known exponential saturation function, the end value of the
concentration of the component of interest in the indicator space can be
determined from the initial value of this concentration, in conjunction
with the value achieved at the end of the measuring period and the
duration of the measuring period. This makes it possible to very
considerably shorten the duration of the measuring operation.
The novel features which are considered as characteristic for the invention
are set forth in particular in the appended claims. The invention itself,
however, both as to its construction and its method of operation, together
with additional objects and advantages thereof, will be best understood
from the following description of specific embodiments when read in
connection with the accompanying drawing.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 depicts a first exemplarly embodiment of the invention;
FIG. 2 depicts a second exemplary embodiment of the invention;
FIG. 3 depicts a third exemplarly embodiment of the invention; and
FIG. 4 depicts a fourth exemplary embodiment of the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
In the embodiment depicted in FIG. 1, an optode 1 comprises a membrane 10
which is permeable for the component of interest in the substance 400 to
be analyzed, i.e., the component whose concentration is to be ascertained.
For example, the substance 400 to be analyzed may be human blood, and the
component of interest oxygen. The optode 1 furthermore comprises a
membrane or diaphragm 11 which is transmissive for the radiation to be
measured. Intermediate the two membranes 10, 11 is an indicator, for
example pyrene butyric acid for the measurement of oxygen concentration in
blood.
Excitation radiation 13 is transmitted to the optode by means of a
light-conductor element 3, from a conventional monochromator or a source
of monochromatic radiation. The light-conductor element 3 is connected to
an intermediate optical coupling element 2, which can be made of
transparent plastic. The optode 1 and the optical coupling element 2 which
surrounds or encloses it are both of circular configuration. The
excitation radiation 13 introduced into the coupling element 2 via the
lightconductor element 13 is directed radially inward into the indicator
space by means of the coupling element 2, from all around the inner
periphery of the circular coupling element 2.
In this embodiment, the membrane 10 separates the indicator in optode 1
from a cuvette 4 containing the substance 400 to be analyzed, the cuvette
4 being provided with inlet and outlet conduits for the flow of substance
400 therethrough. In the interior of cuvette 4, there is provided an
agitator 5 driven by a motor 6 located external to the cuvette 4. The
agitator 5 prevents the formation of too flat a concentration gradient in
front of the membrane 10 such as could result from diffusion of the
component of interest through the membrane 10 into the indicator.
Because the monochromatic excitation radiation 13 penetrates through the
indicator by sweeping alongside the membrane 10, no primary radiation will
be developed within the cuvette 4, i.e., because the direction in which
the excitation radiation 13 passes through the indicator space is such
that it cannot reach the light-measuring unit 9 of the device, and it does
not pass through the cuvette 4 and the substance 400 therein. Accordingly,
the radiation 900 emitted from the indicator space derives only from the
indicator itself and does not include either components attributable to
the excitation energy or components attributable to the response which the
component of interest and/or the substance to be analyzed might have to
the excitation energy and/or to the radiation emitted by the indicator per
se. The radiation 900 emitted by the indicator 12 is projected by an
optical system 7 through a filter 8 onto the light-measuring unit 9 of the
device, this being in other respects conventional.
A mechanical oscillatory-motion generator 102 is mechanicaly coupled to the
optode and is operative for setting the indicator 12 therein into
oscillatory motion, for the reasons discussed earlier. Preferably, the
oscillatory-motion generator 102 is a generator of ultrasonic waves;
however, other means of mechanically transmitting oscillatory motion to
the indicator gas 12 could also be used. For example, piezoelectric
crystals could be disposed on the membranes and energized by oscillatory
voltage in order to produce an oscillating or other external deformation
of the optode itself. Actually, the transmission of ultrasonic waves by
generator 102 will, in itself, to some extent effect external deformation
of the optode and thus oscillate the indicator in that sense, too.
In the illustrative embodiment of FIG. 1, for the materials specified
above, the permeable membrane 10 can be Teflon having a thickness of about
12 microns. The wavelength of the excitation radiation can be about 326
manometers, and the wavelength of the radiation emitted by the indicator
would be 395 nanometers. The velocity of agitation of the indicator can
be, for example, about 300-400 cm/min.
FIG. 2 depicts a second exemplary embodiment. Here, the indicator 12 is
caused to flow through the optode 1 during the course of the measurement
procedure. This flow can, for example, be a circulating flow, i.e., the
indicator leaving the outlet of the optode being immediately returned to
the inlet thereof, or a non-circulating flow. In this embodiment, too, the
substance 400 to be analyzed is located in a cuvette 4, the interior of
which is separated from the indicator space by the permeable membrane 10,
the cuvette 4 again forming, if desired, a single component together with
the optode. In this embodiment, the substance 400 to be analyzed is
transmitted through the cuvette 4 through inlet and outlet conduits, in
either a circulating or non-circulating flow. As depicted in FIG. 2, the
flow directions of the indicator 12 and of the substance 400 to be
analyzed are perpendicular to each other, and generally parallel to the
plane of permeable membrane 10. This results in the establishment of a
very steep concentration gradient on the two sides of membrane 10. This
greatly increases the rate at which the component of interest can
penetrate through the membrane 10, and thereby inherently shortens the
duration of the entire measurement operation.
In the embodiment of FIG. 2, further means are provided, operative for
effecting an additional decrease in the time required for the measurement
operation. At the infeed zone 120 for indicator 12, there is provided a
shield 103--i.e., an element which is not permeable with respect to the
component whose concentration is to be measured. Accordingly, as fresh
indicator gas 12 is introduced into this infeed zone 120, it will not be
loaded by the component of interest, and its spectral response to the
excitation radiation 13 will correspond to its isolation from the
component of interest. As the indicator gas 12 reaches the zone 121
downstream of infeed zone 120, it combines with the component of interest
as the latter penetrates the permeable membrane 10. The indicator will
not, when it reaches the outlet zone of the optode, have yet reached
saturation.
However, the light-measuring unit 9 of the device is provided with an
oscillating mirror 90. Mirror directs onto the light-sensitive surface of
unit 9 first the radiation being emitted by the indicator at zone 100 and
then the radiation being emitted by the indicator at zone 101, in
alternation. The amplitude of the resultant signal produced by
light-measuring unit 9 accordingly corresponds to the difference in
concentration as between these two extreme zones 100, 101. By
extrapolation from these two concentration values, the concentration value
which would be assumed if complete saturation had occurred can readily be
calculated, because saturation proceeds exponentially; indeed, because
each such difference in extreme concentration values can be correlated
with the respective complete-saturation value, in general, the read-out of
the light-measuring unit 9 can be permanently calibrated accordingly, so
that the extrapolation need not actually be performed during use of the
apparatus. I.e., the radiation intensity difference as between the two
extreme zones 100, 101 is dependent upon and directly correlatable with
the concentration of the component of interest in the substance to be
analyzed.
FIG. 3 depicts an embodiment in which a cuvette 4 does not form together
with the optode a single structural component. Instead, the optode
membrane permeable to the component of interest is provided at its rim
with an annular sealing ring AR of adhesive material. The excitation
source and the light-measuring unit of the device are housed in a housing
H, supported by supports S against a conduit through which the substance
400 to be analyzed flows. The conduit, as shown, is provided with an
opening whose configuration corresponds to that of the optode.
Accordingly, when the optode is sealed and fixed in place upon this
opening, by means of annular sealing ring AR, the component of interest in
the flowing substance will permeate through the permeable membrane, as
before. In principle, the conduit could be a blood vessel or could be body
tissue through which blood is perfused.
FIG. 4 depicts an alternative embodiment of particular interest. Here, the
permeable-membrane material of the other embodiments is used to form
microcapsules IM in which indicator is encapsulated along with magnetic
particles, such as very fine iron particles. The diameter of each
indicator microcapsule IM is for example about 10 microns. Thus, each
10-micron-diameter microcapsule, in effect, constitutes a tiny optode in
itself. An excitation source and light measuring unit are used as in FIG.
3 referred to above. The conduit C through which the substance 400 to be
analyzed flows has an opening, across which is applied a transparent
window W--i.e., instead of the optode of FIG. 3. The indicator
microcapsules IM are fed into the conduit C upstream of the actual
measuring location through an infeed branch IB. They are removed from the
conduit C via an outfeed branch OB located downstream of the measuring
location.
A permanent magnet PM, which as indicated in the drawing is oscillated,
pulls the indicator microcapsules IM towards the outfeed branch OB, i.e.,
so that the microcapsules do no travel with the substance 400, due to the
inclusion of the aforementioned magnetic particles within each
microcapsule. The oscillatory motion of the permanent magnet PM increases
the reliability with which the microcapsules are "steered" into outfeed
branch OB.
The great advantage of this embodiment is that the encapsulated indicator
is very quickly penetrated by the component of interest, due to the very
short penetration depth which each 10-micron-diameter microcapsule
presents to the component of interest.
The production of such microcapsules is per se conventional in the art, and
is discussed, just for example, in "Microcapsules and Microencapsulation
Techniques" by M. H. Gutcho, Chem. Tech. Review 73, Noyes Data
Corporation, 1976; and in "Microencapsulation" by J. R. Nixon, Marcel
Dekker, Inc., New York, 1976.
It will be understood that each of the elements described above, or two or
more together, may also find a useful application in other types of
constructions differing from the types described above.
While the invention has been illustrated and described as embodied in the
measurement of oxygen in perfused blood, it is not intended to be limited
to the details shown, since various modifications and structural changes
may be made without departing in any way from the spirit of the present
invention.
Without further analysis, the foregoing will so fully reveal the gist of
the present invention that others can, by applying current knowledge,
readily adapt it for various applications without omitting features that,
from the standpoint of prior art, fairly constitute essential
characteristics of the generic or specific aspects of this invention.
* * * * *
|
|
|
|
|
|
|
Description |
|
