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Claims  |
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We claim:
1. A method of measuring the concentration of gases in a sample comprising
the steps of generating a monochromatic light beam having a predetermined
color characteristic; generating light signals indicative of the
concentration of gases in a sample to be measured by positioning an
indicator having a light-transmissive surface positioned to be impinged by
said monochromatic light beam, a diffusion membrane adapted to be placed
in the proximity of a sample and being selectively permeable to a gas
component thereof, and an indicating substance positioned to be impinged
by the monochromatic light beam penetrating said light-transmissive
surface and by said gas component penetrating said diffusion membrane,
said indicating substance reacting when illuminated by said incident
monochromatic light beam by emitting a resultant light beam having an
emitted component which has a color characteristic different from said
predetermined color characteristic; conducting said resultant light beam
away from said indicating substance through said light-transmissive
surface; and discriminating said emitted component from said resultant
light beam so that the change in the color characteristic of said
indicating substance can be measured and correlated with the concentration
of gases in the sample.
2. In an arrangement for measuring the concentration of gases in a sample,
a combination comprising means for generating a monochromatic light beam
having a predetermined color characteristic; indicating means for
generating light signals indicative of the concentration of gases in a
sample to be measured, including a light-transmissive surface positioned
to be impinged by said monochromatic light beam, a diffusion membrane
adapted to be placed in proximity of a sample and being permeable to a
selected gas component thereof, and an indicating substance positioned to
be impinged by said monochromatic light beam penetrating said
light-transmissive surface and by said gas component penetrating said
diffusion membrane, said indicating substance reacting when illuminated by
said incident monocrhromatic light beam by emitting a resultant light beam
having an emitted component which has a color characteristic different
from said predetermined color characteristic; means for conducting said
resultant light beam away from said indicating substance through said
light-transmissive surface; and means for discriminating said emitted
component from said resultant light beam so that the change in the color
characteristic of said indicating substance can be measured and correlated
with the concentration of gases in the sample.
3. The arrangement of claim 2, wherein said indicating substance is
sealingly embedded thoughout said diffusion membrane.
4. The arrangement of claim 2; and further comprising means for controlling
the temperature of a sample.
5. The arrangement of claim 2, wherein the indicating substance is
.beta.-methyl-umbelliferon.
6. The arrangement of claim 2, wherein the indicating substance is
Pyrene-butyric acid.
7. The arrangement of claim 2; and further comprising additional indicating
substances intermixed with said first-mentioned indicating substance.
8. The arrangement of claim 2; and further comprising a reflecting wall
located behind said membrane.
9. The arrangement of claim 2; and further comprising an absorption wall
located behind said membrane.
10. The arrangement of claim 2, wherein sid discriminating means comprises
filtering means for permitting substantially only said emitted light to
pass through.
11. The arrangement of claim 2, wherein said indicating means is comprised
of a plurality of particles, each comprising said indicating substance and
said diffusion membrane.
12. The arrangement of claim 2; and further comprising additional
indicating means adjacent said first-mentioned indicating means, said
additional indicating means having a diffusion membrane selectively
permeable to another gas component and an indicating substance which
reacts with the latter.
13. The arrangement of claim 12, wherein the diffusion membrane of said
first-mentioned indicating means is substantially permeable to oxygen; and
wherein the diffusion membrane of said additional indicating means is
substantially permeable to carbon-dioxide.
14. The arrangement of claim 2; wherein said means for generating said
monochromatic light beam includes a light-conductive cable for directing
said monochromatic light beam towards said indicating means; and wherein
said conducting means comprises another light-conductive cable for
directing said resultant light beam away from said indicating means.
15. The arrangement of claim 14; and further comprising additional
indicating means located adjacent said first-mentioned indicating means;
and wherein said monochromatic light beam comprises two monochromatic
components, each being directed by said one light-conductive cable towards
said respective indicating means.
16. The arrangement of claim 15, and wherein both said indicating means
respectively emit emitted light components, each being conducted by said
other light-conductive cable towards said discrimination means so that
each emitted light component is individually measured.
17. The arrangement of claim 2; and further comprising a portable housing
containing said means for generating a monochromatic light beam and said
discrimination means for transporting the measuring arrangement to a
sample.
18. The arrangement of claim 17, wherein said indicating means is
interchangeably mounted in said housing.
19. The arrangement of claim 17; and further comprising additional
measuring electrodes mounted in said housing.
20. The arrangement of claim 2, wherein said light-transmissive surface is
planar and constitutes an upper layer, and wherein said indicating
substance is generally located in a plane intermediate said upper layer
and said diffusion membrane.
21. The arrangement of claim 20, wherein said indicating substance is
arranged in a dichroic layer having one side which absorbs said
monochromatic light beam.
22. The arrangement of claim 20, wheren said membrane has a reflective
layer on its side facing said indicating substance.
23. The arrangement of claim 20, wherein said membrane has an absorbing
layer on its side facing said indicating substance.
24. The arrangement of claim 2, wherein said means for generating a
monochromatic light beam includes means for modifying the latter into a
plurality of separate monochromatic components, each monochromatic
component being directed towards said indicating substance.
25. The arrangement of claim 24, wherein said modifying means comprises a
plurality of monochromatic filters, each positioned to be impinged by said
monochromatic light beam.
26. The arrangement of claim 24, wherein said conducting means comprises a
plurality of light-reflective elements, each positioned to be impinged by
said emitted light component.
27. The arrangement of claim 26, wherein said discriminating means
processes each of said emitted light components. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention relates generally to a method and an arrangement for
measuring the concentration of gases in a sample and, more particularly,
to a method and an arrangement which optically measures the concentration
of oxygen and carbon dioxide dissolved in blood.
It is known in the prior art to provide test cells filled with an
indicating substance which reacts with a gas component to be measured in a
sample by emitting a fluorescent-type light beam when the indicating
substance is illuminated by monochromatic light. When the concentration or
distribution of the gas component changes, the indicating substance
changes its color characteristic and intensity. In turn this difference in
intensity is measured by a light-measuring device. Fluorescent-type
indicators are popular because it is relatively simple to filter the
fluorescent-type component, thus making possible a high signal-to-noise
ratio.
However, fluroescent-type indicators have not been successfully used to
measure gases dissolved in the blood stream, because, for example, albumin
in the blood interferes with the reaction of the indictor substance.
Thus, the prior art proposed various electrode techniques to measure the
concentration of gases. However, such electrode-measuring techniques are
possessed of many disadvantages. For example, in the measurement of the
partial pressure of oxygen, the polarization-type electrodes must be
constituted of very pure material which requires a great deal of costly
and frequent maintenance. Moreover, the concentration distribution can
only be determined on a point-by-point basis. Even if the prior art
electrodes are inserted transcutaneously through the skin, then still only
very slight gas quantities ever reach the electrodes. Furthermore, the
measurement is strongly influenced by the inherent properties of the
electrodes themselves. Since the electrodes require a large amount of gas
to flow towards them so as to generate a detectable electrical current,
electrode arrangements having large surface areas are impractical. Thus,
oxygen concentration distributions are not readily attainable in the prior
art.
With respect to the partial pressure measurement of gases other than
oxygen, Stow and Randall Amer. J. Physiol. 179/678p --1954 disclose the
measurement of carbondioxide with glass electrodes. However, such
electrodes require measuring times of over 30 seconds which are
undesirably long in most applications. Moreover, the accuracy of the
measurement is substantially reduced by the presence of the required
reference electrode.
SUMMARY OF THE INVENTION
Accordingly, it is a general object of the present invention to overcome
the drawbacks of the prior art.
Another object of the present invention is to provide a method and an
arrangement for measuring the concentration of gases in a sample which
eliminates the use of electrode-measuring techniques.
Still another object of the present invention is to provide a method and an
arrangement for measuring gas concentrations which is relatively
maintenance-free.
Yet another object of the present invention is to provide a method and an
arrangement for measuring gas concentrations which is fast-acting and
universally usable.
A further object of the present invention is to provide a method and an
arrangement for measuring gas concentrations which optically shows the
entire distribution of the gas in the blood at any one time.
In keeping with these objects and others which will become apparent
hereinafter, one feature of the invention resides, briefly stated, in a
method and arrangement for measuring the concentration of gases in a
sample which comprises means for generating a monochromatic light beam
having a predetermined color characteristic. Indicating means are further
provided for generating light signals indicative of the concentration of
gases in a sample to be measured. The indicating means includes a
light-transmissive surface positioned to be impinged by the monochromatic
light beam, a diffusion membrane which is adapted to be placed in the
proximity of a sample and which is selectively permeable to a gas
component thereof, and an indicating substance positioned to be impinged
by the monochromatic light beam penetrating the light-transmissive surface
and by the gas component penetrating the diffusion membrane. The
indicating substance reacts when illuminated by the incident monochromatic
light by emitting a resultant light beam having an emitted component which
has a color characteristic different from the predetermined color
characteristic of the monochromatic light beam. The resultant light beam
is conducted away from the indicating substance through the
light-transmissive surface, and means for discriminating the emitted
component from the resultant light beam is provided so that change in the
color characteristic of the indicating substance can be measured and
correlated with the concentration of gases in the sample.
In accordance with this feature, the indicating substance reacts very
quickly towards an equilibrium condition even with very small quantities
of gas being diffused from the sample through the diffusion membrane. This
is especially true if the light-transmissive surface is juxtaposed over
the diffusion membrane so as to bound a flat, planar space which is ony a
few microns thick. The relatively large surface area of the indicating
substance permits average measuring values of the gas concentration to be
obtained in a relatively short time. A plurality of such thin so-called
optodes distributed over an area can be used to measure the distribution
of concentration over that area.
Another feature of the invention is that all of the various parts of the
arrangement are mounted in a portable housing which can be easily moved
towards the place where the sample is to be measured. The housing may also
contain additional electrode elements for conducting the resultant
electrical signal which is indicative of the gas concentration towards an
indicating device.
Still another feature is that one optode can be interchanged in the same
arrangement with other optodes which have a different diffusion membrane
which is selectively permeable to another gas component to be measured.
The interchangeability of the optodes in the portable housing provides for
greater versatility.
In accordance with yet another feature, the optode may be constituted not
of the aforementioned multi-layered-type construction, but of a supporting
foil in which the indicating substance is randomly interspersed and
sealingly embedded. The foil itself simultaneously serves as the
gas-permeable membrane as well as the light-transmissive surface. This
design of the optode insures an especially simple and sturdy construction.
The embedding of the indicating substance throughout the foil is obtained
by conventional chemical and physio-chemical techniques, preferably by
polymerization of a solution of silicon or any synthetic plastic material
such as polyvinylchloride mixed with the indicating substance.
An additional feature of the invention resides in controlling the
temperature at which the gas is measured. Heating and/or cooling coils,
heat exchangers, or Peltier-type elements, or the like, can be employed to
control the temperature of the gas. If the heat input necessary for
effecting a temperature change in the sample is measured, the perfusion
rate of the sample can also be determined.
The means for generating light signals indicative of the concentration of
gases may comprise one or more adjacent optodes, each containing a
different indicating substance; or a single optode having separate
sections, each of which contains its own respective indicating substance;
or a single supporting foil having separate indicating subtances embedded
therein. It is especially desirable if a pair of optodes are used
transcutaneously to measure the partial pressure of oxygen and/or
carbondioxide being diffused from a blood vessel through the surrounding
skin. The optodes may, in accordance with the invention, be arranged in
the free end of a catheter having light-conductive fibers which convey
light beams towards and away from the optodes. The cathater can be
arranged then directly in a vein or artery. If two optodes are employed,
then the incident light beam contains two monochromatic components which
are subsequently separately processed. The use of two simultaneously
acting optodes overcomes the prior art disadvantage of having to
separately measure the oxygen and carbondioxide gas concentrations at
separate times at one location on the skin.
Still another feature of the arrangement is to arrange the indicating
substance in dichroic layers so as to absorb the incoming monochromatic
light beam and reduce scattered radiation effects.
Also, it is desirable to provide a reflective surface on the inner side of
the diffusion membrane, or on the inner side of a wall placed behind the
diffusion membrane, in order to direct the monochromatic light beam twice
through the indicating substance. This is especially desirable if the
monochromatic light beam does not have sufficient strength or purity to
illuminate the indicating substance.
On the other hand, if sufficient energy and purity is provided in the
incoming monochromatic light beam, the diffusion membrane or the wall
placed behind the same can be darkened or provided with a light-absorbing
layer so as to reduce scatter.
If the optode is formed with a large light-impinging surface area,
cross-diffusion is substantially reduced by providing for fine, subdivided
groups of optodes.
Still another feature of the invention resides in using very small optodes
in particle form, each containing indicator substance. These particles can
then be introduced into the sample. Such a measuring method is extremely
fast-acting since the combined outer surface areas of all the particles is
quite high.
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 drawings.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a diagrammatic view of a first embodiment in accordance with the
present invention;
FIG. 2 is a diagrammatic view of still another embodiment in accordance
with the present invention;
FIG. 2a is an enlarged view of a detail of FIG. 2
FIG. 3 is still another diagrammatic view of an additional embodiment
according to the present invention;
FIG. 4 is an enlarged, partial diagrammatic view of a detail of the
arrangement;
FIG. 5 is a diagrammatic of still another embodiment in accordance with the
present invention which uses the modification illustrated in FIG. 4; and
FIG. 6 is a bottom view of the catheter illustrated in FIG. 5.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring firstly to the FIG. 1 of the drawing, this illustrated embodiment
for measuring gases in a sample comprise means 2 for generating a
monochromatic light beam. Light emanating from a light source 230 is
focussed by lens element 232 onto a light-dispersion prism 231. The
resulting beam is split up into its spectral components and focussed by
another lens element 232 towards the exit opening or aperture 233.
In order to select one of the spectral components to serve as a source of
monochromatic light, i.e. a light beam having substantially a single
frequency and wavelength, an adjusting arrangement comprising an adjusting
screw 234 is provided. By turning screw 234, the entire monochromatic
light arrangement is moved and thereby the desired wavelength can be
obtained through the aperture 233.
The monochromatic light beam generally identified by reference numeral 20
is directed towards a so-called "optode 1". The optode generates the light
signal which is indicative of the concentration of the gases in a sample.
Optode 1 is composed of an upper layer 60 having a light-transmissive
surface positioned to be impinged by the monochromatic beam 20, and a
juxtaposed lower diffusion membrane 105. The layer 60 and the membrane 105
together bound a space for an indicating substance 100. The membrane 105
is chosen so that it is permeable to a selected gas component of the
sample being measured. If the indicating substance 100 is a liquid, it is
preferable if the membrane 105 and the layer 60 are fluid-tightly sealed
relative to each other.
The indicating substance 100 is positioned in the optode 1 so that it is
impinged by a major portion of the monochromatic light beam 20 which
penetrates the light-transmissive layer 60. Moreover, when illuminated by
the beam 20, the substance 100 reacts with the gas component which
penetrates the diffusion membrane 105 and changes its color
characteristic. Specifically, the substance 100 emits a fluorescent-type
beam whose color and intensity is different from the color characteristic
of the monochromatic light beam.
The resultant light beam emanating from the optode is comprised of two
components 20 and 22. Component 20 is essentially composed of the
monochromatic light beam being reflected from the indicating substance
and/or the light-transmissive layer 60. COmponent 22 is the fluorescent
light signal emitted by the substance 100 itself.
The resultant beam is then conducted away from the indicating substance 100
through the light-transmissive layer 60 so that information contained in
component 22 can be discriminated from component 20 and used to yield the
desired information as to the concentration of the gas currently being
measured in the sample.
This discrimination process can occur in many ways. For example, in FIG. 1,
if an especially pure monochromatic signal is desired (i.e. a
monochromatic signal having predominantly a single frequency) then a very
slight apertural width is provided for the exit opening 233. In addition,
it is advantageous if a modulator 4 having a movable shutter is positioned
in the path of the incident monochromatic light beam 20 so as to
repeatedly interrupt beam 20 and vary its intensity at a predetermined
frequency. (At the same time the modulator 4 generates an electrical
signal which has the frequency of interruption of the light to be used in
the amplifier-demodulator unit 3 for phase sensitive demodulation of the
light signal.) The monochromatic light beam then receives the intelligence
at the optode so that, when the resultant light beam is passed through the
filter 221, only the component 22 remains. Component 22 is thereupon
focussed by lens 222 onto the photocell or receiver 223, whereupon the
receiver conveys the information to be processed in known manner to the
relatively stable and preferably noiseless electronic
amplifier-demodulator unit 3, which is preferably phase-sensitive. The
resulting information signal is then conducted to a display instrument 31.
In use, the optode 1 is placed so that the membrane 105 is in direct
contact with the sample. For example, if the sample is blood, then the
blood B can be passed through a flow-through chamber 6. An upper side of
the chamber 6 is constituted by the optode 1; a bottom opposite side of
the chamber is generally identified by reference numeral 61. If the
concentration of the gas in the blood to be measured changes, then the
amount of gas being diffused through membrane 105 will correspondingly
change. This, of course, means that the strength or intensity of the
fluorescent-type emitted light component 22 will also change. This change
in color characteristic will then be sensed and displayed on the display
instrument 31 which can serve either as a direct or differential read-out
device.
If it is desired to employ a plurality of monochromatic light beam
components, then each monochromatic component can be provided with its own
modulator that is operative at different respective frequencies. Each
frequency after being received by the photocell can be processed in the
same electronic unit and be individually separated and displayed by using
the respective electrical signals for phase sensitive demodulation.
In case it is desired to control the temperature of the sample during the
measurement, the temperature-control means 1000 is placed in the proximity
of the sample for cooling and/or heating the latter. In FIG. 1, the
temperature-controlling means 1000 is configurated as an annular coil
surrounding the optode and is in heat-exchange relationship with the blood
B. If the temperature information is processed with the gas-concentration
information, then the perfusion rate is determinable.
In order to increase the strength and intensity of the emitted light
component 22, it is very desirable to provide a reflective surface at the
inner side of the bottom wall 61 of the flow-through chamber 6 so that the
incident monochromatic light beam will pass twice through the indicating
substance 100. In this case it is advantageous if small apertural widths
are provided at the monochromatic arrangement 2, or if the indicating
substance 100 is arranged in dichroic layers.
If, on the other hand, the purity and strength of the monochromatic light
component is adaquate for exciting the indicating substance 100 to produce
an emitted light component of sufficient strength, then it is desirable to
provide an absorbing layer on the inner side of the bottom wall 61. Thus,
instead of providing a mirror-like surface as in the above-mentioned case,
the bottom wall is blackened. This is advantageous in reducing scatter
radiation caused by the incoming monochromatic beam so that the outgoing
resultant beam is essentially comprised of relatively more emitted light
component 22 and less of the reflected light component 20.
Turning now to the embodiment of FIG. 2, the means for generating
monochromatic light is simplified from the arrangement shown in FIG. 1 and
is provided with a light source 230 which projects at its light onto a
lens which, in turn, directs the light through a monochromatic filter
3210. Filter 2310 is operative for allowing substantially only the desired
monochromatic light beam 20 to pass therethrough towards the optode 103.
Optode 103 is analogous to optode 1 as discussed in FIG. 1 and is similarly
provided with light-transmissive surface 1060, indicating substance 100
and gas-permeable membrane 1050. One essential difference, however,
relates to the placement of the optode and the size thereof with respect
to the sample. In FIG. 1, a flow-through chamber 6 was used; in the
present case, the membrane 1050 is positioned a very slight distance from
a tissue or skin or like object O so that gas diffusing therefrom
penetrates the membrane 1050 and reacts with the indicating substance 100.
Optode 103 is preferably annular and clamped in position by clamping ring
1030 which is provided in housing bracket arm 400. It is advantageous if
the ring 1030 is removable so that different optrodes, each adapted to
measure a different gas component, can be interchanged as desired. In
order to insure that the diffused gas is directed towards membrane 1050,
sealing means 1001 is provided intermediate optode 103 and the object O.
The resultant light beam again has two components, and the emitted
fluorescent-type light component 22 is discriminated from the reflected
component 20 by passing the resultant beam through a filter 221 which
serves to pass substantially only the light component 22. Lens 2210
focusses the light component 22 onto an image area I. Thereupon, the
image-amplifier arrangement 7 with the high voltage source 7'
electronically produces an electrono-optic image on the display screen 70.
Thus, this device can display a stationary or static concentration
distribution of a gas being measured. Of course, the display must be
previously calibrated to account for the particular indicating substance
being used, the particular gas being measured, the distance of the optode
from the object, the size of the optode, etc. If the indicating substance
is subdivided into layers to reduce cross-diffusion, this fact must also
be taken into consideration. The display of the image on a screen can be
permanently recorded by using a camera or like image-recording device.
Instead of forming the optode as a sealed multi-layered construction, i.e.
upper light-transmissive layer (60 or 1060), a lower diffusion membrane
(105 or 1050), and a middle layer of indicating substance 100, the optodes
for all of the previously disclosed embodiments may be constituted of a
supporting foil in which the indicator substance is sealingly embedded.
The foil is generally constituted of any gas-diffusable material, such as
a solution of silicon or any synthetic plastic material such as
polyvinylchloride randomly mixed with the indicating substance preferably
in a polymerization-type reaction. The indicating substance is so strongly
embedded in the supporting foil that, even if it were placed in direct
contact with the blood in flow-through chamber 6 of FIG. 1, the indicating
substance would not be washed away.
Besides the planar configurations of the optodes or supporting foil, each
can be adapted to conform to the particular configuration of the object
being measured. Thus, the optodes may comprise a plurality of very small
carrier particles having the indicating substance embedded therein and
which are added to a carrier fluid containing the gas to be measured for
instance to the blood.
Turning to FIG. 3, this embodiment is essentially analogous to the one
described in connection with FIG. 2 except that the discrimination process
is different. The resultant beam is again passed through a filter 221
which serves to screen out the reflected light component 20. The
fluorescent light component 20 is then scanned by a first swinging mirror
200 in one direction, and then directed by lens 222 towards a second
swinging mirror 201 whereupon another scan is taken in a mutually normal
direction. Thus an areal scan is furnished. The information contained in
the scanning of the optode is then conveyed to a photoelectric element
223, whereupon the information is conducted towards an amplifier 202 and
coverted into an electrono-optic image or raster which can be viewed at
the display screen 70 of the viewing apparatus 203.
In FIG. 4, the incident monochromatic light beam and the outgoing resultant
beam are respectively directed towards and away from one or more optodes
by means of light-conductive fibers 2001 and 2002 of a light-conductive
cable 2000. Light-conductive fiber 2001 has its input end 2022 connected
to a source of monochromatic light so that the latter is thereby brought
to the optode whereupon it impinges on the indicating substance. The free
end of light-conductive cable 2000 is sealingly covered with the
gas-permeable membrane 8 so that the gas being measured can penetrate the
membrane and react with the indicating substance. The emitted light is
conducted by light-conductive cable 2003 towards its output end 2023 to a
discrimination arrangement.
The light fibers may be connected to either one or more optodes and, as
shown in FIG. 4, fiber 2001 is used to illuminate a pair of adjacent
optodes 101 and 102 which lie behind each other as viewed in direction
into the plane of FIG. 4. Moreover, each optode may be used to measure the
same gas component, or preferably different gas components when their
respective gas-permeable membranes are selected accordingly.
The inner surface of the gas-permeable membrane 8 can be provided with a
reflective coating in case an increase in the illumination of the
indicating substance by the monochromatic light is required;
alternatively, the inner surface may be provided with a blackened coating
in order to reduce scatter radiation. Of course, light-scattering not
eliminated thereby can also be reduced and substantially eliminated by
electrical means in the amplifier circuitry.
FIG. 5 shows an embodiment of a multiple analysis-type measuring device
using the concept disclosed in FIG. 4. The light-conductive cable 2080 is
housed in a catheter whose free end is provided with optodes 101 and 102
and covered by membrane 8. The measurement is advantageous since obtaining
a plurality of separate readings, each of which is later processed to
produce a final result, is more accurate as compared with a single
mesurement device according to Pflugers Archiv 342/41--60/1973. With this
method it is possible to account for optical interferences, white light
effects, single measurement errors, etc.
In accordance with the invention, light source 230 directs a light beam 202
towards the input end of cable 2080. Beam 202 is modulated by a rotating
assembly wheel which comprises a drive 2501 which turns shaft 2500. A
first set of five monochromatic filters 2502-2506 are mounted on the shaft
2500 so as to intercept beam 202 in normal direction; a second set of
single frequency light filtering elements 2507-2511 is mounted on the
shaft 2500 so as to subsequently intercept beam 202 at angles of
approximately 45.degree.. The second set of light elements 2507-2511 is
partially mirrored and so positioned that the resultant beams returning
from the optodes 101, 102 are sequentially reflected towards photocells
90-94. Each photocell converts the respective light signals into a
corresponding electrical signal which is then respectively amplified in
amplifiers 130-134. The plurality of electrical signals are processed
together in an analyzer unit 135 which combines the separate signals in a
manner disclosed by Pflugers, Archiv 342/41--60/1973. The display
instruments 1361 and 1362 respectively indicate the gas concentrations
detected by the optodes 101, 102. Thus, optical interference caused by the
optodes or by the blood itself, white light, and additive color effects
from the indicating substance are substantially elimimated.
By placing the optodes 101, 102 directly behind each other, it is possible
to make the free end of the catheter-type cable very thin so that the
latter can be used to measure gas components directly even in very small
blood vessels.
FIG. 6 illustrates an embodiment especially useful when the optode is
directly applied against the skin. Optode 1031 is comprised of two
adjacent membranes 110 and 111. Membrane 110 is selected to be permeable
to oxygen; and membrane 111 is selected to be permeable to carbondioxide.
Then, these two gas components can be simultaneously measured.
As examples of typical indicating substances, .beta.-methyl-umbelliferon
can be used to directly measure the pH value of the blood being measured
from which the carbon-dioxide value can be determined by the use of a
nomograph; in addition, pyrene butyric acid can be directly used to
measure the oxygen concentration of the sample.
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 a
method and arrangement for measuring the concentration of gases, 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 and specific aspects of this invention.
What is claimed as new and desired to be protected by Letters Patent is set
forth in the appended claims.
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