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Claims  |
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What is claimed as new and desired to be protected by Letters Patent is set
forth in the appended claims.
1. In an indicator chamber (optode) comprising an indicator and a membrane
surrounding said indicator and impermeable to it, for measurement of
concentration of particles by means of a light measurement system
including a light source, a light receiver and readout means, the
improvement comprising providing in a filling within said indicator
chamber a substance which reacts with said particle to be measured and
which generates through said reaction a reaction product which modifies
the optical properties of said indicator, thereby allowing the preparation
of highly selective indicator chambers with a broad range of
applicability.
2. An optode as defined in claim 1, wherein said substance is an enzyme.
3. An optode as defined in claim 2, wherein said enzyme is glucose oxidase.
4. An optode as defined in claim 1, wherein said substance is an antibody.
5. An optode as defined in claim 1, wherein said membrane consists of more
than one layer.
6. An optode as defined in claim 1, wherein said membrane is provided with
a carrier for selective transport of said particle to be measured.
7. An optode as defined in claim 1, wherein said substance is fixed into a
carrier matrix.
8. An optode as defined in claim 1, wherein said chamber is in the form of
a flat surface.
9. An optode as defined in claim 1, wherein said chamber is in the form of
a capsule.
10. A optode as defined in claim 1, wherein a first chamber is provided
within a second chamber which surrounds it.
11. An optode as defined in claim 10; further comprising additional
chambers surrounding said first chamber.
12. An optode as defined in claim 1, wherein a substance which binds said
particle to be measured is provided within said chamber.
13. An optode as defined in claim 1, wherein a reference indicator is
additionally provided. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The invention concerns an indicator chamber (optode) comprising an
indicator and a membrane surrounding the indicator and impermeable to it
for measurement of concentrations of substance particles by means of e.g.
a light measurement system, such as a light source, light receiver and
readout means. In particular, the invention concerns the material used for
filling the optode.
The known systems operate on the principle that the portion of a
composition to be measured in separated from components which disturb the
accuracy of measurement. If, for example, the oxygen content of blood is
to be determined through fluorescence methods, certain protein fractions
would render the direct readings inaccurate due either to their own
fluorescence or through binding of the indicator. Through separation of
the measurement area by means of a membrane, through which the fraction to
be measured diffuses, the blood protein fractions and other components are
held back, thereby preventing their affecting the accuracy of measurement.
A disadvantage of these systems lies in the fact that the indicators used
are not terribly selective, and thus would react with other components
than that to be measured, or in that no species-specific indicators are
available. In this, the applicability of the method is restricted. This is
in particular unfortunate, in that the method employed requires a lower
level of the component to be measured than other methods, and in addition
is robust and directly applicable without preparation. With respect to the
nature and operation of the optodes, the entire teachings of U.S. Pat. No.
4,003,707 are hereby incorporated by reference.
SUMMARY OF THE INVENTION
It is, therefore, an object of the invention to prepare fillings for
optodes, which are selective for the particular component particle to be
measured and which would be suitable for the broadest range of particle
types.
This object is achieved by providing in the filling for the optode a
substance which reacts with the component particles to be measured; a
reaction product is produced which then alters the optical properties of
the indicator.
The advantage of the arrangement lies in the fact that the reacting
substance can be matched quite closely to the indicator, the transport
properties of the membrane and the particle to be measured. For example,
if for the measurement of hydrogen ions, acetic acid is used as reacting
substance and .beta.-methyl-umbelliferon as indicator than with the
hydrogen ion indicator, anions can also be measured indirectly since for
every hydrogen ion one anion is freed. Further, through the use of a
selectively reacting substance a known indicator can in effect be
transformed into one for another type of particle. For dynamic use it is
necessary that the reaction be reversible.
A very high selectivity may be achieved if the reacting substance used is
an enzyme, as enzymes generally only react with a single specific
substance, while the reaction products, such as hydrogen ions, oxygen,
etc. are easily detectable through the use of known indicators, such as
.beta.-methyl-umbelliferon and pyrenebutyric acid.
As membranes come into consideration porous membranes which in themselves
are only slightly selective. This difficulty is overcome through the
specificity of the reaction itself.
Certain enzymatic reactions are of particular significance in this context.
Thus, a measurement of glucose through optodes with porous hydrophobic
membranes is convenient with a filling of glucose oxydase and
pyrenebutyric acid for glucose concentration determinations through
fluorescence. Through placement of optode capsules in tissue near the skin
a simple monitoring of the blood sugar level, for example in intensive
care stations, may be carried out. For this, suitable light wave lengths
are used which easily permeate the skin, such as infra-red light.
To strengthen the measurement signal it is possible to provide a substance
which binds with the particle to be measured, as the equilibrium of that
particle component in the interior of the optode is thereby shifted.
In another embodiment of the invention, the reacting substance is an
antibody. This also permits a tremendous increase in the specificity of
the optode, as antibody-antigen reactions are highly specific. A
chromophore as indicator may be chemically affixed to the antibody.
As membranes with relatively large pores are used for the large particles
which, for example, react with antibodies or enzymes, it is desirable in
order to avoid the draining out of indicator, antibodies or enzyme, to fix
these substances. This may be carried out in conventional manner.
When the reacting substance for the transmission of a particle to be
measured to an indicator is not very selective, the selectivity of the
optode may be improved through the use of a selectively-working membrane
provided with a carrier. This type of arrangement also leads to a
broadening of the range of applicability of the optode. Substances, known
as ligands, may be dissolved in solid or liquid membranes and are able to
form complexes with the particles to be measured; in most cases, the
substances completely surround the particle. Cf., e.g., J. Koryta,
Ion-selective Electrodes, Cambridge (1975). It is possible to synthesize
such carrier especially designed for a particular type of particle, so
that the selectivity can be quite high, while the range of possible
applications includes a virtually limitless number of particle types. An
example of such a separation pair is the antibiotic valinomycin and
K.sup.+ ions; the carrier may be dissolved in PVC. See Res. Devel.
25:20-24 (1974); J. Amer. Chem. Soc. 89: 386 (1967).
The selectivity can be further heightened through the use of a multiple
membrane around the optode. In such an arrangement, membranes with diverse
carriers can be used one after the other, such membranes in general having
the highest permeability for the particle component to be measured but a
low permeability for other components.
A further improvement may be achieved through providing an indicator
chamber within a second indicator chamber which encases it, as thereby one
membrane may possess one type of property and the second another. For
example, the outer membrane may be glucose permeable, and the reaction
with glucose would be carried out by glucose oxidase within the first
indicator chamber, while the thus-generated oxygen would diffuse into the
second (internal) indicator chamber through the inner membrane and would
there undergo the fluorescence reaction with pyrenebutyric acid. In
addition, a substance for binding oxygen may be provided in the inner
indicator chamber; the binding should be chemically or physically
reversible, causing no disturbance of the accuracy of measurement while
heightening the oxygen concentration and thus the intensity of the
measuring signal. Additionally, a reference indicator can be provided by
conventional methods in the inner indicator chamber, with the help of
which absolute calibration of the optodes is made possible.
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 DRAWINGS
FIG. 1 illustrates the passage of a particle to be measured into, and the
reaction within, the optode; and
FIG. 2 illustrates a multistage arrangement.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
In the embodiment of FIG. 1, a double membrane 3, 4 closes off an indicator
chamber 2 from a solution to be measured 1. A particle 100 from the
concentration to be measured comes into contact at the membrane border
with a carrier 301 ready to take up the particle. The carrier 302 charged
with the particle 100 subsequently comes into contact at the border of the
second membrane 4 with a carrier 401 ready to take up the particle. The
carrier-particle combination 402 wanders to the inner border surface of
the membrane 4 and the particle 100 enters the indicator chamber 2. A
reacting substance 201 comes together with the particle 100, thereby
producing reaction products 203 and 204. The reaction product 204 is
optically active, for example, becoming fluorescent or changing its color
when in contact with light beam 1001. The resultant radiation 1002 is then
measured by a light measurement device, which is not illustrated. The
preparation of a membrane provided with a carrier and the chemical
affixing of a chromophore onto a reaction partner is known from the
literature. In addition, the preparation of micro- and nano-capsules is
also known, in which the inventive filling may be used, as in surface
optodes. See generally Speiser, in J. R. Nixon, Marcel Dekkar Verlag, New
York (1976), page 1 ff.
In FIG. 2 a multistage arrangement consisting of an outer membrane 3 and
outer reaction chamber 5 as well as an inner membrane 4 and inner reaction
chamber 6. If membrane 3 is porous and for the transport of glucose and
indicator room 5 filled with a glucose-splitting enzyme immobilized within
the indicator chamber, then in chamber 5 oxygen is generated. This can be
carried into inner reaction chamber 6 over membrane 4 which is provided
with a carrier; the inner chamber 6 in addition to the indicator contains
a substance for the binding of oxygen. The fluorescence measurement
follows in a known method by means of a light beam for inducing the
fluoroescence and a light measurement arrangement, which are not
illustrated.
The principle of the invention may be utilized in arrangements with more
stages, in which case further encapsulated indicator chambers are
comtemplated.
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.
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