Title of Invention

NON-COVALENT IMMOBILIZATION OF INDICATOR MOLECULES

Abstract The invention relates to immobilization methods, in particular for immobilizing indicator molecules on supports such as sensors and to sensors having those molecules immobilized to their surface. Non-covalent immobilization of macromolecular indicator molecules on those supports via mechanical interlacing interpenetrating networks with polymers at the surface of a support and via ionic bonding via charged moieties of indicator molecules and ionic groups on the surface of the support are disclosed.
Full Text Non-Covalent Immobilization of Indicator Molecules
BACKGROUND OF THE INVENTION
1. Field of the invention
[0001] The invention relates to immobilization methods and, in particular, for
immobilizing indicator molecules on supports such as optical sensors, and to sensors
having those indicator molecules immobilized on their surfaces.
2. Description of the Related Art
[0002] U.S. Patent No. 5,356,417 describes a fluorescent-based sensing device
comprising indicator molecules and a.photosensitive element, e.g., a photodetector.
Broadly speaking, in the context of the field of the invention, indicator molecules are
molecules where one or more optical characteristics of which is or are affected by the
local presence of an analyte. Indicator molecules have been used to measure a wide
array of analytes, such as glucose, oxygen, toxins, pharmaceuticals or other drugs, •
hormones, and other metabolic analytes. These indicator molecules are often
classified based on the chemical principal on which their activity is based. For example,
the activity of many indicators, such as the one described in U.S. Patent No. 6,344,360,
the disclosure of which is incorporated herein by reference, are based on the principle
of luminescence, in particular fluorescence. U.S. Patent No. 6,344,360 describes a
fluorescent indicator molecule containing a fluorescent lanthanide metal chelate
complex whose fluorescence emission intensity is increased by the presence of certain
sugars. Other categories of indicator molecules include colorimetric indicator molecules

which change their color in the presence of an analyte and indicator molecules which
change absorbency at a particular wavelength.
[0003] Indicator molecules vary widely in their chemical compositions and
properties. For example, indicator molecules may be monomeric or polymeric and/or
hydrophilic or hydrophobic.
[0004] Indicator molecules have been immobilized on supports, such as sensor
surfaces, by attaching the indicator molecule at the surface of the support.
Immobilizing indicator molecules on inert polymeric substrates poses a particular
challenge, since those substrates have to be modified to create or chosen to provide
attachment points for the indicator molecules.
[0005] Molecules can be immobilized on a substrate in different ways.
Immobilization is often based on covalent links between the substrate and the
immobilized molecule. To facilitate immobilization, inert substrates are generally
avoided, as those require pretreatments, e.g., with U.V. or with harsh acids :;uch as
nitric acid to achieve oxidation of the substrate to create reactive sites. These
pretreatments are generally associated with undesirables, such as instability of the
immobilization product or the handling of harsh acids. Thus, more readily modifiable
supports, such as polyacrylamide supports, are generally chosen to attach molecules of
interest. A polyacrylamide support can, for example, be readily modified, for example,
by attaching through reactive amine groups, which enables attachment of a wide variety
of molecules, including haptenes, peptides, carbohydrates and oligonucleotides.

[0006] The immobilization of molecules, such as indicator molecules, on optical
sensors poses some unique challenges. For example, it is important that the
immobilization method does not interfere with the function of the optical sensor. Also,
certain immobilization methods might result in the discoloration of a support and thus,
interfere with its function as optical waveguide. Known immobilization methods can
also change the optical properties of the surface by, e.g., causing bubbling or rippling of
the surface, thus disrupting the optical path of a sensor or adversely affect material
properties. Thus, there is a continuing need for improvements in the way indicator
molecules are immobilized on an immobilization substrate. This need is particularly
conspicuous in the context of immobilizing indicator molecules on sensor bodies, in
particular on optical sensor bodies, used as long term implants.
Summary of the Invention
[0007] In a first aspect, the present invention is directed to a method for non-
covalently attaching a macromolecular indicator molecule to a support. This method
comprises (a) providing a support surface comprising at least one polymer, (b) changing
the integrity of the polymer to provide loosened polymer chains that form at least one
interlacing area, (c) providing at least one macromolecular indicator or monomers
thereof, (d) causing the macromolecular indicator or polymerization products of
monomers thereof to interlace with the interlacing areas, and (e) causing the loosened
polymer chains to tighten to produce surface'immobilized indicator molecules. In this
first aspect of the present invention, the macromolecular indicator molecule in (c) may
be a partially or fully polymerized indicator molecule. Alternatively, the monomers of the

at least one macromolecular indicator molecules in (c) may be sequentially polymerized
in (d) to form a sequential IPN (interpenetrating polymer network).
[0008] The polymer chains may be loosened by a solvent such as, for example,
ethanol, 2-methoxyethanol, dimethylforrnamide, a monomer of a hydrophilic
macromolecular indicator such as HEMA or mixtures thereof. The polymer chains may
be tightened again by the removal of the solvent or by polymerization of the monomer
into the hydrophilic macromolecular indicator, respectively. In this aspect of the
invention, the support surface may be hydrophobic and the macromolecular indicator
molecule may be hydrophilic. The support may be the surface of a sensor or an optical
waveguide. The macromolecular indicator molecule may have one or more reference
regions. These reference regions may be excimer regions or may comprise or consist
of at least one reference molecule. The macromolecular indicator molecule may also
comprise one or more crosslinkers, which in turn crosslink the macromolecular indicator
molecule within the support.
[009J In a second aspect, the present invention is directed to a graft. The graft
preferably comprises a surface including at least one polymer and a macromolecular
indicator molecule. The graft is characterized in that the macromolecular indicator
molecule is stably interlaced between at least one chain of at least one of the polymers
of the support. In accordance with one embodiment of the invention, the
macromolecular indicator molecule in the graft has certain properties that substantially
correspond to the properties of an identical macromolecular indicator molecule that is
not part of a graft (native molecule). Those properties may include, but are not limited

to, the molecule's affinity to an analyte or its reference regions, such as excimer
regions, which, in the native molecule, may be a result of the molecule's primary and/or
tertiary structure. The surface of the graft may be a sensor.
[0010] In a third aspect, the present invention is directed to another method for
non-covalently attaching an indicator molecule to a sensor. The method comprises (a)
providing a support having a surface comprising at least one strong ionic group, (b)
adding to the surface at least one indicator molecule comprising at least one charged
residue having a charge opposite of that of the ionic group, (c) immobilizing the
indicator molecule on the support via an. ionic bond between the ionic group of the
support and the at least one charged residue. The ionic group, for example, may be an
anionic group, in particular, a sulfonate. The at least one charged residue, for example,
may be a positively charged residue. The ionic group may be part of a copolymer of, for
example, sulfonate and methyl methacrylate, which forms a coat on the surface of the
support.
[0011] In a fourth aspect, the present invention is directed to a sensor for
determining the presence or concentration of an analyte within a medium. The sensor
comprises a sensor body preferably having a polymeric outer surface surrounding the
sensor body, and a macromolecular indicator molecule which, in response to the
presence of an analyte in the medium, changes at least one measurable characteristic.
The sensor further comprises a detector which detects radiation from the indicator
molecules and which generates an electrical signal which corresponds to the changes
in at least one characteristic of the indicator molecule which is indicative of the


presence or concentration of the analyte. In this sensor, the macromolecuiar indicator
molecule may be stably interlaced between at least one chain of at least one of the
polymer chains of the sensor surface. The sensor may be an optical sensor which is
adapted to detect one or more analytes of interest in a medium, such as glucose. In a
preferred embodiment, the surface of the sensor may be made from
polymethylmethacrylate.


Brief Description of the Accompanying Drawings
[0012] The accompanying drawings, which are incorporated herein and form part
of the specification, illustrate various embodiments of the present invention and,
together with the description, further serve to explain the principles of the invention and
to enable a person skilled in the art to make and use the invention. In the drawings, like
reference numbers indicate identical or functionally similar elements. Additionally, the
left most digit(s) of a reference number identifies the drawing in which the reference
number first appears. . .
[0013] Figures 1A and 1B is a schematic illustration of the primary and tertiary
structure of a water soluble macromolecuiar indicator molecule according to the present
invention.
[0014] Figures 2A and 2B show an immobilization support for immobilizing
indicator molecules in accordance with one embodiment of the present invention.
[0015] Figures 3A to 3C show the creation of interlacing areas at the surface of
an immobilization support upon addition of a solvent


[0016] Figures 4A and 4B show a mechanism of diffusion of a polymerized
macromolecular indicator molecule through an interlacing area and tightening of the
interlacing area.
[0017] Figures 5A and 5B show macromolecular indicator molecules containing
one or more positively charged moieties and excimer regions.
[0018] Figures 6A to 6C show a mechanism for coating a support with a
copolymer containing ionic groups in accordance with one aspect of the present
invention.
[0019] Figure 6D shows the final product of the mechanism shown in Figures 6A
to 6C.
[0020] Figures 7A to 7C show how a macromolecular indicator molecule carrying
positive charges which are distributed over the entire molecule is attached to the body
of a sensor having anionic groups on its surface.
[0021] Figures 8A to 8C show how a macromolecular indicator molecule carrying
a terminal positive charge is attached to a body of a sensor having anionic groups on its
surface.
Detailed Description of the Invention
[0022] The support for an indicator molecule, such as a sensor device, has to
meet certain design requirements. In the case of an optical sensor housing,
translucency and durability are generally desirable. As a result, the surface of a
support, which may be made of a material that can act as an optical waveguide, often


has a set of properties that is very different from the properties of the indicator molecule

that is desired to be attached to that surface. This set of properties is also often
different from the environment in which the sensor operates. For example, the support
is often very hydrophobic (e.g. for the protection of the microelectronics within the
sensor) while an indicator molecule can be very hydrophiiic. This is especially desirable
if analytes are detected in an aqueous medium. Certain embodiments of the present
invention are directed at achieving effective immobilization of indicator molecules,
including macromolecular indicator molecules, despite the differences in the properties
of the support and the indicator molecule, and without adversely affecting the
performance of the indicator molecule. Certain embodiments of the present invention
actually take advantage of these differences, enhance them and/or even create them to
achieve immobilization.
[0023] A wide variety of indicator molecules can be used in the context of the
present invention. An indicator molecule according to the present invention is a
molecule having at least one characteristic, such as fluorescence, that is affected fay the
local presence of an analyte. Such an indicator molecule can base its activity on any
number of principles including, but not limited to, luminescence, such as fluorescence
and phosphorescence, absorbance or colorimetrics. The indicator molecules of the
' present invention include monomelic molecules as well as macromolecular indicator
molecules, such as water soluble macromolecular indicator molecules. For example,
the compounds described in U.S. Patent Application Ser. No. 10/187,903 and in U.S.
Patent Publication Nos. 2002/0127626 or 2003/0082663, which have at least two


recognition elements for glucose, can be used in the context of the invention. Further,
the fluorescent lanthanide metal complexes described in U.S. Patent No. 6,344,360 or
the fluorescent phenylboronic compounds of U.S. Patent No. 5,503,770 also can be
used in the context of the present invention. The disclosures of these patents and
applications are incorporated herein by reference. However, as the person skilled in the
art will appreciate, any other suitable indicator molecule can be used as well.
[0024] The indicator molecules of the present invention are generally specific for
one or more analytes. For example, in a preferred embodiment, the indicator molecules
are specific for glucose, in other embodiments, the indicator molecules are specific for
oxygen, carbon dioxide, nitric oxide, toxins, pH, ions and mono-or divalent cations.
However, as the person skilled in the art will appreciate, a wide variety of other analytes
can be detected and/or measured using the present invention.
[0025] In certain embodiments of the present invention, monomeric molecules
such as those described in the above-mentioned patents and applications, are
converted into macromolecular .indicator molecules, including water soluble
macromolecular indicator molecules, by polymerization in the presence of expanded
substrate polymer, or attachment to a polymer. "Macromolecular indicator molecules"
or "macromolecular indicators" according to the present invention are molecules acting
as indicator molecules, and are macromolecular from, for example, being partially or
fully polymerized, for example, copolymerized, with one or more molecules of another
type. A polymer, in the context of the present invention, includes any product of the
polymerization of monomers, complex or simple ones, as well as oligomers. "Water


soluble macromolecular indicator molecules" (WSMIM) according to the present
invention are macromolecular indicator molecules which are overall substantially
hydrophiiic. In order to obtain a WSMIM, suitable recognition monomers can be co-
polymerized with hydrophiiic monomers. Examples of suitable hydrophiiic monomers
include, but are not limited to, methacrylamides, certain methacrylates, vinyls,
polysaccharides, polyamides, polyamino acids, hydrophilic silanes or siloxanes, HEMA
(hydroxyethyi methacrylate) or other common hydrogel constituents as well as mixtures
of two or more different monomers. Examples of macromolecular indicator molecules
produced by co- polymerization of a monomeric indicator molecule with a hydrophiiic
monomer are described in U.S. Patent Publications Nos. 2003/0013204,
2003/0013202, 2003/0008408, 2003/0003592, 2002/0039793 and in U.S. Patent
Application No. .10/187,903, incorporated herein by reference.
[0026] The nature and ratio of suitable hydrophiiic monomers will vary according
to a number of factors described, for example, in Patent Publication No. 2003/0013204.
In a preferred embodiment, the water soluble macromolecular indicator molecule is a
copolymer of 2-hydroxy methacrylate (HEMA) and bis-carboxylate bis-boronate-
anthracene. In yet another preferred embodiment, the water soluble macromolecular
indicator molecule is a copolymer of methacrylamidopropyltrimethylammonium chloride
(MAPTAC) and bis-carboxylate bis-boronate-anthracene at ratios between
approximately 5:1 to 80:1.
[0027] In a preferred embodiment, the macromolecular indicator molecules of the
present invention have reference regions such as excimer regions, which are also


referred to as excimer emission regions. "Excimer regions" according to the present
invention refers to the region of a macromolecular indicator molecule that provides an
excimer effect. Sequence specific excimer regions exist as a direct result of the primary
structure of a molecule. However, adoption of its tertiary structure (3-D configuration)
may create additional excimer regions in a molecule. "An excimer effect" in the context
of the present invention refers to a characteristic longer wavelength emission of a
molecule having excimer regions. The molecular basis of an excimer effect is
described, for example, in U.S. Publication No. 2003/0013204, incorporated herein by
reference.
[0028] As described therein, an excimer region is not responsive to changes in
analyte concentration, but is responsive to other aspects of the system analyzed, such-
as excitation intensity, temperature, and pH. As a result, an indicator molecule having
excimer regions may serve as both an indicator and an internal reference. For
example, the emission intensity at the indicator wavelength (i.e., the wavelength
influenced by the analyte) can," via select bandpass filters, be separated optically from
the emission intensity at the excimer wavelength. The resultant value corrects for
interfering factors which affect fluorescent emission properties, such as fluorescent
quenching by, for example, oxygen, drift, photobleaching, degradation and error in pH
etc. Indicator molecules having excimer regions are particularly useful for applications
involving long-term implantation, as ambient conditions in any long-term in vivo
application are bound to be subject to frequent change. Accordingly, molecules with
excimer regions are part of a preferred embodiment of the present invention. U.S.
Patent Publications'Nos. 2003/0013204, 2003/0013202, 2003/0008408, 2003/0003592


and 2002/0039793, incorporated herein by reference, describe examples of such
molecules.
[0029] In another embodiment of the present invention, the macromolecular
indicator molecules comprise one or more reference molecules. Reference molecules
are, for example, fluorescent molecules that emit at wavelengths different from the
respective indicator molecule and are not responsive to changes in analyte
concentration, but responsive to other aspects of the system analyzed, such as
excitation intensity, temperature, and pH.
[0030] Figures 1A and 1B show the primary structure and tertiary structure of a
representative WSMIM 100 according to the present invention, respectively. The
tertiary structure of such a molecule is generally governed by the lowest energy
configuration which it may attain in an aqueous environment. The molecule has, in the
embodiment shown, excimer emission regions 101, some of which are created by the
folding of the molecule 102. In those excimer emission regions, two planar molecules
of aromatic structure (e.g. fluorophores) are oriented in copianar configuration and have
overlapping pi-electron orbitals. This results in one or more emissions at a wavelength
that is different from the wavelength characteristic for the parent species 103. For
example, for fluorescent planar species, a characteristic downfield emission occurs in
comparison to that of the uncoupled species at a wavelength of substantially lower
energy than the uncoupled species. As described above, this characteristic emission
can be used to compensate for variable ambient conditions.


[0031] in certain embodiments of the present invention, indicator molecules
having at least one strong positively or negatively charged moiety at a suitable pH are
preferred. The pH that allows a moiety to carry a strong negative or positive charge
depends directly on the nature of the moiety. In a preferred embodiment, the moiety
may be chosen according to the environment in which the indicator molecule is used.
Accordingly, a "suitable pH", in a preferred embodiment, may be the prevailing pH in
the environment of choice. Thus, in a preferred embodiment, for in vivo applications of
sensors that are submerged in prevailingly neutral bodily fluids, indicator molecules that
are strongly ionic at neutral pH are preferred. For example, at pH values near neutral,
amine moieties are strongly positively charged and can form a strong ionic bond with a
sulfonate that is strongly negatively charged at this pH.
[0032] The indicator molecules may be indicator molecules that inherently
contain strongly positively or negatively charged moieties at a suitable pH or indicator
molecules that have been modified to include such moieties by, for example, attaching
them to a molecule that contains one or more strong positively or negatively charged
moieties, such as MAPTAC or 2-Acryloxyethyltrimethylammonium chloride.
[0033] Figures 5A and 5B show representative cationic macromolecular indicator
molecules containing one or more strong positively charged moieties. In particular,
Figure 5A illustrates a cationic macromolecular indicator molecule 510 containing a
plurality of strong positively charged moieties 511. Figure 5B illustrates a cationic
macromolecular indicator molecule 520 having one strong positively charged moiety
522. The molecule of Figure 5A is positively charged as a result of a large number of


positively charged moieties, such as amine moieties, which are distributed over the
entire molecule 510. In contrast, the molecule 520 of Figure 5B contains only a
terminal positive charge 522, for example, in the form of an amine moiety. As indicated
by the letter "n" in both figures, the molecules can be substantially longer than depicted
in these figures. The illustrated indicator molecules also have excimer emission
regions 101 that are present in the primary structure of the molecule. The advantages
of using indicator molecules having such regions has been described above.
[0034] In a preferred embodiment, the support on which an indicator molecule is
immobilized (hereinafter "immobilization support") is a sensor. Examples of suitable
sensors are described in U.S. Patent Nos. 5,517,313; 5,910,661; 5,894,351, whose
disclosures are incorporated herein by reference. Examples of suitable implantable
sensors are disclosed in U.S. Patent Nos. 6,330,464; 6,011,984; 6,304,766; 6,400,974
and Patent Application Publication No. 2002/0026108, the disclosures of which are
incorporated herein by reference. However, as the person skilled in the art can
appreciate, other sensors may be used.
[0035] In a preferred embodiment, an immobilization support may be formed
from an optically transmissive polymer material. Preferred polymer materials include,
but are not limited to, acrylic polymers such as polymethylmethacrylate (PMMA),
polyhydroxypropylmethacrylate, polystyrene, and polycarbonates such as those sold
under the trademark LEXAN. The most preferred material is PMMA.
[0036] Sensors and supports having indicator molecules attached to them
according to the present invention can be used in a wide variety of fields. For example,


they can be used to detect sub-levels or supra-levels of glucose in physiological buffers
or fluids, such as blood, plasma, serum, interstitial fluid, cerebrospinal fluid, urine,
saliva, intraocular fluid, lymph, tears, or sweat, thus providing valuable information for
diagnosing or monitoring such diseases as diabetes and adrenal insufficiency. Other
uses have been described elsewhere, for example, in U.S. Patent Application No.
2003/0082663. However, the sensors and supports having indicator molecules
attached to them according to the present invention are particularly useful for long term
in vivo uses, such as long term implants.
[0037] Figures 2A and 2B illustrate a representative immobilization support that
may be used in the context of the present invention, in particular, Figures 2A and 2B
show a polymer encasement 204 containing microelectronics 205 of a representative
electro-optical sensing device. The microelectronics 205 may comprise microelectronic
components such as, for example, a radiation source 202 and a detector 201. In one
preferred embodiment, radiation source 202 is an LED, although other radiation
sources may be used. Also in one preferred embodiment, detector 201 is a
photosensitive element (e.g. a photodetector), although other detecting devices may be
used. Microelectronics that may be contained in a representative eiectro-optical
sensing device are described in U.S. Patent No. 6,330,464, the disclosure of which is
incorporated herein by reference.
[0038] As shown in more detail in Figure 2B, the surface 206 of the
immobilization support comprises a polymeric structure 207, such as, for example, the .
chains of PMMA, which are interwoven and intertwined. This polymeric structure


provides, in one embodiment of the present invention, a hard, solid, hydrophobic
boundary to its surrounding and is inert to reaction.
[0039] In certain aspects of the present invention, a macromolecular indicator
molecule is interlaced with the support without substantially affecting its properties, in
particular its affinity to an analyte and/or its reference regions, such as excimer regions,
which in the native molecule, are a result of the molecule's primary or tertiary structure.
Maintaining the properties of the indicator molecule will ensure that the detection ability
of the indicator molecule is not negatively affected. In another preferred embodiment,
the macromolecular indicator molecule is attached to the support in a way that makes
its analyte binding regions highly accessible.
[0040] In one preferred embodiment, the character of the bulk support material is
also substantially preserved after immobilization. This will ensure that a primary
function of the support, for example, the encasement of microelectronics, is not
negatively affected by the immobilization. In a preferred embodiment, this goal is
achieved by relying on non-covalent mechanical interlacing for immobilization.
[0041] In another preferred embodiment, the indicator molecule is associated
with the support in a way that the diffusion distance of an analyte may be maintained
relatively low. For example, the diffusion distance of an analyte is maintained at
approximately 200 microns or less, preferably 150 microns or less, more preferably 125
microns or less, or the diffusion distances of an analyte may also be maintained at
approximately 80 microns or less, more preferably less than approximately 50 microns
and, in certain instances, as low as approximately 1 micron. Maintaining the diffusion


distance relatively low will maintain the response time of the sensor to which the
indicator molecule is attached relatively low. For example, response times may be, for
example, less than about 8 minutes, preferably less than about 6 minutes, more
preferably less than about 5 minutes. In one non-limiting embodiment, for the detection
of glucose in an aqueous medium, a diffusion distance of approximately 100 microns or
less and a response time of approximately 5 minutes or less may be desirable. In
another non-limiting embodiment, for the detection of oxygen gas, a diffusion distance
of approximately 50 microns and a response time of approximately 50 milliseconds may
be desirable. Maintaining the response time of the indicator molecule relatively low will
allow, for example, in the case of a sensor, close to real time monitoring of the
concentration and/or presence of a given analyte.
[0042] In one aspect of the present invention, the macromolecular indicator
molecule that is to be immobilized on a support may be hydrophilic. In a preferred
embodiment of this aspect of the invention, the hydrophilicity of the macromolecular
indicator molecule is substantially maintained after immobilization to the support, in
another preferred embodiment, the macromolecular indicator is associated with the
support in a way that maintains the micro environment of the macromolecular indicator
sufficiently hydrophilic, preferably hydrophilic enough to allow free and saturating
diffusional access to large portions of the entire macromolecular indicator. In yet
another preferred embodiment of this aspect of the invention, the macromolecular
indicator is associated with the support material in a way that minimizes any
hydrophobic influence that a hydrophobic support material will exert on the diffusion
distance of the analyte. In yet another preferred embodiment, the macromolecular


indicator molecule is, after immobilization, oriented outward into the aqueous
surrounding medium. The above embodiments will ensure that the support-indicator
construct is well adapted for detecting an analyte in an aqueous environment.
[0043] In optical sensing devices, it is generally desirable to have a clear optical
path and to be able to expose the sensor to a wide array of wavelengths. Accordingly,
one embodiment of the present invention includes a method of immobilizing an
indicator molecule on a sensor without introducing optical impurities, in another
embodiment of the present invention, the immobilized indicator molecule is resistant to
degradation by light at any wavelength to which it will be exposed.
[0044] . in connection with high throughput manufacturing of immobilized indicator
molecules, it is generally desirable that the manufacturing method may be efficient, can
be scaled up, and that the immobilized indicator can withstand manufacturing stresses.
Accordingly, in one embodiment of the present invention, the immobilization method is
highly efficient with respect to indicator usage (immobilization reaction yield) at scale-
up. In another embodiment of the present invention, the immobilization method can be
readily scaled up and the support-indicator construct can be manufactured at high
throughput rates, in yet another embodiment of the present invention, the support-
indicator construct can withstand the sterilization methods and wash cycles it will need
to be exposed to during manufacturing operations.
[0045] In highly sensitive applications, such as in sensors for in vivo applications,
it is generally desirable that the quality of the product be consistent. Accordingly, in one
embodiment of the present invention, the immobilization method allows for a high


degree of "sameness," ensuring device-to-device consistency in calibration and signal
processing.
[0046] Especially in long term applications, such as In sensor implants, it may be
important that the indicator does not negatively affect its surroundings or'is not
inactivated by prevailing ambient-conditions. Accordingly, in one aspect of the present
invention, the immobilized indicator molecule is in intimate and direct association with
the solid surface of the sensor encasement/waveguide, thus preventing significant
leaching of the indicator into the local environment. In another preferred embodiment,
the immobilized indicator molecule is substantially resistant to in vivo degradation, in
yet another preferred embodiment of the present invention, the support-indicator
molecule constructs have sufficient mechanical integrity to withstand forces anticipated
within its intended environment of use.
[0047] In one aspect of the present invention, a macromoiecular indicator
molecule may be attached to a support by interlacing the macromoiecular indicator with
a polymeric structure on the support forming a graft. A "graft" in the context of the
present invention is an IPN (interpenetrating polymer network) which may be formed by
at least one macromoiecular indicator molecule and at least a portion of a polymer
chain located preferably near the surface of a support network. An IPN, in the context
of the present invention, is a combination of two or more polymers wherein least one is
synthesized and/or crosslinked in the immediate presence of the other without any
covalent bonds between them. As described in more detail below, in a preferred
embodiment, the IPNs of the present invention can be made by sequential


polymerization resulting in sequential IPNs. in another preferred embodiment, the IPNs
of the present invention are made by interlacing a partially or fully polymerized
macromolecular indicator molecule with the polymeric structure of the support, resulting
in what is called, in the context of the present invention, an interpenetrating polymer
network ("IPN").
[0048] A first step in producing a graft is to produce interlacing areas at the
surface of the support. An "interlacing area" according to the present invention may be
an area near the surface of a support in which polymer chains of the support have been
loosened to allow interlacing with a partially or fully polymerized macromolecular
indicator molecule or by sequential interpenetrating polymerization.
[0049] Interlacing areas and grafts can be produced in different ways. For
example, in one embodiment, polymeric chains on the surface of a support are
loosened to form interlacing areas by a monomeric component, preferably a. hydrophilic
monomeric component, such as HEMA (2-hydroxyethyl methacrylate), of the'
macromolecular indicator molecule that also acts as solvent for the support material. In
one" embodiment of this aspect of the invention, a graft is formed by polymerizing the
hydrophilic monomeric components of the macromolecular indicator molecule that
caused the loosening of the polymer chains on the surface of the support, with the
remaining components of what eventually forms the macromolecular indicator
molecule. Interlacing results from having the polymerization proceed through the
interlacing areas to form a sequential IPN. The polymerization creates a mechanical
lock between the support and the polymerized macromolecular indicator molecule, The


polymerization of the components of the macromolecular indicator molecule also
causes interlocking with the loosened polymer chains. In accordance with one
embodiment, the polymer chains may be tightened as described, for example, in
connection with Figures 4A and 4B. The tightening of the polymer chains may be
achieved, for example, by removal of the solvent, drying or other means.
[0050] In a preferred embodiment of the present invention, the polymerization
reaction comprises a radical initiator such as, for example, VA-044 (WAKO Chemical
Co., Japan). In yet another preferred embodiment, one or more crosslinkers, such as,
for example, EGDMA (ethylene glycol dimethyiacrylate), TMPTMA (trimethylolpropane
trimethacryjate) or para-toluene sulfonic acid may be added to the polymerization
reaction mix to crosslink the macromolecular indicator molecule within the support In a
preferred embodiment, the crossiinking of the macromolecular indicator molecules
forms loops, while the loosened support material forms another loop which is
interlocked with the loops of the macromolecular indicator molecule(s).
[0051] The crossiinking of the macromolecular indicator molecules within the
graft is aimed at achieving higher overall reliability of the attachment of the indicator
molecule. In yet another preferred embodiment, the polymerization reaction may be
run within a mold such as a DELRIN© mold similar to the one shown in Figures 6A-6D.
[0052] In another embodiment of the present invention, which is illustrated in
Figures 3 and 4, a graft is formed by first loosening the support material by a solvent
and having a partially or fully polymerized macromolecular indicator molecule interlace
with the interlacing areas of monomer mixture on the support material. In one


embodiment, a crosslinker is added to a mix of solvent and the macromoiecuiar
indicator molecules, which links the macromoiecuiar indicator molecules to each other.
While the crosslinking may occur before interlacing, the process will, in certain
embodiments, continue after interlacing has occurred, thus providing additional stability.
[0053] Figure 3A illustrates a sensor 204 having a polymer encasement for
microelectronics 205 as the immobilization support. Figure 3B is an exploded view of
the surface 206 of such the polymer encasement, in this embodiment, the surface
comprises a tightly interwoven and intertwined long chained polymer such as PMMA.
The arrow pointing from Figure 3B to Figure 3C indicates the transition of the surface of
the encasement material from a tightly interwoven configuration to a loopy
configuration. The loops 308 constitute, in a preferred embodiment, the interlacing
areas. This transition is accomplished by treating the surface with a solvent which may
be, but is not limited to, ethanol, 2-methoxyethanol, DMF (dimethylformamidie), HEMA
or mixtures thereof. However, depending on the support material chosen, the person
skilled in the art will appreciate that any other substance that can attack the surface of
the support to form interlacing areas may be used.
[0054] Figure 4A shows a surface of the support 206 with interlacing areas 308,
which may be, for example, created in the manner shown in Figures 3A-3C. Figure 4A
also shows a macromolecule, such as a macromoiecuiar indicator molecule 100. The
macromolecule is added with the interlacing area forming substance, or after the
appropriate interlacing area forming substance has created interlacing areas on a
support, to a reaction vessel containing such a support. The macromolecule 100


interlaces with the interlacing areas 308 by, for example, simple diffusion. To
ac6omp!ish interlacing of the macromoiecular indicator molecules substantially evenly
over the entire surface of support, e.g., such as a bean shaped sensor device as
described in U.S. Patent No. 6,330,464, the diffusion is allowed to proceed. In a
preferred embodiment, the macromoiecular indicator and the support are both at least
partly soluble in the interlacing area forming substance. In one embodiment, the
macromoiecular indicator molecule is partially polymerized at the time of interaction
with the interlacing areas.
[0055] in another embodiment, the macromoiecular indicator molecule is fully
polymerized at the time of interaction with the interlacing areas. The arrow between
Figures 4A and 4B indicates the secure immobilization of the macromolecule 100 on
the surface of the support as the support material 207 reverts substantially back to,its
original tight configuration. In this process macromolecule 100 is trapped as shown in
Figure 4B and thus securely immobilized on to the surface of the support material. In a
preferred embodiment, this process is accomplished by actively removing the
interlacing area creating substance.
[0056] In another embodiment of the present invention, the interlacing area
creating substance vaporizes over time. In yet another embodiment, the support is
dried in the presence of oxygen to slow down the polymerization reaction, which is
inhibited by oxygen and thus facilitate diffusion of the macromoiecular indicator
molecule through the interlacing areas.


[0057] In another aspect of the present invention, indicator molecules may be
immobilized on a support via ionic bonding. Ionic bonding is based on the electrostatic
attraction of ions.
[0058] Suitable indicator molecules having ionic charges have been described
above. Those indicator molecules may be monomeric or polymeric. Referring to
Figure 5A, a suitable macromoiecular indicator molecule 510 is illustrated which has
charges 511 distributed over the entire indicator molecule. The molecule is positively
charged due to a large number of positively charged moieti as 511, for example, amine
moieties, which are distributed over the molecule. In contrast, the molecule 520
illustrated in Figure 5B, contains only a terminal positive charge 522. However, as
described above, any indicator molecule carrying positive or negative charges at a
suitable pH range can be used in the context of the present invention. In a preferred
embodiment, indicator molecules carrying strong positive or negative charges at pHs
around neutral are preferred.
[0059] Suitable support materials for immobilizing the indicator molecules via
ionic bonding in accordance with the present invention have been described above and
include, for example, PMMA. However, any support material that is ionic at suitable pH
ranges may be used. Such support materials usually are not, but may be, inherently
ionic at such pH ranges. Generally, the support materials may be modified to be ionic.
For example, a support material may be modified to carry charges that, at a certain pH
range, are opposite of the charge(s) of the appropriate indicator molecule that are to
be attached to it. In one embodiment, sulfonates, which have been co-polymerized


with methyl methacrylate (MMA), are covalently attached to a non-ionic support by
methods known from the ion exchange resin art. ionic groups other than sulfonates
may also be used in the context of the present invention. For example, other suitable
strong anionic groups such as, but not limited to, methyfsulfonate, sulfonic acid,
suifoisobutyl and sulfoethy! can be used in the context of the present invention. Strong
cafionic groups such as, but not limited to, quaternary ammonium, quaternary amine,
trimethylammonium methyl and dimethylyethanolamine can also be used in the context
of the present invention. In a preferred embodiment, the groups are ionic at pHs
around neutral. While ionic groups can be covalently linked to the support, in a
preferred embodiment described above, the ionic groups are provided by coating the
support with a copolymer of sulfonate and methyl methacrylate (MMA) or, in certain
embodiments, by a glass or glass-like coating. However, other polymers, such as
acrylate copolymers, can be used in the context of the present invention.
[0060] A process for coating a support in accordance with one embodiment of
the present invention is illustrated in Figures 6A to 6D. Figure 6A illustrates a bean
shaped sensor 600 and a mold 611 having an inner surface 612 which may be
dimensioned to closely match the shape of the sensor 600. As shown in Figure 6B,
when the sensor 600 is inserted into the mold 611, a small gap 613 remains between
the surface 606 of the sensor and the inner surface 612 of the mold. Figure 6C shows
how a coating 614 containing ion-exchanger groups, such as a MMA-su!fonate
copolymer, is added to the mold to fill this gap. The coating is then cured, for example,
by heat, to create a coated sensor device 615, as illustrated in Figure 6D. Figure 6D
' shows the sensing device 615 having a strongly anionic coating 614. As discussed


above, the anionic groups of the coating can form ionic bonds with cationic groups,
such as amine groups, of an indicator molecule. However, as the person skilled in the
art will appreciate, the coating can be applied in a variety of ways including, but not
limited to, dipping or spraying.'
[0061] Figures 7 A to 7C illustrate the formation of ionic bonds and the resulting
immobilization of a positively charged macromolecular indicator molecule on the body
of a sensor surface. In particular, Figure 7A shows the device 615, having a coating
614 having anionic groups 616 equally distributed over its surface. Figure 7B depicts a
macromolecular indicator molecule 510 having positive charges 511 equally distributed
over the molecule. The attraction of the negative charges 616 on the sensor support
on the one hand, and the positive charges 511 on the macromolecular indicator
molecule 510 allow immobilization of the macromolecular indicator molecule on the
surface of the support in a simple ion exchange reaction. Thus, the macromolecular
indicator molecule can be immobilized on the support as shown in Figure 7C by
bringing it into contact with the support in a solution having a pH value that supports a
strongly anionic charge of the support and a strongly cationic charge of the.indicator
molecule. Since the macromolecular indicator molecule has positive charges
distributed over the body of the molecule, these positive charges can form bonds with
multiple negative charges on the support 717.
[0062] Figures 8A to 8C show an immobilization process similar to that shown in
Figures 7A to 7C. However, the macromolecular indicator molecule 520 carries only a
terminal positive charge 522 as opposed to positive charges over the entire body of the


molecule as the molecule shown in Figure 7B. Accordingly, when the macromolecular

indicator molecules of Figure 8B are attached to the anionic substrate 615 via an ion
exchange reaction, the indicator molecules are attached to the substrate terminally 818,
via an ionic bond between the terminal positive charge in each indicator molecule and
an individual negatively charged group on the support.
EXAMPLE I
[0063] An example of a protocol for producing the graft in accordance with one
embodiment of the present invention is described below:
[0064] Solution A comprising HEMA (95.8%), EGDMA (ethylene glycol
dimethacrylate) .(0.2%) as a crosslinker and acrylic acid (4%) was provided. A
fluorescent monomeric indicator molecule, e.g., bis-carboxyiate bis-boronate-
anthracene, was added to Solution A at 14 mg/ml (up to about 28 mg/ml) to create
"Solution 1." 300ul of Solution 1 was then added to 700ul of distilled, deiortized water
to yield "Solution 2" (white gel). 33.6ul of a 10% solution (100 mg/ml) of VA-044
(Wako Chemical Co., Japan) (free radical, water soluble initiator molecule) was added
to "Solution 2" to create "Solution 3."
[0065] In the meanwhile, the immobilization substrate, in this instance a PMMA
core, was exposed to' ozone for overall 30 minutes in a UVOCS (Model # T0606 ozone
chamber) to create hydroxyl groups on its surface to aid in wetting. A thin coating of
stopcock grease was applied on the interface of a two part DELRIN® mold. The two
mold halves were joined and locked together with three hose clamps (9-22.2 mm) and
the bottom hole of the mold was plugged with a rubber septa. The mold was loaded


with 200µl of Solution 3. The internal dimensions of the sensor mold, in this case a
0.203" ID mold, were chosen to ensure that the graft was approximately 100µm thick.
The ozone treated PMMA core was inserted into the mold so that the short bullnose
end of the sensor entered the mold first and the sensor optics faced the wall of the
mold and was perpendicular to the mold seam while avoiding the formation of air voids.
Then the mold was sealed.. Heating at approximately 50°C for approximately 1-24
hours, preferably 3-16 hours, generated a white gel polymer graft. During the heating
at 50°C over an extended period of times,- e.g. 3 hrs., the HEMA monomer had time to
penetrate the PMMA and interweaving with the PMMA polymer to generate an IPN
(interpenetrating polymer network) could proceed. The PMMA core was subsequently
removed from the mold and placed in PBS (phosphate buffered saline) storage.
EXAMPLE II
[0066] An example of a protocol for producing the graft in accordance with
another embodiment of the present invention is described below:
[0067] 500 mg of a monomeric indicator molecule, such as bis-carboxylate bis-
boronate-anthracene, was added to a 5g solution comprising HEMA and acrylic acid
(90:10; w/w) to create "Solution 1." However, the relative molar ratios of the monomers
may be varied to achieve different overall hydrophilicity and control the presence of
excimer regions. The relative concentrations of the monomeric indicator molecule and
hydrophilic monomer may range, for example, from 750mg -250 mg indicator to 5 g of
Solution A. AIBN (2,2' azo-bis-isobutyronitrile, 98%), a free radical initiator that
catalyzes the polymerization of the macromolecular indicator molecule, was added at 1


weight percent to "Solution 1" to create "Solution 2." "Solution 2" was combined with a
solution comprising ethanol and 2-methoxyethanol (70:30, w/w) at a weight ratio of 1:10
to create "Solution 3." The solution comprising ethanol and 2-methoxyethanol was
added to allow the polymerization reaction to take place and ultimately attack the
surface of the PMMA to create interlacing areas. Heating "Solution 3" at approximately
56°C for approximately 24 hours.under nitrogen (to drive off oxygen, which inhibits the
pre-polymerization reaction) activated the AIBN initiator causing the polymerization of
monomers to create polymers. The resulting "Solution 4," generally contains polymers
of differing length as well as un-reacted monomers. "Solution 4" was mixed with the
crosslinker para-toluene sulfonic acid (0.333% w/w). The mix was allowed to stand for
2 hours in the dark to yield "Solution 5." The PMMA core was dipped into "Solution 5"
and was then allowed to stand in the dark exposed to air for 24 hours. The PMMA core
was cured to drive off remaining solvent at 100-110oC for 3 hours. Excess reaction
material, which had not become mechanically fixed to the surface, was washed off in a
washing and finishing step.
[0068] While various embodiments/variations of the present invention have been
described above, it should be understood that they have been presented by way of
non-limiting example only. Thus, the breadth and scope of the present invention should
not be limited by any of the above-described exemplary embodiments, but should be
defined only in accordance with the following claims and their equivalents.


WE CLATM:
1. A method for non-covalently attaching a macromolecular indicator to a support comprising:
(a) providing a support surface which comprises at least one polymer;
(b) changing the integrity of the polymer to provide loosened polymer chains that form at least
one interlacing area;
(c) providing at least one macromolecular indicator or monomers thereof;
(d) causing the macromolecular indicator to interlace with said at least one interlacing area, or
causing the sequential polymerization of said monomers to form polymerization products which
interlace with said at least one interlacing area; and
(e) causing the loosened polymer chains to tighten to produce surface immobilized indicator
molecules.

2. The method as claimed in claim 1, wherein said macromolecular indicator molecule in (c) is a
partially or fully polymerized indicator molecule.
3. The method as claimed in claim 1, wherein monomers of said at least one macromolecular
indicator molecules are provided in (c) and are sequentially polymerized in (d).
4. The method as claimed in claim 1, wherein said support surface is hydrophobic or hydrophilic.
5. The method as claimed in 4, wherein said support surface is hydrophobic and said
macromolecular indicator is hydrophilic.
6. The method as claimed in claim 1, wherein said support is the surface of a sensor or an optical
waveguide.
7. The method as claimed in claim 1, wherein the integrity of said polymer is changed by the
addition of a solvent.


8. The method as claimed in claim 7, wherein the loosened polymer chains are tightened by the
substantial removal of said solvent.
9. The method as claimed in claim 8, wherein the solvent is ethanol, 2-methoxyethanol,
dimethylformamide, hydroxyethyl methacrylate or mixtures thereof.
10. The method as claimed in claim 8, wherein the solvent is a hydrophilic monomer of a
hydrophilic macromolecular indicator.
11. The method as claimed in claim 10, wherein the polymerization of said hydrophilic monomer
with further monomers of said macromolecular indicator molecule tightens the loosened polymer
chains.
12. The method as claimed in claim 10, wherein said hydrophilic monomer is 2-hydroxyethyl
methacrylate or methacrylamidopropyltrimethylammonium chloride
13. The method as claimed in claim 11, wherein said further monomer of the macromolecular
indicator molecule comprises bis-carboxylate bis-boronate-anthracene.
14. The method as claimed in claim 1, wherein said macromolecular indicator has at least one
reference region.
15. The method as claimed in claim 14, wherein said reference region is an excimer region.
16. The method as claimed in claim 15, wherein the excimer region is an excimer region resulting
from the tertiary structure of the native macromolecular indicator.
17. The method as claimed in claim 14, wherein said reference region comprises at least one
reference molecule.
18. The method as claimed in claim 1, wherein said macromolecular indicator is crosslinked by one
or more crosslinkers.


19. The method as claimed in claim 18, wherein the one or more crosslinkers are ethylene glycol
dimethylacrylate, trimethylolpropane trimethacrylate, para-toluene sulfonic acid or mixtures thereof.
20. The method as claimed in claim 18, wherein said at least one macromolecular indicator is
crosslinked to another macromolecular indicator molecule after said at least one macromolecular
indicator molecule interlaced with at least one interlacing area.
21. The method as claimed in claim 18, wherein said at least one macromolecular indicator
molecule is crosslinked during sequential polymerization of the monomers of said at least one
macromolecular indicator molecule.
22. A graft comprising:
a surface comprising at least one polymer, and
a macromolecular indicator molecule,
wherein said macromolecular indicator is stably interlaced with at least one chain of at least one
of said polymers of the support.
23. The graft as claimed in claim 22, wherein properties of the macromolecular indicator molecule
that is part of the graft substantially corresponds to the properties of said macromolecular indicator
molecule before becoming part of the graft.
24. The graft as claimed in claim 22, wherein said surface is the surface of a sensor.
25. The graft as claimed in claim 22, wherein said graft is a sequential IPN.
26. The graft as claimed in claim 22, wherein said graft is an IPN.
27. A sensor for determining the presence or concentration of an analyte within a medium, said
sensor comprising:
a sensor body having an outer surface surrounding said sensor body, wherein said outer surface
comprises at least one polymer;


a macromolecular indicator molecule which, in response to the presence of an analyte in said
medium, changes at least one measurable characteristic;
a detector which measures said changes in said at least one characteristic of said indicator
molecule and which emits an output signal reflecting said changes in said indicator molecule; and
wherein said macromolecular indicator molecule is stably interlaced with at least one chain of
said at least one polymer of said surface.
28. The sensor as claimed in claim 27, wherein the sensor is an optical sensor.
29. The sensor as claimed in claim 27, wherein said polymer is polymethylmethacrylate.
30. The sensor as claimed in claim 27, wherein said analyte is glucose, oxygen, carbon dioxide,
nitric oxide, toxins, pH, ions and mono-or divalent cations.
31. An optical-based sensor for determining the presence or concentration of an analyte in a
medium, said sensor comprising:
an optically transmissive sensor body, said sensor body having an outer surface surrounding
said sensor body and wherein said outer surface comprises at least one polymer;
a radiation source in said sensor body which emits radiation within said sensor body;
a macromolecular indicator molecule having an optical characteristic that is affected by the
presence or concentration of an analyte, said macromolecular indicator molecule being positioned on
said sensor body to receive radiation that travels from said radiation source, and which transmits
radiation into said sensor body;
a photosensitive element located in said sensor body and positioned to receive radiation within
he sensor body and which emits a signal responsive to radiation received from said indicator element;
and wherein said macromolecular indicator molecule is stably interlaced with at least one chain of said
at least one polymer of said surface of said sensor body.
32. A method for non-covalently attaching a macromolecular indicator to a support comprising:
(a) providing a support surface which comprises at least one polymer;
(b) changing the integrity of the polymer to provide loosened polymer chains that form at
least one interlacing area;


(c) providing at least one macromolecular indicator or monomers thereof; and
(d) causing the macromolecular indicator to interlace with said at least one interlacing area,
or causing the sequential polymerization of said monomers to form polymerization products which
interlace with said at least one interlacing area.

33. The method as claimed in claim 32, wherein said method further comprises the step of (e)
causing the loosened polymer chains to tighten to produce surface immobilized indicator molecules.
34. The method as claimed in claim 32, wherein said macromolecular indicator molecule in (c) is a
partially or fully polymerized indicator molecule.
35. The method as claimed in claim 32, wherein monomers of said at least one macromolecular
indicator molecules are provided in (c) and are sequentially polymerized in (d).
36. The method as claimed in claim 32, wherein said support surface is hydrophobic or hydrophilic.


The invention relates to immobilization methods, in particular for immobilizing indicator molecules on supports such
as sensors and to sensors having those molecules immobilized to their surface. Non-covalent immobilization of macromolecular
indicator molecules on those supports via mechanical interlacing interpenetrating networks with polymers at the surface of a support
and via ionic bonding via charged moieties of indicator molecules and ionic groups on the surface of the support are disclosed.

Documents:

03310-kolnp-2006 abstract.pdf

03310-kolnp-2006 claims.pdf

03310-kolnp-2006 correspondence others.pdf

03310-kolnp-2006 description (complete).pdf

03310-kolnp-2006 drawings.pdf

03310-kolnp-2006 form 1.pdf

03310-kolnp-2006 form 3.pdf

03310-kolnp-2006 form 5.pdf

03310-kolnp-2006 international publication.pdf

03310-kolnp-2006 international search authority report.pdf

03310-kolnp-2006 pct others.pdf

03310-kolnp-2006 priority document.pdf

03310-kolnp-2006-assignment.pdf

03310-kolnp-2006-correspondence-1.1.pdf

03310-kolnp-2006-correspondence-1.2.pdf

03310-kolnp-2006-form-3-1.1.pdf

03310-kolnp-2006-general power of authority.pdf

3310-KOLNP-2006-(13-02-2012)-CORRESPONDENCE.pdf

3310-KOLNP-2006-ABSTRACT-1.1.pdf

3310-KOLNP-2006-AMANDED CLAIMS.pdf

3310-KOLNP-2006-ASSIGNMENT.1.2.pdf

3310-KOLNP-2006-CORRESPONDENCE.1.2.pdf

3310-KOLNP-2006-DESCRIPTION (COMPLETE)-1.1.pdf

3310-KOLNP-2006-EXAMINATION REPORT REPLY RECIEVED.pdf

3310-KOLNP-2006-EXAMINATION REPORT.1.2.pdf

3310-KOLNP-2006-FORM 1-1.1.pdf

3310-KOLNP-2006-FORM 18.1.2.pdf

3310-kolnp-2006-form 18.pdf

3310-KOLNP-2006-FORM 2.pdf

3310-KOLNP-2006-FORM 3-1.2.pdf

3310-KOLNP-2006-FORM 3.1.2.pdf

3310-KOLNP-2006-FORM 5.1.2.pdf

3310-KOLNP-2006-GRANTED-ABSTRACT.pdf

3310-KOLNP-2006-GRANTED-CLAIMS.pdf

3310-KOLNP-2006-GRANTED-DESCRIPTION (COMPLETE).pdf

3310-KOLNP-2006-GRANTED-DRAWINGS.pdf

3310-KOLNP-2006-GRANTED-FORM 1.pdf

3310-KOLNP-2006-GRANTED-FORM 2.pdf

3310-KOLNP-2006-GRANTED-SPECIFICATION.pdf

3310-KOLNP-2006-OTHERS.1.2.pdf

3310-KOLNP-2006-OTHERS.pdf

3310-KOLNP-2006-PA.1.2.pdf

3310-KOLNP-2006-PETITION UNDER RULE 137.pdf

3310-KOLNP-2006-REPLY TO EXAMINATION REPORT.1.2.pdf

abstract-03310-kolnp-2006.jpg


Patent Number 252310
Indian Patent Application Number 3310/KOLNP/2006
PG Journal Number 19/2012
Publication Date 11-May-2012
Grant Date 08-May-2012
Date of Filing 10-Nov-2006
Name of Patentee SENSORS FOR MEDICINE AND SCIENCE, INC.
Applicant Address 12321 MIDDLEBROOK ROAD, SUITE 210 GERMANTOWN, MD 20874
Inventors:
# Inventor's Name Inventor's Address
1 COLVIN ,JR., ARTHUR E. 4155 BALTIMORE NATIONAL PIKE MT.AIRY, MARYLAND 21771
2 LORENZ , CARRIE R. 15685 OLD FREDERICK ROAD, WOODBINE, MD 21797
PCT International Classification Number G01N 21/6
PCT International Application Number PCT/US2005/011654
PCT International Filing date 2005-04-07
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/822,670 2004-04-13 U.S.A.