WO2002068958A1 - Molecularly imprinted scintillation polymers - Google Patents

Molecularly imprinted scintillation polymers Download PDF

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Publication number
WO2002068958A1
WO2002068958A1 PCT/SE2002/000268 SE0200268W WO02068958A1 WO 2002068958 A1 WO2002068958 A1 WO 2002068958A1 SE 0200268 W SE0200268 W SE 0200268W WO 02068958 A1 WO02068958 A1 WO 02068958A1
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Prior art keywords
polymer
molecularly imprinted
scintillator
imprinted polymer
scintillation
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PCT/SE2002/000268
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French (fr)
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WO2002068958A8 (en
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Klaus Mosbach
Lei Ye
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Klaus Mosbach
Lei Ye
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Publication of WO2002068958A1 publication Critical patent/WO2002068958A1/en
Publication of WO2002068958A8 publication Critical patent/WO2002068958A8/en

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N33/00Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
    • G01N33/48Biological material, e.g. blood, urine; Haemocytometers
    • G01N33/50Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
    • G01N33/53Immunoassay; Biospecific binding assay; Materials therefor
    • G01N33/536Immunoassay; Biospecific binding assay; Materials therefor with immune complex formed in liquid phase
    • G01N33/542Immunoassay; Biospecific binding assay; Materials therefor with immune complex formed in liquid phase with steric inhibition or signal modification, e.g. fluorescent quenching
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N2600/00Assays involving molecular imprinted polymers/polymers created around a molecular template

Definitions

  • the present invention relates to a molecularly imprinted polymer having specific binding sites, a method of preparing a molecularly imprinted polymer having specific binding sites and use of a molecularly imprinted polymer according to the invention.
  • Background of the invention is a molecularly imprinted polymer having specific binding sites, a method of preparing a molecularly imprinted polymer having specific binding sites and use of a molecularly imprinted polymer according to the invention.
  • Specific binding materials are of critical importance in the development of sensors and assays .
  • Biological antibodies, receptors and single strand DNA segments display very high binding affinity and specificity towards the corresponding antigens, agonists/antagonists and complementary DNA sequences. These biological binders have been widely used- in sensitive detection of target analytes, both for clinical purposes and in drug developments. Since biomacromolecules are not stable, and in many cases are difficult to produce, synthetic materials that mimic the binding characteristics of these biomole- cules have been intensely studied to provide useful affi- nity materials for applications in separation and analysis .
  • molecular imprinting of synthetic polymers.
  • co-polymerisation of functional monomers and cross- linking monomers is carried out in the presence of a molecular template, which results in a rigid polymer matris embedding the template. Removal of the template reveals binding sites specific to the template or its close analogues.
  • Molecularly imprinted polymers are much more stable than biological receptors, and much easier to produce. They have great potential to replace or supplement biological receptors in all affinity-related applications .
  • the amount of bound, radioisotope-labeled analyte is quantified after separation of the unbound fraction by centrifugation or filtration.
  • the separation steps are tedious and difficult to automate, which prevents high throughput in handling large amount of samples. It is desirable that no separation step is used when detecting a target analyte with a molecularly imprinted polymer.
  • the prerequisite of separation when using imprinted polymers in assays is due to the fact that binding of the analyte does not induce any directly detectable physico- chemical changes in the polymeric materials.
  • Imprinted polymers are only used as affinity adsorbents to specifically isolate the target analyte, which is then quantified using routine analytical techniques. However, when imprinted polymers are put in physical contact with appropriate transducers, binding of a target analyte causes physicochemical responses (change in mass, resistance, capacitance, refractive index etc.) that are translated into various sensor signals.
  • US patent 5910286 describes a chemical sensor comprising an acoustic wave transducer and a layer of molecularly imprinted polymer. Binding of the target molecule to the polymer layer affects the propagation of the acoustic wave in a medium, whereby a sensor response is obtained.
  • imprinted polymers Physical attachment of imprinted polymers to transducers is easy to carry out. However, this often leads to sensors showing rather poor selectivity, since non-specific binding also leads to generation of sensor signal .
  • imprinted polymers generate sensor signals only when a target is specifically bound to the polymers. This is obtainable by using a specia- Used functional monomer that either releases an indicator, or displays an altered optical characteristic upon binding of the target molecule.
  • US patent 6063637 describes sensors for use in detecting sugars. The sensor is composed of a metal complex that binds to the target molecule and releases a proton. Measurement of the released proton provides an indirect indication of the target molecule concentration.
  • PCT application WO 96/41173 describes use of fluorescent functional monomers for signal generation.
  • Binding of the target analyte changes fluorescent characteristic of the imprinted polymer, which is detected with a fluorescent spectrophoto- meter.
  • these specialised functional monomers are scarcely applicable to a broad range of different target analytes, to which however many "universal" functional monomers have demonstrated to provide satisfactory binding specificity. 5
  • Another way to circumvent the separation requirement is to utilise the principle of proximity energy transfer, more specifically proximity scintillation.
  • PCT application WO 91/08489 describes a support body for use in scintillation proximity radioimmunoassay, the support
  • the selec- ' tive binding materials in these patents and patent applications are all derived from biological macromolecules such as antibodies, receptors, enzymes, etc.
  • biological macromolecules such as antibodies, receptors, enzymes, etc.
  • the present invention relates in a first aspect to a
  • molecularly imprinted polymer having specific binding sites, which polymer comprises at least one component for energy transfer located in proximity to said binding sites .
  • said reactive group comprises at least one of the groups -COOH, -CHO, -OH and -NH 2 .
  • the polymer is an organic polymer comprising as a main component at least one polymer chosen from the group comprising polyacrylate, polystyrene, polyurethane, polyanaline and polyamide.
  • the polymer is an inorganic polymer obtained from alkoxides of silicon, aluminum or titanium.
  • the polymer has a configuration chosen from the group comprising monolith, irregular particles, thin films, membranes, microspheres and beads.
  • the polymer has been polymerised in situ within wells of a microtitre plate or on a micro- chip.
  • the polymer comprises two scintillators .
  • the polymer comprises an aromatic substance, which assists in exciting the compo- nent for proximity energy transfer.
  • the distance between the component for proximity energy transfer and the binding sites of the polymer is within the range 0-50 ⁇ m.
  • the invention in another aspect relates to a method of preparing a molecularly imprinted polymer having specific binding sites, comprising incorporation into and/or conjugation with the polymer of a component for proximity energy transfer.
  • said method comprises the steps: copolymerisation of functional monomers in the pre- scence of at least one template molecule using conven- tional polymerisation techniques, which monomers comprise at least one component for proximity energy transfer; and removal of the template molecule.
  • said method comprises the steps -. copolymerisation of functional monomers and at least one reactive monomer carrying an optionally protected, reactive group in the prescence of at least one template molecule using conventional tecniques; chemical conjugation of the reactive group of the polymer and a reactive group of the component for proximity energy transfer; and removal, before or after said conjugation, of the template molecule.
  • the component used for proximity energy transfer is a scintillator.
  • the scintillator is 2, 5-diphenyloxazole or a derivative thereof.
  • the reactive group of the scintillator is chosen from the group comprising -C00H, -CHO, -OH and -NH 2 .
  • the reactive group of the monomer is chosen from the group comprising -COOH, -CHO, -OH and -NH 2 .
  • the polymerisation is performed so that a polymer with a configuration chosen from the group comprising monolith, irregular particles, thin films, membranes, microspheres and beads is obtai- ned.
  • the polymerisation is performed in situ within the wells of a microtitre plate or on a microchip .
  • two different scintillators are in use.
  • an aromatic substance which assists in exciting the component for proximity energy transfer, is incorporated into the polymer.
  • the incorporation of the second scin- tillator and/or the aromatic substance is obtained by physical absorption or by chemical linkage.
  • the invention relates to use of a molecularly imprinted polymer according to the in- vention or a polymer prepared according to a method of the invention in a proximity scintillation assay.
  • the invention relates to use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention for screening of combinatorial libraries.
  • the invention relates to use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention for use in sensors .
  • the invention relates to use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention for in situ monitoring of radioactive metabolites or enzymatic reactions .
  • an imaging system is used for quantifying the fluorescence signal.
  • the imaging system is a Charge Coupled Device (a CCD camera) .
  • arrays of photomultiplier tubes are used for scintillation coun- ting.
  • Figure 1 schematically shows the use of a molecularly imprinted scintillation polymer according to the present invention for detection of a target analyte.
  • Figure 2 shows examples of functional monomers and cross-linking monomers used in preferred embodiments of the present invention. ⁇ c to t ⁇ 1 ⁇ >
  • the term scintillator can be defined as a phosphorescent or fluorescent molecule that generates a flash of light when excited by an ionising particle such as a ⁇ -particle or a photon.
  • the scintillator is a derivative of 2, 5-diphenyloxazole.
  • scintillator is also meant a scintillant molecule that has a reactive group, whereby the reactive group is used for chemical immobilisation of the scintillant molecule on the polymer mat- ris.
  • the reactive group is e.g. -NH 2 , -OH, -COOH, or -CHO, which can be used for chemical immo- bilisation of the scintillator on a previously synthesi- sed molecularly imprinted polymer.
  • Said chemical immobilisation reactions can be carried out prior to, or after removal of the template molecules from the polymers.
  • Figure 3 shows examples of scintillator.
  • the term polymer covers both organic and inorganic polymers. Examples of organic polymers are those based on polyacrylate, polystyrene, polyanaline and polyurethane . Said polymers may be cross- linked to various extents.
  • the polymers are obtained by conventional polymerisation reactions, for example free radical polymerisation or condensation polymerisation.
  • An example of an inorganic polymer is a silica gel obtained by hydrolysis of precursor monomers e.g. alkoxysilanes that are commonly used for preparation of silica par- tides.
  • a secondary scintillator can be incorporated into the imprinted polymer, or admixed with the imprinted scintillation polymer used in an assay.
  • the secondary scintillator is a phosphorescent or fluorescent molecule that is excited by the primary scintillator, and emits a flash of light at a longer wavelength.
  • Typical secondary scintillators are those commonly used in liquid scintillation counting, or derivatives of them containing a reactive group. Chemical incorporation of said secondary scintillator can be carried out in the same step as that in which the primary scintillator is incorporated, or achieved in separate post-imprinting steps.
  • the present invention also provides a further method for introducing an aromatic substance into molecularly imprinted scintillation polymers.
  • Said base component assists to transfer the radioisotope decay into a short wavelength radiation, which is able to excite the primary scintillator for generation of a fluorescence signal .
  • Said aromatic substance may be chemically linked to the imprinted polymer, typically by co-polymerisation of aromatic monomers or cross-linking monomers during the imprinting reaction, or be physically absorbed into the polymer matris.
  • the aromatic substance is typically an aromatic solvent, when it is physically absorbed into the polymer matris . This is especially useful when the measu- rements are carried out in a non-aromatic solvent.
  • Said aromatic solvent is confined within the polymer matris when the latter is transferred into the assay solvent, e.g. an aqueous or a highly polar organic solvent.
  • the solvent itself may serve as the base component .
  • the present invention relates to molecularly imprinted scintillation polymers comprising:
  • Chemical fixation of the scintillator is obtained in two ways: (1) by introducing a scintillator into an imprinting mixture, so that the scintillator is co-polymerised with the other monomers during the imprinting reaction; (2) by chemical immobili- sation of a reactive scintillator to a previously synthe- sised molecularly imprinted polymer.
  • the imprinting reaction may be a free radical reaction, an ionic reaction, an oxidation-reduction, an electrochemical reaction, or other polymerisation reactions including hydrolysis polymerisation of inorganic precursor monomers.
  • the imprinting polymerisation may be initiated by heat, UV radiation, ⁇ -radiation, electrochemical potential, acid hydrolysis, or by other chemical means. After the polymerisation, the template is removed and the obtained polymer is worked up following standard procedures.
  • said scintillator is optionally a combination of a primary and a secondary scintillator.
  • the secondary scintillator is incorporated into said polymer, which has a chemically bound primary scintillator, by using the physical absorption method described above.
  • an aromatic monomer more specifically styrene or divinylbenzene, is used in the imprinting reaction to provide a chemically linked base component for better scintillation response in non- aromatic solvents.
  • the aromatic monomer may be the same as the functional monomer or the cross-linker.
  • the optional base component may be co-impregnated with the secondary scintillator into the imprinted polymer by using the physical absorption method.
  • an imprinted polymer is initially synthesised.
  • the imprinted polymer may carry additional reactive groups that can be used for coupling of a scintillator.
  • a small fraction of binding groups in the imprinted polymer is used for coupling of the scintillator.
  • the coupling reaction may be carried out prior to, or after removal of the template molecule from the imprinted polymer.
  • a secondary scintillator and an aromatic substance are also immobilised in the same way.
  • the molecularly imprinted scintillation polymers of the present invention are synthesised in various configurations including monoliths, irregular particles, micro- spheres, membranes, films, and monolayers.
  • the imprinted polymers can also be synthesised in situ in microtitre plate wells .
  • the imprinting reactions are typically similar to those of established ones, except that either the imprinted polymer is further treated by chemical or physical means to incorporate scintillators, or the scintillator is incorporated into the polymer chains during the imprinting reaction.
  • the molecularly imprinted scintillation polymers of the present invention can be synthesised in the form of microparticles or microspheres . Preferably, the micro- particles and microspheres then have an average diameter of 0.01-10 ⁇ m.
  • the imprinted polymers are synthesised using a precipitation polymerisation method described in PCT application WO 00/041723.
  • the imprinted scintillation polymers of the present invention can also be synthesised in situ in microtitre plate wells or on microchips.
  • the polymers may be in the form of continuous films or separate spots. More specifically the thickness of the polymer layer is controlled during preparation to be less than 50 ⁇ m.
  • the obtained polymer is used for detection of a target analyte present in a radioisotope-labelled sample, or in a displacement assay of a target analyte using a radioisotope-labelled probe.
  • the radioactive probe may be the LO L to to ⁇ > ⁇ 1
  • Scintillation monomers are synthesised from 2,5- diphenyloxazole derivatives carrying a reactive group.
  • the scintillation monomers are co-polymerised into the polymer matris during an imprinting reaction.
  • NISP 1 non-imprinted scintillation polymer
  • the obtained polymer microparticles have an average diameter of 0.6-1 ⁇ m, which is determined by scanning electron microscopy. Surface areas of the microparticles are approximately 7 m 2 g _1 , which is determined by nitrogen absorption measurement. Elemental analysis confirms that the imprinted polymer (MISP 1) and non-imprinted polymer (NISP 1) contain approximately equal amounts of scintillator (Table 1) .
  • the obtained polymer microparticles have an average diameter of 0.6-1 ⁇ m, which is determined by scanning electron microscopy.
  • the surface areas of the micropar- ticels are approximately 7 m 2 g _1 , which is determined by nitrogen absorption measurement. Elemental analysis confirms that the imprinted polymer (MISP 2) and non-imprinted polymer (NISP 2) contain approximately equal amount of scintillator (Table 2) .
  • Non-covalent interactions are utilised for preparing a molecularly imprinted scintillation polymer.
  • a scintillation monomer and an aromatic substance are incorporated by co-polymerisation with the functional monomer and/or the cross-linking monomer.
  • a precipitation polymerisation method is used to generate discrete polymer microspheres .
  • the polymer microspheres are finally washed with acetone and dried in vacuum.
  • a non-imprinted polymer (NISP 3) is synthesised under identical condition except omission of the template, (S) -propranolol .
  • the obtained polymers are in the form of micro- spheres having an average diameter of 0.6-2.8 ⁇ m, which is determined by scanning electron microscopy.
  • Example 5 Synthesis of a molecularly imprinted scintillation polymer (MISP 4) specific for (S) -propranolol, having styrene as the aromatic substance (S) -propranolol (0.602 mmol), methacrylic acid (0.392 mmol), styrene (0.392 mmol) ' , trimethylolproprane trimethacrylate (0.784 mmol), 4-hydroxymethyl-2 , 5-diphenyloxazole acrylate (0.157 mmol) and ⁇ , ⁇ '-azoisobutyro- nitrile (0.073 mmol) are dissolved in anhydrous acetoni- trile (40 ml) .
  • MISP 4 molecularly imprinted scintillation polymer
  • the solution is saturated with dry nitrogen gas, and sealed under a nitrogen atmosphere.
  • the solution is transferred into a water bath pre-set at 60°C to initiate the free radical polymerisation.
  • the reaction continues at 60°C for 16 hours.
  • the polymer microspheres are collected by centrifugation.
  • (S) -propranolol is removed by repeated solvent extraction of the polymer in methanol containing 10% acetic acid.
  • the polymer microspheres are finally washed with acetone and dried in vacuum.
  • a non-imprinted scintillation polymer (NISP 4) is synthesised under identical condition except omission of the template, (S) -propranolol .
  • Molecularly imprinted scintillation polymers are prepared by immobilisation of a reactive scintillator on previously synthesised molecularly imprinted polymers.
  • Example 6 Synthesis of molecularly imprinted microspheres carrying a reactive moiety for coupling of a scintillator (MIP 1) To a borosilicate glass tube are added 17 ⁇ -estradiol (0.734 mmol), methacrylic acid (1.884 mmol), trimethylolproprane trimethacrylate (1.884 mmol), 4-nitrophenylacry- late (0.942 mmol) and 2-hydroxy-2-methyl-l-phenyl propan- 1-one (1.0 mmol) dissolved in anhydrous acetonitrile (40 ml) .
  • NMP 1 non-imprinted polymer
  • the molecularly imprinted microspheres (MIP 1, synthesised in Example 6) (200 mg) are suspended in 12 ml of 1 M solution of a reactive scintillator, 4-amino- ethyl-2 , 5-diphenyloxazole dissolved in acetonitrile. The suspension is gently stirred at 20°C for 24 h. The polymer microspheres are separated by centrifugation and repeatedly washed with methanol containing 10% acetic acid (v/v) to remove the template molecule. The polymer microspheres are subsequently washed with acetone and dried in vacuum. No yellow colour is observed when the treated microspheres are added to 1 M NaOH, which confirms complete immobilisation of the scintillator.
  • the non-imprinted scintillation microspheres (NISP 5) are prepared similarly by treatment of the non-imprinted microspheres (NIP 1) .
  • MISP polymer microparticles
  • the imprin- ted polymer binds much more of the tritium-labelled analyte than the control, whereby a much higher scintillation signal (CPM) is obtained.
  • CPM scintillation signal
  • MISP polymer microparticles
  • Figure 7 shows calibration curves for the template molecule, (S) -propranolol, and for its enantiomer, (R) -pro- pranolol .
  • the chemical sensing polymer (MISP 3) displays very high chiral selectivity when used in an aqueous solvent, since the cross-reactivity from (R) -propranolol is less than 5%.

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Abstract

A molecularly imprinted polymer having specific binding sites, which polymer compriese at least one component for energy transfer located in proximity to said binding sites. There is also described a method of preparing and the use of such a molcularly impritned polymer.

Description

MOLECULARLY IMPRINTED SCINTILLATION POLYMERS
Field of the invention
The present invention relates to a molecularly imprinted polymer having specific binding sites, a method of preparing a molecularly imprinted polymer having specific binding sites and use of a molecularly imprinted polymer according to the invention. Background of the invention
Specific binding materials are of critical importance in the development of sensors and assays . Biological antibodies, receptors and single strand DNA segments display very high binding affinity and specificity towards the corresponding antigens, agonists/antagonists and complementary DNA sequences. These biological binders have been widely used- in sensitive detection of target analytes, both for clinical purposes and in drug developments. Since biomacromolecules are not stable, and in many cases are difficult to produce, synthetic materials that mimic the binding characteristics of these biomole- cules have been intensely studied to provide useful affi- nity materials for applications in separation and analysis .
Among the most practicable approaches is molecular imprinting of synthetic polymers. By molecular imprinting, co-polymerisation of functional monomers and cross- linking monomers is carried out in the presence of a molecular template, which results in a rigid polymer matris embedding the template. Removal of the template reveals binding sites specific to the template or its close analogues. Molecularly imprinted polymers are much more stable than biological receptors, and much easier to produce. They have great potential to replace or supplement biological receptors in all affinity-related applications .
In molecular imprinting, the assembly of the tem- plate-functional monomer complex prior to and during the polymerisation reaction, as well as the re-binding of the template by the obtained polymer is driven by various molecular interactions between the template and the functional monomers. ulff and Poll has described a method of using reversible covalent binding for molecular imprinting of an optically active compound, as well as the use of the polymer for separation of an optically active antipode from a racemate mixture (Wulff, G.; Poll, H.-G. Makromol . Chem. 1987, 188, 741-748) . US patent 5310648 describes the use of metal chelating functional monomers for preparation of an imprinted polymer matris . More favourably, non-covalent interactions have been used in the PCT applications WO 93/09075 and WO 98/07671 for preparation of a chiral solid-phase chromatography material containing molecular imprints of an optically pure enantiomer to be separated. In addition to separation, special interests have been focused on using imprinted polymers for the development of sensors and assays, in which synthetic polymers are used to replace biological macromolecules such as antibodies and receptors. In this way the lifetime of the sensors and the affinity reagents for assays are greatly increased, whereas production costs are reduced. PCT application WO 94/11403 describes a method for producing molecularly imprinted polymers as artificial antibodies, and methods for using these artificial antibodies in therapeutic and diagnostic applications. Analogous to the heterogeneous immunoassays, the amount of bound, radioisotope-labeled analyte is quantified after separation of the unbound fraction by centrifugation or filtration. The separation steps are tedious and difficult to automate, which prevents high throughput in handling large amount of samples. It is desirable that no separation step is used when detecting a target analyte with a molecularly imprinted polymer. The prerequisite of separation when using imprinted polymers in assays is due to the fact that binding of the analyte does not induce any directly detectable physico- chemical changes in the polymeric materials. Imprinted polymers are only used as affinity adsorbents to specifically isolate the target analyte, which is then quantified using routine analytical techniques. However, when imprinted polymers are put in physical contact with appropriate transducers, binding of a target analyte causes physicochemical responses (change in mass, resistance, capacitance, refractive index etc.) that are translated into various sensor signals. US patent 5910286 describes a chemical sensor comprising an acoustic wave transducer and a layer of molecularly imprinted polymer. Binding of the target molecule to the polymer layer affects the propagation of the acoustic wave in a medium, whereby a sensor response is obtained.
Physical attachment of imprinted polymers to transducers is easy to carry out. However, this often leads to sensors showing rather poor selectivity, since non-specific binding also leads to generation of sensor signal . In a more sophisticated manner, imprinted polymers generate sensor signals only when a target is specifically bound to the polymers. This is obtainable by using a specia- Used functional monomer that either releases an indicator, or displays an altered optical characteristic upon binding of the target molecule. US patent 6063637 describes sensors for use in detecting sugars. The sensor is composed of a metal complex that binds to the target molecule and releases a proton. Measurement of the released proton provides an indirect indication of the target molecule concentration. PCT application WO 96/41173 describes use of fluorescent functional monomers for signal generation. Binding of the target analyte changes fluorescent characteristic of the imprinted polymer, which is detected with a fluorescent spectrophoto- meter. However, these specialised functional monomers are scarcely applicable to a broad range of different target analytes, to which however many "universal" functional monomers have demonstrated to provide satisfactory binding specificity. 5 Another way to circumvent the separation requirement is to utilise the principle of proximity energy transfer, more specifically proximity scintillation. PCT application WO 91/08489 describes a support body for use in scintillation proximity radioimmunoassay, the support
10 body being constructed of a scintillation material having biological binders coupled to its surface such as antigens, antibodies, etc, which are capable of selective binding of a target analyte. Several patents and patent- applications (US 4271139; US 4568649; EP 1007971 Al) have
15 been related to embodiments of the technique using various scintillation materials and assay formats. The selec- ' tive binding materials in these patents and patent applications are all derived from biological macromolecules such as antibodies, receptors, enzymes, etc. One major
20 disadvantage is, however, that the biological binding materials are unstable and not easy to produce. It is highly desirable that more stable, binding materials are used to replace the biological macromolecules in scintillation proximity assays. Although molecularly imprin- 25 ted polymers have been used in many analytical applications, their use in proximity scintillation assay has been difficult to realize. Summary of the invention
The present invention relates in a first aspect to a
30. molecularly imprinted polymer having specific binding sites, which polymer comprises at least one component for energy transfer located in proximity to said binding sites .
In one embodiment the component for proximity energy 35 transfer is chemically incorporated into the polymer. In another embodiment the component for proximity energy transfer is bound to the surface of the polymer. In a further embodiment, said component is a scin- tillator. In yet another embodiment, said scintillator comprises a reactive group. In still another embodiment, said reactive group comprises at least one C=C bond. In one embodiment the scintillator is 2 , 5-diphenyl- oxazole or a derivative thereof.
In another embodiment, said reactive group comprises at least one of the groups -COOH, -CHO, -OH and -NH2. In a further embodiment the polymer is an organic polymer comprising as a main component at least one polymer chosen from the group comprising polyacrylate, polystyrene, polyurethane, polyanaline and polyamide. In yet another embodiment the polymer is an inorganic polymer obtained from alkoxides of silicon, aluminum or titanium. In one embodiment the polymer has a configuration chosen from the group comprising monolith, irregular particles, thin films, membranes, microspheres and beads. In another embodiment the polymer has been polymerised in situ within wells of a microtitre plate or on a micro- chip.
In still another embodiment the polymer comprises two scintillators .
In yet another embodiment the polymer comprises an aromatic substance, which assists in exciting the compo- nent for proximity energy transfer.
In a further embodiment the distance between the component for proximity energy transfer and the binding sites of the polymer is within the range 0-50 μm.
In another aspect the invention relates to a method of preparing a molecularly imprinted polymer having specific binding sites, comprising incorporation into and/or conjugation with the polymer of a component for proximity energy transfer.
In one embodiment, said method comprises the steps: copolymerisation of functional monomers in the pre- scence of at least one template molecule using conven- tional polymerisation techniques, which monomers comprise at least one component for proximity energy transfer; and removal of the template molecule.
In another embodiment, said method comprises the steps -. copolymerisation of functional monomers and at least one reactive monomer carrying an optionally protected, reactive group in the prescence of at least one template molecule using conventional tecniques; chemical conjugation of the reactive group of the polymer and a reactive group of the component for proximity energy transfer; and removal, before or after said conjugation, of the template molecule. In yet another embodiment the component used for proximity energy transfer is a scintillator. In still another embodiment the scintillator comprises at least one C=C bond. In a further embodiment the scintillator is 2, 5-diphenyloxazole or a derivative thereof. In one embodiment the reactive group of the scintillator is chosen from the group comprising -C00H, -CHO, -OH and -NH2.
In another embodiment the reactive group of the monomer is chosen from the group comprising -COOH, -CHO, -OH and -NH2.
In still another embodiment the polymerisation is performed so that a polymer with a configuration chosen from the group comprising monolith, irregular particles, thin films, membranes, microspheres and beads is obtai- ned. In yet another embodiment the polymerisation is performed in situ within the wells of a microtitre plate or on a microchip .
In one embodiment two different scintillators are in use. In another embodiment an aromatic substance, which assists in exciting the component for proximity energy transfer, is incorporated into the polymer. In still another embodiment the incorporation of the second scin- tillator and/or the aromatic substance is obtained by physical absorption or by chemical linkage.
In still another aspect the invention relates to use of a molecularly imprinted polymer according to the in- vention or a polymer prepared according to a method of the invention in a proximity scintillation assay.
In yet another aspect the invention relates to use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention for screening of combinatorial libraries. In a further aspect the invention relates to use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention for use in sensors . In a last aspect the invention relates to use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention for in situ monitoring of radioactive metabolites or enzymatic reactions . In one embodiment of the use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention an imaging system is used for quantifying the fluorescence signal. In another embodiment the imaging system is a Charge Coupled Device (a CCD camera) .
In another embodiment of the use of a molecularly imprinted polymer according to the invention or a polymer prepared according to a method of the invention, arrays of photomultiplier tubes are used for scintillation coun- ting.
Brief description of the drawings
Figure 1 schematically shows the use of a molecularly imprinted scintillation polymer according to the present invention for detection of a target analyte. Figure 2 shows examples of functional monomers and cross-linking monomers used in preferred embodiments of the present invention. ω c to t μ1 μ>
U1 o LΠ o LΠ o LΠ
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P Φ rt tr μ- h-> μ- rt 0 H μ- tr φ CQ SD μ- SD s; μ- rt O μ- o μ- ϋ μ-
CQ ΓT Ω Φ rt ^ 0 μ- TJ H O P Φ ft Φ -> lb μ- LQ φ ii μ- LQ . LQ <J μ- LQ Φ LQ
Φ J Φ μ- Hi <; P 0 H P rt P SD C rt C- ft SD 0 rt P SD f- φ SD f- ft C
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Φ Φ H P rt 0 ft O s! μ- μ- SD Φ CQ 0 c SD P o rt SD O • 0 3
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P Φ Φ CQ -S μ- Q- 0 rt 3 rt φ P rt PJ SD 3 SD SD ϋ P tr ii 3 tr CQ φ ft CQ Ω 0) ft -1 ^ μ- 3 tr μ- μ- ! U 0 ^-, . H ^-, rt ϋ LQ μ- LQ μ- X μ- tr Φ ^ H Φ rt 0 Φ Ω Ω 3 rt Hi SD Ω H ft Ω H ft SD 3 SD 3 0 SD
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3 Φ P P rt H 3 TJ rt P TJ rt tr μ- Φ μ- 3 C- SD 3 Ω SD Φ SD rr 0 Ω rt SD tr t Ω ii CQ μ- Φ μ- Φ Φ μ- H 0 Ω SD 0 Φ M tr Φ £ tr 3 rt tf P rt rt 0 Φ - M 0 μ- 3 ii <! Ω Ω P φ Hi SD CQ Hi H PJ Φ ϋ φ rt 0
Φ 0 μ- 0 S-. 1 O ^ X rt TJ φ f- rt SD C- Φ SD ii H SD μ- H
3 rt p H P CQ li CQ rt μ- φ ii μ- ii μ- rt T rt ^^ CQ rt . — ^ μ- φ μ- H φ 0 CQ
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$-1 c p 0 p Φ μ- C- ft LQ Ω Φ μ- Φ μ- 0 0 0 O 0 SD H 1 SD TJ 1
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3 rt LQ 3 3 3 ii Φ H O LQ 3 μ- μ- rt ti 3 LQ SD 03 0 <J SD ft SD
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P Φ S P rt SD φ rt SD 0 μ- ii Φ 0 φ < Φ μ- μ- P H Φ CQ rt H rt 03 m Φ rt CQ μ- rt
LQ rt SD μ- rt ii 0 3 tr φ rt Hi 0 LQ tr . Φ 0 SD SD TJ tr 3 Φ 03 Φ
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3 Φ o rt 3 SD Φ rt SD O P 3 φ Ω Ω φ tr φ μ- rt SD 0 SD H Φ Hi Ω K φ Ω Hi Φ CQ Ω 3 μ- ii LQ rt 0 3 SD Φ Ω Hi ft Φ Ω rt CQ H rt P , . μ- rt 0 0 0
H t CQ rt SD rt TJ o φ 3 O O SD SD 0 f- Φ LQ O SD H P tr 03 ii 3 c
CQ X μ- tr μ- μ- P μ- Hi φ rt 0 P H tr μ- ft SD Φ TJ — ^ rt φ Ω Φ Q' LQ
SD Φ 3 SD Φ ft 0 SD SD 0 rt rt Ω μ- ^ Hi < P SD P rt Φ ^ Φ μ- μ- tr
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Φ 0 li 0 Φ • SD rt SD μ- tr 3 D 3 * ; 0 3 SD CQ 3 μ- TJ ft Ω
Φ ii Φ C 3 SD 3 ^ μ- rt Φ H -> rt Φ Ω φ rt rt LQ SD tr rt SD Ω 1
CQ CQ rt φ TJ H 0 P ω Φ 3 < tr tr li Φ μ- μ- tr d Φ tr μ- Ω μ- £ O μ- μ- rt μ- Ω Φ Ω φ μ- 3 TJ •<: μ- TJ Φ SD Ω 0 Φ φ •<: SD ft 3 0 SD Ω μ- 03
0! 0 CQ - -> C- SD Φ H ft rt TJ 03 3 0 3 ft f- 3 TJ rt φ rt μ- rt <! rt SD rt Φ rt Hi μ- rt Hi Ω 0 Φ H SD μ- tr μ- μ- K μ- Φ ft H μ- SD 0 tr tr •
Φ SD s; Q SD Φ 0 01 tr CQ SD rt 3 0 LΠ *< Ω 0 SD Ω μ- P CQ Ω Φ H ft Hi tr φ H H H CQ *< " rt φ TJ s. o 3 SD P ii 0 3 -3 03 O Ω Φ φ < m
C 3 Φ ft 3 3 Φ 1 Φ H CQ φ 3 rt SD 0 tr SD 1 rt SD P μ- SD tr μ- 3 0 ii *< 0 Φ - TJ 0 • 3 μ- £ H 0 μ- TJ Φ tr CQ φ 3 Φ rt rt CQ rt li Φ \Ω
3 Ω Φ rt ft μ- o o P ft 3, Hi 3 H ft Φ Φ i TJ X ft μ- O μ- rt Φ 0 μ- Φ S3 3 rt tr 3 TJ μ- ft Φ μ- Φ 0 μ- Ω 0 03
Hi μ- Ω CQ 3 Ω tr tr ^<j CQ φ Φ Φ SD μ- rt ii CQ CQ Φ μ- Φ 03 rt 3 3 O SD C Ω μ- 0 SD CQ TJ f- Φ Φ μ- 2 TJ Ω ft rt rt α tr μ- φ Ω ft SD P *.. rt φ TJ 3 03 μ- Q 3 μ- TJ ii rt ii P Φ Φ £ TJ 0 ϋ Ω Φ P μ- 03 CQ Ω TJ ii TJ P
P- SD Φ ft φ μ- φ 2 Φ LQ H Ω CQ H μ- 0 rt rt 3 ft SD rt 0 μ- SD SD Hi rt ii Ω 3 •» Φ tr μ- μ- φ Ω μ- rt 03 H tr μ- SD rt SD SD to £. μ- 3 rt H 0 μ-
Φ Ω rt μ- rt Φ > 3 01 Hi - μ- P tr TJ μ- P μ- μ- ii μ- 0 y rt μ- LQ 3
3 {-• SD Hi Φ SD P 0 μ- μ- P Ω Φ SD 0 P LQ LQ rt SD rt 3 3 μ- tr Φ Ω t 0 0 H H- ft P 3 P 3 Ω 0 rt μ- P H ft 0 φ H ft μ- tr Φ P μ-1 rt SD
• 3 CQ LQ Ω ft CQ 0 0 LQ li μ- TJ ii ft PJ μ- SD ii SD rt SD μ- P O H LQ φ μ- rt
0 Φ φ SD TJ SD 3 3 tr μ< Φ rt P 3 1 rt Ω 0 0 K 03 SD 0 0
3 μ-1 rt 0 li μ- I Φ Hi μ- SD H φ Ω μ- Φ LQ ft 3 μ- SD Φ μ- SD rt 03 3 ii 3 H
Φ »< -> Φ ft Ω ii C 3 SD 0 CQ ft SD 0 3 li 03 tr lb SD rt μ- μ- SD li μ- ^ ^ 3 0 03 3 ft 3 rt 0 LQ Q J ft SD - 0 Ω φ 0 K ii rt Φ Ω
CQ H CQ 3 0 Hi <! Ω μ- 0 μ- Hi P μ- μ- μ- rt Φ rt 0 ii SD Φ SD tr rt SD φ tr φ <! £- SD rt P O μ- P P LQ TJ < 3 O 3 P rt ; 3 P
SD H" rr μ- ii μ- P μ- μ- LQ Φ P SD rr rt P H" ii O rt tr T TJ 3 rt f- Φ tr O *-
3 SD t 3 3 Ω Φ 3 0 Ω 3 μ- Ω 0 SD Φ Φ Φ 0 Φ Φ 0 μ- CQ LQ 0 0 3 ft rt Φ ft LQ rt 3 3 CQ C TJ 0 M SD Ω ^ 03 1 rt Hi Φ μ- rt Hi 0 tr
Φ H μ- rt rt SD μ- 0 SD 3 0 0 • CQ 0 3 μ- φ μ-" μ- φ μ- Hi φ tr 3 Φ
Ω ft CQ SD tr CQ 0 tr rt Φ TJ CQ H rt LQ φ P SD rt Ω Ω CQ rt φ Ω ii SD φ SD 3 0 Φ φ TJ CQ φ μ] 3 H rt ^ tr tr μ- SD • rt SD K SD
0 rt 3 μ- SD 4 3 CQ Ω 3 μ- tr tr 0 μ- 03 SD μ- Φ < rt tr ii 03 c
03 0 φ SD H ft TJ 0 μ-1 φ μ- rt TJ 0 φ P rt P φ Φ μ- μ- Φ LQ - 03
H Φ Ω H P 0 o ii Ω φ ii P Φ μ- SD ft φ 03 0 P Φ φ 1 1 0 φ 0 Hi 1 03 SD CQ 0 3 0 Ω 1 ft 3 rt
1 1 1 1 1 ft P 1
In the present invention, the term scintillator can be defined as a phosphorescent or fluorescent molecule that generates a flash of light when excited by an ionising particle such as a β-particle or a photon. In this case the reactive group of the scintillator contains a C=C bond, so that the scintillator can be co-polymerised into the matrix of an imprinted polymer during the imprinting reaction. Preferably the scintillator is a derivative of 2, 5-diphenyloxazole. By scintillator is also meant a scintillant molecule that has a reactive group, whereby the reactive group is used for chemical immobilisation of the scintillant molecule on the polymer mat- ris. In this later case the reactive group is e.g. -NH2, -OH, -COOH, or -CHO, which can be used for chemical immo- bilisation of the scintillator on a previously synthesi- sed molecularly imprinted polymer. Said chemical immobilisation reactions can be carried out prior to, or after removal of the template molecules from the polymers. Figure 3 shows examples of scintillator. In the present invention the term polymer covers both organic and inorganic polymers. Examples of organic polymers are those based on polyacrylate, polystyrene, polyanaline and polyurethane . Said polymers may be cross- linked to various extents. The polymers are obtained by conventional polymerisation reactions, for example free radical polymerisation or condensation polymerisation. An example of an inorganic polymer is a silica gel obtained by hydrolysis of precursor monomers e.g. alkoxysilanes that are commonly used for preparation of silica par- tides.
For optimal signal generation, a secondary scintillator can be incorporated into the imprinted polymer, or admixed with the imprinted scintillation polymer used in an assay. The secondary scintillator is a phosphorescent or fluorescent molecule that is excited by the primary scintillator, and emits a flash of light at a longer wavelength. Typical secondary scintillators are those commonly used in liquid scintillation counting, or derivatives of them containing a reactive group. Chemical incorporation of said secondary scintillator can be carried out in the same step as that in which the primary scintillator is incorporated, or achieved in separate post-imprinting steps.
The present invention also provides a further method for introducing an aromatic substance into molecularly imprinted scintillation polymers. Said base component assists to transfer the radioisotope decay into a short wavelength radiation, which is able to excite the primary scintillator for generation of a fluorescence signal . Said aromatic substance may be chemically linked to the imprinted polymer, typically by co-polymerisation of aromatic monomers or cross-linking monomers during the imprinting reaction, or be physically absorbed into the polymer matris. The aromatic substance is typically an aromatic solvent, when it is physically absorbed into the polymer matris . This is especially useful when the measu- rements are carried out in a non-aromatic solvent. Said aromatic solvent is confined within the polymer matris when the latter is transferred into the assay solvent, e.g. an aqueous or a highly polar organic solvent. When the measurement is carried out in an aromatic solvent, for example in toluene, the solvent itself may serve as the base component .
Thus, the present invention relates to molecularly imprinted scintillation polymers comprising:
(a) Specific binding sites generated by a molecular imprinting reaction. The molecular interactions driving the assembly of functional monomer - template complex during the imprinting, and recognition of the target analyte by the imprinted polymer may be covalent, non- covalent, or a combination of both. (b) At least one scintillator covalently fixed in close proximity (within 50 μm) to the specific binding sites of the imprinted polymer. Chemical fixation of the scintillator is obtained in two ways: (1) by introducing a scintillator into an imprinting mixture, so that the scintillator is co-polymerised with the other monomers during the imprinting reaction; (2) by chemical immobili- sation of a reactive scintillator to a previously synthe- sised molecularly imprinted polymer.
During the co-polymerisation of a scintillator with other imprinting components, the scintillator does not interfere with the functional monomer-template interac- tion, and is randomly incorporated into the growing polymer chain. The imprinting reaction may be a free radical reaction, an ionic reaction, an oxidation-reduction, an electrochemical reaction, or other polymerisation reactions including hydrolysis polymerisation of inorganic precursor monomers. The imprinting polymerisation may be initiated by heat, UV radiation, γ-radiation, electrochemical potential, acid hydrolysis, or by other chemical means. After the polymerisation, the template is removed and the obtained polymer is worked up following standard procedures.
To improve signal detection, said scintillator is optionally a combination of a primary and a secondary scintillator. Alternatively, the secondary scintillator is incorporated into said polymer, which has a chemically bound primary scintillator, by using the physical absorption method described above. Optionally an aromatic monomer, more specifically styrene or divinylbenzene, is used in the imprinting reaction to provide a chemically linked base component for better scintillation response in non- aromatic solvents. The aromatic monomer may be the same as the functional monomer or the cross-linker. Alternatively, the optional base component may be co-impregnated with the secondary scintillator into the imprinted polymer by using the physical absorption method. For the chemical immobilisation of a scintillator on an imprinted polymer, an imprinted polymer is initially synthesised. The imprinted polymer may carry additional reactive groups that can be used for coupling of a scintillator. Alternatively a small fraction of binding groups in the imprinted polymer is used for coupling of the scintillator. The coupling reaction may be carried out prior to, or after removal of the template molecule from the imprinted polymer. Optionally, a secondary scintillator and an aromatic substance are also immobilised in the same way.
The molecularly imprinted scintillation polymers of the present invention are synthesised in various configurations including monoliths, irregular particles, micro- spheres, membranes, films, and monolayers. The imprinted polymers can also be synthesised in situ in microtitre plate wells . The imprinting reactions are typically similar to those of established ones, except that either the imprinted polymer is further treated by chemical or physical means to incorporate scintillators, or the scintillator is incorporated into the polymer chains during the imprinting reaction. The molecularly imprinted scintillation polymers of the present invention can be synthesised in the form of microparticles or microspheres . Preferably, the micro- particles and microspheres then have an average diameter of 0.01-10 μm. The imprinted polymers are synthesised using a precipitation polymerisation method described in PCT application WO 00/041723.
The imprinted scintillation polymers of the present invention can also be synthesised in situ in microtitre plate wells or on microchips. The polymers may be in the form of continuous films or separate spots. More specifically the thickness of the polymer layer is controlled during preparation to be less than 50 μm.
In one embodiment of the invention the obtained polymer is used for detection of a target analyte present in a radioisotope-labelled sample, or in a displacement assay of a target analyte using a radioisotope-labelled probe. In many cases the radioactive probe may be the LO L to to μ> μ1
LΠ o LΠ o LΠ o LΠ
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X 0 CQ 0 ii 03 ^ SD tr CQ 0 tr 3 μ- SD Φ C ^ μ- μ- tr 0 SD 0 μ- rt Φ tr Ω tr SD SD
TJ f- Φ CQ μ- φ TJ Φ tr 3 rt ft tr rt 03 0 μ- H" H SD SD S= H Φ μ- Φ Hi tr
Φ 3 ft Φ ø rt 3 rt Φ μ- ft 0 φ Φ TJ P Ω ^ LQ • ; rt 3 0 3 LQ φ
H ft 3 CQ Φ SD μ- tr 1 SD tr μ- ii CQ CQ ^ tr 3 φ 3 Φ ft H rt rt rt Φ μ- 03 SD Φ N Φ H 3 tr 3 Φ Hi μ- P μ- Ω H SD 0 Φ Φ H SD Φ ω SD μ- Φ rt
3 03 ii ^ ft P CQ TJ SD Hi rt LQ SD μ- 3 0 Ω o Hi rt ii SD H 3 μ- li CQ μ- ii 3 Φ
Φ •> g φ ϋ TJ tr μ- 0 3 ii SD Φ tr CQ 3 3 ft Ω 3 LQ μ1 TJ SD ft
P SD SD Hi ^ 03 μ- n Φ 3 H CQ rt SD P rr 3 rt Φ 0 μ- SD SD Φ ft Φ SD 3 rt 03 0 φ 0 ø P o μ- μ- μ- φ tr SD P P 3 LQ 03 3 μ- rt P SD SD !D
SD Ω TJ μ- H rt Ω CQ rt tr rt rt μ- Hi H- tr p Φ 03 H P 0 μ- Ω Ω P rt rt P
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TJ 3 μ- H 3 P SD LQ rt tr Φ SD rt rt Ω 0 SD TJ ft 0 Ω Φ rt Φ 0 SD 0 Hi Φ ^
SD 0 Hi Φ O 03 TJ o SD SD Hi ii μ- tr SD SD Hi ft Φ Hi H H m μ- 3 Hi 0 •^ rt ii 03 μ- SD CQ rt SD 0 LQ CQ C 0 μ- 0 Φ ϋ μ- Φ TJ o ; μ- * ^ H Φ rt Φ Ω Ω μ- tr SD ii μ* CQ 0 φ 03 ii Φ 3 ii o ii rt 0 03 0 03 rt Φ CQ 03 rt rt 3 0
3 rt rt Φ H k__ φ 3 ft Φ CQ tr μ- tr SD 03 SD μ- rt SD 03 tr Φ Φ CQ H{ 0
03 rt μ- ø H o SD 3 SD μ- ft SD - TJ φ SD Φ Φ Ω rt μ- 3 rt Φ rt μ- φ H ^ HJ
0 0 0 π <: φ K 03 03 P 0 3 i ft rt o rt TJ H 0 3 μ- 0 SD ~. 3 SD
H P 3 Φ α 03 ii Ω rt Ω rt $. ~t LQ ii μ- Φ μ-1 Φ ft CQ 0 t- ii li rt 3 μ-
SD CQ 0 3 CQ tr - ϋ 0 SD tr ^ 0 Φ 0 SD <! tr ft Φ μ- • 3 SD Φ 03 tr rt
Hi 3 - 3 tr Ω 0 Φ LQ Φ 3 ft ft φ φ CQ TJ 3 ft 0 φ SD 03
0 μ- 0 SD Hi Hi SD Φ H 0 ii Φ μ- π rt μ- μ- φ Ω s; μ- LQ CQ 3 ii μ- => rt ft 3 K o 3 3 Φ 3 Φ ii 3 0 0 SD SD 3 SD 3 0 tr 0 Φ rt μ- SD SD
3 tr 0 μ- φ TJ μ- H rt μ- TJ μ- CQ φ £ 3 SD 3 P H rt rt P μ- SD 3 tr 03 3
3 rt Φ 4 3 ii tr LQ SD 3 03 rt 3 TJ μ- Ω SD SD 3 tr Φ 3 Ω Ω Φ SD μ- 0 SD
0 Φ ii μ- Φ (D 0 tr TJ LQ LQ SD rt tr SD rt rt rt μ- Φ 0 rt tr rt H rt P LQ
3 li φ 3 P rt 0 0 Ω - Φ i Φ tr μ- <; : Ω Hi Hi Φ μ- SD LQ μ- O c o ^
3 LQ rt O rt rt P Φ φ φ ft < rt CQ H μ- 0 ii Ω <! rt tr φ LQ ^ rt Φ rt 3 tr Φ μ- X SD TJ Hi SD φ Φ Φ 0 3 H rt SD φ Φ μ- rt
0 ft tr O rt 0 ii 3 03 TJ tr 3 0 C t) ϋ - ft rt TJ 3 tr P ft 3 tr 0 φ
H μ- φ Hi tr O rt rt φ μ- CQ rt Φ ϋ TJ μ- H SD Φ 0 SD ft Φ Hi • μ- SD Φ rt ø μ- ii 0 SD ^ Φ tr < SD ii 0 SD rt μ- rt H tr P - μ- μ-
P rt μ- ii μ- LQ SD μ- P 3 ft Φ μ- Α o li li K 3 μ- Φ SD P 3 3 rt n_
LQ φ 3 S3J Cfl TJ tr 0 3 O rt φ Ω 03 tr φ φ rt μ- 3 SD LQ 0 tr o
TJ ft Ω TJ ii Φ LQ SD H Hi μ- φ Φ iQ Φ 03 <! 3 Λ ^ rt Φ Hi rt 0 ii μ- μ- μ- 0 3 μ- LQ CQ 0 3 0 C SD TJ ft φ SD c rt tr 03 Φ tr ii μ- 0 P φ rt φ μ- rt Ω O ii <! , Hi tr SD ft C 3 SD Φ Φ μ- Ω SD rt
Φ 3 S rt ii SD 3 03 SD 3 tr Φ SD ^ 3 ft SD CQ 03 rt > 3 rt 3 tr
SD rt Ω μ- CQ ft tr • μ- SD CQ 3 TJ rt Φ rt Ω φ μ- CQ rt 0 μ- Φ SD Φ
CQ Φ rt H-1 rt Ω 03 μ- CQ <1 Ω rt O p rt μ- ft Φ μ- ft 0 Φ μ- i 03 SD 03
TJ TJ ft μ- ø H tr H ii rt μ- li μ- O 0 tr Hi 3 3 ft Hi TJ Hi ; φ
Φ ii < SD tr φ rt μ- tr φ ~ P Φ 0 O rt Φ μ- rt Hi μ- TJ ϋ 03 rt
Ω 0 03 φ rt Φ φ tr rt Φ Ω LQ Φ P 0 Ω α Φ μ- 0 rt :> φ ϋ μ- TJ ^ φ TJ μ- ft Ω μ- CQ P SD 0 φ 0 P Ω 3 rt SD μ- H tr μ- ft 0 3 φ
Hi S-- μ- 3 0 μ- rt ii H TJ li 03 μ- rt' SD e SD rt H μ-1 Φ rt tr rt Ω μ- μ- K μ- Ω P Φ P 0 P SD rt TJ P tr 3 ti μ- φ CQ SD SD tr s; φ Φ μ- 3 03 TJ
Ω rt rt rt ii LQ tr μ- ft 0 SD φ LQ φ Φ rt LQ 0 Ω rt 3 0 μ- ft Hi TJ 0
*« μ- SD TJ μ- CQ μ- H 3 Ω Hj μ- Φ 3 rt μ- SD tr SD rt μ- μ- Hi c 03
Ω tr o μ- μ- P 0 CQ μ- Ω μ- Cu_ TJ rt rt 0 rt TJ tr 3 TJ Ω μ- CQ φ
0 μ- μj 0 \-> 3 03 ft C- μ- Φ Hi 0 M H 0 ft 0 3 ; SD TJ ft 0 P φ CQ
3 03 SD
1 rt μ- ^ 3-3 SD 03 03 Hi 3 μ- TJ μ- SD Hi Φ CQ μ- H P rt rt ft
LQ 0 rt Φ 0 0 N Ω H Φ P rt μ- 3 0 Ω ^ O Φ rt μ- rt φ μ- tr O ft 1 H 1 μ- μ- H SD Φ 3 Φ TJ Φ 1 ft SD tr o Φ H 3 1 1 P 1 Ω LQ ft 1 CQ 03 Φ
3 CQ LQ φ 1 1
Synthesis of scintillation monomers
Scintillation monomers are synthesised from 2,5- diphenyloxazole derivatives carrying a reactive group. The scintillation monomers are co-polymerised into the polymer matris during an imprinting reaction. Example 1
Synthesis of 4 -hydroxymethyl - 2, 5-diphenyloxazole acrylate (scintillator 6, see Figure 3)
4-hydroxymethyl-2 , 5-diphenyloxazole (scintillator 2, ' see Figure 3) is synthesised according to a literature method (Hamerton, et al . , Chem. Mater. 2000, 12, 568).
4-hydroxymethyl-2 , 5-diphenyloxazole (1.9 g, 7.57 mmol) and triethylamine (0.917 g, 9.084 mmol) are dissolved in dichloro ethane (30 ml) . The solution is cooled in an ice water bath while acryloyl chloride (0.821 g,
9.084 mmol) is slowly added during stirring. The solution is stirred at 0°C for 2 h, after which it is washed with 1 M HC1 (30 ml) . The organic layer is separated, dried over anhydrous Na2S04 and evaporated to dryness. The crude product is purified on a silica column using ethyl acetate to yield colourless crystals (0.784 g, 34%) . 2H NMR (CDC13) : δ (ppm) 8.10-8.20 (m, 2H, aromatic), 7.70-7.77 ( , 2H, aromatic), 7.36-7.56 (m, 6H, aromatic), 6.50 (dd, 1H, iTtrans = 17.3 Hz , ι7gβm = 1.4 Hz, trans-CH=CH2) , 6.21 (dd, 1H, J" trans = 17 . 3 Hz , Jcis = 10 . 4 Hz , -CH= CH2) , 5 . 88 (dd, 1H , Jcis = 10 .4 Hz , Jgem = 1 .4 Hz , ci s- CH=CH2 ) , 5 . 39 ( s , 2H, -CH20- ) .
Synthesis of molecularly imprinted microparticles carrying a co -polymerised scintillator Non-covalent interactions are utilised for preparing a molecularly imprinted scintillation polymer. A scintillator is incorporated by co-polymerisation together with the functional monomer and the cross-linking monomer. A precipitation polymerisation method is used to generate discrete polymer microparticles. Example 2 Synthesis of a molecularly imprinted scintillation polymer (MISP 1) specific for (S) -propranolol
(S) -propranolol (0.784 mmol), methacrylic acid (1.567 mmol), trimethylolproprane trimethacrylate (1.567 mmol), 4-hydroxymethyl-2 , 5-diphenyloxazole acrylate
(0.784 mmol) and α, α' -azoisobutyronitrile (0.152 mmol) are dissolved in anhydrous toluene (45 ml) . The solution is saturated with dry nitrogen gas, and sealed under a nitrogen atmosphere. The solution is transferred into a water bath pre-set at 60°C to initiate the free radical polymerisation. The reaction continues at 60°C for 16 h. Following the polymerisation, the polymer microparticles are dissected by brief ultrasonic treatment and collected by centrifugation. (S) -propranolol is removed by repeated solvent extraction of the polymer in methanol containing 10% acetic acid. The polymer microparticles are finally washed with acetone and dried in vacuum. A non-imprinted scintillation polymer (NISP 1) is synthesised under identical condition except omission of the template, (S) - propranolol.
The obtained polymer microparticles have an average diameter of 0.6-1 μm, which is determined by scanning electron microscopy. Surface areas of the microparticles are approximately 7 m2g_1, which is determined by nitrogen absorption measurement. Elemental analysis confirms that the imprinted polymer (MISP 1) and non-imprinted polymer (NISP 1) contain approximately equal amounts of scintillator (Table 1) .
TABLE 1 Elemental analysis of scintillation polymers
Polymer C ( %) H ( % ) N ( %)
MISP 1 63 . 2 7 . 7 0 . 79
NISP 1 63 . 1 7 . 5 0 . 80
Example 3 Synthesis of a molecularly imprinted scintillation polymer (MISP 2) specific for (S) -propranolol
(S) -propranolol (0.602 mmol), methacrylic acid (0.784 mmol), trimethylolproprane trimethacrylate (0.784 mmol), -hydroxymethyl-2 , 5-diphenyloxazole acrylate
(0.157 mmol) and α, α'-azoisobutyronitrile (0.073 mmol) are dissolved in anhydrous toluene (40 ml) . The solution is saturated with dry nitrogen gas, and sealed under a nitrogen atmosphere. The solution is transferred into a water bath pre-set at 60°C to initiate the free radical polymerisation. The reaction continues at 60°C for 16 h. Following the polymerisation, the polymer microparticles are dissected by brief ultrasonic treatment, and collected by centrifugation. (S) -propranolol is removed by repeated solvent extraction of the polymer in methanol containing 10% acetic acid. The polymer microparticles are finally washed with acetone and dried in vacuum. A non-imprinted scintillation polymer (NISP 2) is synthesised under identical condition except omission of the template, (S) -propranolol .
The obtained polymer microparticles have an average diameter of 0.6-1 μm, which is determined by scanning electron microscopy. The surface areas of the micropar- ticels are approximately 7 m2g_1, which is determined by nitrogen absorption measurement. Elemental analysis confirms that the imprinted polymer (MISP 2) and non-imprinted polymer (NISP 2) contain approximately equal amount of scintillator (Table 2) .
ΓAB LE 2 emental analysis of scinti .Hation polyme
Polymer C (%) H (%) N (%)
MISP 2 62.4 7.6 1.3 NISP 2 62.8 7.6 1.1 Synthesis of molecularly imprinted microspheres compri sing a co-polymerised scintillation monomer and an aromatic substance
Non-covalent interactions are utilised for preparing a molecularly imprinted scintillation polymer. A scintillation monomer and an aromatic substance are incorporated by co-polymerisation with the functional monomer and/or the cross-linking monomer. A precipitation polymerisation method is used to generate discrete polymer microspheres . Example 4
Synthesis of a molecularly imprinted scintillationpolymer (MISP 3) specific for (S) -propranolol, having divinyl - benzene as the aromatic substance
(S) -propranolol (0.529 mmol), methacrylic acid (1.05 mmol), divinylbenzene (4.20 mmol), 4-hydroxymethyl-2 , 5- diphenyloxazole acrylate (0.262 mmol) and α,α'-azoiso- butyronitrile (0.097 mmol) are dissolved in anhydrous acetonitrile (40 ml) . The solution is saturated with dry nitrogen gas, and sealed under a nitrogen atmosphere. The solution is transferred into a water bath pre-set at 60°C to initiate the free radical polymerisation. The reaction continues at 60°C for 16 h. After the polymerisation, the polymer microspheres are collected by centrifugation. (S) -propranolol is removed by repeated solvent extraction of the polymer in methanol containing 10% acetic acid.
The polymer microspheres are finally washed with acetone and dried in vacuum. A non-imprinted polymer (NISP 3) is synthesised under identical condition except omission of the template, (S) -propranolol . The obtained polymers are in the form of micro- spheres having an average diameter of 0.6-2.8 μm, which is determined by scanning electron microscopy. Example 5 Synthesis of a molecularly imprinted scintillation polymer (MISP 4) specific for (S) -propranolol, having styrene as the aromatic substance (S) -propranolol (0.602 mmol), methacrylic acid (0.392 mmol), styrene (0.392 mmol)', trimethylolproprane trimethacrylate (0.784 mmol), 4-hydroxymethyl-2 , 5-diphenyloxazole acrylate (0.157 mmol) and α, α'-azoisobutyro- nitrile (0.073 mmol) are dissolved in anhydrous acetoni- trile (40 ml) . The solution is saturated with dry nitrogen gas, and sealed under a nitrogen atmosphere. The solution is transferred into a water bath pre-set at 60°C to initiate the free radical polymerisation. The reaction continues at 60°C for 16 hours. After the polymerisation, the polymer microspheres are collected by centrifugation. (S) -propranolol is removed by repeated solvent extraction of the polymer in methanol containing 10% acetic acid. The polymer microspheres are finally washed with acetone and dried in vacuum. A non-imprinted scintillation polymer (NISP 4) is synthesised under identical condition except omission of the template, (S) -propranolol . Immobilisation of the scintillator on molecularly imprinted microspheres Molecularly imprinted scintillation polymers are prepared by immobilisation of a reactive scintillator on previously synthesised molecularly imprinted polymers. Example 6 Synthesis of molecularly imprinted microspheres carrying a reactive moiety for coupling of a scintillator (MIP 1) To a borosilicate glass tube are added 17β-estradiol (0.734 mmol), methacrylic acid (1.884 mmol), trimethylolproprane trimethacrylate (1.884 mmol), 4-nitrophenylacry- late (0.942 mmol) and 2-hydroxy-2-methyl-l-phenyl propan- 1-one (1.0 mmol) dissolved in anhydrous acetonitrile (40 ml) . The solution is saturated with dry nitrogen gas, and sealed under a nitrogen atmosphere. At 20°C, the reaction mixture is exposed to UV irradiation at 350 n for 4 h. Following the polymerisation, the polymer microspheres are collected by centrifugation. The polymer microspheres are washed with acetonitrile and finally dried in vacuum. A non-imprinted polymer (NIP 1) is synthesised under identical condition except omission of the template, 17β- estradiol . Example 7
Preparation of molecularly imprinted scintillation micro- spheres (MISP 5) and non-imprinted scintillation micro- spheres (NISP 5) by immobilization of a scintillator on MIP 1 and NIP 1 via the reactive moieties
4-Aminomethyl-2, 5-diphenyloxazole (scintillator 3, see Figure 3) is coupled to the molecularly imprinted microspheres (MIP 1) using the following reaction:
MISP 5
Figure imgf000021_0001
The molecularly imprinted microspheres (MIP 1, synthesised in Example 6) (200 mg) are suspended in 12 ml of 1 M solution of a reactive scintillator, 4-amino- ethyl-2 , 5-diphenyloxazole dissolved in acetonitrile. The suspension is gently stirred at 20°C for 24 h. The polymer microspheres are separated by centrifugation and repeatedly washed with methanol containing 10% acetic acid (v/v) to remove the template molecule. The polymer microspheres are subsequently washed with acetone and dried in vacuum. No yellow colour is observed when the treated microspheres are added to 1 M NaOH, which confirms complete immobilisation of the scintillator. The non-imprinted scintillation microspheres (NISP 5) are prepared similarly by treatment of the non-imprinted microspheres (NIP 1) .
Synthesis of molecularly imprinted scintillation polymers using sol -gel chemistry ϋJ ω t t
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per minute) are proportional to the amount of bound labelled template. Example 9
Evaluation of binding performance of a molecularly imprinted scintillation polymer (MISP 2) by proximity scintillation counting
In a serie of 500 μl polypropylene microcentrifuge tubes, increasing amounts of polymer microparticles (MISP
2 and NISP 2) synthesised in example 3 are suspended in toluene containing 0.5% (v/v) acetic acid. Tritium- labelled (S) -propranolol (2 pmol) is added and the volume topped with the same solvent to 500 μl . The microcentrifuge tubes are incubated at 20°C for 2 h. After incubation, the microcentrifuge tubes are transferred into 6 ml insert counting vials and counted with a model 2119 RACKBETA β-radiation counter (LKB Wallac, Sollentuna, Sweden) . Both the imprinted polymer and the non-imprinted polymer are tested. The titration curves for the two polymers are shown in Figure 4. As can be seen, the imprin- ted polymer binds much more of the tritium-labelled analyte than the control, whereby a much higher scintillation signal (CPM) is obtained. Example 10 Evaluation of binding performance of a molecularly imprinted scintillationpolymer (MISP 3) by proximity scintillation counting
In a serie of 500 μl polypropylene microcentrifuge tubes, increasing amounts of polymer microparticles (MISP
3 and NISP 3) synthesised in example 4 are suspended in 25 mM citrate buffer (pH 6.0) containing 50% (v/v) acetonitrile. Tritium-labelled (S) -propranolol (2 pmol) is added and the volume topped with the same solvent to
500 μl . The microcentrifuge tubes are incubated at 20°C for 2 h. After incubation, the microcentrifuge tubes are transferred into 6 ml insert counting vials and counted with a model 2119 RACKBETA β-radiation counter (LKB Wallac, Sollentuna, Sweden) . Both the imprinted polymer and the non-imprinted polymer are tested. The titration curves for the two polymers are shown in Figure 5. As can be seen, the imprinted polymer binds much more of the tritium-labeled analyte than the control, whereby a much higher scintillation signal (CPM) is obtained. Example 11
Displacement assay of (S) -propranolol in an aromatic solvent using a molecularly imprinted scintillation polymer (MISP 2) To a serie of 500 μl polypropylene microcentrifuge tubes are added 0.2 mg molecularly imprinted scintillation polymer microparticles (MISP 2) synthesised in example 3. (S) -Propranolol and (R) -propranolol are dissolved in toluene containing 0.5% (v/v) acetic acid, diluted with the same solvent to various concentration, and added into the microcentrifuge tubes . To each of these tubes are finally added the tritium-labelled (S) - propranolol (2 pmol) , and the volume adjusted to 500 μl with toluene containing 0.5% (v/v) acetic acid. The samples are incubated at 20°C for .2 h, after which they are transferred into 6 ml insert counting vials and counted with a model 2119 RACKBETA β-radiation counter (LKB Wallac, Sollentuna, Sweden) to estimate the bound fraction of the labelled analyte. Figure 6 shows cali- bration curves for the template molecule, (S) -propranolol, and for its enantiomer, (R). -propranolol . As seen from the figure, the chemical sensing polymer (MISP 2) displays favourable chiral selectivity when used in an aromatic solvent, as the optical antipode of the template yields much less sensor signal (ΔCPM) . Example 12
Displacement assay of (S) -propranolol in an aqueous solvent using a molecularly imprinted scintillation polymer (MISP 3) To a serie of 500 μl polypropylene microcentrifuge tubes are added 0.2 mg molecularly imprinted scintillation microspheres (MISP 3) synthesised in example 4. (S) - propranolol and (R) -propranolol are dissolved in 25 mM citrate buffer (pH 6.0) containing 50% (v/v) acetonitrile, diluted with the same solvent to various concentration, and added into the microcentrifuge tubes. To each of these tubes are finally added the tritium-labelled (S) -propranolol (2 pmol) , and the volume adjusted to 500 μl with 25 mM citrate buffer (pH 6.0) containing 50% (v/v) acetonitrile. The samples are incubated at 20°C for 2 h, after which they are transferred into 6 ml insert counting vials and counted with a model 2119 RACKBETA β- radiation counter (LKB Wallac, Sollentuna, Sweden) to estimate the bound fraction of the labelled analyte. Figure 7 shows calibration curves for the template molecule, (S) -propranolol, and for its enantiomer, (R) -pro- pranolol . As seen from the figure, the chemical sensing polymer (MISP 3) displays very high chiral selectivity when used in an aqueous solvent, since the cross-reactivity from (R) -propranolol is less than 5%.

Claims

1. A molecularly imprinted polymer having specific binding sites, which polymer comprises at least one component for energy transfer located in proximity to said binding sites.
2. A molecularly imprinted polymer according to claim 1, wherein said component for proximity energy transfer is chemically incorporated into the polymer. 3. A molecularly imprinted polymer according to claim 1, wherein said component for proximity energy transfer is bound to the surface of the polymer.
4. A molecularly imprinted polymer according to any one of claims 1-3, wherein said component is a scintil- lator.
5. A molecularly imprinted polymer according to claim 4, wherein said scintillator comprises a reactive group .
6. A molecularly imprinted polymer according to claim 5, wherein said reactive group comprises at least one C=C bond.
7. A molecularly imprinted polymer according to claim 5 or 6, wherein the scintillator is 2 , 5-diphenyloxazole or a derivative thereof. 8. A molecularly imprinted polymer according to claim 5, wherein said reactive group comprises at least one of the groups -COOH, -CHO, -OH and -NH2.
9. A molecularly imprinted polymer according to any one of claims 1-8, which polymer is an organic polymer comprising as a main component at least one polymer chosen from the group comprising polyacrylate, polystyrene, polyurethane, polyanaline and polyamide.
10. A molecularly imprinted polymer according to any one of claims 1-8, which polymer is an inorganic polymer obtained from alkoxides of silicon, aluminum or titanium. LO to to μ> o o
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chemical conjugation of the reactive group of the polymer and a reactive group of the component for proximity energy transfer; and removal, before or after said conjugation, of the template molecule.
19. A method according to claims 16-18, whereby the component used for proximity energy transfer is a scintillator.
20. A method according to claim 19, whereby the scintillator comprises at least one C=C bond.
21. A method according to claims 19 or 20, whereby the scintillator is 2, 5-diphenyloxazole or a derivative thereof .
22. A method according to any of claims 19-21, whereby the reactive group of the scintillator is chosen from the group comprising -COOH, -CHO, -OH and -NH2.
23. A method according to any one of claims 18-22, whereby the reactive group of the monomer is chosen from the group comprising -COOH, -CHO, -OH and -NH2. 24. A method according to any one of claims 16-23, whereby the polymerisation is performed so that a polymer with a configuration chosen from the group comprising monolith, irregular particles, thin films, membranes, microspheres and beads is obtained. 25. A method according to any one of claims 16-23, whereby the polymerisation is performed in situ within the wells of a microtitre plate or on a microchip.
26. A method according to any one of claims 16-24, whereby two different scintillators are in use. 27. A method according to any one of claims 16-26, whereby an aromatic substance, which assists in exciting the component for proximity energy transfer, is incorporated into the polymer.
28. A method according to any one of claims 16-27, whereby the incorporation of the second scintillator and/or the aromatic substance is obtained by physical absorption or by chemical linkage.
29. Use of a molecularly imprinted polymer according to any one of claims 1-15 or prepared according to any one of claims 16-28 in a proximity scintillation assay.
30. Use of a molecularly imprinted polymer according to any one of claims 1-15 or prepared according to any one of claims 16-28 for screening of combinatorial libraries .
31. Use of a molecularly imprinted polymer according to any one of claims 1-15 or prepared according to any one of claims 16-28 for use in sensors.
32. Use of a molecularly imprinted polymer according to any one of claims 1-15 or prepared according to any one of claims 16-28 for in situ monitoring of radioactive metabolites or enzymatic reactions. 33. Use according to claim 29-32, whereby an imaging system is used for quantifying the fluorescence signal .
34. Use according to any one of claims 29-33, whereby the imaging system is a Charge Coupled Device (a CCD camera) . 35. Use according to claim 29-32, in which arrays of photomultiplier tubes are used for scintillation counting.
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WO2010092071A1 (en) * 2009-02-16 2010-08-19 Imego Aktiebolag Customized molecularly imprinted polymer (mip) units
EP2386061A2 (en) * 2009-01-12 2011-11-16 The Regents of the University of California Imprinted polymer nanoparticles
CN103396512A (en) * 2013-07-24 2013-11-20 河北科技大学 Hybrid template molecularly imprinted polymer as well as preparation method and application of hybrid template molecularly imprinted solid-phase extraction column
CN103558203A (en) * 2013-11-22 2014-02-05 中国农业科学院农业质量标准与检测技术研究所 Magnetic molecularly imprinted polymer-fluorescence analysis method
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