SENSOR FOR DETECTING HEPARIN AND OTHER ANALYTES FIELD OF THE INVENTION
This invention concerns chemical sensors and biosensors, and is particularly directed to sensors for detecting heparin alone, and for detecting heparin in combination with other analytes.
GENERAL DISCUSSION OF THE BACKGROUND A major goal in sensor technology is to develop sensors that are smaller, and yet have greater sensitivity. Also, increasingly stricter specificity and selectivity demands are being imposed, particularly for physiological monitoring, diagnostic monitoring, bioprocessing, agriculture, pharmaceuticals and therapeutic monitoring.
A "sensor" is a type of transducer; i.e., a device that responds to an external stimulus or input signal by producing a measurable response having a magnitude bearing a relationship to the magnitude of the external stimulus or input signal.
A "chemical sensor" is a sensor in which a chemical reaction or molecular change in or on the sensor is an important aspect of the production of a measurable response by the sensor.
A "biosensor" is a sensor that incorporates a biological or biomolecular component as a key functional element in the production of a measurable response by the sensor.
Biosensors have been the subjects of great attention. See, e.g.. Vadgama et al. , "Biosensors: Recent Trends," Analyst U7: 1657-1670 (1992). However, bridging the gap between knowledge of a particular reaction involving biomolecules and the exploitation of the reaction in a biosensor has often proved difficult. For example, in biosensors the biological component is usually in the form of a biolayer that is frequently metastable. Thus, many contemporary biosensors are subject to obfuscating environmental influences. Secondly, biolayers usually need to directly contact the analyte which is frequently present in a complex mixture comprising a large number of other compounds that can
interfere with the response of the biolayer to a target analyte or that can be interfacially active and/or possibly detrimental to the biolayer.
An important problem often encountered in making sensors, particularly biosensors, is how to immobilize molecules of the sensing compound (i.e., the "sensing molecules") at a particular location on an appropriate substrate surface. Such immobilization cannot substantially adversely affect the ability of the sensing molecules to respond to significant changes in the measured parameter when the sensing molecules are exposed or otherwise contacted with molecules of an analyte. Immobilizing sensor molecules on a sensor requires that the sensing molecules retain their reactive specificity toward the corresponding analyte when the sensing molecules are attached to the situs. Otherwise, the function and/or specificity of the sensor may be compromised.
One way to immobilize sensing molecules to a situs is to chemically bond them to the situs. However, particularly with biomolecules, immobilizing sensing molecules on a sensor substrate by conventional bonding techniques can cause the sensing molecules to undergo conformation changes or undergo any of several other changes that can reduce or destroy the capacity of the sensing molecules to respond to the analyte.
Another problem often encountered is that while many substrates have properties that render them desirable for use as substrates, it is often difficult or impossible by contemporary methods to bond sensing molecules to them. This is particularly true when considering that the chemistry used to bond sensing molecules to substrates cannot damage the substrate, the sensing molecules, or both. Attaching sensing molecules to a substrate can be thought of as a form of chemical modification of, or "functionalization" of, a substrate. Sensors useful for continuously monitoring heparin levels currently are needed. Heparin, a naturally-occurring carbohydrate that acts as an anticoagulant, is a polymer of O- and N-linked sulfated glucosamines and hexuronic acids that are linked by glycoside bonds. "Principles of Pharmacology: Basic Concepts and Clinical Application," edited by Paul Munson et al., (Chapman and Hall, 1995).
Commercial heparin preparations have mean molecular weights ranging from
about 15,000 to about 18,000. Although most of the activity appears to be associated with lower molecular weights, it is believed that at least 16 to 20 monosaccharides are required for full expression of heparin activity. Id.
Heparin has an immediate prolongation of plasma clotting time, and hence is the anticoagulant of choice for thromboembolic disease. Id. However, there are complications associated with the use of heparin, the most serious of which is unwanted bleeding. This requires constant monitoring of the patient, and continuous blood sampling, in order to ward off any serious complications arising from the administration of heparin to patients. SUMMARY OF THE INVENTION
The need for a heparin sensor, and a sensor that can monitor heparin in combination with other analytes, is met by the present invention. The invention involves methods for covalently functionalizing materials, including the surfaces thereof, to include sensing materials useful for sensing heparin and other analytes. The invention also concerns detecting analytes once they interact with sensing molecules. Examples, without limitation, of sensing materials for sensing heparin include protamine, heparinase, and other nitrogen containing materials.
A number of substrates can be functionalized to include such sensing molecules. Substrates that can be functionalized according to the method of the present invention include, but are not limited to: a wide variety of polymeric materials, such as polyoctyl-3-thiophene, polystyrene, polypropylene, polyethylene, polyphenol, polyimide, PMMA, and C^; various allotrophic forms of elemental carbon (e.g., graphite, "carbon electrodes," diamond and diamond films, and fullerenes such as Q and C70); siliceous materials; semiconductor materials, such as silicon, gallium arsenide, cadmium sulfate, and other semiconducting materials (doped or not doped); and metals, such as gold, aluminum, platinum, silver, copper iron, and alloys containing these metals, such as steel. Substrate surfaces are functionalized by exposing the surface to a nitrenogenic functionalizing reagent in the presence of a reaction-energy source
such as photons, electrons and/or heat. In the presence of the reaction-energy source, the functionalizing reagent forms a nitrene intermediate that covalently reacts with -CH, -NH, -OH, -C=C-, -C-C- and other groups on the substrate surface so as to cause "nitrene addition" or "nitrene insertion" of the functionalizing reagent to the substrate surface. In order to form nitrene intermediates, the functionalizing reagent must terminate with an azide group or analogous chemical group capable of forming a reactive nitrene when exposed to a reaction-energy source.
The substrate and/or substrate surface is functionalized via either a single- stage or a multi-stage process. In a multi-stage process, each stage typically involves different functionalizing reagents. In both single- and multi-stage processes, at least one stage involves a nitrenogenic functionalizing reagent.
A class of preferred functionalizing reagents for single- and multi-stage processes according to die present invention consists of N-hydroxysuccinimide active ester-functionalized perfluorophenyl azides (NHS-PFPAs). The NHS active ester groups become covalently attached to the substrate via generation during the reaction of highly reactive nitrene intermediates derived from the PFPA portion of the reagent molecules. (The reactive nitrene portion of the intermediates are preferably constrained structurally such that the nitrene portion cannot react intramolecularly with the NHS active ester portion.) Thus, the substrate, either the surface thereof or throughout the substrate cross-section, becomes "modified" (i.e., "functionalized"). Afterward, the active esters can participate in further reactions with a variety of nucleophilic reagents, such as reagents containing primary amines or hydroxyls (such as biomolecules) by way of amide or ester formation, respectively.
According to another aspect of the present invention, a nitrene-forming functionalizing reagent can be applied, such as in the form of a film, to the substrate surface. Alternatively, a mixture comprising molecules of a nitrene- forming functionalizing reagent and polymer molecules can be applied, such as in the form of a film, to the surface of a substrate. Then, the coating, film or coated surface is exposed to a reaction-energy source (such as photons or a beam
of particles such as an electron beam) in a spatially selective way to functionalize certain regions of the surface and not others, thereby creating a functionalized pattern on the surface. Such patterns can have dimensions measured in micrometers and smaller, due to the highly resolved manner in which the coated surface can be exposed to the reaction-energy source. Thus, the present invention has wide applicability in microelectronics and in die construction of novel micron-scale biosensors.
A particularly suitable PHPA is an N-hydroxysuccinimide active ester- functionalized perfluorophenyl azide (NHS-PFPAs). The NHS-PFPA provides an activated ester (i.e., an ester tiiat is more reactive to nucleophilic attack than an alkyl ester or a carboxylic acid) that can be reacted with a nucleophilic sensing molecule e to couple the nucleophile to the substrate. Virtually any nucleophile could be reacted in this manner; however, by way of example only and without limitation, the nucleophile may be selected from the group consisting of peptides, nucleotides, cells and antibodies.
A sensor that includes sensing molecules for detecting heparin, and heparin in combination with other analytes of interest, can be made by coupling a functionalized substrate having sensing molecules for heparin, such as, without limitation, protamine, and for the other selected analytes with a detection system for detecting when die sensing molecules interact with the analytes. A working embodiment of a sensor included protamine as sensing molecules for sensing heparin, and may also have included glucose oxidase for sensing glucose. One embodiment of die invention uses a substrate, such as a one having a metal surface, particularly a silver or gold surface, wherein the surface of the metal has been functionalized to include selected sensing molecules. This substrate was coupled to a surface plasmon resonance detector for detecting when d e protamine sensing molecules interacted with samples containing analytes.
One embodiment of a sensor according to the present invention comprises an analyte detector comprising sensing materials immobilized thereon for ionically or covalently binding heparin. The sensing materials typically, but not necessarily, are selected from d e group consisting of protamine, heparinase,
polylysine, poplybrene, quaternary ammonium salts, and mixtures thereof. Detector means, such as surface plasmon resonance means, are coupled to d e analyte detector for detecting heparin after it binds to the sensing materials. The sensor can be configured to monitor or detect analytes oti er than heparin. Moreover, die sensor can include means for reversing d e interaction of heparin with d e sensing molecules.
The sensors can be small and dierefore configured as a hand-held unit or as implantable devices. Alternatively, the sensor may further comprise at least one catheter fluidly coupled to die sensor and to a patient for flowing blood from die patient to die analyte detector. With such devices, an analyte pump can be fluidly coupled to d e patient for administering analyte to a patient when analyte levels detected by die sensor are lower than a predetermined direshold.
The present invention also provides a mediod for detecting heparin and od er analytes. One embodiment of die method comprises first providing a substrate capable of undergoing an insertion reaction with a nitrene. The substrate is ti en coated wifli an activated perfluorophenyl azide. The substrate and perfluorophenyl azide are d en exposed to a reaction energy source, thereby forming a functionalized substrate. The functionalized substrate is reacted widi heparin sensing molecules, thereby forming a heparin sensitive substrate. A detector is coupled to die heparin sensitive substrate to form a sensor, which is then exposed to samples containing heparin so that the sensing molecules interact with the heparin. The sensing molecule-heparin interactions are then detected using a detector, such as an SPR detector.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 A is an image obtained with an atomic-force microscope of a freshly cleaved graphite surface functionalized first widi NHS-PFPA, then with horseradish peroxidase, as described in Example 1.
FIG. IB is an atomic-force microscope image of an experimental control wherein a freshly cleaved graphite surface was treated wid horseradish peroxidase but not widi NHS-PFPA, as described in Example 1.
FIG. 2 A is a photomicrograph obtained using a fluorescence microscope of circular patterns produced on a film of poly(3-octylthiophene) and 7 wt-% of NHS-PFPA by exposing the film to electron-beam lidiography conditions and subsequently treating the film with amino-fluorescein, wherein the microscope was fitted widi a rhodamine filter set.
FIG. 2B is a photomicrograph obtained using a fluorescence microscope of circular patterns produced on a film of poly(3-octylthiophene) and 7 wt-% of NHS-PFPA by exposing the film to electron-beam lithography conditions and subsequently treating the film wim amino-fluorescein, wherein die microscope was fitted widi a fluorescein filter set.
FIG. 2C is a photomicrograph obtained using a fluorescence microscope of circular patterns produced on a film of poly(3-octylthiophene) by exposing the film to electron-beam lithography conditions and subsequently treating d e film with amino-fluorescein, wherein the microscope was fitted widi a rhodamine filter set.
FIG. 2D is a photomicrograph obtained using a fluorescence microscope of circular patterns produced on a film of poly(3-octylthiophene) by exposing the film to electron-beam lithography conditions and subsequently treating me film with amino-fluorescein, wherein me microscope was fitted widi a fluorescein filter set.
FIG. 3 is a schematic plan view of a flow-through cell useful for analyzing analytes.
FIG. 4 is a schematic crossectional side view of a sensor substrate and detection system. FIG. 5 is schematic illustrating one embodiment of an SPR detection system.
FIG. 6 is a graph illustrating a sample reflectance curve that was obtained using die detection system of FIG. 5.
FIG. 7 is a graph illustrating me time dependence of die SPR minima as the sensor is subjected to different substances.
FIG. 8 is a graph illustrating the SPR position dependence on d e heparin exposure time.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
I. INTRODUCTION This invention concerns methods and sensors for detecting analytes, particularly heparin-sensors alone or sensors that are capable of detecting plural analytes, such as heparin and glucose. The sensors can be irreversible, and hence disposable, or reversible widi respect to the binding or odier interaction between the sensor and d e analytes being detected. The basic approach is to immobilize heparin sensing material or materials, or heparin sensing material(s) in combination with sensing material(s) for other analytes, on a substrate. Typical substrates include, wi out limitation, glass, glass coated wid a metal or metals, chips made from semiconducting materials, polymeric materials, or coated polymeric materials. The substrate is then coupled to a detection system for detecting die analytes of interest.
A. Heparin Heparin is a charged, sulphated glycosaminoglycan found in liver, lung and odier tissues. Heparin has several pharmacological properties [Nader, H.B. & Dietrich, C.P. Heparin. Chapter 5, Edward Arnold, London (1989)]. The property of heparin which has attracted most attention and resulted in its widespread use is its ability to prolong blood clotting times, presumably by preventing the formation of fibrin. The anticoagulant activity of heparin is used in vascular surgery and in treatment of postoperative thrombosis and embolism. A heparin treatment must result in heparin levels in d e blood mat are sufficient to control thrombosis and yet avoid undue risk of bleeding. The antidirombotic effect and the risk of bleeding varies, however, not only widi the dose, but also wid die individual. This variation in response to heparin calls for an individualization of the heparin dose regimen and a careful clinical monitoring by laboratory test. [Abildgaard, U, Heparin. Chapter 23, Edward Arnold, London (1989)].
No consensus of opinion exists concerning which is the most useful test for monitoring heparin treatment. It was observed d at when heparin was injected and subsequently separated from die blood, die separated heparin had higher anticoagulant activity per mg tiian the same heparin before injection (Levym S.W. et al. , Thrombin Research (1978), 13:429-441 and Bjornsson, T.D. et al., European Journal of Clinical Pharmacology. (1982), 21:491). This indicates d at there are important differences between the measurement of absolute concentrations of heparin and die amount of heparin present as determined by an in vitro coagulation test based on a calibration curve. Therefore, it is preferable to have a method for determining ie total absolute amount of heparin in plasma (Jaques, L.B. et. at, Journal of Laboratory Clinical Medicine. (1990), 115, 422- 432).
B. Heparin Sensing Molecules Any material that is capable of interacting with heparin, either ionically or covalendy, and eidier reversibly and irreversibly, are potential candidates for use as heparin sensing materials. Examples, without limitation, of heparin sensing molecules include protamine, heparinase, and polycationic macromolecules known to bind heparin, for example, polylysine and poplybrene. Long-chain quaternary ammonium salts, such as tridodecylmediylammonium chloride, also bind heparin electrostatically.
These sensing molecules can be immobilized on a substrate to serve as die affinity ligands for heparin. The advantage of using protamine or the polycationic macromolecules is diat the electrostatic interaction between these reagents and heparin can be reversed, diereby allowing for the formation of reversible sensors. The electrostatic interaction can be reversed by soaking or flushing the substrate or sensor in concentrated saline solution to back-extract the heparin and regenerate the immobilized sensing reagents.
Protamine currently is a preferred example of a heparin sensing material that forms reversible electrostatic interactions with heparin. Protamine is a very basic protein with a molecular weight of about 4,000-4,500, typically containing 20 arginines out of 30 amino acids. Protamine interacts with heparin through a
1:1 pairing of anionic heparin sites with cationic protamine sites. The binding affinity is 7 X 107 M 1. Yun J.H. et al., Journal of Electroanalvsis. 5:719 (1993). Protamine is used clinically to reverse die anticoagulant activity of heparin. Casu, B. , Heparin and Related Polvsaccharides. Structure and Activities. The New York Academy of Sciences, New York, (1989).
Non-reversible sensors can be made by immobilizing molecules which interact with heparin irreversibly. One example is heparinase. Heparinase is an eliminase which cleaves certain α-glycosidic linkages in heparin. Heparinase can be immobilized on a substrate using an NHS-PFPA ester via the reaction of NHS esters widi die amino groups present in heparinase.
C. Detection Methods There are several transduction methods diat can be used to detect association of me analyte with d e sensor including, without limitation, optical methods, spectrophotometric methods, mediods involving measuring changes in resistivity or capacitance and surface plasmon resonance. A currently preferred med od for such detection is SPR, which is described in detail below. SPR is sensitive to the thickness and index of refraction of material at die interface between a thin metal film (such as gold or silver) and a bulk medium (air). By immobilizing protamine as the affinity ligand, the interaction of protamine and heparin can be detected using SPR because die interactions induce changes in bod index of refraction and die diickness of the film.
The following paragraphs provide definitions of certain terms used in mis application and describe general methods for functionalizing substrates with sensing molecules. Means for detecting analytes once they are associated widi sensing molecules immobilized on substrate surfaces also are described.
II. DEFINITIONS The following terms are used herein:
A "substrate" is a non-fluid material providing a surface that can be functionalized according to die present invention. A substrate can comprise polymer molecules (e.g., thermoplastic polymer molecules), a tiiermoset
molecular network (e.g. , cross-linked polymer molecules), or odier atomic or molecular associations such as found in certain glasses and crystals.
A "surface molecule" is a substrate molecule having at least a portion diereof present on the substrate surface. A "polymeric material or substrate" is a substrate comprising polymer molecules or a network of polymer molecules.
A "polymer molecule" is a relatively large molecule formed by covalently linking smaller molecules termed "monomers. " The monomers present in a polymer molecule can be me same or different. Polymer molecules can be natural, such as (but not limited to) cellulose, starch, proteins, and nucleic acids; or syndietic such as (but not limited to) nylon and polyetiiylene. In a polymeric material, polymer molecules can be associated wid each odier in any of several ways, including non-covalently (as a thermoplastic) or a covalently cross-linked network (as a thermoset). A "functionalized substrate" is a substrate to which one or more functional groups are covalently bonded according to die metiiods of the present invention.
A "functional group" is a group of one or more atoms bonded togetiier in an organized way so as to have a desired chemical property. Certain functional groups can, when covalently bonded to a substrate surface, participate in one or more additional bonding reactions with eitiier a similar functional group or a different type of functional group. Such bonding reactions can result in: (a) attachment to the functional groups of any of a variety of additional functional groups; or (b) coupling together (cross-linking) of the functionalized substrate molecules. Many other functional groups attachable to polymer molecules according to die present invention can confer altered chemical properties to die polymer molecules such as, but not limited to, making them labeled or tagged widi a fluorescent, radioactive, immunologic, diagnostic or tiierapeutic markers.
The term "functionalized polymer" can concern eidier a functionalized polymeric substrate or a functionalized polymer molecule. Functionalized polymer molecules comprise one or more functional groups covalently bonded to die polymer molecules according to the present invention.
A "functionalizing reagent" according to die present invention is a reagent adapted for functionalizing a substrate. Molecules of functionalizing agents have at least one nitrenogenic group (as a first functional group) coupled to a second functional group. The nitrenogenic group preferably is constrained by die molecular strucmre of die functionalizing-reagent between die nitrenogenic group and die functional group. The nitrenogenic groups are capable under reaction conditions of functionalizing a substrate surface.
A "nitrenogenic group" on a functionalizing reagent is a chemical moiety mat, when exposed to a reaction-energy source, becomes a nitrene group. The phrase "addition reaction" when used in me context of reactions of the nitrene group of the functionalizing reagents with surface molecules, generally refers to any of me various addition and insertion reactions that nitrenes can undergo wid molecules on me substrate surface according to the present invention. A "nitrene group" (also generally termed "nitrene" or "nitrene intermediate") is a particular form of nitrogen group that can be depicted as a singlet by the structure: R-N, and as a triplet by the structure: R-N . Nitrenes are regarded by persons skilled in die art as die nitrogen analogs of carbenes. Like carbenes, nitrenes are generally regarded as intermediates diat are highly reactive and generally cannot be isolated under ordinary conditions. However, certain chemical reactions, such as reactions according to d e present invention, would not odierwise be explainable by known reaction mechanisms without die presumed existence of nitrenes. Important nitrene reactions can be summarized by e following: (a) Nitrenes, including aryl nitrenes, can undergo addition reactions at -
CH sites and at -NH sites; e.g. :
Ar-N + R3C-H — > Ar-NHCR3
Ar-N + R2N-H — > Ar-NHNR ■2
(b) Nitrenes can also undergo addition at -C-C- and -C=C- bonds; e.g. :
ΪTN + R2C=CR2 →
H
According to die present invention, a functionalizing reaction occurs when a functionalizing reagent comprising a nitrenogenic group is exposed to a reaction-energy source, which converts the nitrenogenic group to a nitrene intermediate. The functionalizing reaction proceeds by reaction of die nitrene intermediate wid die substrate surface.
A "reaction-energy source" is an energy source diat drives a functionalizing reaction according to die present invention by, in particular, converting nitrenogenic groups on functionalizing reagent molecules to nitrenes which react with die substrate surface. Suitable reaction-energy sources include (but are not limited to): photons (such as ultraviolet (UV) light, deep-UV light, laser light, X-rays, and heat in die form of infrared radiation or conductive heating), energized electrons (such as an electron beam), and energized ions (such as an ion beam). These reaction-energy sources are conventionally used for such tasks as lithography, scanning microscopy, and, in die case of UV and visible photons, effecting photochemical reactions and excitation of fluorescent molecules.
A "functionalizing reaction" is a reaction in which a substrate surface is functionalized according to die present invention. A functionalizing reaction can consist of one or more stages. At least one stage involves die reaction in me presence of a reaction-energy source of die substrate surface with molecules of a functionalizing reagent comprising nitrenogenic groups. m. GENERAL FUNCTIONALIZATION METHODOLOGY According to die present invention, a substrate is functionalized by a chemistry whereby functional groups on functionalizing reagent molecules
become covalently bonded to me substrate or substrate surface. Such covalent bonding is achieved by conversion of nitrenogenic groups on the functionalizing reagent molecules (die functionalizing reagent molecules also each comprising a desired functional group as set forth below) to a nitrene intermediate highly reactive widi die substrate surface by exposing die functionalizing reagent molecules to a reaction-energy source.
The functionalizing reagent is preferably selected from a group consisting generally of: aryl azides, alkyl azides, alkenyl azides, alkynyl azides, acyl azides, and azidoacetyl derivatives, all capable of carrying a variety of substituents. Halogen atoms are present to me maximum extent possible in the positions on die functionalizing reagent molecule adjacent me azide group. Best results are achieved when fluorine and/or chlorine atoms are the halogen atoms.
Each of the foregoing azides may also contain within the same molecule any of the following functional groups, constrained structurally from reacting with d e nitrene moiety after the nitrene moiety is generated:
(a) carboxyl groups and various derivatives tiiereof such as (but not necessarily limited to): N-hydroxysuccinimide esters; N-hydroxybenztriazole esters; acid halides corresponding to die carboxyl group; acyl imidazoles; thioesters; p-nitrophenyl esters; alkyl, alkenyl, alkynyl and aromatic esters, including esters of biologically active (and optically active) alcohols such as cholesterol and glucose; various amide derivatives such as amides derived from ammonia, primary, and secondary amines and including biologically active (and optically active) amines such as epinephrine, dopa, enzymes, antibodies, and fluorescent molecules; (b) alcohol groups, either free or esterified to a suitable carboxylic acid which could be, for example, a fatty acid, a steroid acid, or a drug such as naprosin or aspirin;
(c) haloalkyl groups wherein die halide can be later displaced widi a nucleophilic group such as a carboxylate anion, thiol anion, carbanion, or alkoxide ion, mereby resulting in the covalent attachment of a new group at me site of die halogen atom;
(d) maleimido groups or other dienophilic groups such diat the group may serve as a dienophile in a Diels- Alder cycloaddition reaction widi a 1,3-diene- containing molecule such as, for example, an ergosterol;
(e) aldehyde or ketone groups such that subsequent derivatization is possible via formation of well-known carbonyl derivatives such as hydrazones, semicarbazones, or oximes, or via such mechanisms as Grignard addition or alkyllidiium addition; and
(f) sulfonyl halide groups for subsequent reactions with amines, for example, to form sulfonamides. A general reaction by which a functionalizing reagent is converted to a nitrene intermediate is:
X-R-N3 > X-R-N + N2 photons or e" beam
where X is the functional group and R is an aromatic ring, heteroaromatic ring, or odier carbon-containing fragment.
A reaction-energy source comprising UV light can be supplied to the reaction by, for example, one of the following representative procedures:
(a) A sample comprising functionalizing reagent molecules and a substrate is placed in a well of a Rayonet Photochemical Reactor fitted widi lamps which emit light of a wavelengdi suitable for converting the nitrenogenic group into a nitrene, such as 350-nm, 300-nm, or 254-nm lamps. The substrates and reagent molecules are irradiated at ambient temperature for several minutes under air. The duration of die irradiation can be adjusted to change the exposure dose.
(b) The sample is irradiated through a high-resolution photomask, for example, by (but not limited to) projection UV lithography. In tiiis manner, preselected patterns of functional groups can be immobilized on a substrate. (c) Photolysis is carried out in a KSM Karl Suss deep-UV contact aligner using a contact high-resolution photomask. It will be readily appreciated by persons skilled in die art diat such procedures can also be generally used to provide die functionalizing reaction widi photons of wavelengths other tiian UV.
A reaction-energy source comprising electrons can be supplied to d e reaction by die following representative procedure: A sample is irradiated under vacuum by an electron or particle beam with an energy selected witiiin the range 1-40 kV. (A representative electron-beam source is a JEOL 840A electron microscope modified for electron-beam lithography.) The beam may be stepped across me surface of the treated substrate to expose certain areas and not otiiers. A dwell time at each step can be adjusted to change the exposure dose.
Particularly effective functionalizing reagents are selected from die group consisting of perhalophenyl azides (PHP As), particularly 1 perfluorophenyl azides (PFPAs) derived from 4-azido-2,3,5,6-tetrafluorobenzoic acid in which die carbonyl group is further activated through reactive ester, amide, acid halide, or mixed anhydride formation. For example, and not intended to be limiting, representative functionalized perfluorophenyl azides have die general structure:
wherein X can be any of the following: CN, CONH2, CHO, CO2Me, COMe, NO2, CO2H, COC1, CO-Imidazole, CONHS, CH2OH, CH2NH2, COCH2Br, N-maleimido, NH-biotinyl, CONH-R (where R is a polypeptide moiety), CONH-X-S-S-Y-NH-biotinyl (where X and Y are spacer atoms and die S-S bond is reductively cleavable at a later stage), and CONHS-SO3Na.
Representative activated PFPAs include (but are not limited to) die N- hydroxysuccinimide (NHS) ester A (also designated "NHS-PFPA"), the p.- nitrophenyl ester B, the 1-hydroxybenzotriazole ester C, the acyl imidazole D, me acid chloride E, die mixed anhydride F and die 2,2,2-trichloroetiτyl ester G:
In addition to the foregoing candidate functionalizing reagents, it is possible to utilize other PFPAs having "spacers" situated between the reactive functional group and die PFPA moiety. Omer candidate aryl azides useful as functionalizing reagents are similar to d e above examples except mat another aryl moiety replaces me PFPA.
Candidate substrates diat can be functionalized according to the present invention include, but are not limited to: polymeric substrates, graphite, metals, and siliceous materials; as well as silicon, gallium arsenide, and odier semiconducting materials.
In the case of siliceous substrates (e.g., glass, silica, mica, quartz) it is believed diat die functionalizing reagents, when converted to corresponding nitrenes, react with SiO-H groups, Si-OH groups, or Si-OSi groups on die substrate surface.
In the case of graphite and odier allotrophic forms of elemental carbon, it is believed diat die functionalizing reagents, when converted to die corresponding nitrenes, react widi carbon rings on the substrate surface.
Polymeric substrates diat can be functionalized according to me present invention include virtually any polymeric material comprising polymer molecules possessing -CH groups, and/or -NH groups, and/or -OH groups and/or -C=C- sites. Such polymeric substrates include, but are not limited to:
(a) saturated poly olef ins as exemplified by polyetirylene, poly vinyl chloride, polytetra-fluoroethylene, polypropylene, polybutenes, and copolymers thereof;
(b) acrylic resins such as polymers and copolymers of acrylic acid, metiiacrylic acid [eg. , poly(methyl-methacrylate), poly (hexylmethacry late)] , and acrylonitrile;
(c) polystyrene and its analogues such as poly(p-chlorostyrene) and poly(p- hydroxystyrene);
(d) unsaturated polyolefins such as poly(isoprene) and poly (butadiene);
(e) polyimides such as polyimide(benzophenone tetracarboxylic dianhydride/tetraediylmed ylene-dianiline);
(f) polyesters such as poly(trimethylene adipate) and poly(hexymedιylene sebacate);
(g) conjugated and conducting polymers such as poly(3-alkylthiophene), poly(3-alkylpyrrole), and polyaniline;
(h) inorganic polymers such as poly(aryloxyphosphazene), poly [bis(trifluoro-edιoxy)phosphazenel . polysilanes, and polycarbosilanes, siloxane polymers, and odier silicon-containing polymers;
(i) organic metals (i.e., organic polymers with metallic properties) such as polycroconaines and polysquaraines, as described in Chemical and Engineering News (August 31, 1992), p.8.
(j) organometallic polymers such as palladium poly-yne and ferrocene- containing polyamides; and
(k) polysaccharides such as cellulose fibers, chitin, and starch.
Functionalizing substrates according to die metiiod of the present invention requires diat molecules of die functionalizing reagent and the substrate be brought into "reactive proximity"; i.e. , brought togetiier sufficiently closely so as to undergo a functionalizing reaction when exposed to the reaction-energy source. One way materials, such as polymers, can be functionalized is to prepare a solution comprising the material and the functionalizing reagent. Anotiier way is to prepare a suspension or mixture comprising die functionalizing reagent and substrate particles or substrate agglomerations. Yet another way is to apply the functionalizing reagent (such as a solution of die functionalizing reagent in a solvent capable of absorbing into the substrate) to a surface of the substrate, then allowing e functionalizing reagent to absorb into the substrate.
Functionalization of a substrate can occur in one or more stages, depending upon various factors such as die particular material to be functionalized; the form of the material (i.e., solution, paniculate suspension, non-fluid mass); the functional group(s) to be attached to die polymer molecules; die necessity to protect the functional groups from undesired reactions during reaction of the functionalizing reagent widi d e polymer molecules; and on odier matters.
For example, in a one-stage functionalization, substrate molecules and molecules of a functionalizing reagent each having a nitrenogenic group and a desired functional group are brought into reactive proximity. Upon exposure to a reaction-energy source, the nitrenogenic groups are converted to nitrenes which react widi -CH, -NH, -OH, -C=C-, C-C, and odier groups on die substrate molecules reactive witii nitrenes, thereby covalently bonding die functional groups to the substrate molecules. The functional groups typically do not require additional chemistry performed on diem to confer the desired useful property to the resulting functionalized substrate.
In a two-stage functionalization protocol, each stage involves a different functionalizing reagent. The first stage involves a first functionalizing reagent, such as, wimout limitation, an NHS-PFPA. The first functionalizing reagent is converted during me course of me first-stage reaction to a nitrene intermediate. During the first stage using, for example, a polymeric substrate, the NHS active-
ester groups on the NHS-PFPA molecules become covalently attached to surface polymer molecules.
As another example of a two-stage functionalization reaction, the first stage may involve a first functionalizing reagent such as an NHS-PFPA compound. Upon exposure to a reaction-energy source, die azide group of die PFPA portion is converted to a nitrene intermediate diat reacts with polymer molecules. Thus, e NHS active-ester groups on the NHS-PFPA molecules become covalently attached to d e polymer molecules. Thus, mis first-stage reaction requires generation of a highly reactive nitrene intermediate derived from the NHS-PFPA by exposure of die NHS-PFPA to a reaction-energy source.
As still anodier example of a two-stage reaction protocol, me first stage can be performed by interspersing molecules of a first functionalizing reagent depdiwise into the substrate mass, such as by first forming a fluid solution or suspension comprising the polymer and die first functionalizing reagent; forming the fluid into a desired shape; then converting die fluid into a product having a rigid form. The reaction-energy source is then applied to die rigid product to covalently bond die first functionalizing reagent to die polymer molecules. Subsequently, during die second stage, the second functionalizing reagent is applied to a surface of the rigid product. As can be seen by die preceding examples, the NHS-ester portions of the
PFPAs do not participate in this first-stage chemistry. Rather, die NHS-esters, after being transferred to d e surface molecules, are utilized in second-stage chemistry, discussed below.
In die second stage, the NHS esters readily react widi molecules of a second functionalizing reagent. The second functionalizing reagent is selected from a group consisting of molecules possessing primary or secondary nucleophilic species, such as, but not limited to, amines, sulfhydryls, and/or hydroxyls. Reaction of NHS-esters witii hydroxyls proceeds via ester formation. Since many types of biological molecules possess nucleophilic groups, such as amine and/or hydroxyl groups, these molecules can serve as functionalizing reagents adapted for reaction in a second-stage functionalization reaction witii
NHS-esters covalently bonded to die surface molecules in a first-stage functionalization reaction. Thus, it is possible to attach any of a wide variety of molecules, including macromolecules such as proteins, nucleic acids, carbohydrates, and various odier molecules, to substrates and/or surfaces tiiereof using methods according to die present invention. Thus, the invention provides methods for immobilizing heparin sensing molecules to substrates.
By practicing the methods of die present invention, it also is possible to first prepare nitrenogenic derivatives of molecules (such as biomolecules, drugs, analytes, catalysts [including transition metals], and diagnostic agents) to be attached to the substrate, bring the derivatives into reactive proximity or apply the derivatives to a surface of die substrate, tiien expose the derivatives or treated surface to a reaction-energy source to cause the nitrenogenic derivatives to covalently bond to die substrate and/or surface molecules via nitrene intermediates. It is necessary for me nitrenogenic moiety to be structurally constrained such diat the nitrene cannot readily react with another part of die same molecule. For instance, with NHS-PFPA functionalizing reagents me 4- position of die phenyl ring is the preferred position for die azide group.
IV. DETECTING ANALYTES The present invention relies on first having analytes of interest associate, such as through ionic or covalent bonding, widi sensing materials immobilized on portions of a sensor, and thereafter detecting the presence of die analyte in its associated state with die sensing portion. Working embodiments of die invention have used SPR as the detection method.
A. SEEL Without limiting the invention to one theory of operation, it is believed diat
SPR operates in the following manner. On the plasma surface (usually a material with a relatively large imaginary part and small real part of the optical dielectric constant, i.e. metals such as silver or gold) collective resonating oscillations of free electrons can be established. This produces a charge density wave propagating along the plasma surface. This surface plasmon wave can be excited by an electromagnetic wave traveling dirough the medium coated on die metal.
Light can be used to to excite die SPR. The light should be transverse magnetic (TM) polarized due to me specific boundary conditions at die metal - dielectric interface. When the wave vector and me frequency of the incident light coincide widi those of the surface plasmon the light resonantly excites the surface plasmon. The dispersion relation of die surface plasmon depends on die dielectric constant of the metal and die dielectric of die material in proximity to the metal, such as a metal substrate and any material on top of die metal. By monitoring the resonance condition of die plasmon resonance the dielectric constant of the overlaying material can be obtained. When die overlaying material binds to or somehow otherwise affiliates with different chemical species its dielectric constant changes, which causes a shift in die resonance.
SPR as applied for die detection of surface bound or associated analytes, and perhaps for determining me concentration of such analyte, uses a chemical transduction layer which modifies die surface of die metal. This may enhance the sensitivity and selectivity of the method when d e concentration of the analyte is small. Metal surfaces were functionally modified using the methods described above and exemplified below so diat such surfaces could bind to specific analyte molecules, thereby locally increasing the concentration of die molecules of interest. This enhanced changes of die dielectric constant at die metal-dielectric interface, which resulted in larger changes in surface plasmon resonance position. The resonance condition can be monitored in two ways. First, the light wavelengtii can be fixed and die reflectivity versus the incident angle measured. Attenuation in die intensity of the reflected light occurs at die angular position when die resonance condition is satisfied. At tiiis angle all the energy of the incident beam is taken by me surface plasmon excitation. Second, it is possible to fix the angular position and scan die light frequency. This will again give attenuation at certain wavelengths when die surface plasmon wave vector satisfies me resonance condition. The first approach is a currently preferred approach. The second approach gives similar results but the resulting detection apparatus is more complicated.
B. Sensor with Flow-through Cell and SPR Detector
FIGS. 3 and 4 illustrate die sensing portion 10 of a heparin sensor. FIG. 3 illustrates diat die sensing portion 10 includes a flow-dirough cell 12 and a substrate 14 having analyte sensing materials immobilized tiiereon in the manner described above. Flow-dirough cell 12 was machined from TEFLON, and sealed with O-rings. The substrate 14 may have solely sensing materials for heparin, or may include plural, different sensing materials for sensing plural analytes. Moreover, substrate 14 may have sensing materials immobilzed randomly on die surface of substrate 14, or may have sensing materials immobilized on die surface of substrate 14 in preselected patterns, such as die linear arrays 16 illustrated in FIG. 3.
The heparin sensor can be produced to have a continuous flow-dirough arrangement. In such a system, there must be means for delivering sample containing heparin, such as blood, to me sensing portion 10. Furthermore, it also may be desirable to include flushing capability to d e sensing portion 10 of e sensor so diat d e flow-dirough cell 12 can be flushed after a sample containing analytes is flowed tiirough flow-through cell 12. As shown in FIG. 3, die sensor can include plural sample delivery lines 18 fluidly coupled to me flow- through cell 12 for delivering sample containing analyte to the cell 12. FIG. 3 also illustrates diat a flush line 20 may be fluidly coupled with die flow-tiirough cell 12 for delivering a flushing liquid, such as water or buffer, to die cell 12. Sample, and flushing liquid, is removed from die flow-tiirough cell 12 through exit lines 22. Sample delivery line(s) 18, flush line(s) 20, and exit line(s) 22 were made from TEFLON in a working embodiment. In operation, sample containing analyte is flowed tiirough flow-through cell
12 tiirough supply lines 18. This is accomplished by actuating an upstream valve (not illustrated) diat feeds supply line 18. Once the sample containing analyte is flowed tiirough the flow-through cell 12, upstream sample valve is closed, and an upstream valve is actuated diat feeds flush line 20, thereby flushing flow-through cell 12 widi, for example, water or buffer solution.
In some embodiments, a tiiird supply line can be fluidly coupled to the flow-dirough cell 12. The tiiird supply line can be used to delivering an inert gas, such as N2, to die flow-dirough cell. The inert gas supply line (not illustrated) generally is used to prevent certain analytes from reacting with air, and also may be used to dry die flow-dirough cell after it is flushed with water or buffer using flush line 20.
FIG. 4 illustrates a side cross-sectional view of sensing portion 10 as illustrated in FIG. 3. FIG. 4 also shows diat the flow-through cell portion 12 is covered by a metal-coated surface-plasmon unit 24. A working embodiment of unit 24 comprised a multilayer system made from BK-7 glass as a substrate, which had a tiiin layer of silver metal and organic film deposited tiiereon. This unit was integral in detecting d e association of analytes, such as heparin, with die sensing molecules immobilized on die surface of substrate 14.
FIG. 5 illustrates schematically the arrangement of a detection system for detecting analytes associated widi die sensing molecules. Detection of die analyte was accomplished using an SPR system in standard Kretschmann geometry. A light source 26 capable of producing coherent, polarized light, such as a HeNe polarized laser U-1307P by Uniphase, was used to emit light. Light from coherent and polarized light source 26 was passed tiirough two cylindrical lenses, LI and L2 respectively. This transformed the point image from the light source 26 into a line image. A third lens L3 was used to converge die line light beam from lenses LI and L2 onto die surface of SPR unit 24, which included a tiiin silver film. The beam was TM polarized with respect to the plane of incidence. The reflected beam was converged by a fourth lens (L4) to form a parallel line beam that was directed tiirough a cross polarizer 28 to a photodiode array (PDA) system 30. A working embodiment of the invention used a Hamamatsu C-5964 photodiode array having 1024 silicon photodiodes, each 500 μm long and 25 μm wide. The cross polarizer 28 controlled die intensity of the incident light. This arrangement made it possible to scan die intensity of the reflected light widi respect to die angle of incidence witiiout having to perform any mechanical manipulation while making measurements.
The maximum scanning range for the illustrated system was ± 5° and was determined by die characteristics of die lenses LI, L2, and L3. This range can be changed by using different cylindrical lenses. The resolution and precision of die measurement system was determined by die above scanning range and d e density of the diode array of the detector.
Using the described configuration the resolution was about ± 0.01 °. Solely for convenience, moderately sized system components were used: equilateral prism 40X40 mm2; the focal lengtiis of the lenses LI, L2, L3, and L4 were 6.35, 150, 60 and 60 mm, respectively. The total size of the system is around 1000 X 250 mm2 but it can be reduced substantially using microoptics components including fiberoptic elements. PDA 30 was equipped widi a control circuit which was powered and controlled by an external function generator and a pulse sequence from a National Instruments' DAQ- 1200 card inside a IBM PC based computer. The data acquisition software was written using Lab VIEW 4.0. The output video signal from PDA 20 was synchronously digitized by die DAQ card and stored inside die computer.
The SPR system illustrated in FIGS. 3-5 was designed to avoid using moving mechanical parts during die process of the measurement. The required precision limits the scanning angular range to about 10°. On the other hand, die angle of the attenuated total reflection (ATR) for the multilayer SPR unit 24 is 45° and 65° in die case of air and liquid coverage above me polymer film, respectively. Therefore die system is designed for detecting eitiier in dry or wet flow cell conditions. The current results were performed at around 45° incidence, which allowed recording data only when die multilayer system was dry.
V. EXAMPLES
To further illustrate and describe the present invention, the following examples are provided. These examples are intended to be exemplary only, and should not be construed to limit the invention to die particular aspects described therein.
Example 1
This example illustrates the functionalization of graphite to establish that functionalization of such materials is possible using the methodology discussed above. A piece of pyrolytic graphite was freshly cleaved using transparent adhesive tape and coated witii a solution of 0.5 % w/w N-hydroxysuccinimidyl 4- azidotetrafluorobenzoate (NHS-PFPA) in dry nitromediane by spinning at a speed of 1000 rpm. The coated graphite was baked at 60°C for 20 minutes and irradiated for 5 minutes using 254-nm lamps at ambient temperature under air. The graphite was then incubated in a 50-μM solution of horseradish peroxidase (HRP) in NaHCO3 buffer (pH 8.2) at 25 °C for 3 hours and rinsed thoroughly with phosphate buffer (pH 7.0).
The enzymatic activity of me functionalized graphite was determined spectroscopically at 420 nm and 25 °C in phosphate buffer using 2.2'-azino-bis(3- ethylbenzthiazoline-6-sulfonic acid) diammonium salt (ABTS) and hydrogen peroxide (1.8 mM ABTS/0.8mM H2O2). Assuming that the immobilized HRP had die same activity as die native HRP, the extent of immobilization of HRP was 2.1 ng/mm2.
A control experiment was performed as follows: A piece of freshly cleaved graphite was similarly baked, irradiated, and incubated widi HRP solution. The enzyme-activity of d e control was determined to be 0.4 ng HRP/mm2. Thus, the control was not treated with NHS-PFPA.
Samples and controls were examined using atomic-force microscopy (AFM). The atomic-force microscope was operated in air at ambient temperature. A representative AFM image of the sample is shown in FIG. 1A and of die control in FIG. IB. In FIG. 1A, bright spheres correspond to immobilized HRP molecules. In FIG. IB, only a few faint spheres were seen, indicating much less immobilization of the HRP molecules to die control surface.
Therefore, the NHS-PFPA allows substantial covalent attachment of HRP to the graphite surface.
Example 2
This example illustrates that preselected patterns of functional groups can be immobilized on substrates. In tiiis example, micron-sized patterns were "drawn" on a P3OT film containing NHS active ester using an electron beam. A solution of 25.7 mg of P3OT and 1.8 mg of NHS ester (7 % w/w) in
0.6 mL of xylene was spin-coated on a silicon disc and dried at 60°C for 30 minutes. The resulting film was exposed to an electron beam to "draw" micron- sized patterns on die film (line widtii 0.5 μm; beam intensity 20 μC/cm2). The film was then "developed" by dipping in xylene for 10 seconds, rinsing in isopropyl alcohol for 10 seconds and drying under a stream of nitrogen gas. The film was then immersed in a solution of 1.5 mg of amino-fluorescein and 6 mg of Et3N in 1 mL of EtOH for 4 hours. The film was then washed with EtOH, immersed in EtOH for 1 hour, washed again widi EtOH, tiien air-dried. The sample film was observed and photographed using a fluorescence microscope equipped widi a rhodamine filter set (excitation wavelength 510-560 nm, emission wavelength > 590 nm), yielding die results shown in FIG. 2A. The same sample film was observed and photographed using the fluorescence microscope equipped witii a fluorescein filter set (excitation wavelengtii 450-490 nm, emission wavelength 515-565 nm) yielding d e results shown in FIG. 2B. As can be seen, substantially identical patterns were observed having strong fluorescence at bom the rhodamine excitation wavelength (FIG. 2A) and the fluorescein excitation wavelength (FIG. 2B).
P3OT alone is strongly fluorescent at the rhodamine excitation wavelengtii but only weakly fluorescent at the fluorescein excitation wavelength. (This is why the films in this example were observed using a rhodamine filter set and a fluorescein filter set; strong fluorescence observed at die fluorescein excitation wavelength would necessarily be due to die presence of odier molecules man just P3OT.) FIGS. 2A and 2B indicated diat fluorescein became attached to die regions exposed to die electron beam.
Example 3 This example is a control for example 2. A P3OT film was exposed to an electron beam (intensity 30 μC/cm2, line widtii 0.5 μm), developed, tiien treated widi amino-fluorescein as described in example 2. The micron-sized patterns "drawn" on die control P3OT film were identical to me patterns in Example 2. When the control film was examined using a fluorescence microscope, strong fluorescence was observed at the rhodamine excitation wavelengtii (FIG. 2C), but only weak fluorescence was observed at the fluorescein excitation wavelength (FIG. 2D). The results indicate diat substantially no fluorescein became attached to
P3OT in the absence of activated ester groups. Therefore, the presence of NHS active ester was required to obtain any substantial covalent coupling of the fluorescein to P3OT.
Example 4 This example describes the deposition of silver films on glass substrates, spincoating the metal substrates widi polymeric material, and tiiereafter functionalizing the polymeric film by immobilizing protamine thereon. Thin silver films (56 nm thick) were deposited onto circular glass slides using a thermal evaporator. A solution of polystyrene (PS) in toluene (1 mg/mL) was spin-coated on top of die silver film at 1000 rpm for 2 minutes. The film was baked at 90°C for 30 minutes. After cooling, a solution of 0.5% NHS-PFPA ester in nitromethane was spin-coated on top of die PS film at 1000 rpm for 1 minute. The film was photolyzed in a Rayonet photoreactor at 254 nm for 5 minutes, rinsed widi nitromethane for 10 seconds and blow-dried witii N2. The film was then immersed in a solution of protamine sulfate (Sigma) in pH 9.0 NaHCOj buffer (4 mg/mL) at 25 °C for 1.5 hour, rinsed with water and N2- dried. This attached protamine on the silver substrate.
Example 5 This example describes the deposition of silver or gold films on glass substrates, spincoating the metal substrates with polymeric material, and tiiereafter functionalizing the polymeric film by immobilizing poly-L-lysine on the metal. Thin gold or silver films were deposited onto circular glass slides using a thermal evaporator. A solution of polystyrene in toluene (1 mg/mL) was spin-coated on top of die silver film at 1000 rpm for 2 minutes. The film was baked at 90°C for 30 minutes. After cooling, a solution of 0.5% NHS-PFPA ester in nitromethane was spin coated on top of die PS film at 1000 rpm for 1 minute. The film was photolyzed in a Rayonet photoreactor at 254 nm for 5 minutes, rinsed widi nitromethane for 10 seconds and blow-dried widi N2. The film was then immersed in a solution of poly-L-lysine in pH 9.0 NaHCO3 buffer, rinsed witii water and N2-dried. This attached poly-L-lysine to the metal films.
Example 6 This example describes die deposition of silver or gold films on glass substrates, spincoating the metal substrates witii polymeric material, and thereafter functionalizing the polymeric film by immobilizing heparinase on the metal. Gold or silver tiiin films were deposited onto circular glass slides using a tiiermal evaporator. A solution of polystyrene in toluene (1 mg/mL) was spin- coated on top of die gold or silver film at 1000 rpm for 2 minutes. The film was baked at 90°C for 30 minutes. After cooling, a solution of 0.5% NHS-PFPA ester in nitromethane was spin-coated on top of die PS film at 1000 rpm for 1 minute. The film was photolyzed in a Rayonet photoreactor at 254 nm for 5 minutes, rinsed witii nitromethane for 10 seconds and blow-dried widi N2. The film was men immersed in a solution of heparinase in pH 8.3 NaHCO3 buffer, rinsed witii water and N2-dried. This attached heparinase on the silver substrate.
Example 7 This example describes an alternative method for functionalizing metals with analyte sensing molecules. Thin gold tiiin films (47nm thick) were deposited onto circular glass slides using a thermal evaporator. The film was reacted with 1-decanethiol to form a gold substrate having a pendent C-10 carbon
chain. A solution of NHS-PFPA ester (1) was then spin-coated onto the film followed by photolysis at 254 nm for 5 minutes. This resulted in die formation of a nitrene from the azide group of die NHS-PFPA ester, which underwent an insertion reaction with the pendent methyl group of 1-decantiιiol. This attached die NHS-PFPA ester to the gold substrate. The film was then immersed in a solution of protamine or poly-L-lysine or heparinase. This attached protamine or poly-L-lysine or heparinase to the gold substrate.
Example 8 This example describes the formation of pre-selected patterns of materials on the surface of gold or silver substrates. A substrate made by evaporating gold or silver onto glass was reacted witii 1-decanetiιiol to form a gold or silver substrate having a pendent C-10 carbon chain. A solution of NHS-PFPA ester was then spin-coated onto the film followed by photolysis at 254 nm using a UV mask aligner. This attached NHS-PFPA ester to d e gold or silver surface in preselected patterns. The film was then immersed into a solution of protamine or poly-L-lysine or heparinase. This attached protamine or poly-L-lysine or heparinase to the gold or silver substrate in pre-selected patterns.
Example 9 This example describes d e formation of arrays on the surface of gold or silver substrates. A substrate made by evaporating thin films of gold or silver onto glass was reacted with 1-decanetiιiol to form a gold or silver substrate having a pendent C-10 carbon chain. A solution of NHS-PFPA ester was then spin-coated onto die film followed by photolysis at 254 nm for 5 minutes. This attached NHS-PFPA ester to the gold or silver surface. The films were then spotted witii solutions of different sensing reagents, for example, protamine, heparinase and/ or glucose oxidase using a pipette or a mechanical spotting device. This generated arrays of sensing reagents on the gold or silver substrate.
Example 10 This example describes die immobilization of quaternary amines on substrates for detecting heparin. Thin gold or silver thin films were spin-coated wid a solution of polystyrene in toluene (1 mg/mL) followed by spin-coating a
solution of compound 2. The film was photolyzed at 254 nm and rinsed witii nitromethane. The film was then reacted with a solution of iodomethane in ether. This generated quaternary ammonium ions on the gold or silver surface.
Example 11 A substrate made from gold or silver deposited on glass was reacted widi
HS(CH2)xNMe2 followed by reaction with iodomethane. This generated quaternary ammonium ions on the gold or silver surface.
Example 12 A substrate made from silver on glass was reacted witii HS(CH2)xNMe2 followed by reaction with iodomethane. This generated quaternary ammonium ions on the silver surface.
Example 13 A substrate made from gold or silver on glass was immersed in a solution of 11-mercaptoundecanoic acid (HS(CH2)12COOH) in etiianol for 24 hours followed by rinsing with etiianol and water. The film was then treated witii a solution of protamine or poly-L-lysine or trioctylmethylammonium chloride in pH 8.2 NaCHO3 buffer. This attached protamine or poly-L-lysine or trioctylmethylammonium chloride to die gold or silver surface.
Example 14 A solution comprising a polymer, such as polyvinylphenol, a bis-PFPA crosslinker and a sensing reagent, such as protamine or poly-L-lysine or trioctylmethylammonium chloride, was spin-coated onto gold or silver surfaces and tiien photolyzed. This generated a crosslinked polymer film with the sensing reagent embedded in the film. Example 15
BK-7 glass substrates with a flatness of 1 wavelength were obtained from Argus International. A thin silver film (55 to 60 nm) was directly deposited on die glass surface by vacuum thermal deposition at pressures around 5-7 Ton*. The substrate temperature during evaporation was around 300 K. The silver coated samples were further processed to bind protamine sulfate to its surface as described above in example 4. Samples were mounted in a sample holder
designed so tiiat the silver coating with the bound protamine formed one wall of die flow cell of FIG. 3. The Teflon-flow cell was sealed using a Viton-1 compression O-ring fitting. Optical contact with the BK-7 glass prism was accomplished using index matching fluid (RESOLVE by Stephens Scientific). All of the system was mounted onto a rotational optical stage capable of manually adjusting die rotation angle with a 0.5° precision.
Detection of the analyte was accomplished using a surface plasmon resonance (SPR) system in standard Kretschmann geometry as described above. Various materials, including sample containing analyte, water, and N2 were fed to die flow-through cell 12 using a 6-to-l electromechanical valve system that was computer controlled.
After mounting the sample onto the flow cell the optical system was adjusted to maximize the sensitivity with die set of lenses available. A valve control time sequence was then controlled by the computer program so that at certain times a required liquid or gas was flowed tiirough the cell.
A series of tests were run using the flow through sample and detection system discussed above. The results of these experiments are presented in Table 1 below. Table 1 has the following entries: "N2" refers to flowing ultrahigh pure nitrogen gas through the flow tiirough cell; "water" refers to deionized H2O (18 MΩ); "tris" refers to a tris-sulfate buffer solution; "heparin" refers to a solution comprising tris buffer and heparin. The numbers in parentiieses refer to valves that were opened to introduce each material into die flow-dirough cell.
TABLE 1
STEP VALVE (#) TIME, MIN.
1. closed (6) 10
2. N2(0) 5
3. closed (6) 5
4. N2 (0) 5
5. closed (6) 5
6. water (2) 5
7. N2 30
10 8. closed (6) 10
9. water (2) 5
10. N2 (0) 30
11. closed (6) 10
12. tris (1) 5
15 13. water (2) 10
14. N2 (0) 30
15. closed (6) 10
16. tris (1) 5
17. water (2) 10
20 18. N2 (0) 30
19. closed (6) 10
20. heparin (3) 5
21. water (2) 10
22. N2 (0) 30
25 23. closed (6) 10
24. heparin (3) 5
25. closed (6) 5
26. water (2) 10
27. N2 (0) 30
30 28. closed (6) 10
29. heparin (3) 5
30. closed (6) 15
31. water (2) 10
32. N2 (0) 30
35 33. closed (6) 10
A series of control runs, as well as flowing heparin solutions through the flow-through cell, were then carried out. The flow tiirough cell first was analyzed witii all valves closed. Thereafter, die flow through cell was flushed witii N2 to determine die temperature dependence of d e resonance condition. The temperature dependence of die optical dielectric constant of the metal layer, as well as the coatings above the silver thin film, must be determined so tiiat the size of the effect can be distinguished from when analytes bind to die surface.
After the flow-dirough cell was flushed widi N2, die cell was tiien flushed with deionized water and thereafter dried to see what changes occurred in the SPR position due to residual humidity. This flushing and drying sequence also was done to understand die amount of time that might be required to analyze a sample.
The last preliminary set of control cycles was done using tris-sulfate buffer solution containing no heparin. The sensor surface first was exposed to tris-buffer solution. Thereafter, the flow-through cell was flushed wid deionized water and dried using a flow of UHP N2 gas. This sequence was tested to investigate the influence of running a highly ionic solution on the multilayer structure. This sequence also served as a main control indicator for die test runs with heparin/tris-buffer solution. Flushing with water was used botii in the control runs and in the actual test runs to remove any residual salts which might condense on die sensor surface during die drying process.
FIG. 6 illustrates die data recorded by die photodiode array. On the horizontal axis the diode number is displayed which corresponds to a certain angle of incidence of die laser light. The recorded voltage is reported on die vertical axis, which corresponds to d e light intensity at the specified diode. The curve minima at about diode number 500 corresponds to die surface plasmon resonance condition. The movement of the dip in intensity at which SPR occurs will be of main interest.
FIG. 7 illustrates the peak position dependence on time as the flow cell is subjected to different conditions. At die time when die sensor is under liquid die SPR position is out of die range of incidence angles scanned when die surface is
under liquid. This is represented by die measurement being off scale (position reading showing 400). The position of the SPR minima stays the same after flowing controls through the cell, namely water and tris-buffer (at around 492 ± 2.), and shifts to a higher number when the sensor surface is exposed to heparin. The curve minima dependance on die heparin exposure time is illustrated in
FIG. 8. The SPR shift saturates for times around 30 minutes. This FIG. 8 further illustrates that the SPR detection system can be used for determining concentrations of analytes, in this case heparin, by using a calibrated curve.
VI. APPLICATIONS Sensors made according to die present invention are useful for detecting heparin and heparin concentrations. However, such sensors also can have plural sensing mechanisms on one single unit. With respect to a sensing unit that has plural sensing mechanisms, the heparin sensor as described herein could be combined witii odier sensing mechanisms, such as a glucose sensor, so that heparin and glucose blood levels can be monitored.
The present sensors are small, and tiierefore can be produced in a handheld unit, or other transportable device. Alternatively, the sensing unit can be produced to be integrated widi diagnostic equipment already available. For example, a sensing chip can be produced that is integrated widi otiier electronic portions of existing equipment.
Moreover, the sensors described herein can be used botii in invasive and non-invasive applications, mat is external to the human body, or in vivo. With respect to non-invasive methods, blood samples can be taken from the patient and die heparin blood levels detected. In a non-fully invasive application, the heparin sensor could be attached to a cati eter used to divert blood from a patient's circulatory system through the sensor. This allows blood to be continuously circulated tiirough the catheter, thereby tiirough the heparin sensor, to continuously monitor heparin levels in line. This is possible either by providing a sensor having sufficient heparin sensing units to monitor heparin levels for a given period of time. Alternatively, the heparin sensors of the present invention are reversible, i.e., they can first
detect heparin levels, followed by a regeneration process whereby the heparin sensors are fully regenerated for subsequent use. Regeneration generally is accomplished by flushing the sensor with a salt solution, particularly NaCl. This disrupts die ionic interaction between, for example, protamine and heparin, allowing die heparin to be back-extracted. This regenerates free protamine molecules for subsequent detection of heparin.
The sensors also can be coupled to a feedback system. For example, if d e sensor is solely designed for monitoring heparin levels, a heparin pump can be coupled to die circulatory system of a patient. As heparin levels drop, die pump is activated to increase the heparin concentration in the blood. Similarly, the heparin sensor could be a dual or plural sensing unit with a feedback system. In one embodiment, a heparin sensor that also includes a glucose sensing is coupled witii a feedback system for introducing both heparin and insulin into die patient's blood stream. While the invention has been described in connection witii preferred embodiments and multiple examples, it will be understood that it is not limited to those embodiments. On die contrary, it is intended to cover all alternatives, modifications, and equivalents as may be included wititin the spirit and scope of die invention as defined by die appended claims.