The present invention relates in general to biological sensors, and in particular, to biological sensors arranged in a matrix array.
The simultaneous monitoring for multiple analytes (liquids and gases) has diversified applications in various domains like metabolic monitoring, chemical, biological warfare detection, gas sensing, etc. Most present day sensors have considerable limitations in monitoring more than one analyte due to the problems of cross-sensitivity and interference from other compounds. This limitation is a disadvantage with continuous detection of multiple analytes. Some of the multi-analyte systems do not have sufficient miniaturization for in vivo or other sensitive applications. There is a lack of unified sensor arrays that can monitor both gases and liquids simultaneously.
There have been several reports on the development of biosensor arrays using different methodologies. A common biosensor format for an enzyme based biosensor array to monitor fruit quality was reported (Biosensors & Bioelectronics (2003), 18(12), 1429-1437). Pectin was used as the immobilization matrix for the sensors, but the methodology of immobilization was “drop and dry mechanism” which did not yield good sensitivity.
A two enzyme biosensor array for characterization of wastewaters incorporating tyrosinase and horseradish peroxidase (HRP) or cholinesterase-modified electrodes were combined on the same array (Analytical and Bioanalytical Chemistry, Vol. 376, Issue 7, 2003, p. 1098). The performances of bi-enzyme biosensor arrays in the batch mode and in the flow-injection system were discussed.
A multifunctional bio-sensing chip was reported based on the electrochemiluminescent (ECL) detection of enzymatically produced hydrogen peroxide (Marquette, Christophe A.; Degiuli, Agnes; Blum, Loic J., Biosensors & Bioelectronics (2003), 19(5), 433-439). Six different oxidases specific for choline, glucose, glutamate, lactate, lysine and urate were non-covalently immobilized on in the array sensor but the limit of detection was only towards hydrogen peroxide.
Pin printed biosensor arrays (PPBSA) were reported by pin printing protein-doped xerogels (Cho, Eun Jeong; Tao, Zunyu; Tehan, Elizabeth C.; Bright, Frank V., Analytical Chemistry (2002), 74(24), 6177-6184). The sensor was able to detect glucose and oxygen simultaneously. The overall array-to-array response reproductibilities are around 12%, which limits the long time stability of the sensor.
For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
In the following description, numerous specific details are set forth such as specific memory array configurations, etc. to provide a thorough understanding of the present invention. However, it will be obvious to those skilled in the art that the present invention may be practiced without such specific details. In other instances, well-known circuits have been shown in block diagram form in order not to obscure the present invention in unnecessary detail. For the most part, details concerning timing considerations and the like have been omitted inasmuch as such details are not necessary to obtain a complete understanding of the present invention and are within the skills of persons of ordinary skill in the relevant art.
Refer now to the drawings wherein depicted elements are not necessarily shown to scale and wherein like or similar elements are designated by the same reference numeral through the several views.
One embodiment of the present invention illustrated in
The sensor may find applications in domains like metabolic monitoring (glucose, lactose, fructose, urea, uric acid, phenol, alcohols, ascorbic acid, hydrogen peroxide, phospholipids and other metabolites), chemical warfare detection (sarin, tabun, soman, hydrogen cyanide, cyanogens chloride, mustard, chlorine and other chemical warfare agents), biological warfare agents (ricin, polypeptides and others), potential chemical biological warfare agents (PCB's such as organophosphates, DMMP, malathion, ethion, parathion, paraozon and others), DNA hybridization, gas monitoring (toxic gases like CO, SO2, NO, NO2, NH3, H2S and others), and metals (mercury, arsenic and others). The matrix nanobiosensor can be used to detect both gases and liquid multiple analytes.
Photolithographic Fabrication of a Matrix Nanobiosensor:
Referring to
Sensor Fabrication:
The matrix nanobiosensor substrate developed by photolithography fabrication as described in
In step 2 (
Carbon nanotube paste electrodes (0.5 cm2) were prepared by mixing 50% by weight of carbon nanotubes with 43% by weight of organic (or inorganic) vehicle and 7% by weight of glass frit in a mortar and pestle for 30 minutes followed by grinding in a three roll mill for 20 minutes to disperse the clusters in the mixture. The inorganic vehicle was purchased from Cotronics Corp., Brooklyn, N.Y., USA. The substrate was then baked at 100° C. for 10 minutes in an oven and cooled at room temperature. Different weight percentages of carbon nanotubes can also be employed for the electrode preparation. The prepared carbon nanotube paste electrodes can be fired (hard baked) to remove the organic vehicle and activated using a tape.
Carbon nanotube spray electrodes (0.5 cm2) were prepared by dissolving a known quantity of carbon nanotubes (e.g., 0.1 g) in 20 ml isopropyl alcohol, followed by ultrasonication for 5 minutes, and spraying the solution onto the substrate (silicon substrate, vacuum evaporated with 20 Å chromium and 500 Å gold). The spray electrode was then baked at 100° C. for 10 minutes in an oven and cooled at room temperature.
The carbon nanotubes that can be used with this invention can also be prepared by a chemical vapor deposition process including a catalyst (e.g., nickel, copper, cobalt, iron) and a carbon source (e.g., acetylene, ethylene, methane and other hydrocarbons), or other methods known to one skilled in the art.
In step 3 (
Electropolymerization and enzyme immobilization of polypyrrole and these enzymes was carried out by the oxidation of pyrrole (0.1 M) in a solution containing 0.1 M NaClO4 in a pH 7.0 buffer solution under the same electrochemical conditions. The electrodes were then washed with water and dried in air. Other conducting polymers can also be employed in these matrix nanobiosensors. Additionally, other biological entities such as antibodies, nucleic acids, aptamers, etc., can be immobilized onto the nanotubes using similar methods.
In step 4 (
Electronic Drive Assembly:
Referring to
(a) The Electrometer
The electrometer circuit 301 measures the voltage difference between the reference 203 and working 201 electrodes. Its output has two major functions: it is the feedback signal in the potentiostat circuit, and it is the signal that is measured whenever the cell voltage is needed. An ideal electrometer has zero input current and infinite input impedance. Current flow through the reference electrode 203 can change its potential. In practice, all modern electrometers have input currents close enough to zero that this effect can usually be ignored. Two important electrometer characteristics are its bandwidth and its input capacitance. The electrometer bandwidth characterizes the AC frequencies the electrometer 301 can measure when it is driven from a low impedance source. The electrometer bandwidth is higher than the bandwidth of the other electronic components in the potentiostat. The electrometer input capacitance and the reference electrode resistance form an RC filter. If this filter's time constant is too large, it can limit the effective bandwidth of the electrometer and cause system instabilities. Smaller input capacitance translates into more stable operation and greater tolerance for high impedance reference electrodes.
(b) The Current to Voltage Converter
The current to voltage (I/E) converter 302 in the simplified schematic measures the cell current. It forces the cell current to flow through a current measurement resistor, Rm. The voltage drop across Rm is a measure of the cell current. A number of different Rm resistors can be switched into the I/E circuit 302 under computer control. This allows measurement of widely varying of currents, with each current measured on using an appropriate resistor. An “I/E autoranging” algorithm is often used to select the appropriate resistor values. The I/E converter's bandwidth depends strongly on its sensitivity. Measurement of small currents requires large Rm values. Stray (unwanted) capacitance in the I/E converter 302 forms an RC filter with Rm, limiting the I/E bandwidth.
(c) The Control Amplifier
The control amplifier 303 is a servo amplifier. It compares the measured cell voltage with the desired voltage and drives current into the cell to force the voltages to be the same. Note that the measured voltage is input into the negative input of the control amplifier 303. A positive perturbation in the measured voltage creates a negative control amplifier output. This negative output counteracts the initial perturbation. This control scheme is known as negative feedback. Under normal conditions, the cell voltage is controlled to be identical to the signal source voltage.
(d) The Signal
The signal circuit 304 is a computer controlled voltage source. It is generally the output of a digital to analog (D/A) converter (see DAC in
Mechanism of Sensing:
One of the mechanisms of sensing as described previously is electrochemical based. The qualitative sensing is achieved by cyclic voltammetry, which is used to characterize the unique amperometric oxidative potential. The quantitative sensing is carried out by chronoamperometric measurements at the fixed characteristic potential determined by cyclic voltammetry. The liquid phase sensors require a small amount of analyte (in micromolar range) and the gas phase sensors are provided with a hydrophobic membrane and a liquid or solid electrolyte. The solid electrolyte can be any anionic exchange membrane (e.g., nafion), nanoporous silica (e.g., xerogels, hydrogels).
The enzymes may be immobilized into the nanotubes using a cyclic voltammetric (CV) technique (here the voltage is varied in steps, typically swept between −1V to +1V and reverse for one loop). Nine different enzymes (E) may be immobilized onto the sensor elements using CV to form the sensor array. The nine different enzymes are selected to have a unique reaction with nine different analytes (A) [example: Glucose oxidase (E) for glucose (A)]. When the analyte comes in contact with the sensor, the matrix is turned on by the electronics (the background electrochemical process in the electronics is CV) and the CV has a unique redox peak for each of the analytes resulting from the enzyme (E) vs analyte (A) reaction. Based on the redox peak for each analyte obtained, the software calibrates the concentration levels of the analyte.
Chronoamperometry operates by fixing a constant voltage and gives out current vs time plots. A characteristic voltage is fixed for each analyte obtained from the previous CV run. An advantage of this technique is that the measurements can be done real time and faster compared to the scan method in the CV.
The response of the matrix nanobiosensor towards hydrogen peroxide is shown in equation (1) below. As an example, ten enzymatic schemes are illustrated. It can be seen than hydrogen peroxide is a by-product of the enzymatic reaction in equations (2) through (6).
The response of the individual nine elements of the matrix nanobiosensor towards hydrogen peroxide is shown in
Enzymatic schemes illustrated in equations (7) to (10) do not release hydrogen peroxide as a result of biochemical reaction, but the analytes can be detected by monitoring other products namely dehydroascorbic acid (ascorbic oxidase −7), glutamate (L-glutamic dehydrogenase −8), CO2 (formate dehydrogenase −9), quinone (polyphenol oxidase −10). This invention is not limited to the ten enzymes illustrated in the reaction schemes or in Table 1, but any redox active enzyme systems can be implemented. As an example, the cyclic voltammogram of the polymerization of aniline (0.1 M in 0.2 M H2SO4) in situ with ascorbic acid (equation (7)) onto the carbon nanotube electrode is shown in
Similar results were obtained for other enzymatic systems. The matrix nanobiosensor did not have any interference from consecutive sensor elements, though different enzymes are immobilized onto nine individual elements.
Stability of the Matrix Nanobiosensor:
The matrix nanobiosensor array was stable over a number of assays (over hundred assays), the lifetime of the sensor is a function of the activities of the enzyme. The conducting polymer matrix in the nanobiosensor provides a good stability for the enzymes in the nanotube matrix. The specific enzyme stability based on its biochemical activity is given in Table 2. Further, the enzyme stabilization can extend the lifetime of the sensors.
Matrix Nanobiosensor for the Detection of Toxic Gases:
Carbon Monoxide (CO) Sensor:
The working electrode is composed of a nanostructured platinum material namely platinum nanoparticles or carbon nanotubes electroplated with platinum nanoparticles. The main reason for the employment of platinum as the working electrode is its known catalytic oxidation of carbon monoxide. The coating of the platinum nanoparticles onto the carbon nanotubes increases the surface catalytic activity of the working electrode towards CO yielding a higher sensitivity. The counter electrode is composed of a metal (e.g., platinum, gold, etc.) and the reference electrode (e.g., Ag/AgCl). The electrolyte constitutes a strong acidic electrolyte (e.g., M H2SO4), and the sensor is enclosed in a hydrophilic semi-permeable membrane.
The electrochemical reaction involving the detection of carbon monoxide using the sensor is,
Reaction at the sensing electrode: CO+H2O →CO2+2H++2e−
The cyclic voltammogram of the oxidation of CO at platinum electrodes using the sensor is shown in
The embodiments discussed above describe the fabrication of a nine element matrix for the development of nanobiosensors. The previous design electronics incorporated the individual driving of each sensor element along with the reference and counter electrodes. Though the design is a good development over the single element biosensor, there may be some difficulty extending this design for the development of n×n sensor elements. The previous design also incorporated a planar structure, wherein the reference, counter and working electrodes are in a silicon chip oriented on the X-Y plane. The nanobiosensor can be extended to detect hundreds of analytes if the biosensor substrate is linear. There is a requirement of an optimized design and electronic driving to extend the diversity of the nanobiosensors.
The following embodiments provide an alternative design to the nanobiosensors. Disclosed are the following:
1) A linear design approach for the three electrode system (working, counter, reference electrodes).
2) The specific placement of the reference electrode in close proximity of the working electrode in a single element and a matrix array form.
3) The design of a semi-permeable, hydrophobic membrane on the area of the counter electrode, and design of the counter electrode in close proximity to the reference and working electrode in the electrolyte separate from the membrane. This is of high significance in the development of electrochemical gas sensors.
4) Development of miniaturized electronics which enable the driving of the linear and matrix array elements. The sensor electronics enable cyclic voltammetric and chroamperometric measurements in the sensor without the standard laboratory based potentiostat.
5) Design of an active matrix (analogous to the active matrix in liquid crystal displays) for the nanobiosensor application, which can enable the development of n×n sensor elements in a compact area. This invention is the first reported for the development of active matrix systems for the electrochemical (three electrode) systems. The electronics developed for the active matrix employs a shift register and can drive all the sensor elements in the active matrix.
Electrochemical sensors with three electrode systems (working, counter and reference electrodes) operate in an electrolyte coupled with an external potentiostat (see
U.S. Pat. No. 6,656,712 describes the attachment of proteins to carbon nanotubes by incubation, without stirring. The biological macromolecule in solution is attached to the carbon nanotubes closed at their ends, under suitable temperature and pH conditions. The present invention uses an approach for the attachment of macromolecules, enzymes, proteins, antibodies, aptamers, nucleic acids, antigens, DNA, aptamers, ribozomes that includes electropolymerization with a conducting polymer matrix. An array of such sensors can be carried out within a few minutes and gives a stable framework for the electrochemical/biochemical reactions. The present invention also provides an efficient method of detection of both gaseous and liquid analytes by the use of a hydrophobic, semi-permeable membrane. The electrolyte can be wet (liquid phase) or dry (nafion, nanostructured silica, hydrogels and others) for the detection of chemical, biological warfare agents, gas detection, metabolic monitoring and other applications.
Linear Array Nanobiosensor:
A design of a linear nanobiosensor in accordance with an embodiment of the present invention is shown in
Active Matrix Array Nanobiosensor:
Active matrix circuits have been previously employed in liquid crystal displays (Azuma, Seiichiro, “Fabrication of Thin-Film Transistor for Active-Matrix Liquid-Crystal Display,” Patent: JP 2003100639, 2003; Hebiguchi, Hiroyuki, “Active Matrix Type LCD In Which a Pixel Electrodes Width Along a Scanning Line is Three Times Its Data Line Side Width,” U.S. Pat. No. 6,249,326, 2001). The effectiveness of the matrix nanobiosensor can be enhanced by employing a row-column addressable array which enables the development of an n×n matrix that can be fabricated in a cost effective and miniaturized fashion.
The active working electrode components should incorporate the reference and the counter electrodes (see
Drive Electronics:
The drive electronics for the matrix array nanobiosensor is shown in
Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.
The present application claims priority to U.S. Provisional Patent Application Ser. Nos. 60/529,683 and 60/531,819, which are hereby incorporated by reference herein. The present application is a continuation-in-part application of U.S. patent application Ser. No. 10/952,669, which is hereby incorporated by reference herein.
Number | Date | Country | |
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60529683 | Dec 2003 | US | |
60531819 | Dec 2003 | US |
Number | Date | Country | |
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Parent | 10952669 | Sep 2004 | US |
Child | 11011645 | Dec 2004 | US |