Antigen Monolayer Electrode May Lead To Reusable Immunosensors

MICHAEL FREEMANTLE. Chem. Eng. News , 1994, 72 (44), pp 16–17. DOI: 10.1021/cen-v072n044.p016. Publication Date: October 31, 1994. Copyright ...
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SCIENCE/TECHNOLOGY

Antigen Monolayer Electrode May Lead To Reusable Immunosensors • Multicycle device uses isomerizable antigen to overcome antibody-antigen interactions that have limited other sensors cientists in Israel have construct­ ed a reversible multicycle sensing device that opens the way for the development of reusable amperometric immunosensors. The device is a modi­ fied electrode with a self-assembled an­ tigen monolayer that can be regenerat­ ed by irradiation with light. An amperometric immunosensor is a biosensor that detects a redox change re­ sulting from antigen-antibody binding. A typical sensor is based on an electro­ chemical cell that has a working elec­ trode made of a noble metal, such as gold, with an antigen or an antibody im­ mobilized on the surface. The new reversible electrode has been developed from a single-cycle immu­ nosensor by chemistry professor Itamar Willner, graduate student Ron Blonder, and researcher Arie Dagan at the Insti­ tute of Chemistry and Farkas Center for Light-Induced Processes, Hebrew Uni­ versity, Jerusalem. The single-cycle de­ vice they base their work on utilizes a

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self-assembled monolayer of dinitrophenyl (DNP) antigen on gold. The key development by Willner and his coworkers is use of a photoisomerizable DNP antigen to overcome the strong antigen-antibody interactions that have limited immunosensors to singlecycle devices. "We have developed the first example of the use of an antigen that includes a photoisomerizable com­ ponent/' says Willner. "We then attach the antibody, make a measurement, and then by a two-step photoisomerization process, regenerate the antigen." An antigen is a foreign macromolecule such as a nucleic acid, polysaccha­ ride, or protein that stimulates antibody formation in an animal. The antibody molecule binds at a site on the antigen known as the determinant. A small for­ eign molecule that elicits an antibody re­ sponse when attached to a macromolecule is called the haptenic determinant. The small foreign molecule by itself is known as a hapten. DNP is commonly used as a hapten in experimental immu­ nology since it is particularly effective in stimulating an antibody response. Much of current immunosensor re­ search is directed at the development of low-cost single-cycle disposable de­ vices. "Disposable biosensor devices require production of replaceable de­ tector modules," explains H. Peter Ben-

netto, senior lecturer in physical chem­ istry at King's College, University of London. "An attractive alternative is the reusable sensor, in which the detec­ tion method may depend on displace­ ment of bound material from antibod­ ies, which then need to be loaded up again to work a second time." The Israeli team approaches this at­ tractive alternative by conversion of a single-cycle sensor to a reusable one by use of a reversible process [/. Am. Chem. Soc, 116, 9365 (1994)]. "The con­ version of single-cycle immunosensors to multicycle devices is expected to provide a scientific and technological breakthrough in biosensor technolo­ gy," the Israeli team suggests. Bennetto, whose group is currently working on development of immu­ nosensors for environmental monitor­ ing, agrees. "Cracking the problem of multiple use will be a major advance in immunosensor development," he says. Strong antigen-antibody interactions until now have limited the applicabili­ ty of antigen or antibody sensing sur­ faces to single-cycle devices. "The load­ ing of antibodies or antigens for repeat­ ed use is not easy," says Bennetto. "Many detection methods depend on displacement of one antigen, which goes to a further detection stage, by the analyte antigen, which may be very

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strongly bound. It is then difficult to reverse this in a simple way." The Israeli team has overcome this problem of strong binding between antigen and antibody by using photoisomerizable DNP spiropyran as the antigen monolayer. Irradiation of the monolayer in two steps reversibly isomerizes the spiropyran. In one photoisomeric state, the DNP spiropyran antigen recognizes the DNP antibody, but in the other state it does not. The antigen electrode, when bound to the antibody, is irradiated with light with wavelengths of 360 to 380 nm. This converts the active DNP spiropyran antigen to an isomer that has no affinity for the DNP antibody. The antigen therefore releases the antibody, which is washed off the electrode. Subsequent irradiation of the electrode at a wavelength greater than 495 nm restores the active antigen monolayer electrode. The immunosensor developed by Willner and colleagues is an electrochemical cell with the antigen monolayer gold electrode and an electrolyte solution containing K4Fe(CN)6 as a redox probe. The electrochemical cell also includes a platinum secondary electrode and a Ag/AgCl reference electrode. Interaction of the electrode with the DNP antibody results in the antibody binding to the antigen monolayer of the electrode. In this state, the electrode is insulated from the soluble redox probe and the amperometric response—the current through the device—decreases. The extent of insulation is controlled by the antibody concentration and the incubation time of the electrode with the antibody. Following irradiation and rinsing of the electrode, a high amperometric response is obtained, indicating removal of the insulation and therefore of the antibody. Addition of the DNP antibody at this stage does not alter the response. This shows that the monolayer is inactive in this photoisomeric state. The electrode is then irradiated for a second time to restore the antigen to its active isomeric state. Addition of the DNP antibody now results in a low amperometric signal indicating insulation and therefore binding of the antibody to the electrode. Prolonged irradiation has an adverse effect on the cyclic activity of the electrode, presumably because of partial decomposition of the antigen monolayer. Michael Freemantle

Superconductor tailored for greater stability Researchers at the University of Texas, Austin, have discovered how to dramatically increase the stability of an important high-temperature superconductor, perhaps leading to its more rapid application in thin-film devices. The cuprate superconductors that have emerged as technological contenders in the past eight years have been plagued by a tendency to degrade chemically when exposed to water, acids, and carbon dioxide. This is especially true for yttrium-barium-copper oxide (YBa2Cu307), which is the preferred material for thin-film applications. The chemical literature contains some 300 papers on the chemical corrosion of high-temperature superconductors, notes John T. McDevitt, an assistant professor of chemistry at UT Austin. His own group has helped elucidate what happens when these materials are exposed to water and other reactants. And now, using what he calls "chemical detective work/7 McDevitt and his coworkers have found a simple solution to the problem. The key to making the superconductor less reactive, McDevitt explains, is to relieve the lattice strain that exists in YBa2Cu307, which is sometimes abbreviated YBCO. This material, which becomes superconducting at about 93 K, consists of layers of yttrium cations, barium oxide, and copper oxide. Basically, McDevitt says, a mismatch of the Ba-O and some of the Cu-O bond lengths between layers can lead to internal stresses that make reaction with protons or water molecules much more favorable. Those stresses can be alleviated by making versions of YBCO that contain cationic substitutions. McDevitt and coworkers find that substituting Ca2+ for about one third of the Y3+ and substituting La3+ for about one fifth of the Ba2+ in YBCO reduces the bond-length disparities while maintaining the "electronic bookkeeping" that is essential for preserving the superconductive properties. The resulting Y-Ca-Ba-La-Cu-O materials superconduct at slightly lower temperatures (about 10 K) than YBCO. But their corrosion resistance is increased markedly. McDevitt and colleagues compared the reactivity of YBCO and its chemically tailored varieties by exposing them to water. As they reported a few weeks ago

[/. Am. Chem. Soc., 116, 9389 (1994)], a YBCO pellet becomes completely coated with BaCOs crystallites (from atmospheric C0 2 ) after soaking in water for two days at 25 °C, indicating significant decomposition. By contrast, Y-Ca-Ba-LaCu-O pellets show almost no reaction after soaking in water for one month. One of the substituted materials survived more than 100 times longer than unsubstituted YBCO, the researchers note. They also compared the reactivity of thin films of these superconductors, as grown by laser ablation. YBCO films exposed to water vapor at 75 °C degraded rapidly in the course of two hours. On the other hand, the Y-Ca-BaLa-Cu-O film sample "showed very lit-

Scanning electron micrographs show (top) a pellet of YBa2Cu30694 before conosion, (middle) the same sample after exposure to water at25°C for two days, and (bottom) a pellet of corrosion-resistant Y06Ca0ABa16La0ACu3O696 after soaking in water for 30 days. OCTOBER 31,1994 C&EN

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