Biacore biosensors

Samsonova, J.V., N.A. Uskova, A.N. Andresyuk, et al. 2004. Biacore biosensor immunoassay for 4-nonylphenols Assay optimization and applicability for shellfish analysis. Chemosphere 57 975-985. 

Malmborg AC, Duenas M, Ohlin M, Soderlind E, Borrebaeck C, Selection of binders from phage displayed antibody libraries using the BIAcore biosensor, J. Immunol. Meth., 198 51-57, 1996. 

The detection system utilized in commercially available Biacore biosensors (Biacore, Sweden) is also based on SPR, an optical phenomenon that arises when... 

Keywords Biacore Biosensors Immobilization and surface chemistry Protein chips Protein interaction analysis Surface plasmon resonance... 

Samsanova J. V., Uskova N. A., Andresyuk A. N., Franek M., and Elliott C. T., Biacore biosensor immunoassay for 4-nonyphenols assay optimization and applicability for shellfish analyses, Chemosphere, 57(8), 975-985, 2004. 

Figure 7.9. Schematic diagram of a surface plasmon resonance biosensor. One of the binding partners is immobilized on the sensor surface. With the BIACORE instrument, the soluble molecule is allowed to flow over the immobilized molecule. Binding of the soluble molecule results in a change in the refractive index of the solvent near the surface of the sensor chip. The magnitude of the shift in refractive index is related quantitatively to the amount of the soluble molecule that is bound.

New developments in immobilization surfaces have lead to the use of SPR biosensors to monitor protein interactions with lipid surfaces and membrane-associated proteins. Commercially available (BIACORE) hydrophobic and lipophilic sensor surfaces have been designed to create stable membrane surfaces. It has been shown that the hydrophobic sensor surface can be used to form a lipid monolayer (Evans and MacKenzie, 1999). This monolayer surface can be used to monitor protein-lipid interactions. For example, a biosensor was used to examine binding of Src homology 2 domain to phosphoinositides within phospholipid bilayers (Surdo et al., 1999). In addition, a lipophilic sensor surface can be used to capture liposomes and form a lipid bilayer resembling a biological membrane. 

The results summarized above were obtained by using fluorescence based assays employing phospholipid vesicles and fluorescent labeled lipopeptides. Recently, surface plasmon resonance (SPR) was developed as new a technique for the study of membrane association of lipidated peptides. Thus, artificial membranes on the surface of biosensors offered new tools for the study of lipopeptides. In SPR (surface plasmon resonance) systemsI713bl changes of the refractive index (RI) in the proximity of the sensor layer are monitored. In a commercial BIAcore system1341 the resonance signal is proportional to the mass of macromolecules bound to the membrane and allows analysis with a time resolution of seconds. Vesicles of defined size distribution were prepared from mixtures of lipids and biotinylated lipopeptides by extruder technique and fused with a alkane thiol surface of a hydrophobic SPR sensor. 

Pharmacia Biosensor AB, Uppsala, Sweden BIAcore Immunologic surface plasmon resonance Biomoiecular interactions... 

Very few immunosensors are commercially available. The commercial immunosensors are either the detector or bioanalyzer types. The PZ 106 immunosensor from Universal Sensors Inc. (New Orleans, LA) has been used as a detector to measure antibody-antigen reaction. Ohmicron (Newtown, PA) developed a series of pesticide immuno-bioanalyzers that have been used in field tests. Pharmacia Biosensor USA (Piscataway, NJ) recently introduced BIAcore immunodetection system. A combination of a unique flow injection device and surface plasmon resonance (SPR) detection technique provides a real time analysis. A carboxylmethyldextran layer added to plasmon generating gold film is a hydrophobic, activatable, and flexible polymer that provides high antibody and low non-specific bindings. System demonstration at the Institute of Food Technologists (IFT) 1994 meeting in Atlanta drew attention of food scientists. It should easily be adapted for food protein characterization. 

The surface matrix of a carboxymethylated sensor chip CMS (Pharmacia Biosensor, Uppsala, Sweden) was activated by injection of 35 pL of 0.05 M N-hydroxy-succinimide (NHS)/0.2 M N-ethyl-N (dimethylaminopropyl)carbodiimide (EDC). The BIAcore IFC forms four parallel flow cells on the sensor chip. Three of them were derivatized with 40 mM cystamin-dihydrochloride/ethanolamine in the ratios... 

Protease assay CMV protease activity was measured using the surface plasmon resonance technology of the BIAcore instrument (Pharmacia Biosensor). Briefly, this instrument was used to quantitate residual uncleaved biotinylated... 

The first commercial SPR was launched hy Pharmacia Biosensor AB (presently Swedish BIAcore AB) in 1990. Since then, the device has been refined and now BIAcore [37] offers several models (BIACORE 3000, BIACORE 2000, BIACORE 1000, BIACORE X, J, Q, S51, and C models). The biosensors of BIACORE 1000 to 3000 are fully automated instruments, with a disposable sensor chip, an optical detection unit, an integrated micro-fiuidic cartridge, an autosampler, method programming and control software. Less expensive manually controlled alternatives cU e the BIACORE x and BiacoreQuant . 

BIAcore (BIAcore AB), www.biacore.com Jandratek, Leica, Ibis, Autolab, Texas Instruments (Spreeta), DKTOA, Analytical Microsystems (Biosuplar), NLE (SPR670), HTS Biosystems, Applied Biosystems, GWC, Sensia S.L., Vir Biosensor ASI (Artiflcial Sensing Instrument)... 

Biosensors based on optical fibers as transduction element have been recently reviewed by Wolfbeis [97]. Optical biosensors based on miniattaized SPR or on evanescent field monitoring are not as often found in miniaturized biosensors, especially in comparison to miniaturized electrochemical transducers, yet. Two examples will be given here a miniaturized SPR biosensor by Cullen and co-workers [98] and an evanescent based microchip biosensor by Borchers and co-workers [99]. The best-known SPR biosensor is the BIAcore device from Pharmacia Company, Sweden. It has been on the market for over a decade and is routinely used for hybridization kinetic analyses, specificity analyses, etc. Cullen and co-workers have incorporated a commercially available miniaturized SPR transducer into a field analyzer and developed a competition and inhibition assay for an estrogenic compound in water samples that function as endocrine disrupting compounds (EDCs). 

FIA as such is available from a few different suppliers. Reactors filled with immobilized enzymes are also commercially available. More sophisticated equipment based on the FIA concept is the BIACORE from Pharmacia Biosensor. Here a gold surface covered with a carboxydextran is used as reactor for binding reactions. The reading is done by means of evanescent wave technology [63]. The BIACORE illustrates one step in the direction of miniaturization of the analytical unit. As the understanding of the chemistry and the analytical protocol becomes available, much may be gained by miniaturization [64]. 

Biosensor instruments such as Biacore (General Electric) exploit the sensitivity of a surface plasmon resonance response to the mass localised near the surface of a sensor chip. Various approaches can be used for kinases. Inhibition in solution assays involve immobilisation of a target definition compound (TDQ on the sensor surface.13,30 A buffer containing the kinase is flowed over the surface so that the protein is able to bind to the immobilised TDC, giving a signal. When test compounds are included in the buffer, they can compete for the TDC-kinase interaction, allowing estimation of Kd. 

This optical design has been further advanced by Biacore (Pharmacia Biosensors AB since 1996, Biacore AB) and resulted in a family of commercial SPR sensors [20-22] offering high performance (resolution down to 1x10 RIU) and multiple sensing channels (up to four) for simultaneous measurements. 

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