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Surface plasmon resonance (SPR) technology is an optical detection technique that eliminates the need for labeling the analyte. It enables real-time and dynamic monitoring of quantitative binding affinity, kinetics, and thermodynamics. This high-throughput capacity is highly sensitive and reproducible, allowing for the measurement of various open rates, off rates, and affinity. Additionally, the small sample quantity required further enhances the utility of this method1,2. The fast response biomolecular detection method3, which monitors the affinity binding between biomolecules, has emerged as a prominent research area.
SPR technology has various applications in the field of drug research and development4. One of its uses is in discovering the structural basis of specific drug targets. It can also be employed to identify the active ingredients of Chinese herbs that possess significant pharmacological activities and study their mechanisms for drug screening and verification. Gassner et al. have established a linear dose-response curve for bispecific antibodies through SPR determination, which allows for concentration analysis and quality control5. Additionally, SPR can be utilized for conducting clinical immunogenicity tests in pharmacopeia and vaccine development6.
One area where it can be utilized is in the detection of pesticide residues, veterinary drug residue, illegal additives, pathogenic bacteria, and heavy metals7,8,9,10 in agricultural products and food safety testing. By using SPR technology, the accuracy and efficiency of these tests can be improved.
Another area where SPR technology can be applied is in the rapid detection of toxins and antibiotics. This technology allows for the attachment of viral antibodies, small molecule compounds, and aptamers to the SPR biosensor chip. The SPR biosensor chip then detects different concentrations of viral RNA as the analyte11. This method has been used successfully in the rapid detection of viruses such as H5N1, H7N9 avian influenza virus, and novel coronavirus12,13,14. In addition to these applications, SPR technology is also useful in proteomics, drug screening, real-time detection of related pharmacokinetics, and the study of virus and pathogenic proteins and receptors15,16,17,18. It is particularly suitable for scientific research and teaching experiments in universities and research institutes and is a valuable tool in various scientific and research settings.
The principle of SPR is the collective oscillatory motion of free electrons at the interface between a metal film and dielectric, caused by incident light waves19. It is essentially the resonance between the evanescent wave and the plasma wave on the metal surface20. When light transitions from a photodense medium to a photophobic medium, total reflection occurs under certain conditions. From the perspective of wave optics, when the incident light reaches the interface, it does not immediately generate reflected light. Instead, it first passes through the optically phobic medium at a depth of approximately one wavelength. It then flows along the interface for about half a wavelength before returning to the optically dense medium. This wave passing through the optically phobic medium is referred to as an evasive wave, as long as the total energy of the light remains constant. Since metal contains free electron gas, it can be regarded as plasma. The incident light excites the longitudinal vibration of the electron gas, leading to the generation of a charge density wave along the metal-dielectric interface, known as a surface plasma wave. This resonance propagates in the form of exponential attenuation in both media. Consequently, the energy of the reflected light is significantly reduced. The corresponding incidence angle at which the reflected light completely disappears is known as the resonance angle21. SPR is highly sensitive to the refractive index of the medium adhering to the metal film surface20. The SPR angle varies with the refractive index of the metal film surface, with the refractive index change being primarily proportional to the molecular mass of the metal film surface22. Any changes in the properties of the surface medium or the amount of adhesion will result in different resonance angles. Thus, the molecular interaction can be analyzed by examining the changes in the resonance angle.
This non-destructive, label-free, real-time optical SPR analysis, based on the above principles, is suitable for research in various fields. Therefore, we demonstrated the angular displacement of the SPR curve and experimental results by multi-cycle analysis, taking the combination of quercetin and calycosin with KCNJ2 recombinant protein as an example.