Surface plasmon resonance

Surface Plasmon Resonance (SPR)

Otto-schema

SPR-schema

SPR analysis of purified G6 scFv

SPR-adsorption-data

SPR-curve

Surface Plasmon Resonance (SPR) is a powerful and widely used technique for studying the interactions between biomolecules in real-time, without the need for labeling the interacting partners. This method leverages the phenomenon of surface plasmons, which are coherent delocalized electron oscillations that exist at the interface between negative and positive permittivity material, typically at the interface between a metal and a dielectric medium. SPR is particularly useful in the fields of biochemistry, molecular biology, and chemistry for measuring the affinity and kinetics of interactions between various biomolecules, including proteins, nucleic acids, and lipids.

Principles of Surface Plasmon Resonance[edit | edit source]

The principle behind SPR is based on the excitation of surface plasmons by light. When polarized light hits a metal film under total internal reflection conditions, it can excite surface plasmons at the metal-dielectric interface. This interaction leads to a reduction in the intensity of the reflected light at a specific angle, known as the resonance angle. The resonance angle changes when biomolecules bind to the metal surface, altering the refractive index at the interface. By monitoring these changes, SPR can be used to detect and quantify molecular interactions in real-time.

Components of an SPR Instrument[edit | edit source]

An SPR instrument typically consists of a light source, a metal-coated sensor chip, a prism or grating for coupling light into the surface plasmons, a detector for measuring the intensity of reflected light, and a fluidic system for introducing samples to the sensor surface. The most commonly used metal for the sensor chip is gold, due to its chemical inertness and strong surface plasmon resonance signal.

Applications of Surface Plasmon Resonance[edit | edit source]

SPR is used in a wide range of applications, including:

• Drug Discovery: For screening potential drug candidates by measuring their binding affinity to target proteins.
• Protein-Protein Interactions: For studying the dynamics and mechanisms of interactions between proteins.
• Nucleic Acid-Protein Interactions: For investigating the binding of proteins to DNA or RNA, which is crucial for understanding gene regulation.
• Biosensors: For developing sensitive detection systems for pathogens, toxins, and other analytes.

Advantages and Limitations[edit | edit source]

The main advantages of SPR include its ability to measure interactions in real-time, its high sensitivity, and the fact that it does not require labeling of the interacting molecules. However, SPR also has some limitations, such as its sensitivity to temperature fluctuations and the need for relatively high concentrations of analyte in some cases.

Conclusion[edit | edit source]

Surface Plasmon Resonance has revolutionized the way scientists study molecular interactions, offering a label-free, real-time method for analyzing the kinetics and affinity of biomolecular interactions. Its applications in drug discovery, biosensor development, and basic research continue to expand, making it an indispensable tool in the modern biochemical and biophysical toolkit.

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