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Surface plasmon resonance

Surface plasmon resonance (SPR) is a label-free optical technique that exploits the collective oscillation of electrons at a to detect biomolecular interactions in by measuring changes near the surface. This phenomenon arises when p-polarized light excites surface plasmons, producing an evanescent that penetrates approximately 200 nm into the medium, enabling sensitive detection of adsorption or binding events without the need for fluorescent labels or other modifications. The physical basis of SPR dates back to its first observation in 1902 by R.W. Wood, who noted anomalous diffraction patterns in light reflected from ruled gratings, later interpreted as plasmonic effects by Lord Rayleigh in 1907 and U. in 1941. Practical methods for exciting surface plasmons were developed in 1968 through independent work by A. Otto and by E. Kretschmann and H. Raether, using attenuated total reflection in prism-coupled configurations. The adaptation of SPR for biosensing began in 1983 with demonstrations by B. Liedberg and colleagues, who applied it to monitor antibody-antigen interactions, paving the way for commercial instruments like the Biacore system introduced in 1990. In typical SPR setups, such as the Kretschmann configuration, a thin gold film (around 50 nm thick) is deposited on a high-refractive-index prism, and monochromatic light (e.g., from a 650 nm laser) is directed at varying angles of incidence. At the resonance angle (θ_SPR), energy couples from the incident light to the surface plasmons via the evanescent wave, causing a sharp dip in reflected intensity; this angle shifts proportionally with local refractive index changes (approximately 8.7° per 0.1 unit increase), allowing quantification of surface-bound mass down to 1 pg/mm². Alternative configurations include grating-based or waveguide-coupled systems, while SPR imaging extends the technique for parallel analysis of multiple interactions. SPR has become a cornerstone in biochemistry and biomedical research, enabling kinetic and of interactions such as protein-DNA , small-molecule screening, and detection, with applications in , , and clinical diagnostics. Its advantages include monitoring without sample manipulation, high sensitivity (detection limits around 10 pg/mL for analytes), and versatility across scales from small molecules to whole cells, though challenges like non-specific and instrument cost persist.

Fundamentals

Definition and Principles

Surface plasmons refer to the collective oscillations of free electrons that occur at the interface between a metal and a dielectric material. These oscillations couple with electromagnetic waves to form surface plasmon polaritons (SPPs), which propagate along the interface, or localized surface plasmons (LSPs), which are confined to subwavelength metallic nanostructures such as nanoparticles. The phenomenon was first experimentally observed in 1902 by R. W. Wood, who reported unexplained narrow dark bands in the reflection spectra of light diffracted from metal gratings. It was theoretically described in 1957 by R. H. Ritchie, who predicted the existence of surface plasma oscillations in thin metal films excited by fast electrons. Surface plasmon resonance (SPR) arises when incident light efficiently excites these surface under a specific condition, where the in-plane of the photons matches that required for the plasmon mode. This matching leads to a strong enhancement of the evanescent to the metal-dielectric , with the field intensity decaying rapidly away from the surface. The is highly sensitive to changes in the near the , enabling applications in sensing biomolecular interactions. The physical prerequisites for SPR include metals with a high of free s, such as and silver, which exhibit a negative real part of the constant in the visible and near-infrared spectral range. The interface must separate the metal from a medium with a positive constant, like air or aqueous solutions, to support the bound electron oscillations. A basic experimental setup for observing SPR, known as the Kretschmann configuration, involves a thin metal (typically 40-50 nm thick) deposited on the base of a high-refractive-index , with p-polarized incident from the prism side at a variable angle. At the resonance angle, light energy couples to the surface plasmons, resulting in a sharp minimum in the reflected intensity and excitation of enhanced evanescent fields on the sample side of the .

Theoretical Foundations

The theoretical foundations of surface plasmon resonance (SPR) lie in the electromagnetic theory of surface plasmon polaritons (SPPs), which describe the propagation of waves along a metal-dielectric where the is evanescent perpendicular to the . These modes arise from the coupling of photons to collective oscillations of free electrons in the metal, requiring a negative real part of the metal (Re(ε_m) < 0) and a positive dielectric (Re(ε_d) > 0), with |Re(ε_m)| > Re(ε_d) for bound modes; this is satisfied by noble metals like or silver in the visible range. The wave vector of the SPP, k_sp, which determines its propagation characteristics, is given by the dispersion relation derived from solving for transverse magnetic (TM) polarized waves at the : k_\text{sp} = \frac{\omega}{c} \sqrt{\frac{\varepsilon_\text{m} \varepsilon_\text{d}}{\varepsilon_\text{m} + \varepsilon_\text{d}}} where ω is the angular frequency, c is the speed of light in vacuum, and the real part of k_sp exceeds that of free-space light, making direct excitation impossible without momentum matching. This relation, first theoretically predicted for electron energy loss spectroscopy, shows that SPPs are non-radiative and confined, with dispersion approaching the light line at low frequencies and asymptotically nearing the surface plasmon frequency ω_sp = ω_p / √(1 + ε_d) (where ω_p is the bulk plasma frequency) at high frequencies for non-retarded limits. To excite SPPs optically in configurations like the Kretschmann setup, momentum matching is achieved via a high-refractive-index prism, where the parallel component of the incident light's wave vector equals Re[k_sp]. The resonance angle θ_res for prism coupling satisfies: \theta_\text{res} = \arcsin\left( \frac{c}{\omega} \frac{\text{Re}[k_\text{sp}]}{n_\text{p}} \right) with n_p as the prism refractive index (typically >1.5). At resonance, a sharp dip in reflectivity occurs due to energy transfer to the SPP, enabling sensitive detection of refractive index changes near the surface. Angular interrogation mode fixes the wavelength and scans θ to find θ_res, while wavelength interrogation mode fixes θ and scans λ to locate the resonant wavelength, both exploiting the dispersion's sensitivity to ε_d variations. The associated with the extends into both the metal and , but the δ in the side—defined as the 1/ distance of the (such that |E|^2 to 1/ at 2δ)—is given by \delta = \left[ k_\text{sp}^2 - \varepsilon_\text{d} \left( \frac{\omega}{c} \right)^2 \right]^{-1/2}, where typical values are 100–300 nm for visible light, confining to surface-bound analytes. The sharpness, quantified by the (FWHM) of the reflectivity dip, is influenced by metal film thickness (optimal ~40–50 nm for to minimize radiative to the ) and the environment: higher ε_d broadens the via increased extension, while low-loss s sharpen it. propagation is limited by losses, primarily ohmic from electron-phonon in the metal (imaginary part of ε_m) and, to a lesser extent, in thicker films or structured surfaces.

Experimental Configurations

Optical Excitation Methods

Surface plasmon resonance (SPR) requires optical excitation methods that provide the necessary momentum to couple incident photons to surface plasmons at a metal-dielectric , typically through evanescent fields or . These methods enable the generation of by satisfying the wavevector matching condition, allowing non-radiative surface plasmons to be excited by visible or near-infrared . The choice of excitation technique influences the system's sensitivity, compactness, and suitability for integration, with prism-based configurations dominating early developments due to their simplicity and efficiency. The Kretschmann configuration, introduced in 1968, is the most widely used prism-based method for SPR excitation. In this setup, a thin metal film, typically 50 nm of , is deposited on the base of a high-refractive-index such as BK7 glass (n ≈ 1.52). P-polarized light is incident from within the prism at an angle greater than the for (TIR), generating an that penetrates the metal film and excites surface plasmons on the outer metal-dielectric interface. Resonance occurs at specific angles, often around 60–70° for 633 nm wavelength, where a sharp minimum in reflectivity is observed. This configuration offers high coupling efficiency and is favored for its direct integration with sensor chips, enabling robust biosensing applications. The configuration, proposed in as an alternative prism-based approach, facilitates non-contact excitation suitable for delicate or . Here, the is separated from a thin metal film on a by a thin (typically 100–500 nm air or low-index material), with light undergoing TIR at the prism- interface. The tunnels through the gap to excite plasmons on the metal surface, producing a reflectivity dip similar to the Kretschmann setup but with the metal film isolated from the prism. This method is advantageous for avoiding direct contact, which can prevent contamination or , though it requires precise control for optimal and is less common in commercial systems due to alignment challenges. Grating coupling provides momentum compensation through periodic surface structures etched or embossed into the metal film, eliminating the need for a . Incident diffracts off the , with the \mathbf{k}_g = \frac{2\pi}{\Lambda} \hat{x} (where \Lambda is the period, typically 400–800 for visible ) adding or subtracting from the incident wavevector to match the surface plasmon . is achieved when k_{sp} = k_0 (\sin \theta \pm m \frac{2\pi}{\Lambda}), with m as the diffraction , allowing at or . This enables compact, planar sensors and is particularly useful for integrated , though it suffers from lower coupling efficiency compared to methods due to losses. Waveguide-based excitation integrates SPR into optical waveguides, such as planar or structures coated with metal films, for miniaturized and distributed sensing. Light propagates in the , and its evanescent couples to surface plasmons at the metal cladding via overlap, often enhanced by additional layers to tune the effective . Configurations like coupled waveguide-SPR (CWSPR) use a adjacent to the metal film, achieving through leaky or guided that provide precise matching. This approach supports high-throughput imaging and on-chip integration, with applications in devices, but requires careful engineering to minimize propagation losses. SPR systems commonly employ either angular or wavelength scanning for resonance interrogation. In angular scanning, a fixed wavelength (e.g., 633–785 nm laser) illuminates the interface while the incident angle is varied, yielding high sensitivity (up to 10^{-6} RIU) and sharp resonance dips due to the narrow angular width, though it often involves mechanical rotation for bulkier setups. Wavelength scanning uses a fixed angle with broadband illumination (e.g., white light or tunable source), monitoring the wavelength shift of the minimum reflectivity; it offers compactness without moving parts and easier multiplexing, but typically provides lower resolution (broader dips) and reduced sensitivity compared to angular methods. The trade-offs guide selection: angular for precision kinetics, wavelength for portable arrays. The development of optical excitation methods culminated in commercial SPR systems in the , with Pharmacia Biosensor AB launching the first Biacore instrument in 1990 based on the Kretschmann configuration. This system automated angular interrogation for biomolecular analysis, marking the transition from laboratory prototypes to widespread use in research and industry. Subsequent innovations, including and integrations, have expanded SPR's versatility while building on these foundational techniques.

Sensor Platform Designs

Sensor platforms for surface plasmon resonance (SPR) typically employ chips made from a substrate coated with a thin layer of , usually 50 nm thick, to support the evanescent wave propagation necessary for plasmon excitation. This layer is often overlaid with a carboxymethyl (CMD) matrix, a that provides a hydrophilic for biomolecule immobilization, minimizes non-specific , and enhances by allowing three-dimensional ligand presentation. The CMD layer, with a typical thickness of 100 nm, is covalently attached to the surface via a linker, enabling stable and reproducible . Flow cell designs in SPR systems facilitate controlled delivery of analytes to the surface, commonly using microfluidic channels etched or molded into materials like (PDMS) or integrated into the chip assembly. These channels ensure , reducing sample consumption to microliter volumes per measurement and maintaining consistent contact between the sample and the functionalized surface. Multi-channel arrays, such as those with 4 to 50 parallel flow cells, enable by simultaneously multiple interactions, often with independent fluidic paths to avoid cross-contamination. Surface functionalization of SPR chips begins with the formation of self-assembled monolayers (SAMs) of alkanethiols on the gold surface, creating a stable, oriented layer that serves as a foundation for further modifications. These SAMs, typically composed of thiols with terminal carboxyl or hydroxyl groups, prevent direct exposure of biomolecules to the metal while providing reactive sites for attachment. Ligand immobilization is commonly achieved through NHS/EDC chemistry, where N-hydroxysuccinimide (NHS) and 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) activate carboxyl groups on the CMD matrix or SAMs, forming reactive esters that covalently bind amine groups on the ligand, yielding immobilization levels up to 1000-5000 response units depending on the protein size. SPR platforms incorporate and sample to enable differential measurements, subtracting non-specific effects like bulk changes or temperature drifts from the signal. In multi-channel systems, one is dedicated as a , often with a blank or underivatized surface, while adjacent sample contain the immobilized ; the software processes the difference to yield specific interaction . This referencing strategy improves accuracy, particularly for low-affinity interactions where signal-to-noise ratios are critical. Miniaturization trends in SPR sensor platforms focus on CMOS-compatible chips and lab-on-chip integrations to enable point-of-care applications and reduced footprint. processes allow fabrication of gold-patterned silicon substrates with integrated , supporting on-chip detection without bulky optics and achieving sensitivities comparable to benchtop systems. Lab-on-chip designs combine SPR sensing with elements, such as mixing chambers, in a single disposable cartridge, facilitating portable diagnostics with sample volumes below 1 μL. Commercial examples include the Biacore systems, first introduced in 1990 by Biosensor AB (now Cytiva), which popularized SPR for biomolecular analysis with integrated flow cells and CMD-based chips supporting up to four channels. More recently, the OpenSPR by Nicoya Lifesciences offers a compact, benchtop platform with automated single-channel operation, emphasizing affordability and ease of use for kinetics measurements in research settings.

Detection and Instrumentation

Standard Detection Techniques

Standard detection techniques in surface plasmon resonance (SPR) primarily involve monitoring shifts in the resonance condition, typically manifested as changes in the reflected light intensity, to quantify variations at the surface. The most common approach is angular interrogation, where the angle of incidence is scanned to identify the resonance angle, often using a rotating or detector coupled with photodiodes to measure reflectivity dips. This method achieves angular resolutions on the order of 0.01° in conventional setups, enabling precise tracking of resonance shifts induced by analyte binding. Photodiodes detect intensity changes at the resonance angle, providing high signal-to-noise ratios for real-time monitoring. Wavelength interrogation represents another foundational technique, employing a fixed incidence and a spectrometer to observe shifts in the . This configuration is particularly suited for compact, fiber-optic-based systems and offers sensitivities up to 8000 nm/RIU with spectral resolutions around 0.02 nm. In both angular and methods, the core hardware includes light sources like lasers or LEDs, polarizers to ensure TM-mode excitation, and detectors such as photodiodes or array spectrometers for signal acquisition. These techniques rely on the Kretschmann configuration, where evanescent waves couple to surface plasmons at a metal-dielectric interface, typically gold-coated prisms. Imaging SPR (iSPR) extends these principles to by using (CCD) cameras to capture two-dimensional reflectivity maps across the sensor surface, facilitating multiplexed detection on arrays with spot sizes down to 300 . This allows simultaneous monitoring of multiple interaction sites, such as in formats. is integral to all techniques, involving baseline subtraction to normalize initial reflectivity, drift compensation via reference channels, and (e.g., models) to extract parameters like angle or shifts. These steps mitigate environmental noise and bulk effects, enhancing accuracy. Overall, standard SPR detection achieves refractive index resolutions down to 10^{-6} RIU, corresponding to surface mass densities of approximately 1 pg/mm² for biomolecular layers, making it suitable for label-free kinetics studies. Sensitivity metrics vary with configuration but are benchmarked against commercial systems, where noise levels limit detection to angstrom-scale thickness changes.

Advanced Sensing Modalities

Advanced sensing modalities in surface plasmon resonance (SPR) extend the capabilities of conventional intensity-based detection by leveraging shifts, extended , integrations, and specialized to achieve higher , specificity, and throughput. These approaches address limitations such as , limited , and single-parameter readout, enabling applications in complex biological and . By incorporating , electrochemical modulation, and array formats, these techniques can detect refractive index changes as low as $10^{-7} refractive index units (RIU) and support parallel analysis of thousands of interactions. Phase-sensitive detection exploits the phase variation of the reflected in SPR configurations, offering enhanced compared to interrogation. In interferometric SPR setups, the shift arises from the evanescent field interaction with the , allowing for precise measurement of small perturbations. For instance, differential spectral interferometry has achieved a of $2.2 \times 10^{-7} RIU using a standard gold-coated surface, surpassing traditional methods by factors of 10 or more. This modality is particularly valuable for kinetic studies where subtle binding events must be resolved without labels. Long-range SPR (LRSPR) employs thin metal films (typically 10-20 nm thick) embedded in a low-index medium symmetric to the sensing side, resulting in coupled plasmons with reduced and . This configuration extends the penetration depth to several micrometers, compared to ~200 nm in standard SPR, facilitating the detection of larger analytes like cells or thick biofilms without signal . LRSPR maintains high sensitivity while improving , with propagation lengths exceeding 100 μm in optimized setups using materials like Cytop ( ~1.34). Such deeper probing is advantageous for in vivo-like sensing environments. Multi-parameter sensing integrates SPR with complementary techniques to extract orthogonal information, such as thickness, , and signatures, from the same . When combined with in total internal reflection mode, SPR-enhanced setups measure both amplitude and phase ellipsometric parameters (Ψ and Δ), enabling simultaneous quantification of biomolecular adsorption kinetics and structural changes with sensitivities down to levels. Similarly, coupling SPR with detection via plasmon-waveguide resonance excitation amplifies emission signals while providing label-free data, as demonstrated in multi-channel hyperspectral systems for analyte . These approaches reduce in mixtures by correlating optical and emissive responses. Electrochemical SPR (EC-SPR) incorporates electrodes into the SPR platform to modulate the interfacial potential, dynamically tuning the through charge-induced changes at the metal-dielectric boundary. Applied potentials (e.g., -0.5 to +0.5 V) alter in the metal film or adsorbate layer, shifting the by up to several degrees and enabling real-time correlation of electrochemical currents with optical signals. This potential-modulated technique is ideal for studying redox-active biomolecules or electrocatalytic processes, with enhanced specificity for charge-sensitive interactions. Seminal implementations have integrated thin-film working electrodes directly on SPR chips for bias-free operation. High-throughput microarray SPR utilizes imaging configurations to interrogate arrays of functionalized spots, enabling simultaneous monitoring of thousands of biomolecular interactions in a label-free format. Systems based on polarization-modulated SPR imaging can resolve binding events across 1000+ spots with sub-nanomolar detection, supporting kinetic rate constants from $10^3 to $10^6 M⁻¹s⁻¹. These platforms employ microfluidic delivery for automated screening, as seen in dynamic detection schemes that track protein-protein affinities over hundreds of array elements with under 1 second per frame. Such scalability accelerates and by multiplexing interaction maps. Noise reduction techniques are essential for realizing the full potential of advanced SPR modalities, mitigating , laser instability, and bulk drifts. Lock-in amplification synchronizes detection with a modulated excitation source (e.g., at 1-10 kHz), extracting the signal while suppressing by 20-40 , thereby improving signal-to-noise ratios in phase-sensitive setups. Complementary via Peltier elements or fluidic stabilization maintains bulk index constancy to within $10^{-5} RIU, essential for long-term measurements. Multiple referencing, using adjacent non-functionalized spots, further cancels common-mode drifts through differential analysis. These methods collectively enable stable over hours with minimal wander.

Applications

Biosensing and Biomolecular Interactions

Surface plasmon resonance (SPR) has emerged as a cornerstone for label-free biosensing, enabling the direct observation of biomolecular interactions without the need for fluorescent or radioactive labels. In biosensing applications, SPR detects changes in the near a metal surface caused by the of biomolecules, providing insights into and in . This capability is particularly valuable for studying protein-protein, antibody-antigen, and receptor-ligand interactions, where traditional methods may require extensive sample preparation. Real-time monitoring of biomolecular events is achieved through SPR sensorgrams, which the SPR signal over time as s flow over an immobilized on the surface. The signal is quantified in response units (), where 1 corresponds to a change equivalent to approximately 1 pg/mm² of bound protein or a 10^{-4} degree shift in the . During the association phase, the binds to the , causing an increase in ; in the phase, flow removes unbound or weakly bound , leading to a decrease in signal. These sensorgrams allow for the extraction of kinetic parameters, such as the association rate constant (k_on) and rate constant (k_off), through to models like the Langmuir isotherm. The equilibrium (K_D), a measure of , is determined from these rates as K_D = k_off / k_on, where lower K_D values indicate stronger (e.g., nanomolar or picomolar affinities for high- antibodies). This quantitative approach has been instrumental in characterizing biomolecular affinities, with typical K_D values for -antigen pairs ranging from 10^{-7} to 10^{-10} M. SPR supports various formats for biomolecular detection. In direct assays, the target binds directly to an immobilized capture molecule, such as an on the surface, enabling simple quantification of events. Inhibition assays measure competitive , where free inhibits the between a labeled competitor and the immobilized , useful for detection. Sandwich assays enhance sensitivity by using a capture to immobilize the , followed by a secondary detection , achieving limits of detection as low as 0.29 ng/mL for (). These formats leverage SPR's sensitivity to surface mass changes, often on platforms like prism-based or grating-coupled designs. In drug discovery, SPR facilitates high-throughput screening of antibody-antigen interactions and protein-protein complexes, accelerating lead optimization. For instance, it has been used to evaluate therapeutic antibodies against tumor antigens or viral proteins, providing rapid affinity rankings without cell-based assays. Protein-protein interaction studies, such as those involving p53 and DNA, have revealed binding mechanisms critical for target validation. Despite its advantages, SPR biosensing faces limitations, including mass transport effects where analyte diffusion to the surface limits observed kinetics, potentially underestimating k_on for high-affinity interactions. Non-specific binding of biomolecules to the sensor surface can introduce noise, which is mitigated through surface blocking agents like or coatings. Commercially, SPR has played a pivotal role in vaccine development, notably for , where it enabled rapid characterization of neutralizing antibodies against the SARS-CoV-2 receptor-binding domain (). Post-2020, SPR assays quantified antibody affinities (e.g., 0.82 nM for monoclonal antibody BD-368-2) and supported vaccine efficacy testing by confirming RBD-ACE2 inhibition, contributing to accelerated approvals of mRNA and subunit .

Material and Surface Characterization

Surface plasmon resonance (SPR) has been employed since the 1980s for characterizing films and thin layers, marking an early adoption of the technique for non-biological material analysis beyond its initial optical demonstrations. Pioneering work in this era focused on interrogating evanescent wave interactions at metal-dielectric interfaces to probe film properties, laying the groundwork for quantitative surface studies. One key application of SPR in material characterization is the precise measurement of thickness, often achieved by modeling the SPR reflectivity curve with to profile layered structures. This approach enables layer-by-layer analysis with sub-nanometer resolution, typically achieving an accuracy of approximately 0.1 nm for overlayers. For instance, SPR spectroscopy using angular interrogation has been used to determine the thickness of solution-deposited nanomaterial films, even at sub-10 nm scales, by fitting experimental resonance shifts to theoretical models. SPR also facilitates the determination of refractive indices in dielectrics and polymers by analyzing shifts in the resonance angle or wavelength induced by the material's optical properties. In broadband SPR configurations, spectral interrogation allows simultaneous extraction of both thickness and refractive index for thin dielectric layers, with sensitivities reaching 10^{-4} RIU for polymer coatings. This method has been applied to characterize resins and other synthetic polymers, providing real-time insights into their optical constants without destructive testing. The of adsorption and desorption on surfaces can be monitored in using SPR, often modeled with Langmuir isotherms to describe formation and equilibrium binding. For or adsorbates on metal surfaces, the captures rate constants for association and dissociation, revealing surface coverage dynamics under varying concentrations. This approach is particularly useful for studying processes on nanostructured or coated substrates, where isotherm fitting quantifies and saturation limits. In characterization, SPR employs , such as the Maxwell-Garnett model, to analyze rough or composite films by treating them as homogeneous equivalents with averaged functions. This enables the assessment of effective in nanoparticle-embedded layers or irregular thin films, accounting for scattering and dispersion effects. Limitations of these approximations arise in highly heterogeneous systems, where full electromagnetic simulations may be needed for precise fitting of SPR data. SPR plays a vital role in quality control for coatings, such as anti-reflective layers and organic light-emitting diode () films, by verifying uniformity, thickness, and optical performance in production settings. For anti-reflective coatings, SPR detects deviations in layer profiles that could affect reflectivity minima, ensuring compliance with design specifications. In OLED manufacturing, it assesses the integrity of thin emissive and transport layers, identifying defects or inconsistencies that impact device efficiency.

Environmental and Chemical Sensing

Surface plasmon resonance (SPR) enables sensitive, label-free detection of environmental and chemical analytes, offering monitoring of pollutants in air, , and soil without extensive . This optical technique exploits changes near a metal-dielectric upon analyte binding, making it suitable for trace-level sensing in complex matrices. In chemical sensing, SPR platforms functionalized with selective ligands, such as self-assembled monolayers or aptamers, facilitate detection of heavy metals at parts-per-billion (ppb) levels. For mercury (Hg²⁺), a sensor using 1,6-hexanedithiol self-assembled monolayers achieves a detection limit of 1.0 nM (approximately 0.2 ppb), with selectivity maintained in the presence of interfering ions like Pb²⁺, Ni²⁺, Zn²⁺, and Cu²⁺. Similarly, lead (Pb²⁺) detection reaches sub-ppb sensitivity (0.14 μM) using chitosan/graphene oxide composites, enabling quantification in contaminated water samples. For pesticides, SPR immunoassays detect carbaryl at 1.38 μg/L and chlorpyrifos at 45–64 ng/L, employing antibody-based recognition for high specificity validated against HPLC-MS standards. Gas sensing with fiber-optic SPR configurations addresses volatile organic compounds (VOCs), where the sensor tip is coated with nanoparticles and metal-organic frameworks like to enhance adsorption. This setup detects acetone (limit of detection: 50 ), ethanol (30 ), and methanol (110 ) through refractive index-induced shifts of up to 9 , with fully reversible responses and recovery times under 4 minutes. Sensitivity to is low, with a 25% relative humidity change (50–75% RH) causing only a 0.5 shift, minimizing cross-interference in ambient air monitoring. For water quality monitoring, SPR imaging (SPRi) sensors provide real-time analysis of key contaminants like and pathogens. An enzyme-mediated SPRi system, using and immobilized on a chip, simultaneously detects (limit of detection: 17.8 mg/L; range: 24–780 mg/L) and (0.115 mg/L; 0.26–120 mg/L) in with minimal dilution, supporting aquaponic and optimization. Pathogen detection employs fiber-optic SPR biosensors with nano-grating structures, achieving sensitivities up to 21,276 nm/RIU for in , enabling rapid identification of bacterial contamination. Portable SPR devices for field use have advanced since 2015 through smartphone integration, leveraging device cameras and apps for and analysis. A 2021 fiber-optic long-range SPR (FO-LRSPR) , with a tunable SiO₂ sensing matrix deposited via , uses smartphone blue/red channel intensities to monitor analytes, offering portability for remote environmental assessments and limits of detection around 0.02 for model pollutants. Selectivity in these sensors is enhanced by molecularly imprinted polymers (), which create tailored cavities for specific analytes, reducing matrix effects in environmental samples. MIP-coated SPR platforms detect pollutants like bisphenol A in water through amplified signal responses, achieving improved specificity over non-imprinted controls via non-covalent interactions. This approach has been applied to pesticides and , where MIP films preconcentrate targets, boosting detection limits by factors of 2–10 while maintaining compatibility with standard SPR detection techniques. SPR-based monitoring aligns with regulatory applications, such as U.S. Environmental Protection Agency (EPA) standards for water contaminants. Field-deployed SPR sensors quantify explosives like in natural waters near the EPA action level of 2 ppb, validating performance with spiked samples to ensure compliance in remediation efforts.

Case Studies

Kinetic and Binding Analyses

In surface plasmon resonance (SPR) experiments, sensorgram analysis involves fitting the observed response units (RU) over time to kinetic models to derive association (k_on) and dissociation (k_off) rate constants. For simple interactions, the 1:1 Langmuir model is commonly applied, assuming pseudo-first-order where the immobilized (L) reacts with excess (A) to form the complex (LA): L + A ⇌ LA. The governing the is d[LA]/dt = k_on [L][A] - k_off [LA], with the integrated form for the association phase given by R(t) = R_max [A] k_on / (k_on [A] + k_off) (1 - e^{-(k_on [A] + k_off)t}), where R(t) is the response at time t, R_max is the maximum response, and [A] is the concentration. Fitting is performed using nonlinear least-squares algorithms to minimize residuals between experimental and modeled curves, enabling extraction of k_on (in M^{-1} s^{-1}) and k_off (in s^{-1}), from which the K_D = k_off / k_on is calculated. A representative example of SPR kinetic analysis is the binding of monoclonal antibodies to antigens, where association phases typically occur over seconds to minutes due to k_on values ranging from 10^5 to 10^6 M^{-1} s^{-1}, and dissociation phases extend from minutes to hours reflecting k_off values of 10^{-4} to 10^{-5} s^{-1} for high-affinity interactions (K_D ~ 10^{-9} to 10^{-10} M). In one study of prostate-specific antigen (PSA) binding to a monoclonal antibody, global fitting yielded average k_on = (4.1 ± 0.6) × 10^4 M^{-1} s^{-1} and k_off = (4.5 ± 0.6) × 10^{-5} s^{-1}, demonstrating reproducible kinetics across multiple concentrations. These time scales allow real-time monitoring of binding dynamics without labels, with the sensorgram's exponential rise and decay providing direct visualization of the interaction progression. To ensure , multi-cycle (MCK) protocols involve sequential injections of varying concentrations in separate cycles, each followed by and surface regeneration, allowing independent assessment of each curve while minimizing cumulative artifacts like baseline drift. This approach contrasts with single-cycle and is preferred for validating rate constants, as it permits statistical averaging across replicates with typically below 10% for k_on and k_off. For complex interactions, such as bivalent binding where an binds two sites sequentially, global fitting is employed to simultaneously analyze multiple sensorgrams, sharing parameters like k_on1, k_off1 for the first step and k_on2, k_off2 for the second to improve parameter identifiability and reduce . This method accounts for effects in systems like antibody-antigen pairs with cross-linking, yielding more accurate estimates than local fitting per curve. Dedicated software facilitates these analyses: BIAevaluation (from Cytiva) supports model selection, drift correction, and global fitting for Biacore systems, while enables custom kinetic modeling with emphasis on error propagation for heterogeneous or bivalent interactions. In therapeutic development, SPR has been pivotal for determining binding constants of monoclonal antibodies, as exemplified by characterization of anti-CD20 therapeutics like rituximab, where kinetic assays revealed k_on ≈ 10^5 M^{-1} s^{-1} and k_off ≈ 10^{-4} s^{-1} (K_D ≈ 1 nM), guiding optimization for enhanced efficacy in lymphoma treatment. Such analyses ensure selectivity and potency by quantifying interactions with target antigens while screening for off-target .

Thermodynamic and Structural Studies

Surface plasmon resonance (SPR) enables the determination of thermodynamic parameters for biomolecular interactions by conducting measurements at varying temperatures and applying the van't Hoff equation to the temperature dependence of the equilibrium dissociation constant K_D. The van't Hoff analysis derives changes in (\Delta H) and (\Delta S) from the and intercept of a plot of \ln K_D versus the inverse temperature, providing insights into the driving forces of binding such as enthalpic or entropic contributions. This approach is particularly valuable in fragment-based , where SPR systems integrate software for automated van't Hoff analysis to evaluate binding . For instance, in studies of protein-ligand interactions, temperature-dependent SPR data have revealed enthalpic gains from subpocket binding in enzyme inhibitors. Epitope mapping using SPR employs competition assays to identify overlapping or adjacent binding sites on antigens by assessing pairwise interactions. In these assays, one is immobilized on the sensor surface, followed by injection of the antigen and a soluble competing ; inhibition of binding indicates epitope overlap. High-throughput SPR platforms facilitate binning of panels, classifying epitopes into competitive bins based on cross-blocking patterns, which aids in selecting non-redundant candidates for therapeutic development. For example, indirect competitive SPR binding assays have mapped epitopes on junctional molecule A (JAM-A), showing proximity between sites recognized by distinct . SPR monitors layer-by-layer (LbL) assembly of polyelectrolyte multilayers by tracking incremental shifts in , which correlate with film thickness growth during sequential deposition of oppositely charged polymers. Each bilayer addition typically increases thickness by 1-5 nm, depending on polymer type and , as measured in via the SPR angle shift. In polyelectrolyte systems like poly(acrylic acid)/poly(styrenesulfonate) (PAA/PSS), SPR combined with confirms linear multilayer growth and quantifies changes per layer. This technique has been applied to assemble films on substrates for functionalization, revealing uniform deposition and control over multilayer architecture. Conformational changes in proteins are detected by SPR through localized refractive index (RI) shifts near the sensor surface, which reflect alterations in protein mass distribution or upon unfolding or structural transitions. Immobilized proteins exhibit SPR signal changes proportional to conformational rearrangements, such as those induced by denaturants, allowing from simple events. For instance, in calcium-binding proteins, SPR captures dynamic fingerprints of conformational shifts under native conditions, with signal variations linked to changes in charge state and . These RI shifts enable observation of unfolding pathways, as demonstrated in immobilized enzymes where conformational changes contribute directly to the SPR response beyond bulk effects. A representative example of thermodynamic profiling involves DNA hybridization, where SPR measures temperature-dependent association constants to apply van't Hoff analysis for \Delta H and \Delta S of duplex formation. In solid-phase hybridization assays, cation shielding effects on mismatched DNA pairs have been quantified, showing enthalpic penalties for mismatches via SPR-derived van't Hoff plots. These studies highlight sequence-specific thermodynamics, with hybridization enthalpies around -200 to -360 kJ/mol for short complementary DNA strands (7-11 mers), validated across platforms. SPR thermodynamic data are often integrated with (ITC) for orthogonal validation of biomolecular interactions, combining SPR's kinetic-equilibrium insights with ITC's direct enthalpic measurements in solution. This complementary approach confirms binding affinities and dissects enthalpic versus entropic contributions, as seen in protein-protein and studies where SPR K_D values align with ITC-derived parameters within experimental error. Such validation enhances reliability in characterizing complex interactions, avoiding artifacts from surface immobilization in SPR.

Recent Advances

Nanomaterial Enhancements

have significantly advanced surface plasmon resonance (SPR) sensing by improving sensitivity, field enhancement, and tunability through integration with plasmonic structures. Post-2010 developments emphasize two-dimensional (2D) materials and nanoparticles that amplify (RI) shifts and local electromagnetic fields, enabling detection limits in the attomolar range for biomolecular interactions. These enhancements stem from unique material properties, such as high surface area and mobility, which interact synergistically with SPR modes to boost signal-to-noise ratios without altering core device architectures. Graphene overlays on SPR substrates enhance sensitivity primarily through π-π stacking interactions that promote biomolecular adsorption, such as DNA bases, leading to amplified RI shifts. Monolayer and bilayer graphene configurations have demonstrated sensitivity increases of 3.5-fold and 2.5-fold, respectively, compared to bare films, by extending the and modulating the environment. These overlays also protect underlying metals from oxidation, ensuring long-term stability in aqueous sensing environments. Plasmonic nanoparticles, such as gold or silver colloids, hybridize with SPR films to create electromagnetic hot spots via localized surface plasmon resonance (LSPR)-SPR coupling, confining intense fields at nanogaps for enhanced biomolecular detection. This coupling generates field enhancements exceeding 100-fold in nanoparticle dimers or aggregates, enabling single-molecule sensitivity in configurations like the Kretschmann setup. For instance, Au nanoparticle arrays on SPR chips have improved detection of proteins and DNA by exploiting analyte-induced aggregation to shift resonance peaks, achieving femtomolar limits through amplified scattering and absorption. Ferromagnetic layers in magnetic plasmonics allow tunable SPR resonance by applying external magnetic fields, which modulate and induce magneto-optical effects in hybrid nanostructures. Composite systems of nanoparticles with ferromagnetic thin films, such as Co or Fe, enable dynamic control of plasmon propagation, shifting resonance wavelengths by up to several nanometers under modest fields (e.g., 0.1 T). This tunability, demonstrated in post-2010 magnetoplasmonic crystals, facilitates active sensing of magnetic analytes or environmental changes, with enhanced Faraday rotation for polarization-sensitive detection. Beyond , other 2D materials like molybdenum disulfide (MoS₂) provide broadband enhancement in SPR by increasing penetration and reducing propagation losses across visible to near-infrared wavelengths. MoS₂ nanosheets deposited via layer-by-layer assembly yield sensitivity peaks of 2793 nm/RIU, a 30.67% improvement over conventional SPR, due to optimal thickness tuning that balances field intensity and damping. Hybrid -MoS₂ structures further extend this broadband capability, supporting multi-analyte sensing with figure-of-merit values exceeding 100. Recent 2025 advances include ultra-sensitive SPR sensors integrating /MoS₂ hybrids with Kretschmann configurations, achieving sensitivities over 18,000 nm/RIU for detection in biological media. Photothermal effects in nanomaterial-enhanced SPR arise from plasmonic , generating localized heating that modulates in the sensing for thermoplasmonic applications, though primarily leveraged in sensing to refine temperature-dependent responses. Gold nanotip arrays exhibit temperature rises over 20 K under illumination, inducing LSPR shifts of several nanometers that correlate with changes (e.g., -4 × 10⁻⁴ in ), allowing calibration for precise, heat-assisted detection without external heaters. These effects are harnessed in sensing to amplify signals in low-concentration regimes, distinct from therapeutic uses.

Integrated and Portable Systems

Integrated and portable surface plasmon resonance (SPR) systems represent a significant in the field, enabling and deployment outside traditional laboratory settings. These platforms leverage advancements in , , and to achieve , label-free detection with reduced sample volumes and enhanced accessibility. By incorporating compact light sources, detectors, and units, such systems facilitate on-site applications in biosensing, , and , aligning with trends toward point-of-care diagnostics and . Fiber-optic SPR sensors exploit the along optical fibers coated with a thin metal layer, such as , to excite surface plasmons upon interaction with analytes. This configuration allows for in hard-to-reach environments, as the fiber's flexibility transmits to and from the sensing region without electromagnetic interference. Recent advances include nanostructured coatings like for improved sensitivity up to 10^{-6} refractive index units (RIU), enabling biochemical detection in real-time. These sensors are particularly suited for continuous monitoring, with multiplexing capabilities for multi-analyte analysis. Smartphone-integrated SPR platforms utilize the device's built-in components, including complementary metal-oxide-semiconductor (CMOS) image sensors and (LED) sources, to create cost-effective, portable biosensors. The smartphone camera captures shifts in reflected light intensity or wavelength due to SPR, processed via apps for immediate readout. Sensitivities on the order of 10^{-5} RIU have been achieved, supporting detection limits down to attomolar concentrations for biomarkers like . These systems enhance portability for field applications, such as toxin screening in water, by integrating with 3D-printed . Lab-on-chip SPR devices incorporate microfluidic channels fabricated from (PDMS) to handle small sample volumes (e.g., 90 nL to 1 μL) and automate fluid delivery to the sensing surface. PDMS enables rapid prototyping and biocompatibility, facilitating through electrowetting-on-dielectric (EWOD) or centrifugal mechanisms for precise control. Examples include hybrid prism-based systems detecting with limits of detection around 1 μg/mL in under 5 minutes, ideal for rapid immunoassays. Integration reduces analysis time to 1-20 minutes while minimizing reagent use. Wireless and (IoT)-enabled SPR systems facilitate data transmission from remote sensors to cloud platforms for real-time . These incorporate silver nanostructures in polymer matrices (e.g., ) to boost plasmonic sensitivity and stability, connected via mesh topologies in wireless sensor networks. Response times as low as 0.2 enable tracking of pollutants in air, water, and , with integration allowing large-area coverage and . Such setups support sustainable monitoring by alerting to biochemical changes in harsh conditions. Recent commercialization efforts include portable SPR biosensors for , exemplified by a 2023 smartphone-based imaging SPR device using 3D-printed microfluidic chips to detect total protein in plant-based milks at limits of detection from 0.04 to 0.53 μg/mL. Grating-based portable systems, achieving high for on-site quantification, further drive market adoption in . These developments transition SPR from lab-bound tools to field-deployable units, with projections for broader accessibility by 2030. In 2024-2025, advances in SPR aptasensors have enabled highly specific detection of G protein-coupled receptors and viruses, enhancing portable systems for clinical diagnostics. Despite progress, challenges persist in maintaining stability within non-lab environments, where temperature fluctuations, , and mechanical stress can degrade signal quality and sensor performance. Robust designs, such as -stabilized and anti-fouling coatings, are essential to mitigate non-specific and ensure . Cost barriers and the need for user-friendly interfaces also hinder widespread deployment, though via micro-opto-electro-mechanical systems offers promising solutions.