Phase-polarisation contrast for surface plasmon resonance biosensors

A technique of phase-polarisation contrast (PPC) for the enhancement of the contrast of a surface plasmon resonance (SPR) intensity profile is proposed and experimentally realised. The technique exploits the peculiarities of light phase and polarisation behaviour under SPR. It applies to non-optimum SPR coupling conditions and enables one to lower the resonant minimum of reflected intensity nearly to zero, and hence to increase substantially the ratio of the intensity from the resonance to that at the minimum. We observed the contrast enhancement by more than one order of magnitude when we applied the PPC scheme. The PPC can be efficiently employed in commercial SPR sensors, as it significantly reduces restrictions on allowable parameters of SPR-supporting metal films and biomolecular layers immobilised on them, facilitates SPR observation, and increases the accuracy of SPR shift measurements.     

基于SPR生物传感器的免疫学检测

利用一种全新的生物大分子相互作用检测仪表面等离子激元共振（SPR）生物传感器,对乙肝表面抗原,抗体,破伤风类毒素,抗体等生物制品进行生物特异性相互作用分析（BIA）,并对其在免疫学检测上的特征进行了探讨。     

Real-time and Label-free Bio-sensing of Molecular Interactions by Surface Plasmon Resonance: A Laboratory Medicine Perspective

Radioactive, chromogenic, fluorescent and other labels have long provided the basis of detection systems for biomolecular interactions including immunoassays and receptor binding studies. However there has been unprecedented growth in a number of powerful label free biosensor technologies over the last decade. While largely at the proof-of-concept stage in terms of clinical applications, the development of more accessible platforms may see surface plasmon resonance (SPR) emerge as one of the most powerful optical detection platforms for the real-time monitoring of biomolecular interactions in a label-free environment.In this review, we provide an overview of SPR principles and current and future capabilities in a diagnostic context, including its application for monitoring a wide range of molecular markers of disease. The advantages and pitfalls of using SPR to study biomolecular interactions are discussed, with particular emphasis on its potential to differentiate subspecies of analytes and the inherent ability for quantitation through calibration-free concentration analysis (CFCA). In addition, recent advances in multiplex applications, high throughput arrays, miniaturisation, and enhancements using noble metal nanoparticles that promise unprecedented sensitivity to the level of single molecule detection, are discussed.In summary, while SPR is not a new technique, technological advances may see SPR quickly emerge as a highly powerful technology, enabling rapid and routine analysis of molecular interactions for a diverse range of targets, including those with clinical applicability. As the technology produces data quickly, in real-time and in a label-free environment, it may well have a significant presence in future developments in lab-on-a-chip technologies including point-of-care devices and personalised medicine.     

Surface plasmon resonance sensor for heparin measurements in blood plasma

Surface plasmon resonance (SPR) was used as an affinity biosensor to determine absolute heparin concentrations in human blood plasma samples. Protamine and polyethylene imine (PEI) were evaluated as heparin affinity surfaces. Heparin adsorption onto protamine in blood plasma was specific with a lowest detection limit of 0.2 U/ml and a linear window of 0.2–2 U/ml. Although heparin adsorption onto PEI in buffer solution had indicated superior sensitivity to that on protamine, in blood plasma it was not specific for heparin and adsorbed plasma species to a steady-state equilibrium. By reducing the incubation time and diluting the plasma samples with buffer to 50%, the non-specific adsorption of plasma could be controlled and a PEI pre-treated with blood plasma could be used successfully for heparin determination. Heparin adsorption in 50% plasma was linear between 0.05 and 1 U/ml so that heparin plasma levels of 0.1–2 U/ml could be determined within a relative error of 11% and an accuracy of 0.05 U/ml.     

Kinetic Analysis of Analyte Binding by Optical Biosensors: Hydrodynamic Penetration of the Analyte Flow into the Polymer Matrix Reduces the Influence of Mass Transport

I examined the penetration of the hydrodynamic flow into a polymer matrix immobilized by grafting to a surface, such as used in optical biosensors designed to measure binding reactions in real time. I show that the flow penetrates with an appreciable velocity into a region located at the tip of such a polymer brush, corresponding to about 10 to 15% of the total mass of the grafted polymer. Furthermore, under the conditions recommended for kinetic measurements, the concentrations of both polymer and immobilized ligands are low in these regions of the matrix, where crowding effects are negligible. Under such conditions, the hydrodynamic flow penetrating into the dextran matrix flow will bring the analytes close to their targets, thus considerably reducing transport problems.     

Detection of enzyme-catalyzed polysaccharide synthesis on surfaces

Abstract

Strategically important cellular components, such as the cell wall and the starch granule, present surfaces during their biosynthesis and degradation. The enzymology of such surfaces is experimentally challenging and goes well beyond classical solution-state analyses. The kinetics of surface catalysis is complex but tractable. A number of approaches to monitor surface catalysis are reviewed and each is suited to a different biological problem. Particular attention is paid to a method we have recently developed for quantitatively monitoring polysaccharide synthesis on a surface in real time using surface plasmon resonance spectroscopy. This method has many attractive features with the potential to tackle both biological and industrial problems.