The interaction between antibody and antigen is characterised by relatively high affinity and specificity, making this type of reaction a prime candidate for use as an analytical tool. The interaction may be combined with biosensors in the production of immunosensors for environmental monitoring. Polyclonal and monoclonal antibodies have had a significant impact in analytical detection systems over the past few decades with antibody fragments becoming important in recent years. Production of antibodies to small haptens requires the initial conjugation of hapten to a larger carrier molecule. Once hapten-carrier conjugates have been produced, polyclonal, monoclonal and various antibody fragments may be produced by differing protocols. A critical step in the production of antibody fragments is the development of efficient screening procedures to identify suitable antibody-producing clones and this has been reviewed in this article. Various antibody types may then be used in the generation of immunosensors for the monitoring of environmental pollutants. The selection of the appropriate sensor technology applicable for the determination of an antibody-antigen interaction is of prime importance for immunosensor development. One example of such an application is surface plasmon resonance-based biosensors, as they provide real-time analysis of interactions between the antibody and antigen of interest. 相似文献
Nematic solutions of PPTA and nylon 3T were prepared in H2SO4 Optical microscopy was used to ascertain the phase behaviour of the blends. In the studied concentration range, no phase separation was observed. The solutions were shear-oriented and coagulated, and the resulting samples were studied by x-ray and electron diffraction. Nylon 3T crystallised even at a low concentration, which is indicative of a phase separation. Electron diffraction investigations of the oriented samples showed that well-oriented areas, which were predominantly composed of PPTA, adjoined areas where the major component, nylon 3T, showed no orientation. The relative proportion of the unoriented areas increased with increasing nylon concentration. It was concluded that, upon coagulation, the nylon was segregated into separate phases and crystallised unoriented, whereas for PPTA, crystallisation proceeded with very little chain rearrangement therefore preserving the orientation. 相似文献
Force mapping with the atomic force microscope (AFM) allows the simultaneous acquisition of topography and probe-sample interaction data. For example, AFM probes functionalised with an antigen can be employed to map the spatial distribution of recognition events on a substrate functionalised with its specific antibody. However, to date this method has been limited to the detection of single receptor-ligand species. Were the detection of multiple receptor-ligand interactions possible, force mapping would offer great scope as a sensitive tool for bioassay and screening applications. We have developed an immobilisation strategy, which allows two different molecular species (in this case human serum albumin and the β subunit of human chorionic gonadotropin) to be present simultaneously on an AFM probe. Single point force spectroscopy results have revealed the ability of such probes to discriminate between their corresponding recognition points (anti-HSA and anti-βhCG IgG antibodies). As a control, force measurements were re-recorded in the presence of the known antigen (free in solution) for each antibody species and a marked decrease in the frequency of specific interaction is observed. As an additional control interactions between anti-βhCG IgG and the multifunctional probe are taken in the presence of free βhCG (“true” antigen) and free HSA (“false” antigen). It is shown that measurements recorded in the presence of a non-related protein species results in no change in either the force observed or the frequency of specific interactions, further confirmation that the specificity of force observed is due to the separation of antibody-antigen complex. 相似文献
The structure of polyimide from 1,4-bis (3', 4'-dicarboxyphenoxy) benzene and 4,4'-oxydianiline film specimens before and after hot stretching has been investigated by WAXD, DSC and FTIR. As evidenced by both the WAXD and DSC results, it could be believed that strain induced crystallization did take place after hot stretching. Meanwhile, shifting position and splitting of some band peaks existed on the FTIR spectrograms were explained in terms of the close packing of chains and the changes of inter-molecular charge-transfer interaction between imide groups and aromatic groups upon crystallization. 相似文献
Summary Sedimentation field-flow fractionation was shown to permit the precise evaluation of surface concentrations of human IgG, adsorbed to polystyrene latex spheres of different sizes. Unlike conventional techniques for measuring protein uptake by colloidal substrates, this method allowed a direct evaluation of mass adsorbed per unit area, without the need for potentially destructive labelling reactions. Thus, a four hour adsorption of IgG from a 3–10 fold excess of protein in solution yielded surface concentrations which were 1.4±0.1 mg/m2 on a 272 nm latex and 1.9±0.1 mg/m2 on a latex with a diameter of 142 nm. The lower value coincided with the estimated monolayer surface coverage. The IgG-PS 272 nm adsorption complex was shown to take up negligible amounts of HSA from a 10 mg/mL solution, while its specific uptake of a polyclonal rabbit anti-human IgG was 2.6 molecules per molecule of adsorbed antigen. The same ratio was found for the smaller particles. The surface concentration of adsorbed second antibody, often crucial in immunodiagnostic quantifications, was therefore found to be significantly enhanced by the increased substrate curvature presented by the smaller particles.Dedicated to Professor Leslie S. Ettre on the occasion of his 70th birthday. 相似文献
Stem cell transplantations for spinal cord injury (SCI) have been studied extensively for the past decade in order to replace the damaged tissue with human pluripotent stem cell (hPSC)‐derived neural cells. Transplanted cells may, however, benefit from supporting and guiding structures or scaffolds in order to remain viable and integrate into the host tissue. Biomaterials can be used as supporting scaffolds, as they mimic the characteristics of the natural cellular environment. In this study, hPSC‐derived neurons, astrocytes, and oligodendrocyte precursor cells (OPCs) are cultured on aligned poly(ε‐caprolactone) nanofiber platforms, which guide cell orientation to resemble that of spinal cord in vivo. All cell types are shown to efficiently spread over the nanofiber platform and orient according to the fiber alignment. Human neurons and astrocytes require extracellular matrix molecule coating for the nanofibers, but OPCs grow on nanofibers without additional treatment. Furthermore, the nanofiber platform is combined with a 3D hydrogel scaffold with controlled thickness, and nanofiber‐mediated orientation of hPSC‐derived neurons is also demonstrated in a 3D environment. In this work, clinically relevant materials and substrates for nanofibers, fiber coatings, and hydrogel scaffolds are used and combined with cells suitable for developing functional cell grafts for SCI repair.
We present a rather generic model for toxin (ricin) inhibition of protein biosynthesis in eukaryotic cells. We also study reduction of the ricin toxic effects with application of antibodies against the RTB subunit of ricin molecules. Both species initially are delivered extracellularly. The model accounts for the pinocytotic and receptor-mediated toxin endocytosis and the intact toxin exocytotic removal out of the cell. The model also includes the lysosomal toxin destruction, the intact toxin motion to the endoplasmic reticulum (ER) for separation of its molecules into the RTA and RTB subunits, and the RTA chain translocation into the cytosol. In the cytosol, one portion of the RTA undergoes degradation via the ERAD. The other its portion can inactivate ribosomes at a large rate. The model is based on a system of deterministic ODEs. The influence of the kinetic parameters on the protein concentration and antibody protection factor is studied in detail. 相似文献
Non-linear stress, and orientation characteristics for polymer fluids (melts, solutions) composed of chain macromolecules of finite length have been derived. Freelyjointed chains with inverse Langevin statistics have been assumed, and their behaviour in potential hydrodynamic fields analyzed. Numerical calculations have been performed for uniaxial extensional flow in a wide range of flow rates (and stresses). In the range of small stresses, orientation is a linear function of stress. At higher stresses, orientation factor levels off, asymptotically approaching unity.Flow orientation characteristics significantly differ from those derived from affine deformation of polymer networks. This difference is a natural consequence of constraints imposed by network junctions on chain deformation.This work is dedicated to Professor Hanns-Georg Kilian on his 60th birthday in appreciation of his contribution to Polymer Physics. 相似文献
