Immobilization of antibodies onto glass wool

Glass wool: a novel support for heterogeneous catalysis

Heterogeneous catalysis presents significant advantages over homogeneous catalysis such as ease of separation and reuse of the catalyst. Here we show that a very inexpensive, manageable and widely available material - glass wool - can act as a catalyst support for a number of different reactions. Different metal and metal oxide nanoparticles, based on Pd, Co, Cu, Au and Ru, were deposited on glass wool and used as heterogeneous catalysts for a variety of thermal and photochemical organic reactions including reductive de-halogenation of aryl halides, reduction of nitrobenzene, Csp3-Csp3 couplings, N-C heterocycloadditions (click chemistry) and Csp-Csp2 couplings (Sonogashira couplings). The use of glass wool as a catalyst support for important organic reactions, particularly C-C couplings, opens the opportunity to develop economical heterogeneous catalysts with excellent potential for flow photo-chemistry application.

Combinatorial coating of adhesive polypeptide and anti-CD34 antibody for improved endothelial cell adhesion and proliferation

Improved attachment, adhesion and proliferation of the surrounding mature endothelial cells (ECs) and circulating endothelial progenitor cells (EPCs) is of primary importance to realize the in situ rapid re-endothelialization of cardiovascular stents. To achieve this, a combinatorial coating of synthesized mussel adhesive polypeptide mimics as well as anti-CD34 antibody was constructed onto the devices through a novel adsorption method in this study. To immobilize the polypeptide and target antibody effectively, polycaprolactone (PCL) was first spin-coated onto the substrate as intermediate. The immobilization of polypeptide and antibody was confirmed by the changes of water contact angles and the attachment, growth of ECs and EPCs on the substrates, respectively. The results showed that after adhesive polypeptide or/and antibody immobilization, the hydrophilicity of coated PCL substrate (PCLS) was obviously improved. The amount of the immobilized antibody, determined by enzymelinked immunoassay (ELISA) method, was enhanced with the increase of antibody concentrations in the range from 5 to 25 mug/ml. The coatings after BSA blocking prevented the unspecific protein adsorption as monitored by fluorescent microscopy. The results of in vitro cell culture showed that compared with the PCLS, polypeptide/anti-CD34 antibody coating could effectively enhance the attachment, growth and adhesion of ECs and EPCs, in particular EPCs. A platelet adhesion experiment revealed that the blood compatibility of the PCLS after polypeptide/anti-CD34 antibody coating was also obviously improved. The results showed that the surface modification with adhesive polypeptide and anti-CD34 antibody will be a promising coating technique for the surface modification of the intravascular prostheses for rapid re-endothelialization.

DNA-coated AFM cantilevers for the investigation of cell adhesion and the patterning of live cells

Measurement of receptor adhesion strength requires the precise manipulation of single cells on a contact surface. To attach live cells to a moveable probe, DNA sequences complementary to strands displayed on the plasma membrane are introduced onto AFM cantilevers (see picture, bp=base pairs). The strength of the resulting linkages can be tuned by varying the length of DNA strands, allowing for controlled transport of the cells

Ultrasonic deposition of cells on a surface

Bacteria in water have been driven to a glass surface by an ultrasonic standing wave. On an antibody coated surface capture of Bacillus subtilis var niger (BG) spores (6.6 x 10(6) ml(-1)) was increased more than 200-fold over above the efficiency in the absence of ultrasound. In microfluidic (non-turbulent) systems detection of particles by sensors operating at a surface is diffusion limited. This results in very low detection abilities particularly for particles with diameters greater than 1 microm. Ultrasound is used here to drive bacterial spores to a wall and overcome this limitation. The results confirm: (1) pressure nodes can be formed close to the water-glass interface when the glass thickness is near half the ultrasonic wavelength; (2) the antibody used was able to capture spores in the presence of an ultrasonic standing wave.

Solid supports for microarray immunoassays

Stimulated by the achievements of the first phase in genomics and the resulting need of assigning functions to the acquired sequence information, novel formats of immunoassays are being developed for high-throughput multi-analyte studies. In principle, they are similar in nature to the microarray assays already established at the level of nucleic acids. However, the biochemical diversity and the sheer number of proteins are such that an equivalent analysis is much more complex and thus difficult to accomplish. The wide range of protein concentration complicates matters further. Performing microarray immunoassays already represents a challenge at the level of preparing a working chip surface. Arrays have been produced on filter supports, in microtiter plate wells and on glass slides, the last two usually coated with one-, two- or three-dimensionally structured surface modifications. The usefulness and suitability of all these support media for the construction and application of antibody microarrays are reviewed in this manuscript in terms of the different kinds of immunoassay and the various detection procedures. Additionally, the employment of microarrays containing alternative sensor molecules is discussed in this context. The sensitivity of microspot immunoassays predicted by the current analyte theory is not yet a reality, indicating the extent of both the technology's potential and the size of the task still ahead.

Determination of boron by using a quartz crystal resonator coated with N-methyl-D-glucamine-modified poly(epichlorohydrin)

A nongravimetric quartz crystal resonator for determination of boron was proposed. The key step is the preparation of a polymer that forms a complex with boron (from borate ion). The polymeric film is deposited on one face of an electrode-separated quartz crystal. The backbone of the polymer is poly(epichlorohydrin), which is modified to anchor N-methyl-D-glucamine. After reticulation and reduction, the film presents high stability and sensitivity to boron at pH 8.5. A carrier solution containing 50 mM EDTA ensures high conductivity and the elimination of several interfering metal ions. Boron is strongly retained by the film, and a positive shift of the oscillating frequency is proportional to its concentration. Boron is eluted with 1 mL of a 1 M mannitol solution. For a 0.160-mL sample loop and concentration up to 600 microM, the calibration sensitivity was 1.67 Hz/microM and the LOD was 2 microM. This limit could be lowered to 0.3 microM by using a 1.00-mL sample loop. In both cases, it was possible to detect 3 ng of boron. It was estimated that the nongravimetric sensor is at least 10 times more sensitive that a hypothetical gravimetric sensor.

The solid phase in affinity chromatography: strategies for antibody attachment

Antibodies (Ab) are commonly used in affinity chromatography (AC) as a versatile and specific means of isolating target molecules from complex mixtures. A number of procedures have been developed to immobilize antibodies on the solid matrix. Some of these methods couple the antibody via chemical groups that may be important for specific recognition of antigen, resulting in loss of functionality in a proportion of the antibodies. In other methods, the outcome of immobilization is coupling via unique sites in the Fc region of the antibody molecule, ensuring orientation of the antibody combining sites (Fab) towards the mobile phase. This review discusses the advantages and disadvantages of the various methods available for immobilization and outlines protocols for site-directed, covalent coupling of the antibody to the solid phase that essentially retains the activity of the antibody.