Binding activity of avidin to the biotin within mesoporous silica materials for bioanalytical applications.

It has been reported that the activity of protein improved when it was adsorbed inside the pores of mesoporous silica (MPS). The current study investigated the activity of immobilized avidin to the biotin on MPS with various pore sizes (diameter=2.4-45.0 nm). The binding amount of immobilized avidin to biotin is 123 to 160 ng biotin/10 µg avidin on 2.7- to 5.4-nm pore MPS, but that on 12- to 45-nm pore MPS was markedly decreased (33-42 ng biotin/10 µg). Moreover, the binding amount was approximately 2- and 3-fold higher on the glycidoxypropyl (Gly)-functionalized 5.4- and 45-nm pore MPS in comparison with methyl (Me)-functionalized 5.4- and 45-nm pore MPS, respectively. Furthermore, avidin immobilized in native and Gly-grafted 45-nm pore MPS retained more than 70% and 50% binding activity to biotin, respectively, after incubating at 90°C for 3 h. In contrast, the activity was greatly reduced in the native and Gly-grafted 5.4-nm pore MPS under the same conditions (<36.9%). The immobilization also protected against effects of 0.01 M HCl and 50% MeOH; all of immobilized avidin proteins showed high activity (>50%) with biotin compared with that observed with free avidin (MeOH [<18.2%] and HCl [<32.7%]).

A quantitative determination of magnetic nanoparticle separation using on-off field operation of quadrupole magnetic field-flow fractionation (QMgFFF).

Quadrupole Magnetic Field-Flow Fractionation (QMgFFF) is a technique for characterization of sub-micrometer magnetic particles based on their retention in the magnetic field from flowing suspensions. Different magnetic field strengths and volumetric flow rates were tested using on-off field application and two commercial nanoparticle preparations that significantly differed in their retention parameter, λ (by nearly 8-fold). The fractograms showed a regular pattern of higher retention (98.6% v. 53.3%) for the larger particle (200 nm v. 90 nm) at the higher flow rate (0.05 mL/min v. 0.01 mL/min) at the highest magnetic field (0.52 T), as expected because of its lower retention parameter. The significance of this approach is a demonstration of a system that is simpler in operation than a programmed field QMgFFF in applications to particle mixtures consisting of two distinct particle fractions. This approach could be useful for detection of unwanted particulate contaminants, especially important in industrial and biomedical applications.

Regulation of cellular responses to macroporous inorganic films prepared by the inverse-opal method.

Regenerative medicine for repairing damaged body tissues has recently become critically important. Cell culture scaffolds are required for the control of cell attachment, proliferation, and differentiation in in vitro cell cultures. A new strategy to control cell adhesion, morphology, and proliferation was developed by culturing mouse osteoblast-like MC3T3-E1 cells on novel cell culture scaffolds fabricated using ordered nanometer-sized pores (100, 300, 500, and 1000 nm). Results of this study indicate that after 72 h of incubation, the number of cells cultured on a silica film with a pore size of 1000 nm was similar to or slightly lower than that cultured on a non-porous control silica film. Films with 100-500 nm pore sizes, however, resulted in the cell growth inhibition. Morphology of the cultured cells revealed increased elongation and the formation of actin stress fibers was virtually absent on macroporous silica films with 100-500 nm pore size. Vinculin molecules expressed in cells cultured on the non-porous silica films showed many clear focal adhesions, whereas focal contacts were insufficiently formed in cells cultured on macroporous films. The influence of hydroxyapatite (HAp) and alumina scaffolds on the behavior of MC3T3-E1 cells was also evaluated. The proliferation rate of MC3T3-E1 cells cultured on HAp films with 1000 nm pore size was increased to approximately 20% above than that obtained of cells cultured on non-porous HAp films. These results demonstrate that the pore size and constituents of films play a role in controlling the morphology and proliferation rate of MC3T3-E1 cells.