Yosuke Amemiya

Mechanical force-based probing of intracellular proteins from living cells using antibody-immobilized nanoneedles

We developed a method combining atomic force microscopy (AFM) and antibody-immobilized nanoneedles to discriminate living cells by probing intracellular cytoskeletal proteins without the need for cell labeling. The nanoneedles are ultra-thin AFM probes sharpened to 200 nm in diameter. While retracting a nanoneedle inserted into a cell, we measured the mechanical force needed to unbind the antibody-target protein complex. Using this method, the intermediate filament protein, nestin and neurofilament were successfully detected in mouse embryonic carcinoma P19 cells and rat primary hippocampal cells within a minute for a single cell and cell differentiation states could be determined. Additionally, the measured magnitude of the force detecting nestin was indicative of the malignancy of breast cancer cells. This method was shown to affect neither the doubling time of cells nor does it leave extrinsic antibodies within the examined cells, allowing to be used in subsequent analyses in their native state.

Formation of nanofilms on cell surfaces to improve the insertion efficiency of a nanoneedle into cells

A nanoneedle, an atomic force microscope (AFM) tip etched to 200 nm in diameter and 10 μm in length, can be inserted into cells with the aid of an AFM and has been used to introduce functional molecules into cells and to analyze intracellular information with minimal cell damage. However, some cell lines have shown low insertion efficiency of the nanoneedle. Improvement in the insertion efficiency of a nanoneedle into such cells is a significant issue for nanoneedle-based cell manipulation and analysis. Here, we have formed nanofilms composed of extracellular matrix molecules on cell surfaces and found that the formation of the nanofilms improved insertion efficiency of a nanoneedle into fibroblast and neural cells. The nanofilms were shown to improve insertion efficiency even in cells in which the formation of actin stress fibers was inhibited by the ROCK inhibitor Y27632, suggesting that the nanofilms with the mesh structure directly contributed to the improved insertion efficiency of a nanoneedle.

Analysis of the unbinding force between telomestatin derivatives and human telomeric G-quadruplex by atomic force microscopy

The force analysis between a macrocyclic hexazole (6OTD) monomer/dimer and telomeric DNA using atomic force microscopy revealed the difference in their binding modes. The 6OTD dimer bound to the G-quadruplex more strongly than the monomer by sandwiching the G-quadruplex.

Aminosilane Multilayer Formed on a Single-Crystalline Diamond Surface with Controlled Nanoscopic Hardness and Bioactivity by a Wet Process

Diamond could be an excellent support for nanodevices utilizing biomolecules if it is covered with a polymer layer immobilizing a variety of biomolecules. We report a wet method to form a 3-aminopropyltriethoxysilane (APTES) multilayer with a controlled hardness, roughness, and capacity for immobilizing protein. The method is feasible in typical biochemical laboratories where biomolecules are prepared. Atomic force microscopy (AFM) revealed that the surface geometries and nanoscopic hardness of the multilayers on an oxygen-terminated single-crystalline diamond surface depended on the dielectric constant of the solvent; the smaller the constant, the harder the layer. The hard multilayers had holes and APTES aggregates on the surfaces, while less hard ones had homogeneous surfaces with rare holes and little aggregates. The secondary deposition of APTES in a solvent with a large dielectric constant on a hard multilayer removed the holes, and further treatment of the multilayer in acidic ethanol solution diminished the aggregates. Such a surface can immobilize streptavidin with enough specificity against nonspecific adsorption using a combination of polyethylene glycol reagents. The results of a scratching test and nanoindentation test with AFM provided consistent results, suggesting some universality of the scratching test independent of the tip structure of the cantilever. The mechanism of formation of multilayers on the diamond surface and their binding to it is discussed.

Nanoindentation as a Tool to Clarify the Mechanism Causing Variable Stiffness of a Silane Layer on Diamond

© 2012 Shimamoto et al., licensee InTech. This is an open access chapter distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Nanoindentation as a Tool to Clarify the Mechanism Causing Variable Stiffness of a Silane Layer on Diamond