High-efficiency DNA injection into a single human mesenchymal stem cell using a nanoneedle and atomic force microscopy.

We describe a low-invasive gene delivery method that uses an etched atomic force microscopy (AFM) tip or nanoneedle that can be inserted into a cell nucleus without causing cellular damage. The nanoneedle is 200 nm in diameter and 6 mum in length and is operated using an AFM system. The probabilities of insertion of the nanoneedle into human mesenchymal stem cells (MSCs) and human embryonic kidney cells (HEK293) were higher than those of typical microinjection capillaries.

Enzymatic nanolithography of FRET peptide layer using V8 protease-immobilized AFM probe.

In our study, a method based on Enzymatic nanolithography was successfully performed in a buffered solution using Staphylococcal serine V8 protease and AFM. To estimate the lithographing activity of the protease immobilized on the AFM tip to peptides immobilized on a substrate, we designed fluorescence resonance energy transfer (FRET) peptides as reporter peptides that showed enzymatic action specific to the V8 protease. When the protease digested the reporter peptide a quencher residue was released from the peptide and resulted in the appearance of fluorescence.

Simple and high-sensitivity detection of dioxin using dioxin-binding pentapeptide.

The purposes of this study are to construct a simple dioxin detection system using peptides that bind to dioxin, and to test the system on real environmental samples. In this method, dioxin and N-NBD-3-(3',4'-dichlorophenoxy)-1-propylamine (NBD-DCPPA) are competitively bound to the peptides synthesized on beads. The fluorescence intensity of the bead decreases with increasing dioxin concentration.

Dioxin-binding pentapeptide for use in a high-sensitivity on-bead detection assay.

The purpose of this study is to develop a dioxin detection method using a short peptide alternative to an immunoantibody. A full peptide library consisting of 2.5 million possible amino acid combinations was constructed by a solid-phase split synthesis approach using 19 natural amino acids.

Gene expression using an ultrathin needle enabling accurate displacement and low invasiveness.

We have previously demonstrated a new cell manipulation technology by using an atomic force microscope (AFM) and ultrathin needles, named nanoneedles. The nanoneedle is an AFM tip etched by a focused ion beam (FIB) and is sharpened from 200 to 800 nm in diameter. In this study, we have evaluated the proper diameter of a needle required for insertion into human cells over a long period without causing cell death, and achieved highly efficient gene expression method for human cells using a nanoneedle and an AFM.

Nanoscale operation of a living cell using an atomic force microscope with a nanoneedle.

We have developed a tool for performing surgical operations on living cells at nanoscale resolution using atomic force microscopy (AFM) and a modified AFM tip. The AFM tips are sharpened to ultrathin needles of 200-300 nm in diameter using focused ion beam etching. Force-distance curves obtained by AFM using the needles indicated that the needles penetrated the cell membrane following indentation to a depth of 1-2 microm.

A molecular delivery system by using AFM and nanoneedle.

We developed a new low invasive cell manipulation and gene or molecule transfer system in a single living cell by using an atomic force microscope (AFM) and ultra thin needle, a nanoneedle. DNA was immobilized on the surface of the nanoneedle by covalent bonding and avidin-biotin affinity binding. Immobilization of DNA on the nanoneedle was confirmed by measuring the unbinding force between avidin and biotin.

Mechanical sensing of the penetration of various nanoneedles into a living cell using atomic force microscopy.

Mechanical responses during insertion of a silicon nanoneedle into a living melanocyte were observed by using an atomic force microscope (AFM). In order to study the dependence of the mechanical response on the shape of the nanoneedle, we prepared various shapes of silicon AFM tips by focused-ion beam (FIB) etching. The force curves showed increases up to 0.