Oxide nanowire microfluidics addressing previously-unattainable analytical methods for biomolecules towards liquid biopsy.
Hiromi TakahashiYoshinobu BabaTakao YasuiPublished in: Chemical communications (Cambridge, England) (2021)
Nanowire microfluidics using a combination of self-assembly and nanofabrication technologies is expected to be applied to various fields due to its unique properties. We have been working on the fabrication of nanowire microfluidic devices and the development of analytical methods for biomolecules using the unique phenomena generated by the devices. The results of our research are not just limited to the development of nanospace control with "targeted dimensions" in "targeted arrangements" with "targeted materials/surfaces" in "targeted spatial locations/structures" in microfluidic channels, but also cover a wide range of analytical methods for biomolecules (extraction, separation/isolation, and detection) that are impossible to achieve with conventional technologies. Specifically, we are working on the extraction technology "the cancer-related microRNA extraction method in urine," the separation technology "the ultrafast and non-equilibrium separation method for biomolecules," and the detection technology "the highly sensitive electrical measurement method." These research studies are not just limited to the development of biomolecule analysis technology using nanotechnology, but are also opening up a new academic field in analytical chemistry that may lead to the discovery of new pretreatment, separation, and detection principles.
Keyphrases
- liquid chromatography
- label free
- mass spectrometry
- cancer therapy
- loop mediated isothermal amplification
- room temperature
- high throughput
- tandem mass spectrometry
- real time pcr
- single cell
- small molecule
- escherichia coli
- ultrasound guided
- staphylococcus aureus
- cystic fibrosis
- biofilm formation
- candida albicans
- drug discovery
- fine needle aspiration