chemistry
Chemical Engineering Laboratory
Using plastic to examine molecules inside the body
We are devising techniques for observing various phenomena in the body by creating plastics that remember the shapes of molecules we want to measure. For example, we are developing a sensor that can monitor levels of medicine in a patient's body to determine whether there is enough to be effective or too much. We are also developing technology that will allow us to determine whether the concentration of substances in animal brains increases when they are thinking about things.
College of Engineering Chemistry and Materials Chemistry and Biotechnology
/ Graduate School of Engineering and Science(Master's Program) Applied Chemistry Course
/ Graduate School of Engineering and Science(Doctor's Program) Regional Environment Systems Course
- Faculty Name
- YOSHIMI, Yasuo
- Keyword
- Artificial nerves,Sensors,Biological information,Medical engineering,Biosensors
- Laboratory location
- Research Building TOYOSU Campus 12F 12C25
This lab is for this SDG activity:
STUDY FIELDS
- Chemical engineering
- Physical chemistry
- Macromolecular chemistry
- Electrochemistry
- Thinking strategies for solving problems
FOR SOCIETY
Drug-resistant pathogens that have rendered antibiotics ineffective due to habituation have become a global problem. Preventing drug resistance requires checking that levels of antibiotics in the blood are no 欧洲杯足彩app下载_欧洲杯下注平台-【直播*网站】 than are needed to eradicate the pathogens. However, analyses to confirm this have failed to take root in developing countries due to the enormous costs and time involved. To address this, our laboratory developed a disposable sensor that can quickly and cheaply measure the concentration of antibiotics in the blood. Because it is made from cheap plastic, each sensor is expected to cost only a few dozen yen, which we hope will lead to widespread adoption around the world.
RESEARCH THEMES
- Development of sensors to measure drug levels in the blood using molecularly imprinted macromolecules
- Visualization of neurotransmitter secretion in the brain using molecularly imprinted macromolecules
- Analysis of the mechanism of molecularly imprinted macromolecule swelling that accompanies molecular recognition
