Schematic diagram showing removal of bacterial biofilm via Mtex
POSTECH-UNIST joint research team finds ways to control the surface texture of nanostructures
The COVID-19 pandemic is raising fears of new pathogens such as new viruses or drug-resistant bacteria. To this, a Korean research team has recently drawn attention for developing the technology for removing antibiotic-resistant bacteria by controlling the surface texture of nanomaterials.
A joint research team from POSTECH and UNIST has introduced mixed-FeCo-oxide-based surface-textured nanostructures (MTex) as highly efficient magneto-catalytic platform in the international journal Nano Letters. The team consisted of professors In Su Lee and Amit Kumar with Dr. Nitee Kumari of POSTECH’s Department of Chemistry and Professor Yoon-Kyung Cho and Dr. Sumit Kumar of UNIST’s Department of Biomedical Engineering.
First, the researchers synthesized smooth surface nanocrystals in which various metal ions were wrapped in an organic polymer shell and heated them at a very high temperature. While annealing the polymer shell, a high-temperature solid-state chemical reaction induced mixing of other metal ions on the nanocrystal surface, creating a number of few-nm-sized branches and holes on it. This unique surface texture was found to catalyze a chemical reaction that produced reactive oxygen species (ROS) that kills the bacteria. It was also confirmed to be highly magnetic and easily attracted toward the external magnetic field. The team had discovered a synthetic strategy for converting normal nanocrystals without surface features into highly functional mixed-metal-oxide nanocrystals.
The research team named this surface topography – with branches and holes that resembles that of a ploughed field – “MTex.” This unique surface texture has been verified to increase the mobility of nanoparticles to allow efficient penetration into biofilm*1 matrix while showing high activity in generating reactive oxygen species (ROS) that are lethal to bacteria.
This system produces ROS over a broad pH range and can effectively diffuse into the biofilm and kill the embedded bacteria resistant to antibiotics. And since the nanostructures are magnetic, biofilm debris can be scraped out even from the hard-to-reach microchannels.
“This newly developed MTex shows high catalytic activity, distinct from the stable smooth-surface of the conventional spinel*2 forms,” explained Dr. Amit Kumar, one of the corresponding authors of the paper. “This characteristic is very useful in infiltrating biofilms even in small spaces and is effective in killing the bacteria and removing biofilms.”
“This research allows to regulate the surface nanotexturization, which opens up possibilities to augment and control the exposure of active sites,” remarked Professor In Su Lee who led the research. “We anticipate the nanoscale-textured surfaces to contribute significantly in developing a broad array of new enzyme-like properties at the nano-bio interface.”
The Latest Updates from Bing News & Google News
Go deeper with Bing News on:
Antibiotic-resistant bacteria
- Sophisticated mechanism that bacteria use to resist antibiotics
Researchers have discovered a significant and previously unknown mechanism that many bacteria use to resist antibiotics.
- Bipartisan bill on antibiotics faces crucial stretch
A health care bill is facing criticism from some experts who say it could lead to huge spending on new antibiotic drug development that may not improve patient outcomes in the long run. The ...
- Feeding Dogs Raw Meat Might Exacerbate The Antibiotic Resistance Crisis
In a new study published in the Journal of Antimicrobial Chemotherapy, a team of researchers at the University of Bristol observed that pet dogs who were predominantly on a diet of raw meat were far ...
- Rifamycin-Resisting Trick Discovered in Bacteria
Rifamycin-associated helicase-like protein HelR in Streptomyces venezuelae is a highly specific rifamycin resistance enzyme.
- Viruses help combat antibiotic-resistant bacteria
More and more bacteria are becoming resistant to antibiotics. Bacteriophages are one alternative in the fight against bacteria. These viruses attack very particular bacteria in a highly specific way.
Go deeper with Google Headlines on:
Antibiotic-resistant bacteria
Go deeper with Bing News on:
Nanoscale-textured surfaces
- Surfaces Designed That Make Water Boil More Efficiently
Improving the efficiency of systems that heat and evaporate water could significantly reduce their energy use. Now, researchers have found a way to do just that.
- Tech Imitates Life: Fireflies Make Better Light Bulbs
One known mitigation for this is creating a tiny texture pattern on the LED surface which allows more ... Verified both with computer models and a nanoscale 3D printed prototype, the researchers ...
- MIT Engineers Find a Way To Save Energy and Make Water Boil More Efficiently
New surface treatments could save energy for systems used in many industries. At the heart of a wide range of industrial processes, including most electricity generating plants, many chemical ...
- Three Ways Nanotechnology Is Changing The Healthcare Industry
Although medical nanotechnologies are relatively new, they’re already impacting the way we diagnose, treat and prevent a broad range of diseases.
- New research into making water boil using less energy
Can the boiling of water be done more efficiently? If so, a wide range of processes can save energy, not least the standard use of steam turbines in electricity generators. David Chandler at MIT ...
