*This is not jello.* This block M is composed of engineered bacteria and silica — a material commonly used in plaster — cross-linking together. The purple tint is a protein produced by the bacteria. If the M was damaged, researchers could add nutrients and any cracks would self-heal.
Credit: Dr. Sunyoung Kang, Postdoctoral Associate, Schmidt-Dannert Lab.
Some engineered living materials can combine the strength of run-of-the-mill building materials with the responsiveness of living systems.
Think self-healing concrete, paint that changes color when a specific chemical is detected or material that could reproduce and fill in a crack when one forms. This would revolutionize construction and maintenance, with wide-reaching economic and environmental implications.
Seeing this new category of adaptive materials on consumer shelves may be a ways off. Still, critical early research from the University of Minnesota sheds new light on this exciting advancement, which shows promise beyond building materials, including biomedical applications.
In a new study in Nature Communications, researchers from the College of Biological Sciences demonstrate how to transform silica — a common material used in plaster and other construction materials — into a self-assembling, dynamic and resilient material.
Currently, the majority of engineered living materials rely on adding a living component into a material. While this additive-approach has benefits, it falls short of the aspirational material — a product that grows, self-organizes, and heals itself. Other researchers were able to engineer a bacteria to produce the target material, but it could only survive in ideal lab conditions. That wouldn’t cut it in real-world applications.
Researchers, led by Claudia Schmidt-Dannert, a Distinguished McKnight Professor in the Department of Biochemistry, Molecular Biology and Biophysics, used a well-studied and benign bacteria, Bacillus subtilis, which goes dormant in unfavorable conditions and springs to life when conditions are favorable for growth. This trait made it a strong candidate as future products would eventually need to be shelf stable and easily activated. The research team then engineered the bacteria and studied the optimal approach to integrate it into the silica structure.
“The first time we saw that the bacteria and the silica were cross-linking and forming a rigid material was pivotal. At that moment, we knew it was working,” says Schmidt-Dannert.
Original Article: Step forward in quest to develop living construction materials and beyond
More from: University of Minnesota
The Latest Updates from Bing News & Google News
Go deeper with Bing News on:
Living construction materials
- 'A living hell': Residents' relief as construction waste site finally closes
Betrayed and disappointed” locals are celebrating the closure of a cleanfill site – but furious over a failure to deal with repeated consent breaches. Wainuiomata neighbours have been locked in a ...
- Barcalo Living & Commerce taking shape in Old First Ward
Developers Karl Frizlen and Michael Masters are in the midst of turning the former Barcalo Manufacturing plant into Barcalo Living & Commerce, a mixed-use community in the Old First Ward ...
- Outdoor living room ideas – 31 ways to create space to unwind
These outdoor living room ideas will help you transform your backyard into an extension of your home. All it takes is a little planning, design know-how and expert advice.Until we turned our gardens ...
- Redwood Living eyes major expansion across the Chicago area
Redwood Living Inc., an owner and developer of single-story apartment homes, plans to open its first development in the Chicago area in Lockport, Illinois. The Independence, Ohio-based company said ...
- Global Flat Steel Market To Be Driven By The Rising Demand For The Product From The Construction Industry In The Forecast Period Of 2022-2027
The new report by Expert Market Research titled, ‘Global Flat Steel Market Report and Forecast 2022-2027’, gives an in-depth analysis of the ...
Go deeper with Google Headlines on:
Living construction materials
Go deeper with Bing News on:
Adaptive materials
- Focus on adaptive reuse: Saving Redlands treasures
Adaptive reuse, a term referring to the repurposing an existing structure, is a cornerstone of Redlands development.
- Hybridization alters the shape of the genotypic fitness landscape, increasing access to novel fitness peaks during adaptive radiation
Hybridization not only generates genetic diversity, but this diversity can alter the shape of the fitness landscape, changing which genotypic combinations are favored by natural selection and which ...
- Processes in the Body Could Turn Harmless Immune Cells Into Ruthless Killers
It had been assumed that the gamma delta subset of T cells are pre-programmed to attack cells infected with a pathogen, but new research has revealed that gamma delta T cells are more adaptive than ...
- Automotive Adaptive Lighting System Market Estimated to Touch USD 3.91 Billion at a CAGR of 7.6% by 2027 – Report by Emergen Research
The Global Automotive Adaptive Lighting System Market is projected to reach USD 3.91 billion in 2027. The continual development in automotive ...
- Automotive Adaptive Lighting Market Share,Size 2022 – Global Trends, Market Demand, Industry Analysis, Growth, Opportunities and Forecast 2028
Global Automotive Adaptive Lighting Market provides In-Depth analysis on the market status of the Automotive Adaptive Lighting manufacturers with best facts and figures, overview, definition, SWOT ...
