Home > Press > Boosting armor for nuclear-waste eating microbes
 |
| A microbe developed to clean up nuclear waste and patented by Gemma Reguera, MSU microbiologist, has just been improved. Photo by Dena Cologgi |
Abstract:
A microbe developed to clean up nuclear waste and patented by a Michigan State University researcher has just been improved.
A team of MSU researchers has discovered how some microbes with a taste for uranium can clean up nuclear waste. To learn more visit report.president.msu.edu
Boosting armor for nuclear-waste eating microbes
East Lansing, MI | Posted on September 12th, 2014In earlier research, Gemma Reguera, MSU microbiologist, identified that Geobacter bacteria's tiny conductive hair-like appendages, or pili, did the yeoman's share of remediation. By increasing the strength of the pili nanowires, she improved their ability to clean up uranium and other toxic wastes.
In new research, published in the current issue of Applied and Environmental Microbiology, Reguera has added an additional layer of armor to her enhanced microbes.
The microbes also use the pili to stick to each other and grow a film on just about any surface, similar to the bacterial film that forms on teeth. The Geobacter biofilm, encased by a network of nanowires and slime, gives the bacteria a shield and increases their ability to neutralize even more uranium. The improvement also allows the bacteria to survive longer even when exposed to higher concentrations of the radioactive material.
Geobacter immobilizing uranium can be described as nature's version of electroplating. The beefed-up microbes engulf the uranium and turn it into a mineral, preventing the toxic material from leaching into groundwater.
Reguera's team had previously linked the conductive pili to the ability of the microbe to mineralize the soluble uranium. As the biofilm concentrates many nanowires around the Geobacter cells, more uranium can be bound and mineralized. The pili are immersed in a matrix of slime, which surrounds the biofilm cells and boosts the Geobacter's pili armor, so the biofilm now can pull double duty by helping mineralize uranium.
The shield keeps the uranium from penetrating deep into the Geobacter biofilm. By keeping this process on the surface of the film, the bacteria are not exposed to uranium and, as a community, they are able to clean up more toxic waste.
"The results surpassed our most optimistic predictions," Reguera said. "Even thin biofilms immobilized uranium like sponges. They reduced it to a mineral, all while not suffering any damage to themselves, for prolonged periods of time."
Even when exposed to extremely high and toxic concentrations of uranium, levels that would destroy individual Geobacter cells, the biofilms didn't just survive, they thrived, she added.
Additional MSU researchers contributing to the study include Dena Cologgi, Allison Speers and Blair Bullard. Shelly Kelly with EXAFS Analysis, also contributed to the study.
Reguera's future research on this front will focus on deciphering how the biofilm matrix that encases the cells shields them so effectively and how to improve its properties further.
####
For more information, please click here
Contacts:
Layne Cameron
517-353-8819
Copyright © Michigan State University
If you have a comment, please Contact us.Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.
Bookmark:
| Related News Press |
News and information
Electrifying results shed light on graphene foam as a potential material for lab grown cartilage June 6th, 2025
Quantum computers simulate fundamental physics: shedding light on the building blocks of nature June 6th, 2025
A 1960s idea inspires NBI researchers to study hitherto inaccessible quantum states June 6th, 2025
Discoveries
Researchers unveil a groundbreaking clay-based solution to capture carbon dioxide and combat climate change June 6th, 2025
Cambridge chemists discover simple way to build bigger molecules – one carbon at a time June 6th, 2025
Electrifying results shed light on graphene foam as a potential material for lab grown cartilage June 6th, 2025
A 1960s idea inspires NBI researchers to study hitherto inaccessible quantum states June 6th, 2025
Announcements
Electrifying results shed light on graphene foam as a potential material for lab grown cartilage June 6th, 2025
Quantum computers simulate fundamental physics: shedding light on the building blocks of nature June 6th, 2025
A 1960s idea inspires NBI researchers to study hitherto inaccessible quantum states June 6th, 2025
Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters
Cambridge chemists discover simple way to build bigger molecules – one carbon at a time June 6th, 2025
Electrifying results shed light on graphene foam as a potential material for lab grown cartilage June 6th, 2025
Quantum computers simulate fundamental physics: shedding light on the building blocks of nature June 6th, 2025
A 1960s idea inspires NBI researchers to study hitherto inaccessible quantum states June 6th, 2025
Environment
Researchers unveil a groundbreaking clay-based solution to capture carbon dioxide and combat climate change June 6th, 2025
Onion-like nanoparticles found in aircraft exhaust May 14th, 2025
SMART researchers pioneer first-of-its-kind nanosensor for real-time iron detection in plants February 28th, 2025
Nanobiotechnology
Ben-Gurion University of the Negev researchers several steps closer to harnessing patient's own T-cells to fight off cancer June 6th, 2025
Electrifying results shed light on graphene foam as a potential material for lab grown cartilage June 6th, 2025
Self-propelled protein-based nanomotors for enhanced cancer therapy by inducing ferroptosis June 6th, 2025
 |
||
 |
||
| The latest news from around the world, FREE | ||
 |
||
|
|
||
| Premium Products | ||
 |
||
|
Only the news you want to read!
Learn More |
||
 |
||
|
Full-service, expert consulting
Learn More |
||
|
|
||