ETH researchers have developed a biocompatible ink for 3D printing using living bacteria. This makes it possible to produce biological materials capable of breaking down toxic substances or producing high-purity cellulose for biomedical applications.
There will soon be nothing that cannot be produced with 3D printing. However, the materials used for this process are still “dead matter” such as plastics or metals.
A group of ETH researchers led by Professor André Studart, Head of the Laboratory for Complex Materials, has now introduced a new 3D printing platform that works using living matter. The researchers developed a bacteria-containing ink that makes it possible to print mini biochemical factories with certain properties, depending on which species of bacteria the scientists put in the ink.
Adding bacteria with desired properties
Studart’s group members and first authors Patrick Rühs and Manuel Schaffner used the bacteria Pseudomonas putida and Acetobacter xylinumin their work. The former can break down the toxic chemical phenol, which is produced on a grand scale in the chemical industry, while the latter secretes high-purity nanocellulose. This bacterial cellulose relieves pain, retains moisture and is stable, opening up potential applications in the treatment of burns.
The ETH researchers’ new printing platform offers numerous potential combinations. In a single pass, the scientists can use up to four different inks containing different species of bacteria at different concentrations in order to produce objects exhibiting several properties.
The ink is composed of a biocompatible hydrogel that provides structure. The hydrogel itself is composed of hyaluronic acid, long-chain sugar molecules, and pyrogenic silica. The culture medium for the bacteria is mixed into the ink so that the bacteria have all the prerequisites for life. Using this hydrogel as a basis, the researchers can add bacteria with the desired “range of properties” and then print any three-dimensional structure they like.
As viscous as toothpaste
During the development of the bacteria-containing hydrogel, the gel’s flow properties posed a particular challenge: the ink must be fluid enough to be forced through the pressure nozzle. The consistency of the ink also affects the bacteria’s mobility. The stiffer the ink, the harder it is for them to move. If the hydrogel is too stiff, however, Acetobacter secretes less cellulose. At the same time, the printed objects must be sturdy enough to support the weight of subsequent layers. If they are too fluid, it is not possible to print stable structures, as these collapse under the weight exerted on them. “The ink must be as viscous as toothpaste and have the consistency of Nivea hand cream,” is how Schaffner describes the successful formula.
The scientists have named their new printing material “Flink”, which stands for “functional living ink”, and recently presented the technique in the journal Science Advances.
Enormous potential
As yet, the material scientists have not studied the lifespan of the printed minifactories. “As bacteria require very little in the way of resources, we assume they can survive in printed structures for a very long time,” says Rühs.
However, the research is still in its initial stages. “Printing using bacteria-containing hydrogels has enormous potential, as there is such a wide range of useful bacteria out there,” says Rühs. He blames the bad reputation attached to microorganisms for the almost total lack of existing research into additive methods using bacteria. “Most people only associate bacteria with diseases, but we actually couldn’t survive without bacteria,” he says. However, the researchers believe their new ink is completely safe. The bacteria they use are all harmless and beneficial.
Sensors for toxic substances and filters for oil spills
In addition to medical and biotechnology applications, the researchers envisage many other potential uses. For example, objects of this kind can be used to study degradation processes or biofilm formation. One practical application might be a bacteria-containing 3D-printed sensor that could detect toxins in drinking water. Another idea would be to create bacteria-containing filters for use in disastrous oil spills. First, it will be necessary to overcome the challenges of the slow printing time and difficult scalability. Acetobacter currently takes several days to produce cellulose for biomedical applications. However, the scientists are convinced that they can further optimise and accelerate the processes.
The development of special materials for 3D printing is a speciality of ETH professor André Studart’s research group. For example, he and his interdisciplinary team have also developed a printable high-porosity ink made of ceramic, which allows the printing of very lightweight bone-like structures used for energy production.
The Latest on: Mini biochemical factories
[google_news title=”” keyword=”mini biochemical factories” num_posts=”10″ blurb_length=”0″ show_thumb=”left”]- Garment factories not reopening tomorrowon August 5, 2024 at 2:45 pm
The Bangladesh Garment Manufacturers and Exporters Association (BGMEA) today decided not to reopen factories from tomorrow as their management wants to observe the situation further for the change ...
- Mini supersizes, electrifies product lineupon August 4, 2024 at 3:00 am
Mini has not announced plans to bring a pair of China-made electric models to the U.S., but it is likely once production expands to Mini's Oxford, England factory in 2026.
- The best mini PCs in 2024on August 1, 2024 at 6:31 am
Here’s how it works. The best mini PCs might be tiny compared to standard-sized rigs but they pack enough power to perform a wide range of tasks — including web browsing, content creation and ...
- Build A Factory Codes (August 2024)on August 1, 2024 at 3:47 am
Follow our easy steps bellow in order to redeem Build a Factory codes: Of course, we also recommend bookmarking this page and checking back regularly. We’ll update our guide as soon as we spot ...
- How researchers turn bacteria into cellulose-producing mini-factorieson July 30, 2024 at 12:59 pm
Researchers have modified certain bacteria with UV light so that they produce more cellulose. The basis for this is a new approach with which the researchers generate thousands of bacterial variants ...
- Turning Bacteria Into Cellulose-Producing Mini-Factorieson July 29, 2024 at 10:15 pm
Researchers at ETH Zurich have introduced an innovative approach to transform the bacterium 'Komagataeibacter sucrofermentans' into a highly-efficient cellulose-producing mini-factory. This ...
- Researchers Transform Bacteria into Efficient Cellulose-Producing Mini-Factorieson July 29, 2024 at 5:00 pm
Consequently, researchers have for some time been trying to turn microorganisms into living mini-factories that can produce larger quantities of a desired product more quickly. This requires either ...
- The 2025 Mini Cooper S Is Speeding to Maturityon July 18, 2024 at 5:00 pm
A sea of Mini silhouettes charged around the bend as we descended down the Million Dollar Highway into the bygone towns of the Rocky Mountain mining era. The hatchback shape hasn't changed much ...
- What’s next for the iPad mini? Here’s what the rumors sayon July 16, 2024 at 5:49 pm
The current-generation iPad mini was introduced back in September 2021 and hasn’t been updated since. What’s next for the iPad mini? Rumors suggest an update could come later this year with an ...
- I visited 8 Chinese factories in 8 days, and it blew my mindon July 15, 2024 at 7:39 am
So I made the trip to China and snuck my way behind the scenes at a number of factories to check out some ... and have been excited to watch each new mini-electric motorcycle the company has ...
via Google News and Bing News