{"id":48268,"date":"2017-12-07T07:26:15","date_gmt":"2017-12-07T06:26:15","guid":{"rendered":"https:\/\/renewable-carbon.eu\/news\/?p=48268"},"modified":"2017-12-05T14:25:15","modified_gmt":"2017-12-05T13:25:15","slug":"3d-printed-minifactories","status":"publish","type":"post","link":"https:\/\/renewable-carbon.eu\/news\/3d-printed-minifactories\/","title":{"rendered":"3D-printed minifactories"},"content":{"rendered":"
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3D printing with a new kind of ink which is containing living bacteria. (Illustration: science animated by Bara Krautz)<\/figcaption><\/figure>\n

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.<\/strong><\/p>\n

There will soon be nothing that cannot be produced with 3D printing. However, the materials used for this process are still \u201cdead matter\u201d such as plastics or metals.<\/p>\n

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The ETH logo, layer by layer printed in 3D with bacterial printing ink.<\/figcaption><\/figure>\n

A group of ETH researchers led by Professor Andr\u00e9 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.<\/p>\n

Adding bacteria with desired properties<\/h3>\n

Studart\u2019s group members and first authors Patrick R\u00fchs and Manuel Schaffner used the bacteria Pseudomonas putida<\/em> and Acetobacter xylinum<\/em> in 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.<\/p>\n

The ETH researchers\u2019 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.<\/p>\n

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 \u201crange of properties\u201d and then print any three-dimensional structure they like.<\/p>\n

As viscous as toothpaste<\/h3>\n
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Bacteria-containing ink can also be printed on a complex three-dimensional surface such as this doll’s head.<\/figcaption><\/figure>\n

During the development of the bacteria-containing hydrogel, the gel\u2019s 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\u2019s 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. \u201cThe ink must be as viscous as toothpaste and have the consistency of Nivea hand cream,\u201d is how Schaffner describes the successful formula.<\/p>\n

The scientists have named their new printing material \u201cFlink\u201d, which stands for \u201cfunctional living ink\u201d, and recently presented the technique in the journal Science Advances<\/a>.<\/p>\n

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