Researchers have fabricated 3D scaffold implants containing antibiotics at high temperatures. These scaffolds support bone regeneration and manage the bone infections.
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A dose of artificial intelligence can speed the development of 3D-printed bioscaffolds that help injuries heal.
The combination of a 2Photon 3D-printer with an innovative hydrogel-based bioink allows the direct printing of 3D structures containing living cells at both the meso- and microscale.
Human-machine interaction is complex. Researchers investigate a new form of interaction between humans and machines.
Researchers have designed a new bioink which allows small human-sized airways to be 3D bioprinted with the help of patient cells for the first time.
New hydrogel-based materials that can change shape in response to psychological stimuli, such as water, could be the next generation of materials used to bioengineer tissues and organs.
Researchers have used lasers and molecular tethers to create perfectly patterned platforms for tissue engineering.
In a research-first, scientists from Empa were able to 3D print stable well-shaped microstructures made from silica aerogels for use in biotechnology and precision engineering.
Biomedical engineers developed a handheld 3D bioprinter that could revolutionize the way musculoskeletal surgical procedures are performed.
Researchers are 3D printing "groovy" tissue-engineering scaffolds with living cells to help heal injuries.
Researchers have found a way to speed up tissue engineering for potential organ regeneration or replacement using a novel bioprinter.
A new 3D printing platform is able to fabricate multi-component scaffolds that “steal from nature” to engineer tissues organized like native tissues.