Bioprinted heart provides new tool for surgeons
Surgeons will soon have a powerful new tool for planning and practice with the creation of the first full-sized 3D bioprinted model of the human heart.
Surgeons will soon have a powerful new tool for planning and practice with the creation of the first full-sized 3D bioprinted model of the human heart.
Researchers mechanically reprocess silk into a biologically compatible component of bioinks that improves the structural fidelity of 3D-printed hydrogels containing cells for use in drug development and regrowing lost or damaged body
Researchers have developed an approach to print tiny tissues that look and function almost like their full-sized counterpart.
Researchers have developed an oxygen-releasing bioink that may be useful in 3D printing bioengineered cell constructs.
An international team of scientists have discovered a new material that can be 3D printed to create tissue-like vascular structures. In a new study, researchers have developed a way to 3D print graphene oxide with a protein which can organise into tubular structures that replicate some properties of vascular tissue.
Researchers have developed a new bioprinting technique based on voxels.
The researchers have use a new laser-assisted technology that maintains high levels of cell viability and functionality.
A team of Texas A&M University has designed a 3D-bioprinted model of a blood vessel that mimics the native vascular function and disease response.
The Scar Free Foundation has launched a research programme that aims to revolutionise surgeons’ ability to reconstruct nose and ear cartilage in patients affected by facial difference.
3D models of bone formation provide a tool for tissue engineering, biomedical research and drug testing.
Researchers used a customized, low-cost 3D printer to print electronics on a real hand for the first time.
Scientists have developed a new microscopic imaging approach to take a closer look at 3D printing for developing future patient implants, as well as improved disease modelling and drug screening.
Researchers look to a future someday in which doctors can hit a button to print out a scaffold on their 3D printers and create custom-made replacement skin, cartilage, or other tissue for their patients.
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.
Scientists have discovered that a molecular species known as ulvan aids wound healing in humans.
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.
A bioprinting method enables advanced tissue fabrication by using a yield-stress support bath that holds bioinks in place until they are cured and works with a wide array of bioinks.
Researchers have produced biodegradable stents with esophageal-derived bioink to directly treat radiation esophagitis.
Researchers have developed a printable bioink that could be used to create anatomical-scale functional tissues.
Researchers demonstrated a methodology that combines the bioprinting and imaging of glioblastoma cells in a way that more closely models what happens inside the human body.
Biomedical engineers developed a handheld 3D bioprinter that could revolutionize the way musculoskeletal surgical procedures are performed.
3 新利18官方d打印技术允许制造相乘ilayer blood vessels that have the unique biomolecules needed to transform into functional blood vessels when they are implanted.
With a new process, living cells can be integrated into fine structures created in a 3D printer - extremely fast and with very high resolution.
3D printing can be used to make a variety of useful objects by building up a shape, layer by layer. Scientists have now bioprinted living tissues, including muscle and bone.
Researchers have developed a 3D-printable hydrogel bioink containing mineral nanoparticles that can deliver protein therapeutics to control cell behavior.
Bioengineers have cleared a major hurdle on the path to 3D printing replacement organs with a breakthrough technique for bioprinting tissues.
Scientists hope we will soon be using 3D-printed biologically functional tissue to replace irreparably damaged tissue in the body.
Researchers have "printed" the world's first 3D vascularised engineered heart using a patient's own cells and biological materials.