Spray-On Hydrogel to Prevent Post-Surgery Adhesions
“Researchers at University of California San Diego have developed a spray-on hydrogel that forms a [MORE]
NEST3D Printing
From RMIT University (Melbourne, Australia): “Negative patterns in a water-soluble sacrificial template can be “developed” by casting in a [MORE]
Controlling cellular organization in bioprinting
Bioengineers at the University of Connecticut (and collaborators) present “a rapid, simple, and cost-effective approach is [MORE]
3D-Bioprinting for culture model for CLL cells.
Italian oncologists report “we exploited for the first time three-dimensional (3D) bioprinting to advance [MORE]
Light-Responsive Hydrogel to Fill Cerebral Aneurysms
South Korean scientists have found a way to stabilize brain aneurysms with a light activated [MORE]
Nasal cartilage
Bioengineers at the University of Alberta in Edmonton report “the fidelity of Freeform Reversible Embedding of Suspended Hydrogel (FRESH) [MORE]
Hydrogel Releases Drugs in Response to Tumor Microenvironment
Cancer drugs can break down in the body before they reach a tumor [MORE]
Brain cancer stem cells forming spheres on DN gel and SOX2 marker
Japanese scientists have developed a hydrogel—named DN for double [MORE]
Extracellular-Matrix-Reinforced Bioinks for 3D Bioprinting Human Tissue
From stem cell scientists at Lund University: “a tissue‐specific hybrid bioink is described, composed [MORE]
Ag-hydrogel composite for soft bioelectronics
“Researchers in Carnegie Mellon University’s Soft Machines Lab have developed a unique silver-hydrogel composite that has [MORE]
Rapid 3D Printing of Materials with Livings Cells for Organ Replacement
University of Buffalo researchers report: “. . . the [3D] [MORE]
Bioengineered hybrid muscle fiber
A research collaboration between scientists at Yonsei University in South Korea and MIT sought to address volumetric [MORE]
Superstructures formed by walking molecules help create neurons
Northwestern University bioengineers report their success in designing a superstructural material engineering functional [MORE]
Grow organoids faster by squeezing them
MIT engineers have found that compressing different cells in hydrogel causes them to differentiate and [MORE]