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Video/AnimationJanus Tough Adhesives for Tendon RepairThere is a large unmet need for tendon regeneration therapies after injury. Building upon the tough gel adhesive technologies developed at the Wyss Institute at Harvard University and the Harvard School of Engineering and Applied Sciences, researchers from these institutions collaborated with a group at Novartis to create the Janus Tough Adhesives (JTAs). This two-sided... -
Video/AnimationInnovation Showcase – Tough Gel TechnologyJay Sugarman talks with Benjamin Freedman, PhD. Benjamin is a Postdoctoral Fellow at the Wyss Institute for Biologically Inspired Engineering at Harvard University. He’s on Innovation Showcase to inform viewers about the groundbreaking research he and some of his colleagues have been involved with related to the development of the next generation of medical-grade adhesives,... -
Video/AnimationSelf-regenerating bacterial hydrogels as intestinal wound patchesThis animation explains how self-regenerating bacterial hydrogels could be used as adhesive patches to help intestinal wounds heal. Credit: Wyss Institute at Harvard University. -
Video/AnimationTough Gel AdhesivesInspired by the mucus secreted by the Dusky Arion slug, researchers at the Wyss Institute have developed a surgical adhesive that can adhere to wet and dynamic surfaces inside the body, including the heart, lung, tendons, cartilage, and bone. Coupled with a novel tough hydrogel, which can undergo huge amounts of deformation without breaking, this... -
Audio/PodcastDisruptive: Cancer Vaccine and Immuno-MaterialsImmunotherapy – treatment that uses the body’s own immune system to help fight disease – has groundbreaking and life-saving implications. In an effort to make immunotherapy more effective, Wyss Institute researchers are developing new immuno-materials, which help modulate immune cells to treat or diagnose disease. In this episode of Disruptive, Dave Mooney, Wyss Core Faculty... -
Video/AnimationFouling Marine FoulingMarine fouling occurs when organisms attach themselves to underwater objects like boats, rope, pipes and building structures. Mussels are one of the biggest culprits. Once attached, they are difficult to remove, leading to operational downtime, increased energy use and damage. Paints and coatings are currently used to prevent marine fouling, but are frequently toxin-based and not... -
Audio/PodcastSlug Slime Inspires Scientists To Invent Sticky Surgical GlueSlug Slime Inspires Scientists To Invent Sticky Surgical Glue was originally broadcast on NPR’s All Things Considered on July 27, 2017. This story features Wyss Institute Technology Development Fellow Jianyu Li. The original broadcast story can be found here. -
Audio/PodcastBiofilms: Reprogramming Bacteria to Improve LivesWyss Core Faculty member Neel Joshi and Postdoctoral Fellow Anna Duraj-Thatte discuss the intersection between synthetic biology and materials science as an underexplored area with great potential to positively affect our daily lives—applications ranging from manufacturing to medicine. Dr. Joshi outlines ways that his lab at the Wyss Institute is looking at reprogramming bacteria in... -
Video/AnimationWyss Focus: Immuno-MaterialsWyss Core Faculty, Dave Mooney, explains our new Immuno-Materials Focus Area, which adds a new dimension to immunotherapy in that it harnesses materials to make treatments more efficient and effective. These material-based systems are capable of modulating immune cells and releasing them into the body where they can treat diseases. -
Video/AnimationArtScience Talks @ Le Lab – Seeing Is Believing: Therapeutic Cancer VaccinesWyss Core Faculty member David Mooney presents a talk with Mary Mooney, titled Seeing Is Believing: Therapeutic Cancer Vaccines. Marshaling a patientÍs immune system to recognize and destroy cancerous cells is an exciting strategy to attack cancer, and this talk will explore materials that engage the immune system through science and artistic representation. Mary K.... -
Video/AnimationEfficient Recovery of Stem Cell SheetsSee in this video how an intact sheet of mesenchymal stem cells, stained with a violet dye, can be lifted off the infused polymer substrate in the culture dish using a filter paper and transferred to a new surface. Credit: Wyss Institute at Harvard University -
Video/Animation4D Printing: Shapeshifting ArchitecturesA team at the Wyss Institute and Harvard SEAS has developed a new microscale printing method to create transformable objects. These “4D-printed” objects go a step beyond 3D printing to incorporate a fourth dimension: time. The method was inspired by the way plants change shape over time in response to environmental stimuli. This orchid-shaped structure... -
Video/AnimationEnvironmental Impact: Chitin-Inhibiting Pesticides Called into QuestionChitin, a molecule that serves a purpose in the developmental biology of insects, fungi and shrimp, has long been a target of growth-inhibiting pesticides due to the belief that it did not exist in vertebrates. For decades, chitin-inhibiting pesticides have stunted the growth of insects and fungi to protect valuable crops. Now, research from the... -
Video/AnimationHuman Organs-On-ChipsWyss Institute researchers and a multidisciplinary team of collaborators have engineered microchips that recapitulate the microarchitecture and functions of living human organs, including the lung, intestine, kidney, skin, bone marrow and blood-brain barrier. These microchips, called ‘organs-on-chips’, offer a potential alternative to traditional animal testing. Each individual organ-on-chip is composed of a clear flexible polymer... -
Video/AnimationBioinspired Blood Repellent CoatingIn this video, Wyss Institute Founding Director Don Ingber, Core Faculty member Joanna Aizenberg, Staff Scientist Dan Leslie and Postdoctoral Fellow Anna Waterhouse explain how a coating they developed using FDA-approved materials could prevent blood clotting in medical devices without the use of blood thinners. Credit: Wyss Institute at Harvard University -
Video/Animation3D Printing: Cellular CompositesMaterials scientists at Harvard University have created lightweight cellular composites via 3D printing. These fiber-reinforced epoxy composites mimic the structure and performance of balsa wood. Because the fiber fillers align along the printing direction, their local orientation can be exquisitely controlled. These 3D composites may be useful for wind turbine, automotive and aerospace applications, where... -
Audio/PodcastShrimp Shells Could Make the Green Plastic of the FutureUnlike other forms of bioplastic, like those made from potatoes or corn, chitin plastic does not simply replace the carbon source for the polymer, it actually replaces the carbon-based plastic polymer, making it a totally biodegradable and sustainable material. Researchers at Harvard’s Wyss Institute used chitin from discarded shrimp shells from a shrimp processing plant... -
Video/AnimationTough GelA team at the Wyss Institute is honing a tough, rubbery hydrogel initially developed at Harvards School of Engineering and Applied Sciences. The gel is 90 percent water, yet it stretches without breaking to more than 20 times its original length and recoils like rubber, the researchers first reported in Nature in 2012. In fact,... -
Video/AnimationShrinking GelWhen the temperature rises to just below body temperature, this biocompatible gel shrinks dramatically within minutes, bringing tooth-precursor cells (green) closer together. Credit: Basma Hashmi -
Video/AnimationChitosan BioplasticIn this video, the team grew a California Blackeye pea plant in soil enriched with its chitosan bioplastic over a three-week period – demonstrating the material’s potential to encourage plant growth once it is returned to the environment. Credit: Wyss Institute at Harvard University -
Video/AnimationBioprinting: Building in Blood VesselsBuilding in blood vessels. Then they addressed a big challenge in tissue engineering: embedding 3D vascular networks. They developed a ‘fugitive’ ink that can easily be printed, then suctioned off to create open microchannels that can then be populated with blood-vessel-lining cells to allow blood to flow. Read more: wyss.harvard.edu/viewpressrelease/141 Credit: Wyss Institute at Harvard... -
Video/AnimationBioprinting: Building with Bio-InksBuilding with bio-inks. Using their custom-built printer, the fugitive ink for the vasculature, and other biological inks containing extracellular matrix and human cells, the researchers printed a 3D tissue construct. Credit: Wyss Institute at Harvard University -
Video/AnimationBioprinting: Building Intricate StructuresBuilding intricate structures. The team first designed a custom printer that can precisely co-print multiple materials in 3D to create intricate heterogeneous patterns. Credit: Wyss Institute at Harvard University -
Video/AnimationNew coating turns glass into superglassA transparent new coating makes ordinary glass tough, ultraslippery, and self-cleaning. The coating is based on SLIPS — the world’s slipperiest synthetic substance. Here, a droplet of dyed octane quickly beads up and rolls off a watch glass with the new coating. To learn more, go to Credit: Wyss Institute at Harvard University -
Video/AnimationNanoRx: Clot-Busting NanotherapeuticIn this animation, learn how the Wyss Institute clot-busting nanotherapeutic is activated by fluid high shear force – which occurs where blood flows through vessels narrowed by obstruction – to specifically target clots and dissolve them away. By pairing this drug with an intra-arterial device that restores blood flow to complete obstructions, the drug-device combination... -
Video/AnimationMeTro HydrogelsAn international team led by the Wyss Institute recently used microfabrication techniques to design a new micropatterned hydrogel that shows great promise for tissue engineering — cardiac tissue in particular. It incorporates an elastic protein called tropoelastin, which is found in all elastic human tissues. The Wyss Institute’s Ali Khademhosseini discusses the research. Credit: Wyss... -
Video/AnimationSLIPS‘SLIPS’ technology, inspired by the slippery pitcher plant that repels almost every type of liquid and solid, is a unique approach to coating industrial and medical surfaces that is based on nano/microstructured porous material infused with a lubricating fluid. By locking in water and other fluids, SLIPS technology creates slick, exceptionally repellent and robust self-cleaning... -
Video/AnimationSLIPS: Keeping Ice AwayWhat if we could design surfaces that prevent ice formation? ‘SLIPS’ technology, inspired by the slippery pitcher plant that repels almost every type of liquid and solid, is a unique approach to coating industrial and medical surfaces that is based on nano/microstructured porous material infused with a lubricating fluid. By locking in water and other... -
Video/AnimationIntroduction to Organs-on-a-ChipWhat if we could test drugs without animal models? Wyss Institute researchers and a multidisciplinary team of collaborators have engineered microchips that recapitulate the microarchitecture and functions of living human organs, including the lung, intestine, kidney, skin, bone marrow and blood-brain barrier. These microchips, called ‘organs-on-chips’, offer a potential alternative to traditional animal testing. Each...