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Video/AnimationPhonoGraft: Programming the eardrum to repair itselfEardrum perforations are a widespread problem affecting millions worldwide. Current standard of care is invasive, involves harvesting an autologous tissue to patch the eardrum, and often requires to revision surgeries, while hearing outcomes remain unsatisfying. What if we could program the eardrum to repair itself after injury? Researchers at the Wyss Institute, Massachusetts Eye and...
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Video/AnimationBeating Back the Coronavirus: Face Shields for Frontline Healthcare WorkersThere is a national shortage of personal protective equipment (PPE) for frontline healthcare workers battling the COVID-19 pandemic. Researchers from the Jennifer Lewis Lab at the Harvard School of Engineering and Applied Sciences and Wyss Institute at Harvard University self-assembled into a team manufacturing greatly needed face shields for local hospitals. Credit: Wyss Institute at...
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Video/AnimationVoxelated Soft Matter via Multimaterial, Multinozzle 3D PrintingMultimaterial Multinozzle 3D (MM3D) Printing, a new technique developed by engineers at the Wyss Institute and Harvard SEAS, allows seamless switching between up to eight different materials within a single nozzle, allowing for the creation of complex 3D objects in a fraction of the time required by other extrusion-based 3D printing methods. Credit: Wyss Institute...
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Audio/PodcastDisruptive: 3D BioprintingThere are roughly 120,000 people in the United States on waiting lists for live-saving organ transplants, with only about 30,000 transplants happening every year. To address this great challenge of organ shortages, a team at the Wyss Institute led by Core Faculty member Jennifer Lewis, Sc.D., is developing a method for 3D bioprinting organ tissues...
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Video/AnimationA Swifter Way Towards 3D-printed Organs20 people die waiting for an organ transplant every day in the US, but lab-grown organs so far lack the cellular density and functions required to make them viable replacements. The new SWIFT method from the Wyss Institute and Harvard SEAS solves those problems by 3D printing vascular channel networks directly into living tissue constructs,...
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Video/AnimationKidney Organiods: Flow-Enhanced Vascularization and Maturation In VitroThis video explains how the collaborative project created vascularized kidney organoids and how they advance the field of tissue engineering. Credit: Wyss Institute at Harvard University.
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Video/AnimationAcoustophoretic PrintingHavard researchers have developed acoustophoretic printing, a method that uses 3D printing technology and highly localized sound waves to generate of droplets with defined sizes and a wide range of viscosities.
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Video/Animation3D Printing: Soft Robots with Embedded SensorsResearchers from the Wyss Institute and Harvard SEAS have developed a platform for 3D printed, soft robots with embedded sensors that can feel touch, pressure, motion and temperature. This technology could be used for integrated sensing across a range of soft robotic applications. Credit: Harvard SEAS
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Video/AnimationNew Wyss Institute Initiative – 3D Organ EngineeringWyss Institute Core Faculty members Christopher Chen and Jennifer Lewis describe the Wyss Institute’s new initiative focused on organ engineering, which leverages our expertise in biomaterials, tissue engineering, three dimensional biofabrication, and stem cell development.
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Video/AnimationTherapeutic Organ Engineering: Highlights From The 8th Annual Wyss SymposiumThe 8th Annual Wyss International Symposium focused on innovations in therapeutic organ engineering, featuring diverse speakers doing exciting work in 3D organ engineering, materials fabrication, and vascular integration. This video highlights some of the themes discussed in their presentations as well as the advances that are leading to the ultimate goals of developing new approaches...
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Audio/PodcastHow 3D Bioprinting Could Revolutionize Organ ReplacementHow 3D Bioprinting Could Revolutionize Organ Replacement was originally broadcast on WBUR on November 22, 2017. This story features Wyss Core Faculty member Jennifer Lewis. The original broadcast story can be found here.
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Video/Animation8th Annual Wyss Institute Symposium: Therapeutic Organ EngineeringScreened just before the symposium opening, this animation artistically connects concepts of therapeutic organ engineering presented during the event. Credit: Wyss Institute at Harvard University
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Video/AnimationHybrid 3D Printing of Soft ElectronicsA new hybrid 3D printing technique developed at the Wyss Institute at Harvard University, Harvard’s John A. Paulson School of Engineering and Applied Sciences, and the Air Force Research Laboratory combines stretchable conductive inks and electronic components into flexible, durable wearable devices that move with the body and offer increased programmability. This research was supported...
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Video/Animation3D Printing Ceramic FoamThis video shows the 3D printing process that adds layer upon layer of the foam link to create a 3D porous ceramic honeycomb pattern. This new capability is an important step toward generating porous materials for lightweight structures, thermal insulation, tissue scaffolds and other applications. Credit: Lori Sanders
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Video/Animation3D Printed Heart-on-a-ChipIn this video, learn how Wyss Institute and Harvard SEAS researchers have created a 3D-printed heart-on-a-chip that could lead to new customizable devices for short-term and long-term in vitro testing. Credit: Johan U. Lind (Disease Biophysics Group), Alex D. Valentine and Lori K. Sanders (Lewis Lab)/Harvard University
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Video/AnimationBioprinting: The Kidney’s Proximal TubulesIn this video, see how the Wyss Institute team has advanced bioprinting to the point of being able to fabricate a functional subunit of a kidney. Credit: Wyss Institute at Harvard University
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Video/AnimationOctobot: A Soft, Autonomous RobotThe Octobot is the first entirely soft, autonomous robot. It is made by a combination of embedded 3D printing, modeling, and soft lithography. Inspired by real octopuses, the Octobot has no rigid components. It is powered by a chemical reaction and controlled with a microfluidic logic that directs the flow of fuel. The logic circuit...
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Video/Animation3D Printing Metal in MidairIn this video, see the laser-assisted method developed by Wyss Core Faculty member Jennifer Lewis that allows metal to be 3D printed in midair. Credit: Lewis Lab / Wyss Institute at Harvard University
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Video/AnimationPrinting Vascular TissuePrinting vessel vasculature is essential for sustaining functional living tissues. Until now, bioengineers have had difficulty building thick tissues, lacking a method to embed vascular networks. A 3D bioprinting method invented at the Wyss Institute and Harvard SEAS embeds a grid of vasculature into thick tissue laden with human stem cells and connective matrix. Printed...
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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...
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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...
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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...
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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
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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
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Video/AnimationTiny 3D-Printed BatteryIn this video, a 3D-printer nozzle narrower than a human hair lays down a specially formulated “ink” layer by layer to build a microbattery’s anode from the ground up. Unlike ink in an office inkjet printer, which comes out as droplets of liquid and wets a piece of paper, these 3D-printer inks are specially formulated...