Multimedia
- Multimedia Type
- Focus Areas
- 3D Organ EngineeringHighly functional, multiscale, vascularized organ replacements that can be seamlessly integrated into the body
- Bioinspired Therapeutics & DiagnosticsTherapeutic discovery and diagnostics development enabled by microsystems engineering, molecular engineering, computational design, and organ-on-a-chip in vitro human experimentation technology
- Computational Design & DiscoveryCombining predictive bioanalytics and machine learning with physical and mathematical modeling and simulation
- Diagnostics AcceleratorDeveloping new diagnostic technologies that solve important healthcare challenges through collaboration at the Wyss Institute with clinicians and industry partners
- Immuno-MaterialsMaterial-based systems capable of modulating immune cells ex vivo and in the human body to treat or diagnose disease
- Living Cellular DevicesRe-engineered living cells and biological circuits as programmable devices for medicine, manufacturing and sustainability
- Molecular RoboticsSelf-assembling molecules that can be programmed like robots to carry out specific tasks without requiring power
- Synthetic BiologyBreakthrough approaches to reading, writing, and editing nucleic acids and proteins for multiple applications, varying from healthcare to data storage
- Technology Areas
- 3D Printing
- Actuators
- Biomarker
- Building Materials
- Cell Therapy
- Diagnostics
- Disease Model
- DNA Nanostructures
- Drug Development
- Filtration & Separation
- Gene Circuits
- Imaging
- Immunotherapy
- Medical Devices
- Microbiome
- Microfabrication
- Microfluidics
- Microsystems
- Nanodevices
- Organs on Chips
- Robots
- Sensors
- Surface Coatings
- Therapeutics
- Vaccines
- Wearable Devices
- Disciplines
- Aging
- Architecture
- Biochemistry
- Bioinformatics
- Biotechnology
- Cell Biology
- Chemical Engineering
- Chemistry
- Computer Science
- Control
- Design
- Electrical Engineering
- Genetics
- Genome Engineering
- Immune Engineering
- Materials Science
- Mechanical Engineering
- Mechanobiology
- Medicine
- Microtechnology
- Nanobiotechnology
- Nanotechnology
- Pharmacology
- Physics
- Physiology
- Polymer Chemistry
- Regenerative Medicine
- Robotics
- Self Assembly
- Stem Cell Engineering
- Surgery
- Synthetic Biology
- Tissue Engineering
- Toxicology
- Application Areas
- Anti-aging
- Apparel
- Bacteria
- Balance & Motor Control
- Brain Disease
- Cancer
- Diabetes
- Drug Development
- Energy
- Fundamental Research
- Heart Disease
- Hemostasis
- Infectious Disease
- Inflammatory Diseases
- Intestinal Disease
- Kidney Disease
- Liver Disease
- Lung Disease
- Manufacturing
- Motor Control
- Personalized Medicine
- Rehabilitation
- Sepsis
- Stroke
- Sustainability
- Targeted Drug Delivery
- Toxicology
- Water
- Women's Health
294 Results for Video/Animation
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Video/AnimationThe milliDelta RobotDelta Robots are comprised of three articulating arms connected to an output stage. They are extremely precise and agile, and can be used for “pick & place” and 3D Printing. Researchers at the Wyss Institute and Harvard SEAS have developed a millimeter-scale delta robot, the “milliDelta.” Possible applications at this scale include microassembly, micromanipulation, and... -
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. -
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... -
Video/AnimationOrigami-Inspired Artificial MusclesArtificial muscles could make soft robots safer and stronger. Researchers at the Wyss Institute, Harvard SEAS, and MIT CSAIL have developed a novel design approach for origami-inspired artificial muscles, capable of lifting 1000x its own weight. The muscles are made of a compressible skeleton and air or fluid medium encased in a flexible skin, and... -
Video/AnimationPrimer Exchange ReactionIn this video, Jocelyn Kishi illustrates how Primer Exchange Reaction (PER) cascades work to autonomously create programmable long single-stranded DNA molecules. Credit: Wyss Institute at Harvard University. -
Video/AnimationWhat Is BIOMOD?BIOMOD is a biomolecular design competition for students created by the Wyss Institute for Biologically Inspired Engineering at Harvard University. Each year BIOMOD holds a Jamboree, an annual conference at which all BIOMOD teams convene to present their work from the summer. This year’s Jamboree will take place in Genentech Hall at UCSF in San Francisco,... -
Video/AnimationAerial-Aquatic MicrorobotInspired by insects, researchers at the Wyss Institute and Harvard SEAS have developed a robot capable of flying…and swimming. Once the robot swims to the surface of the water, surrounding water is collected in a buoyancy chamber. Within the chamber, an electrolytic plate produced oxyhydrogen. This gives the robot extra buoyancy, which enables it to... -
Video/AnimationScience On TapDuring this live studio recording of Science On Tap, Donald Ingber, M.D., Ph.D. will explain to host Graham Chedd why the name of the institute he heads at Harvard, the Wyss Institute for Biologically Inspired Engineering, nicely sums up its goal. Dr. Ingber’s stellar career has focused on turning nature’s solutions to engineering problems into... -
Video/AnimationThe BeginningThe struggle for supremacy has begun. But only one will be victor. Only one will dictate the future for generations to come… Watch the new official trailer now. -
Video/AnimationAuto-cyclic Proximity RecordingThis video explains how “Auto-cycling Proximity Recording” works to identify pairs of nearby molecular targets and how it can be used as a tool to decipher the geometry of 3-dimensional engineered and natural molecules. Credit: Wyss Institute at Harvard University -
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 -
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...