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
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Video/AnimationProgrammable Paper: Advances in Synthetic BiologyWyss Institute scientists discuss the collaborative environment and team effort that led to two breakthroughs in synthetic biology that can either stand alone as distinct advances – or combine forces to create truly tantalizing potentials in diagnostics and gene therapies. Credit: Wyss Institute at Harvard University. -
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/AnimationBIND BiofilmIn this video Wyss Institute Core Faculty member Neel Joshi and Postdoctoral Fellow Peter Nguyen describe how their protein engineering system called BIND (Biofilm-Integrated Nanofiber Display) could be used to redefine biofilms as large-scale production platforms for biomaterials that can be programmed to provide functions not possible with existing materials. An animation depicts how it... -
Video/AnimationGyrification: How the Brain Got its FoldsA team led by Wyss Institute Core Faculty member L. Mahadevan used numerical simulations and a physical gel model to answer an age-old question that has vexed scientists for years: how did the outer layer of the mammalian brain (gray matter) become so convoluted atop the brain’s inner white matter? It turns out that at... -
Video/AnimationKilobots: A Thousand-Robot SwarmIn this video, Kilobots self-assemble in a thousand-robot swarm. The algorithm developed by Wyss Institute Core Faculty member Radhika Nagpal that enables the swarm provides a valuable platform for testing future collective Artificial Intelligence (AI) algorithms. Credit: Harvard School of Engineering and Applied Sciences. -
Video/AnimationDynamic Daylight Redirection SystemThis video shows Keojin Jin conducting a shoebox test that shows the light reflection effect to the top surface of the box as well as the reduction of direct light to the bottom surface of the box. Credit: Wyss Institute at Harvard University -
Video/AnimationSelf-Folding RobotsIn this video, Wyss Institute Core Faculty member Rob Wood, who is also the Charles River Professor of Engineering and Applied Sciences at Harvard’s School of Engineering and Applied Sciences (SEAS), and SEAS Ph.D. student Sam Felton discuss their landmark achievement in robotics – getting a robot to assemble itself and walk away autonomously –... -
Video/AnimationCRISPR-Cas9: Gene DrivesThis animation explains how an emerging technology called “gene drives” may be used to potentially spread particular genomic alterations through targeted wild populations over many generations. It uses mosquitoes as an example of a target species – and illustrates how the versatile genome editing tool called CRISPR makes it possible. Credit: Wyss Institute at Harvard... -
Video/AnimationSoft Robotic ExosuitIn this video, Harvard faculty member Conor Walsh and members of his team explain how the biologically inspired Soft Exosuit targets enhancing the mobility of healthy individuals and restoring the mobility of those with physical disabilities. This research is partially funded by the National Science Foundation. Note: This technology is currently in the research and... -
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... -
Video/Animation2014 Graeme Clark OrationGraeme Clark Oration 2014, The Next Technology Wave: Biologically Inspired Engineering, delivered by Dr Donald Ingber, Founding Director of the Wyss Institute for Biologically Inspired Engineering at Harvard University, at the Melbourne Convention Centre, Thursday 5 June 2014. -
Audio/PodcastCyborg Microchip MedicineThis edition of Revolutions focuses on Cyborg Microchip Medicine. Dr Don Ingber, Director of the Wyss Institute for Biologically Inspired Engineering at Harvard University is visiting Melbourne University and discussed this revolutionary research with Jon Faine.