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/AnimationClot-busting nanotherapeuticWyss Core Faculty member Donald E. Ingber describes the clot-busting nanotherapeutic. Credit: Wyss Institute at Harvard University -
Audio/PodcastBuilding an Organ on a ChipProduced for MIT Technology Review by Kyanna Sutton and Susan Young, this audio segement features Wyss Institute Core Faculty member Don Ingber speaking about how cells grown on the Wyss Institute’s organ-on-chip devices behave more like cells in the body. The devices could improve the speed and success of drug discovery and reduce animal testing.... -
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/AnimationVibrating Mattress: Preventing Infant ApneaWhat if we could prevent infant apnea? Credit: Wyss Institute at Harvard University -
Video/AnimationMaking Structures with DNA “Building Blocks”Researchers at the Wyss Institute have developed a method for building complex nanostructures out of short synthetic strands of DNA. Called single-stranded tiles (SSTs), these interlocking DNA “building blocks,” akin to Legos, can be programmed to assemble themselves into precisely designed shapes, such as letters and emoticons. Credit: Wyss Institute at Harvard University -
Video/AnimationMagnetic YeastIn this video, Wyss Core Faculty member Pamela Silver describes how her team at the Wyss Institute and Harvard Medical School induced magnetic sensitivity in a non-magnetic organism. This technology could potentially be used to magnetize a variety of different cell types in medical, industrial and research applications. Credit: Wyss Institute at Harvard University -
Video/AnimationDNA Nanorobot: Cell-Targeted, Payload-DeliveringThis video describes a cell-targeted, payload-delivering DNA nanorobot developed at the Wyss Institute that can trigger targeted therapeutic responses. This novel technology could potentially seek out cancer cells and cause them to self-destruct. Credit: Wyss Institute at Harvard University -
Video/AnimationTermite-inspired robotsInspired by termites and their building activities, the TERMES project is working toward developing a swarm construction system in which robots cooperate to build 3D structures much larger than themselves. The current system consists of simple but autonomous mobile robots and specialized passive blocks; the robot is able to manipulate blocks to build tall structures,... -
Video/AnimationWyss Institute: Self-AssemblyWyss Institute Retreat 2011. Credit: Wyss Institute at Harvard University -
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 Programmable NanoroboticsWhat if we could build programmable nanorobots to attack disease? Credit: Wyss Institute at Harvard University -
Video/AnimationWyss Institute: Our ModelWhat if we could transform the future? This video explores the Wyss Institute model of translation. Credit: Wyss Institute at Harvard University