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
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- Building Materials
- Cell Therapy
- Diagnostics
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- DNA Nanostructures
- Drug Development
- Filtration & Separation
- Gene Circuits
- Imaging
- Immunotherapy
- Medical Devices
- Microbiome
- Microfabrication
- Microfluidics
- Microsystems
- Nanodevices
- Organs on Chips
- Robots
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- Surface Coatings
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- Aging
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- Anti-aging
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- Balance & Motor Control
- Brain Disease
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- Drug Development
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- Personalized Medicine
- Rehabilitation
- Sepsis
- Stroke
- Sustainability
- Targeted Drug Delivery
- Toxicology
- Water
69 Results for Audio/Podcast
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Audio/PodcastScience, Your Body, And TestingIn 2015 the London Design Museum announced it’s “Design of the Year” award, and for the first time it went to a Medical design. The Wyss Institute for Biologically Inspired Engineering at Harvard University’s “Organs-on-chips” was the overall winner. The chips mimic the functions of human organs for the purpose of medical testing. This broadcast... -
Audio/PodcastDisruptive: Synthetic BiologyWhat sorts of breakthroughs are possible by modifying an organism’s genome – something researchers are now able to do ever more cheaply and efficiently? Researchers around the world are already able to program microbes to treat waste water, generate electricity, manufacture jet fuel, create hemoglobin, and fabricate new drugs. What sounds like science fiction to... -
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. -
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... -
Audio/PodcastA Lecture in Cell and Developmental Biology: Mechanobiology and Developmental ControlDonald E. Ingber, Founding Director of the Wyss Institute, Judah Folkman Professor of Vascular Biology at Harvard Medical School, and Professor of Bioengineering at the Harvard School of Engineering and Applied Sciences, talks about his article “Mechanobiology and Developmental Control,” which he wrote with Tadanori Mammoto and Akiko Mammoto for the 2013 Annual Review of... -
Audio/PodcastRobotics Lessons from TermitesJustin Werfel, Wyss Institute Research Scientist, shared his story for The Story Collider in a live storytelling event with the theme ‘The Science I Never Expected’ in June 2013. Justin Werfel received his PhD at MIT and did postdoctoral work at Harvard and the New England Complex Systems Institute. He works on topics including swarm... -
Audio/PodcastBuilding Organs, On One Microchip At A TimeBuilding Organs, On One Microchip At A Time was originally broadcast on NPR on July 29, 2012. This story features Wyss Core Faculty member Don Ingber. Original broadcast story can be found here. -
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.... -
Audio/PodcastBuilding a Sustainable FutureIn this episode of Harvard Medical LabCast, Harvard Medical School Professor of Systems Biology and Wyss Institute Core Faculty, Pam Silver discusses engineering organisms that produce fuel and even food. Find out how she’s working to build a sustainable future through synthetic biology.