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Video/AnimationDoriNano – Improved DNA Origami Nanodelivery to Fight Cancer and Other DiseasesWe’re developing DNA Origami nanodelivery, which is transforming nanoparticle industry. Developed at the Dana Farber Cancer Institute and the Wyss Institute at Harvard University, this innovative approach overcomes the challenges of other nanoparticles, offering stability, high drug loading capacity, nano-scale control of cargo spacing, and more – making it a highly customizable solution for delivering... -
Video/AnimationInnovating Diagnostics to Improve Clinical Care and Patient OutcomesGuest speaker, Sarah-Beth Perullo, shares the immense difficulty she faced in obtaining a diagnosis for her mysterious symptoms. Her story is a sobering reminder of how frequent patient symptoms are dismissed in the medical field. Credit: Wyss Institute at Harvard University -
Video/AnimationReimagining Solutions to the Infectious Disease ChallengeWilliam Lautzenheiser narrowly survived a rare and devastating infection that claimed all four of his limbs. In a brilliant display of resilience and to cope with his new normal, he turned to comedy, as a way of telling his story in a relatable way. Comedy footage courtesy of STUMPED: stumpedthemovie.com Credit: Wyss Institute at Harvard... -
Video/AnimationReimagine the World – Volume 2 – Diagnostics AcceleratorTwo clinicians collaborating with the Wyss Diagnostics Accelerator (DxA), Lise Johnson and Craig Hersh, as well as two members of the Wyss DxA Industrial Partnership Program, Nell Meosky Luo and Andy Levin, share how they would Reimagine the World and the personal stories that fuel their passion for the work they are doing. Credit: Wyss... -
Video/AnimationFeCILL: Reimagining How We Treat the Sickest PatientsOpportunistic fungal infections usually only affect patients whose immune systems are compromised, but when they do, they are often deadly – the mortality rate for these infections can be as high as 25%. Existing antifungal treatments have high levels of toxicity, and can harm the patient more than they help. Researchers at the Wyss Institute... -
Video/AnimationDoriVac: Square Block DNA Origami VaccineThis animation explains how DoriVac leverages DNA origami nanotechnology and immune activators to stimulate stronger and long-lasting immune responses against cancer and potentially infectious diseases. Credit: Wyss Institute at Harvard University -
Video/AnimationReimagine the World: Volume 1Four Wyss Institute scientists, Mariana Garcia-Corral, Pawan Jolly, Megan Sperry, and Mike Super, share how they would Reimagine the World and the personal stories that fuel their passion for the work they are doing. We’d love to hear how you would Reimagine the World! Please visit the following link to share your ideas: https://wyss.typeform.com/to/o9xM7cG1 Credit:... -
Audio/PodcastPreventing the Next Pandemic with Organ ChipsIn search for strategies to curb pandemics, scientists strive to understand how pathogens slip past the immune system and wreak havoc on the body. To achieve this goal, researchers study viral infection in models that mimic how different cell types interact with each other, the immune system, or the environment. Organ-on-a-chip models combine tissue engineering... -
Audio/PodcastDr. Adama Sesay – BioengineerHost Naomi Sesay interviews Wyss Senior Staff Engineer Adama Sesay, who, despite the odds against her, works on the front line of COVID-19 research. -
Audio/PodcastBIOS Podcast – Accelerating Diagnostics Innovation with David Walt – Professor at Harvard, Core Faculty member at the Wyss InstituteDavid Walt is the Hansjörg Wyss Professor of Bioinspired Engineering at Harvard Medical School, Professor of Pathology at Harvard Medical School & Brigham and Women’s Hospital, Core Faculty Member of the Wyss Institute at Harvard University, Associate Member at the Broad Institute, Howard Hughes Medical Institute Professor, and is co-Director of the Mass General Brigham... -
Video/Animation2021 Kabiller Prize in Nanoscience and NanomedicineDavid R. Walt, a Wyss Core Faculty member, member of the faculty at Harvard Medical School in the Department of Pathology, and a Howard Hughes Medical Institute Professor, is the winner of the 2021 Kabiller Prize in Nanoscience and Nanomedicine, the world’s largest monetary award for outstanding achievement in the field of nanotechnology and its... -
Video/AnimationeToehold: an RNA-detecting control element for use in RNA therapeutics, diagnostics and cell therapiesThis animation shows an example of an eToehold that detects and signals the presence of a specific viral RNA in a human cell. After the virus has injected its RNA into a host cell, the RNA acts as a “trigger RNA” by binding to a complementary sequence within the eToehold specifically engineered for its detection.... -
Video/AnimationBeating Back the Coronavirus – Nasal swabsEarly in the COVID-19 pandemic, Nasopharyngeal swabs or nasal swabs, used to collect mucus samples to test for the SARS-CoV-2 virus, were in short supply. This created a bottleneck in diagnostics, hampering our ability to control the pandemic. To respond to this need, an interdisciplinary team at the Wyss Institute and Harvard Medical School collaborated... -
Video/AnimationInnovation Showcase – Wyss Institute: Wearable Technology with BiosensorsJay Sugarman talks with Peter Nguyen Ph.D., Luis Soenksen, Ph.D., and Nina Donghia–all of whom are associated with the Wyss Institute for Biologically Inspired Engineering at Harvard University. They’re on Innovation Showcase to inform viewers about the groundbreaking research they and their colleagues have been involved with related to the development of wearable technology as... -
Video/AnimationmiSherlock – Detecting COVID-19 Variants from SalivaDespite increasing vaccination rates, new, more-infectious variants of SARS-CoV-2 could prolong the COVID-19 pandemic. Researchers at the Wyss Institute at Harvard University and MIT have created a low-cost, CRISPR-based diagnostic platform that can detect SARS-CoV-2 variants in a patient’s saliva without the need for any additional equipment. The team hopes their device will enable more... -
Audio/PodcastTalking Biotech: COVID-19 Detection Masks and WearablesCOVID-19 is the spectrum of pathologies caused by the SARS-CoV2 virus. While the pandemic moves well into its second year, the importance of detection in populations cannot be overstated. However, testing methods typically include visiting testing centers, and it is hard to find a test that is both rapid and precise. Wyss Research Scientist Dr.... -
Video/AnimationBeating Back the Coronavirus – COVID-19 detecting face maskUsing freeze-dried cell free reactions and CRISPR-based biosensors, researchers at the Wyss Institute and M.I.T. have created a face mask that can detect the SARS-CoV-2 virus in a wearer’s breath in under 90 minutes. Such a mask would allow medical professionals to quickly identify COVID-19 patients and begin effective treatments. This facemask is a proof-of-concept... -
Video/AnimationWearable Synthetic Biology – Clothing that can detect pathogens and toxinsWhat if we could create clothing that harnesses synthetic biology to detect the wearer’s exposure to toxins and pathogens? A team of researchers at the Wyss Institute and M.I.T. did just that byembedding freeze-dried, synthetic biology-based sensors into flexible materials and textiles. These sensors can detect pathogens such as the SARS-CoV-2 virus and toxins such... -
Video/AnimationThe Game-Changing Potential of mRNA VaccinesPromising mRNA vaccines years ago emerged from early-stage development, only to stall before proving themselves in clinical trials. Pushed by pandemic urgency across the notorious “Valley of Death,” this platform vastly exceeded expectations and is now poised to transform the vaccine R&D landscape. During the early months of the historic rollout of COVID-19 vaccines, Sabin’s... -
Video/AnimationOMNIVAX: Infection Vaccine PlatformThis video explains how OMNIVAX – an immuno-material-based vaccine technology can be used to rapidly create injectable vaccines against diverse viral and bacterial pathogens, and how the platform is used by the team to develop a vaccine against recurring urinary tract infections (UTIs) in their lead human application. Credit: Wyss Institute at Harvard University. -
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... -
Video/AnimationBeating Back the CoronavirusWhen the coronavirus pandemic forced Harvard University to ramp down almost all on-site operations, members of the Wyss Institute community refocused their teams, and formed new ones, in order to fight COVID-19 on its multiple fronts. These efforts include building new pieces of personal protective equipment that were delivered to frontline healthcare workers, developing new... -
Video/AnimationRapid Triage Test for Active Pulmonary TuberculosisThere’s a large unmet need for accurate, fast, and inexpensive diagnostics for active tuberculosis (ATB), which claims the lives over a million people per year. A team of researchers from the Wyss Institute for Biologically Inspired Engineering, The Broad Institute of Harvard and MIT, Brigham and Women’s Hospital (BWH), and several other collaborating institutions have... -
Video/AnimationHumans of the Wyss – Faculty Edition with Mike LevinOur interview series, “Humans of the Wyss – Faculty Edition,” features Wyss Institute faculty members discussing how they think about their work, the influences that helped shape them as scientists, and their collaborations at the Wyss Institute and beyond. In the second edition of the series, Benjamin Boettner, Wyss Institute Communications team member, talks to... -
Video/AnimationLiquid-Infused Tympanostomy TubesResearchers at the Wyss Institute have developed next-generation tympanostomy tubes with an innovative material design that significantly reduces biofouling, implant size, need for revision surgeries, and promotes drug delivery into the middle ear. Credit: Wyss Institute at Harvard University -
Audio/PodcastProtein Engineering: Editing FunctionalityProtein Engineering: Editing Functionality was originally broadcast on Think Research, a podcast by Harvard University, on April 19, 2018. In this story, Wyss Lead Senior Staff Scientist Michael Super, Ph.D. shares his story of how the spread of infectious disease throughout South Africa and London inspired him to pursue human health and combat disease. The... -
Video/AnimationToehold Exchange ProbesThis animation explains how toehold probes consisting of a “probe strand” and a “protector strand” are assembled and how they leverage thermodynamic principles to allow the specific detection of a correct target sequence, or to prevent them from detecting a spurious target sequence that can differ from the correct target sequence by only a single... -
Audio/PodcastDisruptive: Cancer Vaccine and Immuno-MaterialsImmunotherapy – treatment that uses the body’s own immune system to help fight disease – has groundbreaking and life-saving implications. In an effort to make immunotherapy more effective, Wyss Institute researchers are developing new immuno-materials, which help modulate immune cells to treat or diagnose disease. In this episode of Disruptive, Dave Mooney, Wyss Core Faculty... -
Video/AnimationWyss Focus: Immuno-MaterialsWyss Core Faculty, Dave Mooney, explains our new Immuno-Materials Focus Area, which adds a new dimension to immunotherapy in that it harnesses materials to make treatments more efficient and effective. These material-based systems are capable of modulating immune cells and releasing them into the body where they can treat diseases. -
Audio/PodcastDisruptive: Rapid, Low-Cost Detection of Zika & Future PandemicsThe rapid emergence of the Zika virus on the world stage calls for a detection system that is just as quick. In this episode of Disruptive, Wyss Core Faculty member and MIT professor Jim Collins and University of Toronto Assistant Professor Keith Pardee discuss how they developed a low cost, paper-based diagnostic platform that can... -
Video/AnimationDetecting Zika: A platform for rapid, low-cost diagnosticsIn this video, a team of collaborators led by Wyss Core Faculty member James Collins discuss a low-cost, paper-based diagnostic system that they developed for detecting specific strains of the Zika virus, with the goal that it could soon be used in the field to easily screen blood, urine, or saliva samples. Credit: Wyss Institute... -
Video/AnimationSmall Airway-on-a-Chip: Modeling COPD and AsthmaDevelopment of new therapeutics for chronic lung diseases have been hindered by the inability to study them in vitro. To address this challenge, Wyss Institute researchers used their Organ-on-a-Chip technology to produce a microfluidic ‘human lung small airway-on-a-chip.’ The device, which is composed a clear rubber material, is lined by living Human lung small airway... -
Video/AnimationDistributed Cell Division CounterGenetically engineered E. coli containing a fluorescing red protein enabled a Wyss Institute and Harvard Medical School team to analyze the population fluctuations of gut microbes by comparing proportion of “marked” to “unmarked” cells. Credit: Wyss Institute at Harvard University -
Video/AnimationCRISPR-Cas9: Safeguarding Gene DrivesIn this animation, learn how effective safeguarding mechanisms developed at the Wyss Institute and Harvard Medical School can be applied to ensure gene drive research is done responsibly in the laboratory. These safeguards enable responsible scientific investigation into how gene drives could one day be leveraged for the greater good of human health, agriculture, and... -
Audio/PodcastDisruptive: Confronting SepsisIn this episode of Disruptive, Wyss Institute Founding Director Don Ingber and Senior Staff Scientist Mike Super discuss how their team developed a new therapeutic device inspired by the human spleen. This blood-cleansing approach can remove sepsis-causing pathogens from circulating blood without ever needing to know their identity. In animal studies, treatment with this device... -
Video/AnimationPathogen-Extracting Sepsis TherapyThis video explains how sepsis induced by an overload of blood pathogens can be treated with the Wyss Institute’s improved pathogen-extracting, spleen-mimicking device. Blood is flown through a cartridge filled with hollow fibers that are coated with a genetically engineered blood protein inspired by a naturally-occurring human molecule called Mannose Binding Lectin (MBL). MBL is... -
Video/AnimationCRISPR-Cas9: Gene Target TroubleshootingIn this animation, learn how a “library on library” approach was used to create a software algorithm that can predict the best way to target any specific gene. Using the most effective RNA sequence, which can be selected using the novel software’s ranking and scoring algorithm, the gene editing mechanism known as CRISPR-Cas9 can be... -
Video/AnimationGastrointestinal Re-ProgrammingIn this animation, see an example of how genetically engineered microbes being developed by researchers at the Wyss Institute could detect and treat a wide range of gastrointestinal illnesses and conditions. Credit: Wyss Institute at Harvard University -
Video/AnimationAntibiotic EfficacyIn this video, Wyss Institute Core Faculty member James Collins and Michael Lobritz explain how antibiotics can have vastly different effects on pathogenic bacteria and suggest potential implications for improving antibiotic treatments in infected patients. Credit: Wyss Institute at Harvard University -
Video/AnimationCircadian TransplantThe first successful transplant of a circadian rhythm into a naturally non-circadian species could lead to precisely timed release of drugs and other innovative therapeutic applications. In this video, gut bacteria (E. coli) exhibit a circadian rhythm after circadian oscillators were transferred from cyanobacteria. The ‘mother cell’ at the top blinks on and off with... -
Video/AnimationHuman Organs-On-ChipsWyss Institute researchers and a multidisciplinary team of collaborators have engineered microchips that recapitulate the microarchitecture and functions of living human organs, including the lung, intestine, kidney, skin, bone marrow and blood-brain barrier. These microchips, called ‘organs-on-chips’, offer a potential alternative to traditional animal testing. Each individual organ-on-chip is composed of a clear flexible polymer... -
Video/AnimationToehold SwitchesIn this animation, Wyss Institute Postdoctoral Fellow Alex Green, Ph.D., the lead author of “Toehold Switches: De-Novo-Designed Regulators of Gene Expression”, narrates a step-by-step guide to the mechanism of the synthetic toehold switch gene regulator. Credit: Wyss Institute at Harvard University -
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/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/AnimationBioinspired Approach to Sepsis TherapyWyss Institute Founding Director Don Ingber, Senior Staff Scientist Michael Super and Technology Development Fellow Joo Kang explain how they engineered the Mannose-binding lectin (MBL) protein to bind to a wide range of sepsis-causing pathogens and then safely remove the pathogens from the bloodstream using a novel microfluidic spleen-like device. Credit: Wyss Institute at Harvard... -
Video/AnimationVirus-inspired DNA NanodevicesWyss Institute Core Faculty member William Shih and Technology Development Fellow Steven Perrault explain why DNA nanodevices need protection inside the body, and how a viral-inspired strategy helps protect them. Credit: Wyss Institute at Harvard University -
Video/AnimationNew coating turns glass into superglassA transparent new coating makes ordinary glass tough, ultraslippery, and self-cleaning. The coating is based on SLIPS — the world’s slipperiest synthetic substance. Here, a droplet of dyed octane quickly beads up and rolls off a watch glass with the new coating. To learn more, go to Credit: Wyss Institute at Harvard University -
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/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 Organs-on-a-ChipWhat if we could test drugs without animal models? Wyss Institute researchers and a multidisciplinary team of collaborators have engineered microchips that recapitulate the microarchitecture and functions of living human organs, including the lung, intestine, kidney, skin, bone marrow and blood-brain barrier. These microchips, called ‘organs-on-chips’, offer a potential alternative to traditional animal testing. Each... -
Video/AnimationIntroduction to Implantable Cancer VaccineWhat if we could prevent and treat cancer with a simple vaccine? Credit: Wyss Institute at Harvard University -
Video/AnimationIntroduction to Sepsis DiagnosticWhat if we could diagnose sepsis in just hours, not days? Wyss Institute researchers discuss their approach to a rapid sepsis diagnostic. Credit: Wyss Institute at Harvard University