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Video/AnimationHow do we make safer and more effective drugs?Wyss researchers are using an ever-growing number of human tissue-mimicking Organ Chips to improve and accelerate the drug development process for a wide number of unmet diseases – and understand what causes them to erupt. More recently, they added a human Vagina Chip and personalized Barrett’s esophagus Chip to their arsenal, and created in vitro... -
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... -
Audio/PodcastAnimal Free Labcast #4 – The PioneerWorld-class pioneer of biomedical research and innovation, Dr. Don Ingber, is the founding director of Harvard University’s Wyss Institute for Biologically Inspired Engineering. In 2010, Dr. Ingber developed a lung-on-a-chip – the first of its kind – and has continued to lead the field by developing numerous other organ chip models, demonstrating their ability to... -
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... -
Video/AnimationBeating Back the Coronavirus: FDA-Approved Drug Repurposing PipelineWith the goal of rapidly repurposing FDA-approved drugs to treat COVID-19, the Wyss Institute is collaborating with the Frieman Lab at the University of Maryland Medical School and the tenOever Lab at the Icahn School of Medicine at Mount Sinai to establish a multidisciplinary pipeline that can rapidly predict, test, and validate potential treatments. Credit:... -
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/AnimationInterrogator: Human Organ-on-ChipsThis video describes the “Interrogator” instrument that can be programmed to culture up to 10 different Organ Chips and sequentially transfer fluids between their vascular channels to mimic normal human blood flow between the different organs of our body. Its integrated microscope enables the continuous monitoring of the tissues’ integrities in the individual organ chips... -
Video/AnimationSmoking Human Lung Small Airway-on-a-ChipIn this video, Wyss Founding Director Donald Ingber and Technology Development Fellow Kambez Benam explain how the integrated smoking device mimics normal cigarette smoke exposure and how it can impact research into the causes of COPD and into new biomarkers and therapeutics. Credit: Wyss Institute at Harvard University -
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/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/AnimationNanoRx: Clot-Busting NanotherapeuticIn this animation, learn how the Wyss Institute clot-busting nanotherapeutic is activated by fluid high shear force – which occurs where blood flows through vessels narrowed by obstruction – to specifically target clots and dissolve them away. By pairing this drug with an intra-arterial device that restores blood flow to complete obstructions, the drug-device combination... -
Video/AnimationResearchers mimic pulmonary edema in Lung-on-a-ChipThe Wyss Institute’s human breathing lung-on-a-chip, made using human lung and blood vessel cells, acts much like a lung in a human body. A vacuum re-creates the way the lungs physically expand and contract during breathing. As reported in Science Translational Medicine on November 7, 2012, Wyss researchers have now mimicked a human disease –... -
Video/AnimationClot-busting nanotherapeuticWyss Core Faculty member Donald E. Ingber describes the clot-busting nanotherapeutic. Credit: Wyss Institute at Harvard University -
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/AnimationLung-on-a-ChipCombining microfabrication techniques with modern tissue engineering, lung-on-a-chip offers a new in vitro approach to drug screening by mimicking the complicated mechanical and biochemical behaviors of a human lung. This extended version of the video includes our findings when we mimicked pulmonary edema on the chip. Credit: Wyss Institute at Harvard University