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Video/AnimationESCAPE BioengineeringA research team at the Wyss Institute and Boston University has developed ESCAPE, the first method that enables the engineering of tissues across multiple length scales, ranging from the diameter of a cell to the cm scale of a heart valve. Credit: Wyss Institute at Harvard University -
Video/AnimationGenetic & Cellular Engineering w/ David Schaffer & Samir Mitragotri – BIOS RoundtableSamir Mitragotri is a Core Faculty member at the Wyss Institute and the Hiller Professor of Bioengineering & Hansjorg Wyss Professor of Biologically Inspired Engineering at Harvard SEAS. David Schaffer is Professor at UC Berkeley & Director at BBH. The two discuss Genetic and Cellular Engineering, with a focus on delivery challenges. -
Video/AnimationMetabolic T cell Labeling: simple and effective enhancement of therapeutic T cells with immune-stimulating cytokinesThis animation shows how the surface of patient-derived T cells is metabolically labeled with azido-sugar molecules that then can be used to attach immune-enhancing cytokines with the help of click chemistry. The approach could help expand adoptive T cell therapies to treatment of solid tumors. Credit: Wyss Institute at Harvard University -
Video/AnimationLight-Seq: Light-Directed In Situ Barcoding of BiomoleculesThis animation explains how the Light-Seq technology works to barcode and deep-sequence selected cell populations in tissue samples, and how the team applied it to the analysis of distinct and rare cells in the mouse retina. Credit: Wyss Institute at Harvard University. -
Audio/PodcastIlluminating Biological Context with Josie Kishi – Translation by Fifty YearsTechnologies like next-generation sequencing allow us to understand which RNA transcripts and proteins are expressed in biological tissues. However, it’s often equally important to understand how cells or molecules are positioned relative to one another! Whether it be a cell changing its shape, an organelle ramping up a metabolic process, or a DNA molecule traveling... -
Video/AnimationSomaCode: GPS for Cell TherapyJust like zip codes help drivers navigate to specific addresses using a GPS system, the molecular ‘zip codes’ identified via the SomaCode platform can be used to deliver cell therapies to their specific targets in the human body, increasing the therapies’ efficacy and reducing side effects. Credit: Wyss Institute at Harvard University -
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/AnimationPhonoGraft: Programming the eardrum to repair itselfEardrum perforations are a widespread problem affecting millions worldwide. Current standard of care is invasive, involves harvesting an autologous tissue to patch the eardrum, and often requires to revision surgeries, while hearing outcomes remain unsatisfying. What if we could program the eardrum to repair itself after injury? Researchers at the Wyss Institute, Massachusetts Eye and... -
Video/AnimationKidney Organiods: Flow-Enhanced Vascularization and Maturation In VitroThis video explains how the collaborative project created vascularized kidney organoids and how they advance the field of tissue engineering. Credit: Wyss Institute at Harvard University. -
Video/AnimationNew Wyss Institute Initiative – 3D Organ EngineeringWyss Institute Core Faculty members Christopher Chen and Jennifer Lewis describe the Wyss Institute’s new initiative focused on organ engineering, which leverages our expertise in biomaterials, tissue engineering, three dimensional biofabrication, and stem cell development. -
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. -
Video/AnimationPodocyte Cells: Kidney-on-a-ChipThis video shows a 3-dimensional rendering of the glomerulus-on-a-chip with human stem cell-derived mature podocytes (in green) grown and differentiated in one channel (shown on top) and that extend their processes through the modeled glomerulus basement membrane towards glomerular vascular cells (in magenta) in the parallel running channel (shown on the bottom). Credit: Wyss Institute... -
Audio/PodcastDisruptive: Mechanotherapeutics – From Drugs to WearablesMechanobiology reveals insights into how the body’s physical forces and mechanics impact development, physiological health, and prevention and treatment of disease. The emerging field of Mechanotherapeutics leverages these insights towards the development of new types of pharmaceuticals, drug delivery systems, engineered tissues, and wearable therapeutic devices that leverage physical forces or target mechanical signaling pathways... -
Video/AnimationMechanotherapeutics: From Drugs to WearablesThe Wyss Institute’s 7th annual international symposium focused on advances in the field of Mechanobiology that have resulted in the development of new types of pharmaceuticals, drug delivery systems, engineered tissues, and wearable therapeutic devices that leverage physical forces or target mechanical signaling pathways as a core part of their mechanism of action. Organized by... -
Video/AnimationPrinting Vascular TissuePrinting vessel vasculature is essential for sustaining functional living tissues. Until now, bioengineers have had difficulty building thick tissues, lacking a method to embed vascular networks. A 3D bioprinting method invented at the Wyss Institute and Harvard SEAS embeds a grid of vasculature into thick tissue laden with human stem cells and connective matrix. Printed... -
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/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/AnimationCas9: As a Transcriptional ActivatorIn this technical animation, Wyss Institute researchers instruct how they engineered a Cas9 protein to create a powerful and robust tool for activating gene expression. The novel method enables Cas9 to switch a gene from off to on and has the potential to precisely induce on-command expression of any of the countless genes in the... -
Video/AnimationGene Editing Mechanism of CRISPR-Cas9In this animation, learn how CRISPR-Cas9 gene editing technology can be used to precisely disrupt and modify specific genes. Credit: Wyss Institute at Harvard University. -
Video/AnimationShrinking GelWhen the temperature rises to just below body temperature, this biocompatible gel shrinks dramatically within minutes, bringing tooth-precursor cells (green) closer together. Credit: Basma Hashmi -
Video/AnimationBioprinting: Building in Blood VesselsBuilding in blood vessels. Then they addressed a big challenge in tissue engineering: embedding 3D vascular networks. They developed a ‘fugitive’ ink that can easily be printed, then suctioned off to create open microchannels that can then be populated with blood-vessel-lining cells to allow blood to flow. Read more: wyss.harvard.edu/viewpressrelease/141 Credit: Wyss Institute at Harvard... -
Video/AnimationBioprinting: Building with Bio-InksBuilding with bio-inks. Using their custom-built printer, the fugitive ink for the vasculature, and other biological inks containing extracellular matrix and human cells, the researchers printed a 3D tissue construct. Credit: Wyss Institute at Harvard University -
Video/AnimationBioprinting: Building Intricate StructuresBuilding intricate structures. The team first designed a custom printer that can precisely co-print multiple materials in 3D to create intricate heterogeneous patterns. Credit: Wyss Institute at Harvard University -
Video/AnimationMeTro HydrogelsAn international team led by the Wyss Institute recently used microfabrication techniques to design a new micropatterned hydrogel that shows great promise for tissue engineering — cardiac tissue in particular. It incorporates an elastic protein called tropoelastin, which is found in all elastic human tissues. The Wyss Institute’s Ali Khademhosseini discusses the research. Credit: Wyss... -
Video/AnimationIntroduction to Implantable Cancer VaccineWhat if we could prevent and treat cancer with a simple vaccine? Credit: Wyss Institute at Harvard University