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23 Results for ''
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Video/AnimationHarborSite AnimationThis animation explains how the Wyss Institute’s HarborSite genome editing technology uses highly specific and efficient recombinase enzymes and genomic safe harbors to achieve more predictable, safe, and durable gene therapies. Credit: Wyss Institute at Harvard University
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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.
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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
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Video/AnimationCogniXense: Speeding Up Treatments for Rare DiseasesAt the Wyss Institute, we are tackling Rett syndrome, a rare disease that affects 1 out of 9,000 children, by developing a scalable model for neurodevelopmental and cognitive diseases. This model can test drugs to see which will improve memory, learning, and behavior, with the end goal of finding effective therapies. Credit: Wyss Institute at...
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Video/AnimationAAV Capsid EngineeringWyss researchers have created a high-throughput platform to generate an Adeno-associated virus 2 (AAV2) library containing 200,000 variants, each carrying a distinct mutation in the virus capsid protein. Their analysis identified capsid changes that enhanced “homing” potential to specific organs in mice and virus viability, as well as a new protein hidden in the capsid-encoding...
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Video/AnimationEngineered Cross-feeding in Bacterial ConsortiaThrough engineered amino acid cross-feeding, researchers at the Wyss Institute and Harvard Medical School modified multiple bacterial strains to reverse antagonistic interactions and develop symbiotic relationships, resulting in a more balanced consortium and paving the way for future bacteria-based therapeutics. Credit: Wyss Institute at Harvard University
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Video/AnimationSelf-regenerating bacterial hydrogels as intestinal wound patchesThis animation explains how self-regenerating bacterial hydrogels could be used as adhesive patches to help intestinal wounds heal. Credit: Wyss Institute at Harvard University.
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Video/AnimationLight-driven fine chemical production in yeast biohybridsWyss Institute Core Faculty member Neel Joshi explains the concept of yeast biohybrids and how they can be used to harvest energy from light to drive the production of fine chemicals. Credit: Wyss Institute at Harvard University
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Video/AnimationTEDx Beacon Street Salon: Reversing Human AgingWyss Institute Core Faculty member George Church, Ph.D., was the opening speaker at the TEDx Beacon Street saloon event hosted at the Franklin Park Zoo. He presented from inside the tapir cage! Talk summary: Animals can be an extremely useful resource in prolonging human lives and promoting general health. For example, there are organs in...
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Video/AnimationCRISPR-Cas: Molecular RecordingIn this video, Wyss Institute and Harvard Medical School researchers George Church and Seth Shipman explain how they engineered a new CRISPR system-based technology that enables the chronological recording of digital information, like that representing still and moving images, in living bacteria. Credit: Wyss Institute at Harvard University
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Video/AnimationWyss Study: Memory GenesResearchers at the Wyss Institute and the Personal Genome Project (PGP) are using Lumosity games to evaluate memory functions and response times. The genomes of high performers will be sequenced, with the goal of uncovering the relationship between genetics, memory, attention, and reaction speed. This video featuring George Church, Core Faculty of the Wyss Institute and Professor...
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Audio/PodcastFireside Chat with George ChurchAudio recording of a fireside chat with Wyss Core Faculty member George Church at the 2016 Convergence Forum, held in Chatham, Mass. on May 12 and 13, 2016. Moderated by Alison Taunton-Rigby.
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Audio/PodcastGeorge Church: Responsibility, art & science of intentional extinction, de-extinction & agingGeorge Church Responsibility, art & science of intentional extinction, de-extinction & aging Wednesday, Feb 17, 2016 ArtScience @ Le Lab Lecture Series: Art, Design, Engineering & Biology – Core Faculty from the Wyss Institute for Biologically Inspired Engineering at Harvard University discuss how the arts and design are informing the frontiers of science. ArtScience @...
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Audio/PodcastMusings on Science and Society, with a dash of CRISPRThe Science Soapbox team sits down with Dr. George Church to talk everything from the dawn of CRISPR to the place of science fiction in society. Dr. Church is Professor of Genetics at Harvard Medical School, leader of the Synthetic Biology Platform at the Wyss institute, and director of PersonalGenomes.org. This episode was recorded on...
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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
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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...
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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...
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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...
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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...
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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...
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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.
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Video/AnimationBIND BiofilmIn this video Wyss Institute Core Faculty member Neel Joshi and Postdoctoral Fellow Peter Nguyen describe how their protein engineering system called BIND (Biofilm-Integrated Nanofiber Display) could be used to redefine biofilms as large-scale production platforms for biomaterials that can be programmed to provide functions not possible with existing materials. An animation depicts how it...
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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...