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Video/Animation20-ish Questions with Natalie Artzi20-ish Questions shows a different side of Wyss Institute faculty, touching on aspects of their personal life, hobbies, interests, as well as their research. This round follows Natalie Artzi, a new addition to the Wyss Institute’s Core Faculty. Credit: Wyss Institute at Harvard University -
Video/AnimationProgress, Potential, and Possibilities with Luba Perry, Ph.D. – Bioengineered Breast Reconstruction And AugmentationEach episode of this podcast includes a discussion with fascinating people designing a better tomorrow. Luba Perry, Ph.D. is Co-Founder and CEO of ReConstruct Bio, an innovative venture emerging from Harvard’s Wyss Institute, aimed at redefining the fields of medical reconstruction and aesthetics with an initial application of their groundbreaking technology on breast reconstruction and... -
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/AnimationDeep-dive Molecular Blueprinting of Therapeutic Nanostructures | Anastasia ErshovaAnastasia Ershova, a scientist at the Wyss, introduces the innovative field of bionanotechnology. In this talk from LabWeek Field Building, she explores how this cutting-edge science is revolutionizing therapeutics and diagnostics by building molecules that interact with the body in novel ways. Ershova discusses DNA nanotechnology, where DNA is used as a material to create... -
Video/AnimationAminoX: Making Better Protein Drugs, Quicker and CheaperA synthetic biology and advanced chemistry platform that efficiently incorporates non-standard amino acids by hacking the ubiquitous protein synthesis process. Credit: Wyss Institute at Harvard University -
Video/AnimationReimagine the World – Volume 4 – ReConstruct EditionDenise Skok, a two-time breast cancer survivor, Luba Perry, a scientist at the Wyss Institute, and Samuel Lin, a plastic surgeon collaborating with the Wyss Institute, are all working to reimagine a world where breast cancer patients have better reconstruction options. The ReConstruct project at the Wyss Institute uses adipose tissue assembled from a patient’s... -
Video/AnimationReimagining a World Without Breast CancerDenise Skok, a three-times cancer survivor, twice breast cancer and once skin cancer, shares the medical and emotional challenges she had to overcome to be cancer-free. Credit: Wyss Institute at Harvard University -
Video/AnimationReConstruct – 3D Bioprinted Vascularized Fat Tissues for Breast ReconstructionBreast cancer affects 15% of all women. Current options for breast reconstruction are insufficient and have poor patient outcomes. A research team at the Wyss Institute is addressing this clinical need by fabricating vascularized adipose tissue flaps for therapeutic use. Credit: Wyss Institute at Harvard University -
Video/AnimationHow can we train the immune system to fight cancer?The implantable cancer vaccine is a biomaterial that recruits and reprograms a patient’s own immune cells on-site to kill cancer cells. This revolutionary immuno-material technology was tested in a Phase I clinical trial with promising results and is currently licensed by Novartis as an immunotherapy to treat specific tumor types. Credit: Wyss Institute at Harvard... -
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/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/AnimationEliminating brain cancer at its source | Natalie Artzi | TEDxMITGlioblastoma is a lethal, aggressive brain cancer with a dismal median overall survival rate of 15 months, a number that has remained unchanged for decades. Treatment for this devastating disease involves surgical resection followed by chemotherapy and radiation therapy; however, tumor recurrence is inevitable as it is impossible to eliminate all tumor cells with current... -
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 -
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... -
Audio/PodcastImmunoengineering with Dave Mooney – BIOS PodcastWyss Core Faculty member Dave Mooney is a leader in the fields of biomaterials, mechanotransduction, drug delivery, tissue engineering and immunoengineering. He is interested in understanding how cells sense signals in their environment and how this alters cell behavior. His laboratory develops biomaterials that exploit these signals to regulate specific cells and their function. They... -
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/AnimationUsing deep learning to detect cancerous skin lesionsMelanoma is a very severe cancer that is often diagnosed too late to save patients’ lives, and most people do not regularly visit a dermatologist for skin exams. Early-stage identification of suspicious pigmented lesions (SPLs), ideally by primary care providers, could lead to improved melanoma prognosis. Researchers at the Wyss Institute and MIT have developed... -
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/PodcastDavid and Mary Mooney: Seeing Is Believing-Therapeutic Cancer VaccinesWyss Core Faculty member David Mooney presents a talk with Mary Mooney, titled Seeing Is Believing: Therapeutic Cancer Vaccines. Marshalling a patient’s immune system to recognize and destroy cancerous cells is an exciting strategy to attack cancer, and this talk will explore materials that engage the immune system through science and artistic representation. Mary K.... -
Video/AnimationArtScience Talks @ Le Lab – Seeing Is Believing: Therapeutic Cancer VaccinesWyss Core Faculty member David Mooney presents a talk with Mary Mooney, titled Seeing Is Believing: Therapeutic Cancer Vaccines. Marshaling a patientÍs immune system to recognize and destroy cancerous cells is an exciting strategy to attack cancer, and this talk will explore materials that engage the immune system through science and artistic representation. Mary K.... -
Audio/PodcastDisruptive: Sports GenomicsWith 100 trillion cells in the human body, bacteria outnumber our own human cells 2 to 1. These bacteria make up one’s microbiome, and particularly bacteria in our guts affect all our key organ functions. They play a role in our health, development and wellness, including endurance, recovery and mental aptitude. In this episode of... -
Audio/PodcastWilliam Shih: Lego-Style Construction of Future Therapeutics From DNAListen to Wyss Core Faculty member William Shih’s lecture on how custom molecular shapes can be designed using DNA building blocks and how these minuscule devices could have a profound impact on fields ranging from molecular biophysics to therapeutics to nano-optics for decades to come. Shih’s lecture is part of the ArtScience lecture series at...
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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... -
Audio/PodcastDisruptive: Fluorescent In Situ SequencingDeveloped at the Wyss, FISSEQ (fluorescent in situ sequencing) is a spatial gene sequencing technology that reads and visualizes the three-dimensional coordinates of RNA and mRNAs – the working copies of genes – within whole cells and tissues. FISSEQ affords insights into biological complexity that until now have not been possible. In this episode of... -
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... -
Audio/PodcastDisruptive: Cancer Vaccine & Hydrogel Drug DeliveryIn this episode of Disruptive, Wyss Founding Core Faculty Member Dave Mooney discusses programmable nanomaterials approaches to fighting disease. Mooney explains how a cancer vaccine, developed by his team and currently in a clinical trial at the Dana-Farber Cancer Institute, can train one’s own immune system to target specific cancer cells. He also describes the... -
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/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/AnimationDesigning Fusion-Protein TherapiesIn this video, watch the new computational model in action as it simulates the behavior of a fusion-protein drug molecule after the targeting protein has attached to a cell. Developed by Wyss researchers, this model helps design more effective biologic drugs while eliminating drug candidates that are prone to causing side effects. Credit: Harvard’s Wyss... -
Video/AnimationImplantable Cancer VaccineThis animation explains how the Wyss Institute cancer vaccine technology developed in collaboration with biologists, clinicians and researchers at the Institute, the Dana-Farber Cancer Institute and Harvard’s School of Engineering and Applied Sciences works by reprogramming the immune system to reject cancer cells. Credit: Wyss Institute at Harvard University -
Video/AnimationBone Marrow-on-a-ChipWyss Institute Founding Director Don Ingber, Postdoctoral Fellow Yu-suke Torisawa, and Researcher Catherine Spina explain how and why a they built bone marrow-on-a-chip, and how they got it to act like whole living marrow and manufacture blood cells. Credit: Wyss Institute at Harvard University -
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/AnimationDNA CagesTo create supersharp images of their cage-shaped DNA polyhedra, the scientists used DNA-PAINT, a microscopy method that uses short strands of DNA (yellow) labeled with a fluorescent chemical (green) to bind and release partner strands on polyhedra corners, causing them to blink. The blinking corners reveal the shape of structures far too small to be... -
Video/AnimationFluorescent in situ SequencingIn this video, George Church, Ph.D., a Core Faculty member at the Wyss Institute and Professor of Genetics at Harvard Medical School, explains how fluorescent in situ sequencing could lead to new diagnostics that spot the earliest signs of disease, and how it could help reveal how neurons in the brain connect and function. Credit:... -
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/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/AnimationDNA Nanorobot: Cell-Targeted, Payload-DeliveringThis video describes a cell-targeted, payload-delivering DNA nanorobot developed at the Wyss Institute that can trigger targeted therapeutic responses. This novel technology could potentially seek out cancer cells and cause them to self-destruct. Credit: Wyss Institute at Harvard University -
Video/AnimationIntroduction to Programmable NanoroboticsWhat if we could build programmable nanorobots to attack disease? Credit: Wyss Institute at Harvard University -
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 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...