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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/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/AnimationReimagine the World – Volume 3 – Northpond EditionThe Wyss Institute’s alliance with Northpond Labs supports early-stage, transformative research with strong translation potential. Hear Northpond Ventures co-founders Michael Rubin and Sharon Kedar explain why they decided to partner with the Wyss, as well as the leaders of various Wyss projects and startups about how support from Northpond has helped accelerate their technologies to... -
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/AnimationSeed-dependent crisscross DNA-origami slatsThis animation explains how the newly invented crisscross origami method can be used to build functionalized micron-scale DNA megastructures composed of many unique DNA origami “slats,” each with their own complexity and interactive properties. 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/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/AnimationDNA Nanoswitch CalipersThe world’s tiniest ruler for biomolecules has been created by researchers at the Wyss Institute at Harvard University, Harvard Medical School, and Boston Children’s Hospital. DNA Nanoswitch Calipers can measure very small peptides to better understand their structure and function, and enable them to be quickly identified in mixed samples. These insights could lead to... -
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/AnimationLighting up proteins with Immuno-SABERThis animation explains how Immuno-SABER uses the Primer Exchange Reaction (PER) to enable the simultaneous visualization of multiple proteins in tissues in different applications. Credit: Wyss Institute at Harvard University. -
Video/AnimationSABER-FISH: Enabling the sensitive and multiplexed detection of nucleic acids within thick tissuesThis animation shows how SABER-FISH uses a suite of DNA nanotechnological methods that together enable the sensitive and multiplexed detection of DNA and RNA targets within cells and thick tissues. Credit: Wyss Institute at Harvard University -
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... -
Exchange-PAINT: Neurons Up Close and PersonalDNA Exchange Imaging of fixed mouse hippocampal neurons stained sequentially with antibodies recognizing neuronal markers Synapsin I, vGAT, MAP2, pNFH, α-tubulin, acetyl-tubulin, GFAP and nuclear marker DAPI. Credit: Wyss Institute at Harvard University -
Video/AnimationPrimer Exchange ReactionIn this video, Jocelyn Kishi illustrates how Primer Exchange Reaction (PER) cascades work to autonomously create programmable long single-stranded DNA molecules. Credit: Wyss Institute at Harvard University. -
Video/AnimationWhat Is BIOMOD?BIOMOD is a biomolecular design competition for students created by the Wyss Institute for Biologically Inspired Engineering at Harvard University. Each year BIOMOD holds a Jamboree, an annual conference at which all BIOMOD teams convene to present their work from the summer. This year’s Jamboree will take place in Genentech Hall at UCSF in San Francisco,... -
Video/AnimationAuto-cyclic Proximity RecordingThis video explains how “Auto-cycling Proximity Recording” works to identify pairs of nearby molecular targets and how it can be used as a tool to decipher the geometry of 3-dimensional engineered and natural molecules. Credit: Wyss Institute at Harvard University -
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... -
Audio/PodcastDisruptive: Molecular RoboticsHow can DNA be programmed to build novel structures, devices, and robots? We have taken our understanding of DNA to another level, beginning to take advantage of some of DNA’s properties that have served nature so well, but in ways nature itself may have never pursued. Humans can now use DNA as a medium for... -
Video/AnimationDNA NanoswitchesGel electrophoresis, a common laboratory process, sorts DNA or other small proteins by size and shape using electrical currents to move molecules through small pores in gel. The process can be combined with novel DNA nanoswitches, developed by Wyss Associate Faculty member Wesley Wong, to allow for the simple and inexpensive investigation of life’s most... -
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/AnimationBuilding 3D Structures with DNA BricksThe nanofabrication technique, called ‘DNA-brick self-assembly,’ uses short, synthetic strands of DNA that work like interlocking Lego bricks. It capitalizes on the ability to program DNA to form into predesigned shapes thanks to the underlying ‘recipe’ of DNA base pairs. This animation accurately shows how the DNA strands self assemble to build a structure.DNA Nanostructures... -
Video/AnimationDNA Bricks: Molecular AnimationThe nanofabrication technique, called ‘DNA-brick self-assembly,’ uses short, synthetic strands of DNA that work like interlocking Lego bricks. It capitalizes on the ability to program DNA to form into predesigned shapes thanks to the underlying “recipe” of DNA base pairs. Animation created by Digizyme for the Wyss Institute. Credit: Wyss Institute at Harvard University -
Video/AnimationMaking Structures with DNA “Building Blocks”Researchers at the Wyss Institute have developed a method for building complex nanostructures out of short synthetic strands of DNA. Called single-stranded tiles (SSTs), these interlocking DNA “building blocks,” akin to Legos, can be programmed to assemble themselves into precisely designed shapes, such as letters and emoticons. Credit: Wyss Institute at Harvard University -
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