Wyss InstituteImaging – Wyss Institute https://wyss.harvard.edu Wyss Institute at Harvard Thu, 30 Apr 2026 21:39:06 +0000 en-US hourly 1 https://wordpress.org/?v=6.7.1 Toward autonomous self-organizing biological robots with a nervous system https://wyss.harvard.edu/news/toward-autonomous-self-organizing-biological-robots-with-a-nervous-system/ Mon, 16 Mar 2026 18:30:42 +0000 https://wyss.harvard.edu/?p=44996 In a first-of-its-kind study, researchers demonstrate that functional nervous systems can form within self-organized living cellular robots, conferring complex movement patterns and distinct gene expression profiles By Benjamin Boettner (BOSTON) — Biobots, whose growing line of variants started with Xenobots, are fascinating tiny self-powered living robots built exclusively using frog embryonic cells. Originally developed in the laboratories of Wyss Institute Associate Faculty member and Tufts University Professor Michael Levin, Ph.D. and his collaborators at University of Vermont…

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]]> https://wyss.harvard.edu/news/toward-autonomous-self-organizing-biological-robots-with-a-nervous-system/ The team made an important step towards creating self-organizing biological robots with a functional nervous system. As can be seen in this image, neurobots are made of an outer surface consisting of multicilliated cells, mucus-secreting goblet cells, ionocytes, and small secretory cells, and a nervous system that reaches out to surface cells underneath. Credit: Wyss Institute at Harvard University https://wyss-prod.imgix.net/app/uploads/2026/03/09141311/Neurobot-cover-image-e1773080011693.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=1fb2c1abf80eec239961949d4dffbf6e"/> Wyss Institute appoints three new Associate Faculty members: Ahmad Khalil, Jarad Mason, and Ting Wu https://wyss.harvard.edu/news/wyss-institute-appoints-three-new-associate-faculty-members-ahmad-khalil-jarad-mason-and-ting-wu/ Mon, 08 Dec 2025 14:50:20 +0000 https://wyss.harvard.edu/?p=44386 These three distinguished researchers bring their expertise in synthetic biology, materials science, and genome research to contribute to the Institute’s mission of societal impact By Jessica Leff The Wyss Institute is proud to welcome three new Associate Faculty members: Ahmad (Mo) Khalil, Ph.D., Jarad Mason, Ph.D., and Chao-ting (Ting) Wu, Ph.D. Each has a history of collaborating with the Institute’s researchers. Their diverse expertise and fresh perspectives will further strengthen the Wyss’ innovative and collaborative ecosystem and enable pioneering advances in…

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]]> https://wyss.harvard.edu/news/wyss-institute-appoints-three-new-associate-faculty-members-ahmad-khalil-jarad-mason-and-ting-wu/ The Wyss welcomed <a href="https://wyss.harvard.edu/news/wyss-institute-appoints-three-new-associate-faculty-members-ahmad-khalil-jarad-mason-and-ting-wu/"> three new Associate Faculty members, Ahmad Khalil, Ph.D., Jarad Mason, Ph.D., and Chao-ting (Ting) Wu, Ph.D.</a> They are bringing expertise in synthetic biology, materials science, and genome research. Credit: Wyss Institute at Harvard University https://wyss-prod.imgix.net/app/uploads/2025/12/04113526/New-Associate-Faculty-Listing-Image-scaled.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=ebaa61d75da3e2378cc130527161cb3e"/> Namita Sarraf on Using DNA as a Building Block https://wyss.harvard.edu/news/namita-sarraf-on-using-dna-as-a-building-block/ Thu, 18 Sep 2025 15:26:34 +0000 https://wyss.harvard.edu/?p=43699 The Humans of the Wyss (HOW) series features members of the Wyss community discussing their work, the influences that shape them as professionals, and their collaborations at the Wyss Institute and beyond. Namita Sarraf loves to find herself at intersections, whether it’s pursuing a Ph.D. at the nexus of bioengineering and computer science or hosting a “Diwali-sgiving” dinner party to…

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]]> https://wyss.harvard.edu/news/namita-sarraf-on-using-dna-as-a-building-block/ Namita Sarraf, Postdoctoral Fellow. Credit: Wyss Institute at Harvard University https://wyss-prod.imgix.net/app/uploads/2025/09/16161112/HoW-Namita-Sarraf-09258-scaled.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=7557ae3692ee9bddf1d31db319fc54c7"/> Blood Clot Dx https://wyss.harvard.edu/technology/blood-clot-dx/ Wed, 09 Jul 2025 17:00:40 +0000 https://wyss.prod.a17.io/technology/microfluidic-hemostasis-monitor/ Blood clots can arise anywhere in the body, blocking blood flow and causing pain and other symptoms. The most serious types of clots, called deep vein thrombosis (DVT), typically form in the veins in the legs, and can break off and become lodged in a lung. This can cause a pulmonary embolism (PE), which is when blood flow to the lungs is prevented and can be fatal. The symptoms of PE resemble…

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]]> https://wyss.harvard.edu/technology/blood-clot-dx/ Abidemi Junaid holding the microfluidic chip used to monitor blood clotting. https://wyss-prod.imgix.net/app/uploads/2016/08/09145422/Abidemi-with-Hemostasis-Chip-Posed-08089-scaled.jpeg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=799ada1f03931c9e36620cd1d4f32f2f"/> DARPA-ABC program supports Wyss Institute-led collaboration toward deeper understanding of anesthesia and safe drugs enabling anesthesia without the need for extensive monitoring https://wyss.harvard.edu/news/darpa-abc-program-supports-wyss-institute-led-collaboration-toward-deeper-understanding-of-anesthesia-and-safe-drugs-enabling-anesthesia-without-the-need-for-extensive-monitoring/ Wed, 15 Jan 2025 14:55:41 +0000 https://wyss.harvard.edu/?p=41847 Novel anesthesia-inducing drugs developed through multidisciplinary neuroscience-driven approaches could help save numerous lives in conflict and disaster situations By Benjamin Boettner (BOSTON) — Currently, no anesthetic compound or cocktail can be used safely outside of a hospital facility. This is because current drugs impair the brain and central nervous system’s ability to regulate a number of vital processes, including respiration, body temperature, and heart rate in addition to creating a state of unconsciousness or sedation…

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]]> https://wyss.harvard.edu/news/darpa-abc-program-supports-wyss-institute-led-collaboration-toward-deeper-understanding-of-anesthesia-and-safe-drugs-enabling-anesthesia-without-the-need-for-extensive-monitoring/ A Wyss Institute-led cross-institutional collaboration of exceptional and highly-complementary researchers aims to develop a deeper understanding of anesthesia, as well as safe drugs that enable anesthesia in conflict and disaster situations without the need for extensive monitoring. Credit: Chalabala https://wyss-prod.imgix.net/app/uploads/2025/01/13152912/emergency-medical-service-2023-11-27-05-07-02-utc.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=211a9f573f1f72d7379b92f184ad12a0"/> Starting a fluorescent biosensor revolution https://wyss.harvard.edu/news/starting-a-fluorescent-biosensor-revolution/ Thu, 05 Sep 2024 09:00:00 +0000 https://wyss.harvard.edu/?p=40904 Molecular biosensors that only light up upon binding their targets open vast possibilities for medical diagnostics, fundamental research, environmental monitoring, and more By Benjamin Boettner (BOSTON) — Biosensors – devices that use biological molecules to detect the presence of a target substance – have enormous potential for detecting disease biomarkers, molecules-in-action in diverse biological processes, or toxins and other harmful substances in the environment. One of the more common types, fluorescent biosensors, consists of a target-binding biomolecule…

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]]> https://wyss.harvard.edu/news/starting-a-fluorescent-biosensor-revolution/ As an “instant COVID-19 diagnostic,” a binding-activated biosensor, developed to bind the Spike protein of the SARS-CoV-2 virus, is able to detect its target within milliseconds as shown by the development of green fluorescence in this sample. Credit: Wyss Institute at Harvard University https://wyss-prod.imgix.net/app/uploads/2024/09/03234828/Fluorescent-Biosensor_Squeeze.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=0e8c626bb57e813b3203cc03937f7d49"/> ACE-ing protein detection in single cells https://wyss.harvard.edu/news/ace-ing-protein-detection-in-single-cells/ Tue, 30 Jul 2024 14:55:40 +0000 https://wyss.harvard.edu/?p=40516 ACE, a new DNA-powered signal amplification technology, dramatically increases sensitivity of mass cytometry, opening new windows on many biological and pathological processes By Benjamin Boettner (BOSTON) — Since the 1950s, researchers have used a famous method invented by Wallace Coulter known as “flow cytometry” to characterize different types of immune cells in research studies and in blood samples from human individuals. This has enabled a much deeper understanding of immune cell development as well as new ways to assess human health and diagnose various blood…

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]]> https://wyss.harvard.edu/news/ace-ing-protein-detection-in-single-cells/ ACE technology enables highly multiplexed and sensitive signal amplification to detect proteins in single cells using suspension mass cytometry single-cell suspension and imaging mass cytometry analysis. This illustration shows how proteins in individual cells of a tissue section can be quantified with ACE-enhanced antibodies binding to them. Credit: Su Min Suh/SciStories https://wyss-prod.imgix.net/app/uploads/2024/07/29091918/ACE-technology-graphic_wide.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=b792c4812e4d5c036e795d0352bcb043"/> Human cervix modeled in microfluidic organ chip fills key women’s health gap https://wyss.harvard.edu/news/human-cervix-modeled-in-microfluidic-organ-chip-fills-key-womens-health-gap/ Fri, 31 May 2024 14:55:29 +0000 https://wyss.harvard.edu/?p=40143 Engineered cervix with in vivo-like mucus production, hormone sensitivity, and associated microbiome creates novel testbed for bacterial vaginosis therapeutics and other treatments By Benjamin Boettner (BOSTON) — Bacterial Vaginosis (BV) has been identified as one of the many unmet needs in women’s health and affects more than 25% of reproductive-aged women. It is caused by pathogenic bacteria that push the healthy microbiomes in the female vagina and cervix – the small gatekeeper canal that connects the uteruns and vagina – into a state of imbalance known as dysbiosis.

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]]> https://wyss.harvard.edu/news/human-cervix-modeled-in-microfluidic-organ-chip-fills-key-womens-health-gap/ Wyss researchers have developed a human Cervix-on-a-Chip that models the complex cervix tissue in vitro, and overcomes major limitations of existing animal and <em>in vitro</em> models to enable the study of bacterial vaginosis and development of drugs. Credit: Shutterstock https://wyss-prod.imgix.net/app/uploads/2024/05/30093346/shutterstock_2079694981.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=323deb424d3beb82ea428aa293bc4ea0"/> Evolving how we use DNA through nanotechnological innovations https://wyss.harvard.edu/news/evolving-how-we-use-dna-through-nanotechnological-innovations/ Thu, 25 Apr 2024 13:51:37 +0000 https://wyss.harvard.edu/?p=39732 Three Wyss Faculty members explain how they’re using DNA nanotechnology to shape the future of diagnostics, therapeutics, and sustainability as they work towards the initial vision of the Molecular Robotics Initiative By Jessica Leff On April 25, 1953, a group of researchers published papers in Nature detailing the molecular structure of DNA, the building block of the genetic code of all organisms, for the first time. Since then, our understanding of DNA, genes, and genetics has blossomed, enabling the creation of genetic testing, gene therapies, and synthetic DNA. In 2018, four Wyss faculty members…

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]]> https://wyss.harvard.edu/news/evolving-how-we-use-dna-through-nanotechnological-innovations/ https://wyss-prod.imgix.net/app/uploads/2024/04/18114735/DNADayListingImage.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=66cdcbc1d446b5336db7937c682d2ed2"/> Helena de Puig on Rapidly Sensing Proteins with Project Sparkle https://wyss.harvard.edu/news/humans-of-the-wyss-helena-de-puig-on-rapidly-sensing-proteins-with-project-sparkle/ Wed, 07 Dec 2022 15:58:32 +0000 https://wyss.harvard.edu/?p=34775 The Humans of the Wyss (HOW) series features members of the Wyss community discussing their work, the influences that shape them as scientists, and their collaborations at the Wyss Institute and beyond. After watching Formula 1 racing when she was younger, Helena de Puig was inspired to become an engineer and build the fastest car in the world. Though she now focuses on synthetic biology…

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]]> https://wyss.harvard.edu/news/humans-of-the-wyss-helena-de-puig-on-rapidly-sensing-proteins-with-project-sparkle/ Helena de Puig, Postdoctoral Fellow. Credit: Wyss Institute at Harvard University https://wyss-prod.imgix.net/app/uploads/2022/12/02103230/WoW-Helena-De-Puig-Guixe-Neutral-1333.jpg?auto=format%2Ccompress&crop=faces%2Centropy&fit=crop&h=400&q=50&w=300&s=6bad4f60647a278e12d4576c9f49a5fe"/>