Podcasts about biobricks

Outline00:00 - Intro01:28 - Platform-based design (PBD) in biology16:42 - Cyberphysical systems,  automotive industry,  hybrid systems27:32 - Contracts in system design34:50 - Chiplets41:48 - About time: the tag signal model52:15 - Neuromorphics59:21 - Innovative ecosystems1:07:35 - Advice to future students1:16:26 - The role of luckLinksBiKi Technologies: https://t.ly/RuaW7R. Murray: https://t.ly/Zy_Up S. Sastry: https://t.ly/qsf44C. Tomlin: https://t.ly/tQ0XZPlatform-based design for energy systems: https://t.ly/RJdpiState charts: https://tinyurl.com/yw69przwContracts for system design: https://tinyurl.com/496e953kFormal methods: https://tinyurl.com/2yftcwswChiplets: https://tinyurl.com/mrxyswua A framework for comparing models of computation: https://tinyurl.com/2awyw3crCategory theory: https://tinyurl.com/3bbfjdv9E. Frazzoli: https://tinyurl.com/mspckmpdA. Censi: https://tinyurl.com/5c87wuyxA mathematical theory of co-design: https://tinyurl.com/ydp6jvp8Prophesee: https://tinyurl.com/mtf9hpfmNeuralink: https://tinyurl.com/bdcww89eOpeneye: https://tinyurl.com/3vh6ydmkEpictetus:  https://tinyurl.com/57ef2rudSeneca: https://tinyurl.com/f7zuyz4dF. Nietzsche: https://tinyurl.com/bd7znm4nJ. P. Sartre: https://tinyurl.com/3b2zt5crSupport the showPodcast infoPodcast website: https://www.incontrolpodcast.com/Apple Podcasts: https://tinyurl.com/5n84j85jSpotify: https://tinyurl.com/4rwztj3cRSS: https://tinyurl.com/yc2fcv4yYoutube: https://tinyurl.com/bdbvhsj6Facebook: https://tinyurl.com/3z24yr43Twitter: https://twitter.com/IncontrolPInstagram: https://tinyurl.com/35cu4kr4Acknowledgments and sponsorsThis episode was supported by the National Centre of Competence in Research on «Dependable, ubiquitous automation» and the IFAC Activity fund. The podcast benefits from the help of an incredibly talented and passionate team. Special thanks to L. Seward, E. Cahard, F. Banis, F. Dörfler, J. Lygeros, ETH studio and mirrorlake . Music was composed by A New Element.

In an iGEM competition, open source interchangeable parts of genetic material (BioBricks) allow hundreds of teams of students to create synbio solutions to real world problems. Joined by captain Johannes and treasurer Niko from the 2023 Wageningen iGEM team, we discuss their challenges and ideas about creating novelty, using non-model organisms, and the importance of educating ourselves about novel technologies, not to be dissuade by fear. 

Andrew Hessel: Are Humans Just Squishy Machines? Can cells be programmed like computers? Synthetic Biology, Genetic Engineering, Genomics Conversation with Andrew Hessel, co-author of The Genesis Machine. We discuss his book and the topics of Synthetic Biology, Genetic Engineering, Genomics, mRNA, BioBricks, Life Sciences and so much more, including Dune and Gattaca. Andrew is involved with Autodesk and Humane Genomics. Thank you for watching! For more info, visit https://www.DavidBramante.com YouTube video: https://youtu.be/k3EZHFc_jfw

No episódio dessa semana contamos com a ilustríssima presença do SynBio, o Clube de Biologia Sintética da Universidade Federal de São Carlos (UFSCar), representados pelos discentes de biotecnologia, Beatriz Lecce e Vitor Cerati, para falar sobre biologia sintética. Aqui o assunto gira em torno do que é essa área cada vez mais crescente no mundo, das coisas que se pode fazer com ela, o qual difícil é e do que se precisa para trabalhar com biologia sintética. Pois pega seu not milkinho e vem aqui com a gente!! Participantes: Anderson Freitas e Gabriel Nunes Canal da Twitch: https://www.twitch.tv/biotecempauta Vinheta: Cold Funk by Kevin MacLeod Link: https://incompetech.filmmusic.io/song/3522-cold-funk License: https://filmmusic.io/standard-license Background: Wholesome by Kevin MacLeod Link: https://incompetech.filmmusic.io/song/5050-wholesome License: https://filmmusic.io/standard-license

Support these videos: http://pgbovine.net/support.htmhttp://pgbovine.net/PG-Podcast-53-Mike-Loukides.htm- [Toward the next generation of programming tools](https://www.oreilly.com/radar/toward-the-next-generation-of-programming-tools/)- [UNIX: A History and a Memoir](https://www.amazon.com/UNIX-History-Memoir-Brian-Kernighan/dp/1695978552)- [RapidAPI's RapidQL](https://thenewstack.io/rapidapis-rapidql-an-open-source-query-language-for-apis-and-databases/)- [Glitch](https://glitch.com/)- [Data Carpentry](https://datacarpentry.org/)- [Grappling With Its Identity, MIT Shuts A Dorm For Misfits](https://www.forbes.com/sites/matthewherper/2017/06/28/mit-shuts-down-a-dorm-and-grapples-with-its-identity)- [Bexley residents, student leaders respond to dormitory closing due to structural problems](http://news.mit.edu/2013/students-administrators-letters-on-bexley-hall-closing)- [Dark: A language built for deployless backends](https://darklang.com/)- [BioBricks](https://biobricks.org/)Recorded: 2020-02-10

Tom Knight, considered the “godfather” of synthetic biology, discusses the origin of the scientific field and how it has evolved. In the early 2000s, a group of scientists from outside mainstream biology proposed that they would make living things behave like computers. They would treat DNA like command code; they would make cells behave with Boolean logic; and ultimately they would make life programmable. They called their field synthetic biology. Since its inception, synthetic biology has influenced the practice biological research, current understanding of biological systems, and the biotech economy— by 2019 the global synthetic biology market is projected to be worth $13.4 billion. Tom Knight spent most of his career teaching computer science and electrical engineering at MIT, before playing the major role in creating the engineering discipline of synthetic biology. In 1996 he seeded interest in the field at DARPA, and built a molecular biology laboratory in the MIT computer science department. He developed important standards for engineering biological systems, specifically Biobricks, the first standard assembly technique for functional DNA components, and in establishing the MIT Registry of Standard Biological Parts. He was one of four founders of IGEM, an international competition between undergraduate teams to design and build biological systems, now hosting 300 teams across the globe. In 2008, he co-founded Ginkgo Bioworks, where he remains a full time researcher. His interests include minimal organisms, origins of life, and predictive models of biological systems. He is a Fellow of the American Association for the Advancement of Science, a director of the IGEM Foundation, and member of the International Committee on the Taxonamy of the Mollicutes.

iGEM stands for the “International Genetically Engineered Machines” competition. Thousands of student bioengineers from all over the world construct new life forms and race them every year at the Giant Jamboree in Boston. iGEM has been going on for ten years (2,500 competitors this year, over 32 countries, 20,000+ alumni) and gives a peerless window into the global grassroots synthetic-biology revolution, yet the phenomenon has been largely overlooked by the media, industry, and most governments. iGEM began with college undergraduates and recently expanded to include high school teams. In making their genetic creations students get from and give back to a repository of over 10,000 genetic components called BioBricks parts. The organisms (mostly microbes) the students engineer range from frivolous (doing a stadium-style “wave”) to beneficial (detecting and eliminating water pollutants) to ingenious (increasing plant root structure to fix carbon while ensuring that no exotic genes can escape). iGEM teams "are also challenged to actively consider and address the safety, security and environmental implications of their work." Drew Endy, a professor of Bioengineering at Stanford, was one of the creators of iGEM and is co-founder and president of the BioBricks Foundation, an organization whose mission is "to develop biotechnology in an open and ethical manner to benefit all people and the planet." He is a strong proponent of “open source” biotech and public discussion of the techniques, benefits, and potential hazards of synthetic biology.

Marianne Talbot talks about the uses and dangers of the relatively new discipline of synthetic biology.

Marianne Talbot talks about the uses and dangers of the relatively new discipline of synthetic biology.

We explore synthetic biology in this Naked Scientists Show, finding out how to learn from, and improve on, the structures and systems we find in nature. We'll meet the team of students who designed a biological sensor to win the international genetically engineered machine competition, or iGEM, and find out how to build bespoke proteins. In Kitchen Science, we feed an egg to some enzymes to find out how biological washing powder works. Plus, what the brain does when it sees a familiar face, genetically modified crops boost resistant bug numbers, how to create hair cells, essential for hearing,... Like this podcast? Please help us by supporting the Naked Scientists

We explore synthetic biology in this Naked Scientists Show, finding out how to learn from, and improve on, the structures and systems we find in nature. We'll meet the team of students who designed a biological sensor to win the international genetically engineered machine competition, or iGEM, and find out how to build bespoke proteins. In Kitchen Science, we feed an egg to some enzymes to find out how biological washing powder works. Plus, what the brain does when it sees a familiar face, genetically modified crops boost resistant bug numbers, how to create hair cells, essential for hearing,... Like this podcast? Please help us by supporting the Naked Scientists

Stanford University's Drew Endy is a synthetic biologist, or as he puts it, someone who makes biology easier to engineer. He's one of the leading lights of this relatively new scientific field which builds on disciplines like computer science, electrical engineering and genetics. Find out why Endy is passionate about the cutting edge of biology.

This month on the podcast, Chris French on anti-arsenic eco- E. coli, Andrew Millar clocks in on plant clocks, Heather McQueen gets personal about personal response systems, and a research round-up from the Institute of Evolutionary Biology with Ed Sykes.