Podcasts about bioprinting

February is American Heart Month, and in light of that, we're bringing back an episode about a group here at Stanford Engineering that's developing 3D printing methods for human tissues and organs, a process known as bioprinting. Motivated in part by the critical need for heart transplants, Mark Skylar-Scott and his team are specifically working to bioprint tissues of the human heart. It may sound like science fiction, but it's actually just another example of the groundbreaking research we do here. We hope you'll take another listen and be inspired by the possibilities.Have a question for Russ? Send it our way in writing or via voice memo, and it might be featured on an upcoming episode. Please introduce yourself, let us know where you're listening from, and share your quest. You can send questions to thefutureofeverything@stanford.edu.Episode Reference Links:Stanford Profile: Mark A. Skylar-ScottMark's Lab: The Skylar-Scott Lab | Stanford MedicineConnect With Us:Episode Transcripts >>> The Future of Everything WebsiteConnect with Russ >>> Threads / Bluesky / MastodonConnect with School of Engineering >>> Twitter/X / Instagram / LinkedIn / FacebookChapters:(00:00:00) IntroductionRuss Altman introduces guest, Mark Skylar-Scott, a professor of bioengineering at Stanford University.(00:02:06) What is Bioprinting?The role of cells and biopolymers in printing functional biological structures.(00:03:31) Bioprinting a HeartThe potential of printing organs on demand, especially heart tissue.(00:04:38) Obtaining Cells for BioprintingUsing stem cells derived from the patient's own cells to create heart tissue.(00:06:29) Creating Multiple Cell Types for the HeartThe challenge of printing eleven different heart cell types with precision.(00:08:50) The Scaffold for 3D PrintingThe support material used in 3D printing and how it's later removed.(00:10:10) Cell Migration and Organ FormationHow cells organize themselves to form functional heart tissue.(00:12:08) Growing a Full-Sized HeartWhether they're printing full-sized hearts or starting with smaller organs.(00:13:34) Avoiding Overgrowth RisksThe role of bioreactors in shaping the early stages of the organ.(00:14:57) Scaling Up Cell ProductionThe need to generate massive numbers of cells for experimentation.(00:18:32) The Challenge of VascularizationCreating a blood vessel network to supply oxygen and nutrients.(00:22:35) Ethical Considerations in BioprintingConsent, stem cell sourcing, and the broader ethical landscape.(00:26:04) The Timeline for Bioprinted OrgansThe long timeline for bioprinted organs to reach clinical use.(00:27:24) The State of the Field & CollaborationThe collaborative, competitive biofabrication field and its rapid progress.(00:28:20) Conclusion Connect With Us:Episode Transcripts >>> The Future of Everything WebsiteConnect with Russ >>> Threads / Bluesky / MastodonConnect with School of Engineering >>>Twitter/X / Instagram / LinkedIn / Facebook

From creating firearms to three-bedroom homes, the capability of 3D printing technology is regularly meeting new benchmarks.

In the quest to revolutionize medicine, our bodies are becoming living laboratories. By 2030, it's estimated that bioprinting could address up to 20% of the organ transplant waiting list globally. These groundbreaking technologies are set to generate custom, patient-specific organs

Keith Murphy, co-founder of Organovo, discusses the growing potential of bioprinting and how the company is using its technologies to study and develop treatments for inflammatory bowel disease (IBD).

Welcome to Astronomy Daily, your go-to podcast for the latest updates in the universe. I'm Anna, your host for today. In today's episode, we'll explore a wealth of exciting topics. We'll be delving into the recent scrubbing of a Firefly Aerospace mission that aims to send educational cubesats into space. We'll also discuss groundbreaking research at the intersection of space medicine and human longevity. And finally, we'll look at the fascinating potential of using Martian lava caves as habitats for future astronauts. Today's episode promises to be both engaging and informative, covering the latest developments that push the boundaries of our understanding of the cosmos. So let's dive into our stellar lineup of stories.Thank you for tuning into Astronomy Daily. I'm Anna, and I hope you enjoyed today's journey through some of the most exciting news and discoveries in astronomy and space exploration. Remember to visit our website at astronomydaily.io for back episodes, our daily newsletter, and the latest news in space and astronomy.Astronomy Daily is available on Spotify, Apple Podcasts, YouTube Music, and iHeartRadio. Please subscribe, rate, and review.Special thanks to our sponsors NordPass, NordVPN, ProtonMail, and Amazon. Links to their offers are available on our website. Until next time, keep looking up.www.astronomydaily.iowww.bitesz.comBecome a supporter of this podcast: https://www.spreaker.com/podcast/astronomy-daily-the-podcast--5648921/support.

A best of episode where Russ interviews one of his bioengineering colleagues,  Fan Yang, about some of the fascinating work she's doing in the realm of tissue engineering. Hear more about the ways her lab is modeling human tissue to help develop a better understanding of how we might effectively replace damaged tissues and alleviate a number of health concerns.Episode Reference Links:Fan Yang's Stanford Profile: WebsiteFan Yang's Stanford Lab: WebsiteEp.174 Regenerating and Rejuvenating Human Tissues: Website / YouTube (original episode) Connect With Us:Episode Transcripts >>> The Future of Everything WebsiteConnect with Russ >>> Threads or Twitter/XConnect with School of Engineering >>> Twitter/XChapters:(00:00:00) IntroductionHost Russ Altman introduces guest Fan Yang, a bioengineer at Stanford.(00:03:15) The Basics of Tissue EngineeringThe purpose and significance of tissue engineering, emphasizing its role in addressing critical medical needs like late-stage arthritis.(00:04:23) Challenges in Tissue EngineeringTechnical hurdles in creating viable tissues for clinical use, such as integrating these tissues into the human body.(00:07:00) 3D Printing and In Situ PolymerizationTechnological advances in shaping tissues using 3D printing and the benefits of in situ polymerization to adapt to complex tissue shapes.(00:09:15) Specific Challenges with CartilageThe challenges specific to cartilage regeneration, explaining why it has been a difficult tissue to replicate and heal.(00:13:56) Micro Ribbon Based HydrogelsExplanation of micro ribbon based hydrogels, a new development aimed at improving tissue regeneration.(00:19:16) Cancer Research and Tissue EngineeringHow tissue engineering technologies are not only pivotal for therapeutic uses but also crucial for understanding diseases and aiding drug discovery.(00:24:38) Regulatory Challenges and CommercializationThe regulatory and commercialization challenges facing new medical technologies, including the need for industry partnerships and the role of the FDA(00:26:20) Conclusion Connect With Us:Episode Transcripts >>> The Future of Everything WebsiteConnect with Russ >>> Threads or Twitter/XConnect with School of Engineering >>> Twitter/X

Dietmar Hutmacher is a Professor and Chair in Regenerative Medicine at the Faculty of Engineering, School of Mechanical, Medical, and Process Engineering at Queensland University of Technology. He possesses extensive experience in 3D cell cultures, grafts, biomaterials, scaffolds, bone engineering scaffolds, biofabrication, and more. On this episode of the 3DPOD, we engage in a candid discussion about the hype surrounding bioprinting, the reality, and the forefront of bioprinting in patients.

Beim Bioprinting werden lebende Zellen, Biomaterialien und Wachstumsfaktoren verwendet, um Gewebe und sogar Organe schichtweise zu drucken. Damit könnte die Transplantationsmedizin revolutioniert werden, weil sie die Herstellung von Organen für Transplantationen erleichtert und personalisierte Behandlungen ermöglicht. Doch wie weit ist die Forschung hier und was sind die Herausforderungen? Darüber reden wir mit dem Molekularbiologen und Gründer von Österreichs erstem 3D Biodruck Labor, Michael Außerlechner.Die Idee für diese Podcastfolge kam von LOOKAUT und der interaktiven Innovation Map der WKÖ. Diese zeigt visionäre Technologien, die unsere Zukunft maßgeblich prägen können. Auf Basis von fünf großen Clustern lassen sich Wechselwirkungen zwischen Technologien, Gesellschaft und Unternehmen nachvollziehen. Hier geht es zur Map.

Mark Skylar-Scott is one of the world's foremost experts on the 3D printing of human tissue, cell by cell. It's a field better known as bioprinting. But Skylar-Scott hopes to take things to a level most never imagined. He and his collaborators are working to bioprint an entire living, working human heart. We're printing biology, Skylar-Scott tells host Russ Altman on this episode of Stanford Engineering's The Future of Everything podcast.Episode Reference Links:Skylar-Scott LabConnect With Us:Episode Transcripts >>> The Future of Everything WebsiteConnect with Russ >>> Threads or Twitter/XConnect with School of Engineering >>> Twitter/XChapters:(00:00:00) IntroductionHost Russ Altman introduces the episode, guest Mark Skylar-Scott and his work bioprinting the heart.(00:02:15) What is Bioprinting & Tissue Engineering?Explanation of bioprinting and its distinction from traditional 3D printing. Overview of the technology and its applications in tissue engineering and how to get the cells for this purpose.(00:06:37) Engineering the Cells of the HeartThe 11 different cell types of the heart that are being created, and the steps involved in printing them, scaffolding them, and how they form tissue.(00:12:23) Building Hearts: Size and Growth ConsiderationsThe scale of bio-printed hearts, potential strategies for growth and integration, & technical challenges in controlling cell growth and development. (00:15:05) Scaling Up Cell ProductionThe importance of scaling up cell production for efficient experimentation. Exploration of the transition from laboratory research to clinical implementation. (00:18:40) Vascularization: The Key to Functional Bioprinted OrgansCritical importance of creating a comprehensive vascular network & the challenges of integrating capillaries and ensuring nutrient delivery to all cells. (00:23:00) Ethical Considerations in BioprintingExamination of the ethical issues surrounding the use of human cells in bioprinting, focusing on consent and the potential for inequality in access due to cost.(00:26:12) The Future of Bioprinting: Timeline and Field DynamicsProjections about the timeline for the clinical application of bio-printed organs and the state of collaborative competition within the fabrication field. (00:28:28) Conclusion Connect With Us:Episode Transcripts >>> The Future of Everything WebsiteConnect with Russ >>> Threads or Twitter/XConnect with School of Engineering >>> Twitter/X

The bioprinting sector has seen rapid growth, with Vital3D leading innovations like their 2 mm tall Christmas tree scaffold, demonstrating advanced 3D-printed tissue scaffolds. This technology promises significant impacts in organ transplantation and reducing animal testing in drug development. In the last few years, the bioprinting sector has experienced rapid growth, marked by significant milestones and innovations. Notable achievements include the successful transplantation of small-scale 3D-printed heart tissues into animals, the creation of 3D-printed kidney models that replicate human renal structure for studying diseases, advancements in 3D-printed liver tissues for drug testing, the development of 3D-printed skin for burn treatments, and progress in 3D-printing cartilage tissue with applications in joint and ear reconstruction. Micro Christmas Tree with Living Cells Innovative approach to bioprinting Amidst this advancing landscape, Vital3D, which specializes in 3D bioprinting solutions stands out with its unique approach to 3D printing scaffolds for organoid growth and tissue regeneration. The company leverages femtosecond laser-based two-photon polymerization technology to address emerging challenges in the field, such as maximizing organoid size, complexity, and diversity of cell types. The company's recent endeavor, a 2 mm tall Christmas tree scaffold, exemplifies its commitment to innovation. This festive creation not only showcases the precision of the FemtoBrush technology but also highlights the potential for complex, functionalized scaffolds that provide ideal environments for cell growth. Dr. Linas Jonušauskas, Chief Technology Officer at Vital3D Technologies, emphasizes the significance of this development: "Our Christmas tree scaffold, while playful, represents a serious step forward. It's a clear demonstration of the ability to create structures that support cell growth in more intricate and specialized ways. This rudimentary square scaffold is just the beginning. The future of bioprinting: beyond organoids Bioprinting holds immense promise beyond the creation of complex organoids. One of the most impactful potential applications is in the field of organ transplantation. By advancing the technology for creating viable, functional organs, bioprinting could revolutionize transplant medicine, offering solutions to organ shortages and compatibility issues. Furthermore, bioprinting has the potential to significantly reduce animal testing in drug development. Providing more accurate human tissue models, enables more effective drug testing and individualization, leading to safer and more tailored medical treatments. Dr. Jonušauskas adds, "Bioprinting is not just about creating structures; it's about creating hope and solutions. From addressing organ transplant needs to reducing reliance on animal testing, the possibilities are vast." About Vital3D Vital3D is a pioneering biotechnology company headquartered in Lithuania, dedicated to innovating advanced solutions in medical research, drug discovery, and regenerative medicine. Established in 2021, the expert team at Vital3D introduced groundbreaking 3D bioprinting technology aimed at bridging the organ supply-demand gap by specializing in the 3D printing of human organs, particularly the kidney. See more breaking stories here.

Welcome to a new episode of  Innovation Fuel! Dave Keighron and Dr. Gelareh Farhadian delve into the cutting-edge world of biotechnology, focusing on tissue engineering and bioprinting. They talk to  Kevin Vos, Ph.D.,  the Director of Business Development and Strategic Alliances at VoxCell BioInnovation. VoxCell is no ordinary bioprinting company; they are a trailblazing tissue engineering firm responsible for a groundbreaking line of Truly Biomimetic solutions for the drug development industry and the field of Oncology research. 

In this podcast episode, MRS Bulletin's Sophia Chen interviews Alice Soragni of the University of California, Los Angeles about her work in precision oncology. Rather than sequence the DNA of a patient's tumor, Soragni uses bioprinting to create organoids from the patient's cells. She then adds various drugs to the cells to directly test their response to each drug. To check the effectiveness of the drugs, Soragni's group measures the organoid's mass with a technique called interferometry. Interferometry is a non-invasive technique that involves shining light on the cells to monitor their response to the drug. This process allows Soragni to characterize the organoid's response to the drug in fine detail. This work was published in a recent issue of Nature Communications. 

The International Space Station has been orbiting in lower earth since 1998 and has been continually inhabited since November 2000. The ISS was originally conceived as a staging base for future missions into deep space. As it turns out, lower earth orbit is an ideal setting for scientific research, from physics and meteorology to astronomy and the life sciences. In this episode we talk with three scientists whose projects are using lower earth orbit to deepen our knowledge of biotechnology and its benefits for mankind.

The pace at which bioprinting technology is advancing shows that it is not just a passing trend, but rather a powerful force that's revolutionizing healthcare.To better understand the current state of bioprinting and its clinical applications,  we're joined by bioprinting expert Didarul Bhuiyan, Ph.D., Sr. Scientist, R&D - Bioprinting at West Pharmaceuticals Services. Didarul shares his expertise in the field, explaining the differences between bioprinting and traditional 3D printing, the challenges faced when using cells in the 3D bioprinting process and the materials used in bioinks for this technology.Key Learning Points:What all is involved with bioprintingHow bioprinting can revolutionize preclinical drug discoveryThe current challenges facing bioprinting technologyThe opportunities for automation within bioprinting workflowsHow hospitals could use bioprinting technologyTake our Podcast Survey!We want to hear from YOU to ensure that we keep providing valuable content that reflects what our listeners and the SLAS community are interested in! Take our brief survey to help us learn how we can improve New Matter.https://www.surveymonkey.com/r/BD7BC82Stay connected with SLASOnline at www.slas.orgFacebookTwitter @SLAS_OrgLinkedInInstagram @slas_orgYouTubeAbout SLASSLAS (Society for Laboratory Automation and Screening) is an international professional society of academic, industry and government life sciences researchers and the developers and providers of laboratory automation technology. The SLAS mission is to bring together researchers in academia, industry and government to advance life sciences discovery and technology via education, knowledge exchange and global community building. Upcoming SLAS Events: SLAS 2023 Microscales Innovation in Life Sciences Symposium September 14-15, 2023 La Jolla, CA, USA SLAS 2023 Sample Management Symposium October 12-13, 2023 Washington, D.C., USA SLAS 2023 Data Sciences and AI Symposium November 14-15, 2023 Basel, Switzerland SLAS2024 International Conference and Exhibition February 3-7, 2024 Boston, MA, USA

This episode is part of the Transforming The Future of Proteins series. XPRIZE Feed the Next Billion is a multi-year, $15M competition that incentivizes teams to produce chicken breast or fish filet alternatives that replicate or outperform these conventional proteins in the following ways: access, environmental sustainability, animal welfare, nutrition, as well as taste and texture. Robin is the Founder and CEO of Revo Foods. Robin has a Ph.D. in Biotechnology from the University of Gothenburg and Tufts University and is recognized as one of FORBES "30 under 30" for the DACH region. With a background in biotechnology and a passion for ocean sustainability, Robin has extensive experience in the field of 3D food printing, which he used when building his first start up. Revo Foods has revolutionized the production of plant-based fish alternatives and is currently the largest supplier of salmon alternatives in Europe. We have a great conversation with Robin as we discuss 3d Bioprinting technologies for food, what is like creating a startup, and the opportunities competitions can bring to the table. Learn more about the XPRIZE Feed The Next Billion Challenge at ⁠www.xprize.org/feed⁠ Learn more about Revo Foods at www.revo-foods.com --- Support this podcast: https://podcasters.spotify.com/pod/show/futurefoodshow/support

بررسی و آگاهی نسبت به ترند‌ها و روند‌های تکنولوژی، کسب‌و‌کار، صنعت و سازمان‌های سلامت یکی از مهم‌ترین راه‌ها برای آگاهی، کسب مهارت و انطباق زود‌تر افراد با تغییرات و شرایط جدید ‌است.در این کادر آیدین و رضا به بررسی ۶ ترند مهم سلامت پرداختند. علاوه بر بررسی ترند‌ها سلامت به این موضوع پرداخته‌شد که به چه مهارت‌هایی با توجه به ترند‌ها و تغییرات جهان نیاز داریم؟، چه فرصت‌هایی در صنعت سلامت در پیش رو است و آینده سلامت به چه شکل خواهد‌بود؟1. AI and Machine learning platforms(10:10)2. Implementing new technologies(26:20)3. life science (designer baby, genetic, aging, Bioprinting, biotechnology, drug discovery, food tech and cultured meat) (33:42)4. Homecare (48:42)5. Digital front door (56:53)6. One Health approach (1:02:26)Future and skills (1:12:40)شبکه‌های اجتماعیInstagram: https://www.instagram.com/uncadr.podcast/Castbox : https://castbox.fm/channel/id4935315?utm_source=website&utm_medium=dlink&utm_campaign=web_share&utm_content=UnCadr%20%7C%20%D8%A2%D9%86%DA%A9%D8%A7%D8%AF%D8%B1-CastBox_FMSpotify: https://open.spotify.com/show/7G85ljGwWSmHOTV5ijBL7IApple podcast: https://podcasts.apple.com/us/podcast/uncadr-%D8%A2%D9%86%DA%A9%D8%A7%D8%AF%D8%B1/id1509976193Google podcast: https://podcasts.google.com/feed/aHR0cHM6Ly9mZWVkcy5hY2FzdC5jb20vcHVibGljL3Nob3dzLzYyNzdhOWFjNmMwNThlMDAxMjRhMTI1OA?sa=X&ved=0CAMQ4aUDahcKEwiYxoitz7n4AhUAAAAAHQAAAAAQAQEverywhere else: https://yek.link/UNCADR Hosted on Acast. See acast.com/privacy for more information.

The International Space Station has been orbiting in lower earth since 1998 and has been continually inhabited since November 2000. The ISS was originally conceived as a staging base for future missions into deep space. As it turns out, lower earth orbit is an ideal setting for scientific research, from physics and meteorology to astronomy and the life sciences. In this episode we talk with three scientists whose projects are using lower earth orbit to deepen our knowledge of biotechnology and its benefits for mankind.

As a mechanical engineer, Jin-Hyung Shim, Ph.D. has a unique perspective on tissue and organ regeneration. He discusses the present and potential of 3D printed biomaterials. Series: "Stem Cell Channel" [Health and Medicine] [Science] [Show ID: 38321]

As a mechanical engineer, Jin-Hyung Shim, Ph.D. has a unique perspective on tissue and organ regeneration. He discusses the present and potential of 3D printed biomaterials. Series: "Stem Cell Channel" [Health and Medicine] [Science] [Show ID: 38321]

As a mechanical engineer, Jin-Hyung Shim, Ph.D. has a unique perspective on tissue and organ regeneration. He discusses the present and potential of 3D printed biomaterials. Series: "Stem Cell Channel" [Health and Medicine] [Science] [Show ID: 38321]

As a mechanical engineer, Jin-Hyung Shim, Ph.D. has a unique perspective on tissue and organ regeneration. He discusses the present and potential of 3D printed biomaterials. Series: "Stem Cell Channel" [Health and Medicine] [Science] [Show ID: 38321]

As a mechanical engineer, Jin-Hyung Shim, Ph.D. has a unique perspective on tissue and organ regeneration. He discusses the present and potential of 3D printed biomaterials. Series: "Stem Cell Channel" [Health and Medicine] [Science] [Show ID: 38321]

(2:25) - Episode 75. Dandelion Inspired Sensors & Microscale Robotic Cilia(5:10) - Episode 99. Ensuring AI Works With The Right Dose of Curiosity(9:40) - Episode 88. AI For Making AI More Creative(15:36) -Episode 90. Wearable To Detect Sleep Apnea(21:49) - Episode 87. Sustainable Hydropower(22:38) - Episode 93. Algorithms predict sports teams' moves with 80 percent accuracy

(3:10) - Printed Bioelectronic PatchesThis episode was brought to you by Mouser, our favorite place to get electronic components for any project. Click HERE to learn more about how nanotechnology is enabling the future of flexible wearables.

(2:55) - Researchers 3D Bioprint Breast Cancer TumorsThis episode was brought to you by Mouser, our favorite place to get electronic components for any project. Click HERE to learn more about how machine learning is being leveraged to more accurately detect cancer via imaging techniques.

Speculation of what alien life may look like is ever changing, but what about life on Earth? Soon the organisms here may be as alien as anything in the cosmos...http://www.troubledminds.org Support The Show! https://www.buymeacoffee.com/troubledminds https://rokfin.com/creator/troubledminds https://troubledfans.com https://patreon.com/troubledminds#aliens #conspiracy #paranormalRadio Schedule Mon-Tues-Wed-Thurs 7-9pst - https://fringe.fm/iTunes - https://apple.co/2zZ4hx6Spotify - https://spoti.fi/2UgyzqMStitcher - https://bit.ly/2UfAiMXTuneIn - https://bit.ly/2FZOErSTwitter - https://bit.ly/2CYB71UFollow Algo Rhythm -- https://bit.ly/3uq7yRYFollow Apoc -- https://bit.ly/3DRCUEjFollow Ash -- https://bit.ly/3CUTe4ZFollow Daryl -- https://bit.ly/3GHyIaNFollow James -- https://bit.ly/3kSiTEYFollow Jennifer -- https://bit.ly/3BVLyCMFollow Joseph -- https://bit.ly/3pNjbzb Matt's Book -- https://bit.ly/3x68r2d -- code for free book WY78YFollow Nightstocker -- https://bit.ly/3mFGGtxRobert's Book -- https://amzn.to/3GEsFUKFollow TamBam -- https://bit.ly/3LIQkFw--------------------------------------------------SETI: Why extraterrestrial intelligence is more likely to be artificial than biological | Astronomy.comhttps://astronomy.com/news/2022/09/seti-why-extraterrestrial-intelligence-is-more-likely-to-be-artificial-than-biologicalChild Born With Exposed Brain Has Life Saved By 3D-Printed Skullhttps://uk.style.yahoo.com/child-born-exposed-brain-life-140000177.html?guccounter=1&guce_referrer=aHR0cHM6Ly9kdWNrZHVja2dvLmNvbS8&guce_referrer_sig=AQAAADXv7fOcMzd6lvM6_YqisK655NmbESlcmsD-AN5XWFQkbR138CQ5e4ApU0fDJMk-8B0w5QpvFPcvDXJhhRFTYZXK1BOEdkDT6QN9XtH4tSaxziab4Dr6vORDZZBFxaDPNNcFK5nYHEu6XOGSm_ZDmxQO99ERMxN_tIGJU4jmd8aU3D Printing Organs: How Soon Are Bioprinting 3D Printed Organs Coming?https://www.allthat3d.com/3d-printing-organs/Homunculus | The Embryo Project Encyclopediahttps://embryo.asu.edu/pages/homunculusHomunculus - Wikipediahttps://en.wikipedia.org/wiki/HomunculusParacelsus, the Alchemist Who Wed Medicine to Magic | Science History Institutehttps://www.sciencehistory.org/distillations/paracelsus-the-alchemist-who-wed-medicine-to-magicParacelsus - Wikipediahttps://en.wikipedia.org/wiki/ParacelsusParacelsus – OCCULT WORLDhttps://occult-world.com/paracelsus/Paracelsianism - Wikipediahttps://en.wikipedia.org/wiki/ParacelsianismStates Adopt a Jumbled Stew of Definitions for Human Lifehttps://archive.ph/B4ElLResearch using bacteria brings scientists a step closer to creating artificial cells with lifelike functionalityhttps://phys.org/news/2022-09-bacteria-scientists-closer-artificial-cells.htmlBioprinting: What It Is and How It's Used in Medicinehttps://www.verywellhealth.com/bioprinting-in-medicine-4691000Understanding Bioprinting and Its Applicationshttps://www.thoughtco.com/what-is-bioprinting-4163337A Milestone in 3D Printed Organshttps://www.mddionline.com/3d-printing/milestone-3d-printed-organsRamping Up the World of Bio-fabricationhttps://www.mddionline.com/3d-printing/ramping-world-bio-fabricationNew granular hydrogel bioink could expand possibilities for tissue bioprinting -- ScienceDailyhttps://www.sciencedaily.com/releases/2022/09/220901135837.htmHomunculus - Monsters - D&D Beyondhttps://www.dndbeyond.com/monsters/16926-homunculusArtificial Life After Frankenstein on JSTORhttps://www.jstor.org/stable/j.ctv16qjxnk?turn_away=trueSlenderman: A Myth Come to Life? | Psychology Todayhttps://www.psychologytoday.com/us/blog/the-asylum/202209/slenderman-myth-come-life

US President Joe Biden recently issued an executive order entitled, “Advancing Biotechnology and Biomanufacturing Innovation for a Sustainable, Safe, and Secure American Bioeconomy.” In this episode of the Xtalks Food Podcast, Sydney talks about the new executive order, which prioritizes research and innovation in a variety of fields, including food. While biotech in general is often associated with energy, medicine and pharmaceuticals, it plays a significant role in the food and beverage industry. She discusses the regulation, safety and controversy behind genetically modified organisms (GMO) as well as precision fermentation to create animal protein without the animals. The team talk about how anti-GMO groups are doing a disservice to consumers and wonder whether biomanufacturing is the key to sustainably feeding future generations.Also, in this episode, Sydney talks about cultivated meat company Steakholder Foods, whose 3D bioprinting capabilities allow it to print steaks, among other meats. To create the true taste, texture and mouthfeel of traditional steak, the company uses a special process that combines cell cultivation with 3D bioprinting, which can produce structured meat with any muscle-to-fat ratio at an industrial scale. Steakholder's other offerings include cultured pork, chicken, fish and seafood. As the only cultivated meat company that is publicly traded on the Nasdaq market, the Israeli food tech company is hoping its 3D-printed cultivated meats will allow it to stand out among the 107 other companies in the space. The team are curious to know what bio-printed cultivated meat tastes like and wonder when these types of products will finally hit the market. Read the full articles here:How Biden's New Biotechnology and Biomanufacturing Executive Order Will Impact the Future of FoodSteakholder Foods is 3D Bioprinting Steak, Among Other MeatsFor more food and beverage industry content, visit the Xtalks Vitals homepage.Follow Us on Social Media Twitter: @XtalksFood Instagram: @Xtalks Facebook: https://www.facebook.com/Xtalks.Webinars/ LinkedIn: https://www.linkedin.com/company/xtalks-webconferences YouTube: https://www.youtube.com/c/XtalksWebinars/featured

Inventia's mission is to scale the creation of human tissue. This startup is creating some of the most powerful tools for advanced medical discovery today, and today we dive into how Inventia has been built from the ground up. Why an agile mindset was a “game changer” for building teams Breaking up a long term goal into smaller “units of progress”. How Inventia teams share responsibility for outcomes, not tasks. How technology is reshaping medicine. Inventia builds machines to bioprint human cells in 3D. These machines help forward-thinking drug discovery and medical research pioneers create human tissue for research and therapy that mimic real human tissue structures, rather than in environments that fail 90% of the time. Episode Highlights from Cameron & Aidan: “We tried to adopt an agile mindset and have outcome driven teams, so putting biologists, material scientists and engineers together in a team, and having really clear outcomes for the product to guide them. They can use all their different skills and experience and deliver something really incredible.” - Aidan “The technology that we're developing is a fundamental shift in our ability to engineer biological tissue at scale, so it's a big mission. We're setting out to build a generational business. And we knew from the outset it was important to break that up into discrete horizons or units of progress.” - Cameron “We thought we had a product, but then we realised the printer was not the product, the product was what the customer takes out of it. It's been that journey of learning more about what's the actual product, and what our customer is going to get value out of.” - Aidan “The one thing I'd do differently is seek to get the product into the hands of more customers early on. The only way to truly iterate on the product and learn where the real value is is to work with as many customers as you can, and learn as much as you can from their usage and feedback.” - Cameron Learn more about Inventia Life Sciences: https://bit.ly/3RhRjz6 Cameron Ferris's Linkedin: https://bit.ly/3TrHSz2 Dr Aidan O'Mahony's Linkedin: https://bit.ly/3CDo2ed Get in touch with Mason using his Blinq card below: https://bit.ly/3AqLYQq

(2:35) - 3D Printing Ice

In this podcast episode, MRS Bulletin's Sophia Chen interviews graduate student John Ahrens of Harvard University about challenges in bioprinting heart tissue. One challenge in particular is aligning the cells. Heart cells are narrow and rectangular in shape. In a natural heart, they line up in parallel to form aligned filaments. Those aligned filaments are built up into a larger tissue with more complex alignment. Cellular alignment correlates with heart function. The research team has programmed the bioprinter to make tissues that are aligned vertically, in a circular pattern, or in the shape of a chevron.  This study is published in Advanced Materials (doi:10.1002/adma.202200217). 

The conflict in Ukraine has intersections with the world of additive manufacturing. Hosts Stephanie Hendrixson, Peter Zelinski and Julia Hider discuss ways that 3D printing is bringing aid; realities of distributed manufacturing; and the effects of the war on one additive manufacturing business with operations in Ukraine.   This episode is brought to you by the Additive Manufacturing Conference at IMTS.   Mentioned in this episode: Project DIAMOnD Tucker Induction Systems, manufacturer and Project DIAMOnD node IQ Manufacturing, another Project DIAMOnD participant MarkForged Dinara Kasko on Instagram Ultimaker Extrusion in Motion ADAM Bioprinting and its entry in The Cool Parts Showcase: 3D printed bone Past episode on blockchain and AM Together We Are Strong Tech Against Tanks United 24 Mint for Ukraine

Along with his fellow researchers at Carnegie Melon University, Adam Feinberg developed what is known as FRESH bioprinting technology. We discuss how and why FRESH is important. We also get to talk about Adam's company, FluidForm, which is commercializing FRESH, but perhaps not in the most obvious way. The episode covers how FluidForm is doing the heavy lifting to commercialize its bioprinting techniques as it works towards scalable bioprinting technologies. All in all, an eye opening podcast.

(2:31) - 3D Printed Bio-Plaster(9:38) - Duct Tape SuturesEpisode 57 was brought to you by Mouser Electronics, Farbod & Daniel's favorite electronics distributor. Click here to read the article discussing how 3D printing is bringing upon the dawn of creativity.

As of 2021, more than 102,000 Americans are waiting for an organ transplant. Learn how doctors are shrinking that number with the help of bioprinted organs on this episode of Tech Tmrw, Explored

(2:40) - Episode 2 - Boom – The Future of Supersonic Flight(6:05) - Episode 8 - Eliminating Emission Inspections Via IoT(10:09) - Episode 28 - Marsquakes Shed Light On The Red Planet's Origins(13:40) - Episode 39 - The 3D Printed Car That Beat The Best(16:45) - Episode 35 - Robot Mimics Mantis Shrimp(20:00) - Episode 42 - World's Most Advanced Prosthetics 

(3:14) - Compact 3D Laser Nanoprinters

In this fun and insightful conversation with the co-founder and co-owner of Cabiomede (Instagram: @CabiomedeVet), I learned a lot more about Mateusz Pawlik, who is behind many of the incredible 3D printing veterinary products for both surgical plannings and for educational purposes. As a young entrepreneur, Mateusz shared with us his earlier failures right out of school, later, business pivots, and future outlook on healthcare 3D printing, not just for veterinary medicine but also for human medicine. We discussed many challenges facing the industry, in particular, how to encourage healthcare providers to adopt a new way of practice and thinking. Links: Instagram: https://www.instagram.com/tv/CUvBfRTJef4/?utm_source=ig_web_copy_linkYoutube:  PendingShownotes: https://3dheals.com/category/blog/interviews/ig-live-interviewAbout our guest this week:Mateusz Pawlik, co-owner of CabiomedeGraduate of Biomedical Engineering at the Silesian University of Technology in Poland. He gained his experience working in international companies in the medical industry as a product engineer and continuous development manager. Co-owner of CABIOMEDE – company providing R&D services in medical engineering area and Pets Analytics – startup developing an innovative solution in the field of animal health monitoring.Operations Manager responsible for new products and technology development – presurgical models, custom made surgical guides and implants, polymeric and metal spine and joint implants for animals. Together with CABIOMEDE team developed more than 500 patient's cases on a basis of Computed Tomography. His biggest project was related to create veterinary surgical workshop models – full canine and feline fractures database according to AOVet classification.Support the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

In this episode, we were fortunate to interview the CEO of Brinter, Tomi Kalpio, on Instagram Live to learn the birth history of Brinter, what makes Brinter differentiated from other bioprinting platforms, biotechnology entrepreneur life in Finland, Tomi's vision for the bioprinting and regenerative medicine field, and the future of Brinter, why “collaboration” is more meaningful in 3D bioprinting either in the academia or commercial/pharma world, why is no one creating software for bioprinting? Links: Shownotes: https://3dheals.com/category/blog/interviews/ig-live-interviewInstagram:  https://www.instagram.com/tv/CUK8Y9Vppvx/?utm_source=ig_web_copy_linkAbout our Guest for this Episode: Tomi Kalpio, CEO of BrinterAn innovative leader always looking for new ways to tackle old challenges by creating solutions you did not know that you need.Leadership and Management skills:- Technological Competence Management; Technologically-oriented business knowledge which creates a solid ground to analyze and develop global operations and processes- Order-to-Delivery processTechnical skills:- Bioprinting / Additive Manufacturing / 3D-printing / 3D Design Professional- Value-adding to production processes and product- Know how from small product specific details to large production linesSupport the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

(1:00) - Biomedical Engineers Grow 3D Bioprinted Blood Vessel: Do you ever read about a groundbreaking new drug and then wonder why it never actually becomes available to the general public? Well, a group of Texas A&M researchers plan to address that by mimicking human biology using functional 3D printed blood vessels.  (9:10) - 3D Printed Eardrum Graft: Eardrum damage is difficult to address with most treatments being intensive, expensive, and ineffective. To address this problem, researchers developed a 3D printed eardrum graft that can be implanted via a non-invasive procedure and return full functionality. About the podcast:Every day, some of the most innovative universities, companies, and individual technology developers share their knowledge on Wevolver. To ensure we can also provide this knowledge for the growing group of podcast listeners, we started a collaboration with two young engineers, Daniel Scott Mitchell & Farbod Moghaddam who discuss the most interesting content in this podcast series. To learn more about this show, please visit the shows page. By following the page, you will get automatic updates by email when a new show is published.Be sure to give us a follow and review on Apple podcasts, Spotify, and most of your favorite podcast platforms!Take a few seconds to leave us a review. It really helps! https://apple.co/2RIsbZ2 if you do it and send us proof, we'll give you a shoutout on the show.

Rice University bioengineer Jordan Miller and his students cleared a major hurdle on the path to 3D printing replacement organs when they published a breakthrough technique for bioprinting "multivascular" tissues that was featured on the cover of the journal Science in 2019.Their innovation allows scientists to bioprint tissues with exquisitely entangled vascular networks for transporting blood, air, lymph, and other vital fluids. The work included a stunning proof-of-principle demonstration: a hydrogel model of a lung-mimicking air sac that was rhythmically filled and emptied of air, simulating inhalation and exhalation. A basket-like network of blood vessels surrounded the air sac but did not physically touch it. As deoxygenated blood flowed past the air sac, red blood cells became oxygenated from air that diffused from the sac to the nearby blood vessels.Jordan joins us today to talk about these innovative movements forward. Want better health and nutrition? Now you can get personalized supplement recommendations and custom vitamin packs delivered to your door! Go to PersonaNutrition.com/Roizen and take your free assessment and get 50% off your order today. - sponsor  BonusHow Your Diet Affects Your Risk for Cancer

In this episode, we were able to have an in-depth conversation surrounding not just Amy Karle's major artworks using 3D printing and Bioprinting, but also her personal journey as a bioartist and the meanings behind her artworks.  The two works we focused on include :1. Regenerative Reliquary, which is a bioprinted scaffold with stem cells in the shape of a hand in a bioreactor to grow bone tissue2. Heart Evolution, which is an artistic alternative design for a "better" heart that potentially could avoid existing Some of the questions we explored include:What does bioprinted organ replace imply to humanity and our identities?Who has the right to live and access the new and expensive technology that can prolong life?Who will have access to bioprinted or 3D printed medical devices first? What makes something beautiful (Aesthetics)?Why is it important to make something beautiful (or not)?What is the role of an artist in terms of aesthetics?Why is 3D printing (especially in medicine) often perceived as beautiful?How does an artist feel about generative design? Threatened by robots?  Youtube ShownotesInstagramBlogsAbout our guest: Amy Karle is an internationally award-winning bioartist whose work can be seen as artifacts of a speculative future when digital, physical, and biological systems merge. Her work opens future visions of how technology could be utilized to support and enhance humanity while making advancements towards those goals in the process.In the process of making the artwork, Karle utilizes the technological tools in question and collaborates directly with science and technology to create a joint space for imagination, exploration, and creation. Current projects probe who we could become as a result of exponential technologies and how interventions could alter the course of our future.Karle has exhibited in prestigious museums worldwide, including at the Smithsonian, USA; The Mori Museum, Japan; The Centre Pompidou, France; Beijing Media Arts Biennale, China; Ars Electronica, Austria; and is regularly invited to share her insights as an expert speaker and in think tanks. Karle was honored as one of “BBC's 100 Women”, has been named one of the “Most Influential Women in 3D Printing”, and was Grand Prize Winner of the "YouFab Global Creative Award". Karle was also an Artist Diplomat through the U.S. Department of State tasked with women's empowerment and supporting collaborations using art and technology to address social issues. The long-term goals of her work are to continue to pioneer in the art and tech field and make contributions to the advancement of society, technology, and healthcare in the process. www.amykarle.comSupport the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

In this episode, I had the pleasure to chat with professor Stephanie Willerth at the University of Victoria, also the founder of Axolotl Biosciences.Stephanie is not only an expert in bioprinting and bioinks in general, but also one of a few scientists in the world focusing on using 3D cell models on common but devastating neurological diseases such as GBM, Parkinson's Disease, and Alzheimer's Disease. We started with some basic concepts related to bioprinting, bioinks, organoids, and organ-on-a-chip, and some of the general current applications and ongoing researches. All of these technologies, however, require sophisticated bioink formulation to achieve structural and functional goals. Also, who are the major players in commercial bioprinting? Other versions of this episode: WebsiteInstagramAxolotl BiosciencesWillerth LabYoutubePast blog by prof. Willerth: 3D Bioprinting Glioblastoma Models for Drug Screening3D Bioprinting Personalized Brain TissuesAbout Our Guest:Dr. Willerth holds a Canada Research Chair in Biomedical Engineering at the University of Victoria where she has dual appointments in the Department of Mechanical Engineering and the Division of Medical Sciences as an Associate Professor.She serves as the Acting Director for the Centre for Biomedical Research at the University of Victoria and on the steering committee of the B.C. Regenerative Medicine Initiative. She also served as the President of the Canadian Biomaterials Society from 2017-2018. Her honors include being named the 2018 REACH award winner for Excellence in Undergraduate Research-inspired Teaching, a Woman of Innovation in 2017, one of the 2015 Young Innovators in Cellular and Biological Engineering, and a “Star in Global Health” by Grand Challenges Canada in 2014. She spent the Fall of 2016 on sabbatical at the Wisconsin Institute for Discovery supported by the International Collaboration on Repair Discoveries International Travel Award where she wrote her book “Engineering neural tissue using stem cells” published by Academic Press.She completed her postdoctoral work at the University of California-Berkeley after receiving her Ph.D. in Biomedical Engineering from Washington University. Her undergraduate degrees were in Biology and Chemical Engineering from the Massachusetts Institute of Technology.Support the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

I had a lot of fun chatting with this international group of young entrepreneurs out of KTH from Akira Science ( @akirascience) in Sweden. We started the conversation on how the members of the team met. Then we moved onto the biopolymers the team is working on and commercializing, including why it is important to have controllable biodegradable biocompatible and 3D printable materials. We also touched upon the potential killer applications using the Akira biopolymer, including creating a scaffold for breast cancer lobectomy patients and wound healing. We also talked about the unique innovation and entrepreneurial environment in Sweden. You can find additional resources here: https://www.akirascience.com/YoutubePodcastWebsite linkInstagram liveAbout Our Guests: Tiziana Fuoco: Chief Operating OfficerAstrid Ahlinder: Product ManagerÁlvaro Morales López: Marketing ManagerSupport the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

In this live Youtube interview, I had the pleasure of getting to the co-founders (also husband and wife) for 3D Biotechnology Solutions, Ana Millás and Pedro Massaguer. 3DBS is the first Brazilian startup that brought bioprinters to its local research institutions and market, and now it is gearing up to expand its global market including that of the United States. Some of the major talking points of this episode include Ana and Pedro's early journey as biotech cofounders in Brazil, their funding strategies, market product fit, and their strategies in dealing with the local innovation ecosystem and regulatory agencies. We also dig a little deeper on their new hybrid bio fabrication bioprinter that combines electrospinning and extrusion-based bioprinting to generate unique tissue engineering capability for its customersFollow 3DHEALS: https://www.instagram.com/3dheals/https://linktr.ee/3dhealsFollow our guests: https://www.instagram.com/3dbiotechnologysolutions/Show Notes: https://3dheals.com/made-in-brazil-interview-with-the-co-founders-of-bioprinting-startup-3d-biotechnology-solutionsMore on our Guests: Ana MillásAs a biologist, Millás holds her PhD and Master's degree from the Department of Materials Engineering and Bioprocesses at the School of Chemical Engineering of State University of Campinas/UNICAMP. Post-doctoral degree at School of Pharmaceutical Sciences - University of São Paulo. Ana has made part of her research in internationally renowned research centers and institutions, among them, at Cornell University in the United States and Nottingham Trent University and The Electrospinning Company in UK. She has an amazing experience in the amazon forest, also experience in the textile industry. As the R&I Director at 3D Biotechnology Solutions startup, she focused her research on the development of 3D skin in vitro models, vascularized tissues and cartilage reconstruction using the technologies of electrospinning and 3D bioprinting.Pedro MassaguerBusiness Developement, is a specialist in Strategic Business Management. He completed a Master's and Doctorate in the Science and Technology Policy program at the state University of Campinas (UNICAMP). He has experience in innovative technology-based projects, business development, and strategic planning in the area of Biotechnology. He is the CEO of 3D Biotechnology solutions and also partner of In Situ Cell Therapy and Labtermo Microbiology Consultancy.Support the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

Do us a favor and leave us a review on Apple podcasts: apple.co/2RIsbZ2 (0:50) - Bioprinting During Surgery: Trauma to the head or face can be difficult to address and oftentimes requires bone grafts from the patient or cadaverous. Professor Ibrahim Ozbolat's team at Penn State has addressed this by developing bio inks for hard and soft tissue enabling in situ bioprinting during surgery. (7:40) - Hairbrush Robot:Nurses spend 18-40% of their time on direct patient care which involves hygienic maintenance like brushing hair. A joint effort from MIT & Harvard aims to alleviate so of their workload by automating the hair brushing process using robots.(13:10) - Anode Free Batteries:Lithium ion batteries power almost all major electronic appliances that we use today; however the main ingredient is scarce and therefore ~25% of the cost we pay is just for the battery. Professor Pen Bai from Washington University wants to address this issue using their new anode free sodium based battery cells that were developed.

It has been almost nine months since we interviewed Mike Graffeo, CEO, and co-founder of Fluidform, a 3D printing startup out of Carnegie Mellon University focusing on key applications using Freeform Reversible Embedding of Suspended Hydrogels (FRESH) technology.  If the average lifetime of a typical startup is five years, the one-year time of a startup is equivalent to 20 human years.  Check out the recording of this episode of Instagram Live on how a bioprinting startup was founded, lessons learned, ambitions, and more.  The video format of this interview can be found on 3dheals.com.Instagram Live occurs every Thursday to put the innovators, artists, and founders behind impressive 3D technology Instagram shares in front of the camera.  Want to join us next Thursday? Direct message us on Instagram @3dheals. About our guest:Mike Graffeo CEO and co-founder of FluidformA senior executive with a proven track record in the commercialization of innovative medical technology, Mike is a results-oriented, decisive leader with a track record of successfully growing new businesses in both startup and growth organizations. Throughout his career, he has gained extensive experience translating highly complex devices and clinical data into successful businesses, both in the US and globally. Mike holds a BS in Engineering Physics and an MEng in Mechanical Engineering from Cornell University, as well as an MBA from Harvard Business School.Support the show (https://www.paypal.com/cgi-bin/webscr?cmd=_s-xclick&hosted_button_id=STF9STPYVE2GG&source=url)

Dr. Chitra Chakravarthy is a maxillofacial surgeon with more than 21 years of surgical experience. She is a Professor & Head of the Department of Maxillofacial Surgery at Navodaya Dental College, Raichur. She also runs her own private dental practice.    Learn more about 3D Printing on www.surgeonsin3dprinting.com.   Subscribe    Apple I  Google I  Amazon Music I Spotify I Gaana   Resources:   Join the Facebook community Surgeons in 3D Printing!   Visit the website: www.surgeonsin3dprinting.com.   Three Takeaways Mindset is the biggest hurdle for embracing this technology. The cost can be managed in different ways. There are a plethora of maxillofacial applications with 3D Printing.   Sponsors: Reconstructive Healthcare Solutions Private Ltd.   Show Notes   Today's AudioTraining: Unstoppable by the hindrance of the cost when it came to 3D Printing and its applications, with Dr. Chitra Chakravarthy   [1.46]  Dr. Chitra shares her journey about the beginning of 3D Printing as a hobby   [2:36] She shares how she started 3D Printing in her profession and. Her feelings associated with the model in hand.Dr. Chitra shares how she learned from her engineer friends and both learned with each other     [4:46] Dr. Chitra shares how her mind always works to incorporate 3D Printing in her work. She shared other applications she does with 3D Printing.     [9:00]  Maam shares her passion for 3D Printing. She also shares how she began by herself and then added her engineer to her team. She also shares her experience with open-source software.     [12:20]   Dr. Chitra reveals that she could do dental implant guides by herself. She also shares hurdles that come in which affect the penetration of the technology. The mindset has to be changed for the adoption of technology.     [14:40]   Dr. Chitra shares the learning curve of this technology. Technology, Cost, and Mindset are three big challenges.     [16:00]  Dr. Chitra shares her vision with 3D Technology and BioPrinting. She then shares a week of her dental and surgical practice.   [18:11] Dr. Chitra shares her academic teaching model.   [20:21] Dr. Chitra shares her concluding messages.   Killer Resources   Take the first step to your 3D Printing journey.   Register for the upcoming course on Introduction to 3D Printing.   Connect with us on a zoom call for 20 minutes of free consultation.

Dr. Veerabahu M is a renowned Maxillofacial Surgeon and the President of the Association of Oral & Maxillofacial Surgeons, India. He is the Professor & Head of the Department of Oral & Maxillofacial Surgery at Ragas Dental College & Hospital, Chennai. He is one of the pioneers who envisioned the potential of 3D Printing technology and its application when the technology was still in its infancy in India. Learn more about Medical 3D Printing on www.surgeonsin3dprinting.com. Subscribe    Apple I  Google I  Amazon Music I Spotify I Gaana   Resources:   Join the Facebook community Surgeons in 3D Printing!   Visit the website: www.surgeonsin3dprinting.com.     Three Take aways 3D Technology will soon be the part of our curriculum so one needs to get trained. It is a stepping stone for learning other technologies like Bioprinting. It is an important part of enhancing surgical outcomes and helps in patient education.   Sponsors: Reconstructive Healthcare Solutions Private Ltd.   Show Notes **Click the time stamp to jump directly to that point in the episode.   Today's AudioTraining Insights & Future of 3D Technology in Maxillofacial Reconstruction   [00:41]: Dr Veerabahu shares his story about how he got started with 3D Technology and its applications.He shares the contribution of his colleague , his mentor and engineers with whom he got associated.   [02:07]: Dr Veerabahu elaborates the difficulties and outcomes of conventional surgery for complex orbital injuries which led him to find his way to 3D Technology as a surgical tool.   [04:16]: He discusses in detail his experience of using virtual planning for reconstruction of secondary traumatic injuries of orbit and how it could prevent complications.He also discusses the role  of  Medical Models on enhancing Patient education.    [05:12]: Dr Veerabahu shares about his famous case which appeared in the Times of India when not many people were aware of  3D Technology.He shares his story about the case and about his vision that he had about the technology.   [07:30]: Dr Veerabahu shared insights about sub-periosteal Implants.   [08:33]: He also shares his views on how 3D Printing is growing through branches of dentistry and maxillofacial surgery. It is now growing bigger and getting to regenerative medicine and Bioprinting organs.   [11:42]: Dr Veerabahu shares his message to the surgeons at different stages in their career to start with 3D Technology before it is too late.He says it is coming in our curriculum and can be made affordable by more people using it.   [15:49]: Here is his message for surgeons who are just beginning their surgical journey.   [17:27]: Dr Veerabahu shares his insights on how this technology is also creating job opportunities  for our dental fraternity to work with medical fraternity as this technology is a common thread across specialities.   [18:18]: Dr Veerabahu shares the inside story of the Association working to build platforms for the penetration of this technology.   Killer Resources   Take the first step to your 3D Printing journey.   Register for the upcoming course on Introduction to 3D Printing.   Connect with us on a zoom call for 20 minutes free consultation.

This week on News Time, we're singing with the sparrows, getting colourful with crayons and cooking up some scientific snacks...