Atzeyo Biosensors, Inc.的动态

Executing a DOE experiment in an afternoon isn't a pipe dream. It's a real possibility, and it's already here. Our Customer Success Scientist Nathan Hardingham shows how you can use Synthace DOE and a powerful liquid handler from Hamilton Robotics to get the job done quickly and effectively. In this case, it was optimizing the expression of a fluorescent-tagged protein of interest in neural stem cells. 7 factors. 96 runs. 3 replicates. 1000 (ish) liquid handling actions. Easy. #LabAutomation #DOE #DesignOfExperiments #DOEForBiology

A research team led by Chemistry's Anna-Karin Gustavsson has unveiled soTILT3D, a cutting-edge imaging platform that could change how we explore cellular structures at the nanoscale. Published in Nature Communications, the breakthrough enables faster, more precise 3D imaging of cells, paving the way for deeper insights into health and disease. soTILT3D can capture nanoscale details that reveal critical molecular interactions driving cellular behavior. It also allows flexible control of the cellular environment for dynamic studies, and it overcomes limits of traditional microscopy by addressing challenges related to high-background fluorescence and imaging speed. https://bit.ly/4eWuE6Q #RiceNatSci #RiceUniversity

Since the initial discovery of DNA's molecular structure, our understanding of DNA, genes, and genetics has blossomed, enabling the creation of a variety of exciting innovations. Now, researchers at the Wyss are exploring new frontier of DNA: not just understanding it, but using it as a building material to solve a whole new set of problems at the nanoscale. In this Q&A Story to celebrate #DNADay, the leaders of the Wyss' Molecular Robotics Initiative, William Shih, Wesley Wong, and Peng Yin, discuss how they're using DNA, what problems they can solve with DNA nanotechnology, and their progress towards the ambitious founding vision of this Initiative. #Nanotechnology #DNANanotechnology #MolecularRobotics #Innovation https://lnkd.in/eK5hGdVR

?? Recently, I stumbled upon an intriguing article by Adam Zewe from MIT News that truly grabbed my attention. It's about a breakthrough in noninvasive imaging methods that can penetrate deeper into living tissue, and I couldn't help but feel excited about the implications of this technology! ?? The article highlights several key advancements, such as the development of a new laser technique by MIT researchers that more than doubles the usual depth limit of metabolic imaging. This innovation not only enhances imaging speeds but also delivers richer and more detailed visuals without the need to alter the tissue with dyes or slicing. These insights particularly stood out to me because they offer a more accurate representation of cellular structure and function. As someone who values precision in technology, this advancement is absolutely fascinating. ?? From my perspective, this leap forward in imaging technology is bound to transform fields such as cancer research, tissue engineering, and drug discovery. The ability to observe metabolic dynamics deep within living systems could empower scientists and engineers to innovate further, much like the approach we take in software development to continuously improve and iterate. It's a reminder that distinguishing innovation often sparks from pushing existing boundaries while maintaining core functionality. ?? I'm curious to hear your thoughts: How do you think advancements like this in metabolic imaging could influence other technological fields, including software engineering? Let's discuss in the comments! ???? #Innovation #TechnologyAdvancement #MetabolicImaging #LifeSciences #TechLeadership

Could magnetic skin transform cancer treatment? ?? A groundbreaking study from the University of Leeds suggests it just might! Researchers have developed a new class of robots featuring magnetic skin that grows and moves like creeping vine plants, allowing them to navigate narrow pathways deep within the body, such as the bronchial tree. "These new robots represent a significant advancement in surgical navigation technology that could benefit millions of people," says Professor Pietro Valdastri, Director of the STORM Lab and research supervisor. ?? Curious to learn more? Check out the full article from the University of Leeds: https://lnkd.in/eaq9s8Vz

Publication in Nature Communications reveals cellular communication in real-time. Researchers from KTH-SciLifeLab and the University of Padua, Italy, have introduced advanced imaging tools to study how cells communicate. In a recent paper in Nature Communications, the team presented a new technology that allows scientists to observe cellular interactions, specifically focusing on membrane contact sites and calcium signalling, in real-time. These sites are essential areas where different cellular parts come together to exchange molecules, playing a key role in cell function. Traditional imaging struggled to capture these rapid interactions, but this new approach allows high-resolution tracking of these events as they happen. Hjalmar Brismar, Professor at KTH and co-author: "We are excited to have contributed to this study, utilizing the advanced ALM microscopy infrastructure at KTH and SciLifeLab. This collaborative effort exemplifies how KTH's cross-disciplinary approach and state-of-the-art facilities can drive significant advancements in research. Our findings highlight the potential for future discoveries in fundamental cell biology and have implications for understanding complex diseases like Alzheimer's and cancer." Read the study in Nature Communications: https://lnkd.in/giDnqRth

AI Brains: FinalSpark's Biocomputers Pave the Way for a Sustainable Future Swiss tech firm FinalSpark has?unveiled?Neuroplatform, a revolutionary biocomputing platform that uses human brain cells—organically grown organoids—as computing units. This innovative approach marks a significant step towards creating AI systems that are much more energy-efficient than traditional silicon-based models. By connecting clusters of brain organoids to electrodes and training them with dopamine, Neuroplatform mimics the learning processes of human brains, potentially enabling these biocomputers to perform tasks akin to modern CPUs and GPUs. Stay ahead with the latest insights and breakthroughs in AI-driven healthcare. Subscribe now for free to read our upcoming newsletter- https://lnkd.in/drMdAFND #hearthealth #aihealthcare #healthcare #ainews #aiinmedicine #heartdisease #aibreakthroughs #aiinnovation #aidevelopments #cancercare #cancer #diabetes #breastcancer #biocomputers #biotechnology

An MIT research team, including MechE Faculty members Roger Kamm and Linda Griffith, has developed a new technique that more than doubles the usual depth limit of metabolic imaging, a noninvasive method that enables clinicians and scientists to study living cells using laser light. The method boosts imaging speeds, yielding richer and more detailed images. https://lnkd.in/e2GBnZ7b

Focusing :- Researching on Human Autoimmune Disorder (Lungs, Kidney Liver Failure and Cancer Heart disease, Biomedicine, Robotics and Neural Network System based on Quantum Computing and Molecular Quantum Mechanics. Biomedicine and Nanotechnological Bio informational Technologies.