At Medphoton, a Brainlab company, we invent cutting-edge medical technologies for intraoperative imaging. That is why we are thrilled to announce that the mobile imaging robot, Loop-X, developed by Medphoton, is being used to further the research on the optimization of smart operating rooms. Principle investigator Mathias Unberath, Benjamin Killeen and the rest of the team at the Johns Hopkins Department of Computer Science Advanced Robotics and Computationally AugmenteD Environments (ARCADE) Lab from the Johns Hopkins Whiting School of Engineering are using Loop-X to develop an autonomous, integrated system that can automatically take and interpret X-ray scans. Their goal is to expand the capabilities of smart operating rooms and simplify complicated procedures. Read the full press release for more details here: https://lnkd.in/g4su3GqA #medtech #medicalresearch Image Credit: Will Kirk / Johns Hopkins
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High-Content Imaging Essentials in 60 Seconds! https://lnkd.in/dQTRF24e High-content imaging might sound complicated, but we’ll break it down in just one minute! 🌟 Imagine scanning thousands of cells simultaneously with high-resolution microscopy, optimized optics, and special microtiter plates designed for ultra-high throughput. 🔬 Paired with automated setups, robotics, and AI, high-content imaging accelerates drug development like never before. 🚀 What you need: dedicated scientists and technicians working tirelessly to optimize every step of the process. Curious about how science is shaping the future? Follow us for more exciting insights! #HighContentImaging #DrugDevelopment #ScienceExplained CELLIMA Scientific Services
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Elon Musk’s company, Neuralink, has announced a new feasibility trial to test its brain implant for controlling a robotic arm using thought alone. The trial will extend the capabilities of the N1 brain-computer interface (BCI). BCIs enable direct control of external devices by decoding brain waves and interpreting movement signals from neurons, helping in assistive technology. Neuralink shared the news on social media platform X, marking a significant step forward in testing the N1 implant for practical and assistive robotic applications. #Techwixer #Elon #Musk #Robotic #Neuralink #Technology #Tech #Devices
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Providing the best Talent and Services for your team globally within the Life Science / Biotech sector
🤖💡 Neuralink Advances Brain-Controlled Robotic Arms 🧠✨ Neuralink has received approval for a new clinical study (CONVOY) to connect its N1 brain chip with robotic arms, empowering individuals with severe paralysis to regain physical freedom. 🌟 Key Updates: 🔹 Participants from the PRIME trial (spinal cord injury & ALS) can now join this study. 🔹 Neuralink’s tech has already enabled users to play chess and music using mental commands. 🎵♟️ 🔹 Future potential includes integration with Tesla’s Optimus humanoid robot. 👏 This milestone blends neurotech and robotics, offering hope to millions and redefining assistive technology. #Neurotech #Innovation #Robotics #BrainComputerInterface #HealthcareRevolution #AssistiveTech
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Professor & Senior UA Engineering Research Chair in Healthcare Robotics, University of Alberta
To build a robot-assisted surgical system, dynamic uncertainties can be a critical issue when it comes to robot control. "Disturbance observer" is a common tool for disturbance estimation and compensation by taking all uncertainties as disturbances, but this will refuse human-robot interaction since the human-applied force will also be regarded as a disturbance by the observer! #Iterative #learning for #gravity #compensation can be a promising way to solve this problem when gravity compensation is the main concern. In our newest publication, we present a gravity iterative learning (Git) scheme in Cartesian space for gravity compensation that integrates with an impedance controller. The integration of Git with an impedance controller allows for seamless human-robot interactions. This framework promises to improve the precision and safety of surgical robots by ensuring accurate trajectory tracking and set-point regulation without the need for high impedance gains. Teng Li, Amir Zakerimanesh, Yafei Ou, Armin Badre, and Mahdi Tavakoli, Iterative Learning for Gravity Compensation in Impedance Control, IEEE/ASME Transactions on #Mechatronics, 2024. https://lnkd.in/gUCvte4b https://lnkd.in/grsfJyRM
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@UMD computer scientists have developed a groundbreaking camera inspired by the human eye. The Artificial Microsaccade-Enhanced Event Camera (AMI-EV) mimics tiny eye movements to capture sharper, blur-free images, revolutionizing robotic vision and beyond. https://lnkd.in/gYJpHKf4
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Chinese researchers have achieved a groundbreaking milestone by developing a robot powered by a miniature human brain, reminiscent of Frankenstein's creation. This innovative robot operates using a lab-grown brain organoid, which consists of a cluster of cells and a computer chip that interfaces seamlessly with the brain's nervous system. Dubbed the "brain on a chip," this system simulates human brain functions with the help of sensors and an Al-driven algorithm, allowing the robot to move, grasp objects, and navigate around obstacles. Discover the full story on https://lnkd.in/dGDyfAz7 #Innovation #Artificiallntelligence #Robotics #Technology #Al #BrainTech #Research #FutureTech #Biotechnology #TechTrends
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An excellent session on how the healthcare landscape is changing through AI, quantum sensing for brain imaging, medical devices and sensors, robotic surgeries and drug discovery. King's College London #healthcare
Join us on Monday 25 November for our latest King’s Experts Series webinar, exploring the topic of ‘AI, Quantum and Microtechnologies in Healthcare’. We’ll be joined by leading King’s experts who will discuss cutting-edge research across medical imagining technologies, surgical robotics and quantum science, and will consider how these technologies are changing medical diagnosis and treatment, designing a future that empowers us to live well with technology. Register your place now 👇 https://loom.ly/ulSsh9U #ForeverKings🦁
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RL controllers for quadruped locomotion are great but black-box. Are they safe enough? Our new work in #RSS2024 reveals the risk of small noises and low-frequency velocity commands falling SOTA controller, which helps win SubT Challenge, even on the simplest flat terrain. We explored whether standard robustness tests, human experiences, and domain randomization are enough, together with tons of other extensive studies. This work is collaborated with Chong Zhang, Takahiro Miki, Joonho Lee, Marco Hutter, Stelian Coros at Robotic Systems Lab, Computational Robotics Lab - ETH Zürich, and ETH AI Center. Project page: https://lnkd.in/eHKhfvPZ
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Click the link in order to read “From Molecular Robotics to Molecular Cybernetics: The First Step Toward Chemical Artificial Intelligence” for free! “Molecular Cybernetics” is an emerging research field aiming the development of “Chemical AI”, artificial intelligence with memory and learning capabilities based on molecular communication. Read now: https://bit.ly/3UTOtEy
