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Electric eels have inspired the development of soft, stretchable batteries with the potential to be used for wearable devices, soft robotics and implants. Electric eels stun their prey with modified muscle cells called electrocytes. Like electrocytes, the jelly-like materials developed by The University of Cambridge researchers have a layered structure that makes them capable of delivering an electric current. The so-called jelly batteries can stretch to over ten times their original length without affecting their conductivity – the first time that such stretchability and conductivity has been combined in a single material, the team reported. Their results are detailed in 'Science Advances'. Read more here 👇 https://lnkd.in/eYMbbvU3 #theengineer #batteries #wearable #devices #robotics #implants University of Cambridge Yusuf Hamied Department of Chemistry

Soft, stretchy ‘jelly batteries’ inspired by electric eels - https://lnkd.in/es9RJ3E3 - Researchers have developed soft, stretchable ‘jelly batteries’ that could be used for wearable devices or soft robotics, or even implanted in the brain to deliver drugs or treat conditions such as epilepsy. The researchers, from the University of Cambridge, took…<p class="more-link-p"><a class="more-link" href="https://accionvegana.org/accio/0ITbvNmLulGZltmbpxmL3d3d6MHc0/">Read more →</a></p>

🔬 The innovation in medical sensors continues to push boundaries! Electronics Weekly reports on a groundbreaking development in elastic conductive films used in medical sensors, improving flexibility, and accuracy for patient monitoring. This advancement could reshape how we approach medical diagnostics and wearable tech, providing a new level of precision in real-time health data. #MedicalDevices #EmbeddedEngineering #UKEmbedded #TechInnovation #nGenium Sam O'Leary Nathan Upton Nathan Read Jowell Grandison Alan Ling

Big changes are coming to #Biotech Flexible nano-sized ribbons of plastic and peptides that can store energy, record digital information, and recharge like a battery could deepen the future of wearable technology and medical devices. While there has been significant progress in the development of wearable and implantable technology in recent years, most electronic materials are hard, rigid, and feature toxic metals. A variety of approaches for creating “soft electronics” has emerged, but finding ones that are durable, power-efficient, and easy to manufacture is a significant challenge. The researchers told Science that as well as being able to store energy or information in the material’s polarization, it’s also biocompatible. This means it could be used in everything from wearable devices that monitor vital signs to flexible implants that can replace pacemakers. The peptides could also be connected to proteins inside cells to record biological activity or even stimulate it.

Researchers at Tampere University have created the world's first soft touchpad capable of sensing force, area, and location of contact without the need for electricity. Utilizing pneumatic channels embedded within a soft silicone structure, the device is designed for use in environments unsuitable for electronic sensors, such as MRI machines. The touchpad features 32 narrow channels that adapt to touch, allowing it to accurately recognize handwritten letters and distinguish multiple simultaneous touches. Its non-electrical nature makes it immune to interference from strong magnetic fields, making it particularly suitable for medical applications, such as guiding pneumatic robots to perform biopsies during MRI scans. This innovative technology also holds promise for soft robotics and advanced prosthetics, where traditional hard electronics are impractical. The integration of touch sensors into soft devices can enhance their functionality, enabling safer and more delicate interactions in various applications, including rehabilitation aids. The flexibility of silicone enhances comfort and usability, positioning this technology as a significant advancement in the field of soft robotics and wearable devices.

#Researchers have developed soft, stretchable #jellybatteries that could be used for #wearabledevices or soft #robotics, or even implanted in the brain to deliver drugs or treat conditions such as epilepsy. The researchers from the #UniversityofCambridge took their inspiration from electric eels, which stun their prey with modified muscle cells called #electrolytes. The ability to precisely control mechanical properties and mimic the characteristics of human tissue makes #hydrogels ideal candidates for #softrobotics and #bioelectronics. #wearabledevices #softrobotics #jellybatteries #ions #biomedicalimplants

Breaking the Rules of Polymer Science! Researchers at the University of Virginia have done the impossible: they made a material that’s both stiff and stretchy at the same time. For over 180 years, we thought if you made a polymer stiffer, it had to lose its stretchiness. Not anymore. They created foldable bottlebrush polymers that can store extra length, solving the stiffness vs. stretchiness problem. This breakthrough could change the game for medical implants, wearable electronics, and even soft robots. Instead of adding more crosslinks, they focused on smart molecular design, giving the polymer strength AND flexibility. Imagine heart implants that bend with every beat but last for years, or prosthetics that feel more like natural limbs. This innovation opens up new possibilities in health care, robotics, and more. https://lnkd.in/gANi9Kaa #Innovation #PolymerScience #Engineering #MaterialsScience #SoftRobotics #MedicalDevices #WearableTech #StretchableMaterials #NSFfunded #FutureOfTechnology

Inching closer to my chip-in-the-brain! 💽🧠 Full article link below 👇🏼 Recent breakthroughs in material science are paving the way for a new generation of flexible, bio-compatible electronics. Researchers have developed a unique electric plastic, combining peptides and polymers, which can mimic biological tissues while being capable of electrical activity. This innovation holds significant promise for applications in wearables, smart fabrics, and medical implants, enabling devices that are not only soft and stretchable but also capable of interacting with biological systems at low power levels. The plastic's piezoelectric properties allow it to generate electric signals, making it suitable for medical devices and energy-efficient tech. These materials can be customized to match human tissue, reducing the risk of rejection in medical implants. With no rigid components, they integrate smoothly with body tissues, potentially revolutionizing implantable tech and energy storage systems. This breakthrough, inspired by naturally occurring biological systems like the electric eel, showcases the potential for smarter, more adaptable wearable tech and life-saving medical devices. #neuroscience #engineering #materialscience https://lnkd.in/eWfbwxK5

🌟 Exploring the Future of Healthcare with Bioelectronics 🌟 Bioelectronics is transforming how we approach medicine and technology by merging biology with electronics. This field holds immense potential to improve diagnostics and patient care, from wearable devices that track vital signs to neural interfaces and biosensors that enable real-time health monitoring. Bioelectronics involves the design and use of electronic devices, such as sensors, actuators, and circuits, to monitor, manipulate, or mimic biological functions. Bioelectronics is key in the development of wearable medical devices, neural interfaces, biosensors, and bio-computers, contributing to advancements in areas like medical diagnostics, prosthetics, and brain-computer interfaces. It bridges the gap between biology and technology, enabling innovative solutions for health and medicine. Excited to see where this interdisciplinary field takes us! 💡 #Bioelectronics #HealthcareInnovation #MedicalTechnology #WearableTech #Biosensors #FutureOfHealthcare

Revolutionizing Medical Diagnostics with NanoWear’s Breakthrough in Cloth Nanotechnology During The Tape Lab Summit, I had the pleasure of speaking with Venk Varadhan, co-founder and CEO of NanoWear, about their groundbreaking advancements in cloth nanotechnology sensors. This conversation was truly eye-opening, and I wanted to share a few key highlights from our discussion that I believe will be game-changers for the future of wearable medical devices: 1. Cloth Nanotechnology: A Game-Changer in Health Monitoring Venk’s company has developed a first-of-its-kind textile-based nanosensor. These fabric-based sensors contain billions of vertically aligned nanosensors, offering a dramatically higher signal-to-noise ratio. This precision allows for clinical-grade monitoring in real-world conditions, addressing the challenges faced by conventional sensors, such as motion interference, sweat, or even body hair. 2. Moving from Defense to Health: Versatility of Nano Sensors Originally designed for defense applications, NanoWear’s cloth sensors are now revolutionizing healthcare. By leveraging billions of touchpoints on a flexible, non-corrosive surface, these sensors offer highly accurate diagnostics for cardiopulmonary assessments—all while being comfortable enough for daily wear. 3. Impact on Home-Based Diagnostics The integration of these sensors into home-based digital diagnostics platforms is reshaping how we think about healthcare. Patients can self-administer tests at home, receiving real-time, clinical-grade data without needing frequent hospital visits. This is particularly transformative for populations that face challenges in accessing traditional healthcare settings, making advanced diagnostics more accessible. Venk and his team have pioneered a solution that has the potential to completely change the landscape of remote patient monitoring. By increasing accuracy and comfort, while reducing noise and interference, NanoWear is setting a new standard for wearable tech in healthcare. 👉 Don't miss out—you can still sign up for The Tape Lab Summit to catch Venk’s full session and more invaluable insights from industry leaders! Learn more and register here: https://lnkd.in/gb2AX_-N #MedicalDevices #WearableTech #AdhesiveScience #HealthcareInnovation #TapeLabSummit