Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog

Category: electronics

Using bacteria to aid in the design of superior biomedical implants capable of resisting colonization by infectious bugs.

Dr. Pushkar Lele, assistant professor in the Artie McFerrin Department of Chemical Engineering at Texas A&M University, is developing novel insights in cellular mechanics with bacteria to aid in the design of superior biomedical implants capable of resisting colonization by infectious bugs. Lele’s group also focuses on unraveling the fundamental principles underlying interactions in biological soft-matter to build bio-nanotechnology-based molecular machines. Lele’s lab currently focuses on a unique electric rotary device found in bacteria — the flagellar motor.

According to Lele, it is well established how motile bacteria employ flagellar motors to swim and respond to chemical stimulation. This allows bacteria to search for nutrients and evade harmful chemicals. However, in his recent work, Lele has now demonstrated that the motor is also sensitive to mechanical stimulation and identified the protein components responsible for the response. Sensing initiates a sensitive control of the assemblies of numerous proteins that combine to form the motor. Control over motor assemblies facilitates fine-tuning of cellular behavior and promotes chances of survival in a variety of environments.

“What is the sense of touch in a bacterium? It is likely that they employ appendages such as the flagella to detect solid substrates, analogous to our use of fingers,” Lele said. “How they recognize the substrate using the flagellum has been a long-standing question in biology with tremendous biomedical significance. Our findings have provided a handle on this important problem. We now know [how] the motor-components [are] involved in sensing the substrate [and] would like to know how these sensors trigger signaling networks that ultimately cause infections. “.

Read more

Quantum Sensors enables precise imaging of magnetic fields of superconductors.

Scientists at the Swiss Nanoscience Institute and the Department of Physics at the University of Basel have developed a new method that has enabled them to image magnetic fields on the nanometer scale at temperatures close to absolute zero for the first time. They used spins in special diamonds as quantum sensors in a new kind of microscope to generate images of magnetic fields in superconductors with unrivaled precision. In this way the researchers were able to perform measurements that permit new insights in solid state physics, as they report in Nature Nanotechnology.

Researchers in the group led by the Georg-H. Endress Professor Patrick Maletinsky have been conducting research into so-called nitrogen-vacancy centers (NV centers) in diamonds for several years in order to use them as high-precision sensors. The NV centers are natural defects in the diamond crystal lattice. The electrons contained in the NVs can be excited and manipulated with light, and react sensitively to electrical and magnetic fields they are exposed to. It is the spin of these electrons that changes depending on the environment and that can be recorded using various measurement methods.

Maletinsky and his team have managed to place single NV spins at the tips of atomic force microscopes to perform nanoscale magnetic field imaging. So far, such analyses have always been conducted at room temperature. However, numerous fields of application require operation at temperatures close to absolute zero. Superconducting materials, for example, only develop their special properties at very low temperatures around −200°C. They then conduct electric currents without loss and can develop exotic magnetic properties with the formation of so-called vortices.

Read more

I forgot Sony in the list of contact lens patents. Sony’s new camera contact patent. So, we have Google, Huawei, and Samsung with AR and CPU patents and Sony’s patents on the camera. Waiting for Apple and my favorite Microsoft’s announcements.

Sony has joined Google and Samsung in the world of contact lens camera patents, Sony’s version also has zoom and aperture control built in.

Read more

00_naut

“These cables, whilst stylish, still put a large emphasis on practicality – having been crafted from durable, braided nylon designed to withstand wear and tear. The range also goes further, the company professes, by solving everyday problems such as ‘forgetting your cable, running out of battery on-the-go, or straining to use your device while charging’.”

Read more

LeEco is known as the “Netflix of China” due to its very popular video streaming service, but the conglomerate also has interests in a much wider range of sectors including smartphones, TVs and electric vehicles.

Ding Lei, LeEco’s auto chief and a former top official at General Motors’ China venture with SAIC Motor, says part of LeEco’s advantage in tomorrow’s auto industry is that it carries no baggage from today’s.

This, the man said, is the future of cars, and the Chinese consumer electronics company LeEco is going to make that future a reality.

Read more

Blockchaining coming to healthcare digital services.

Blockchain and digital health services could be a perfect match for each other across a variety of applications. From distributed interoperable health records to proof of adherence for medication, the healthcare industry is ripe for digital innovation. More generally, technology is a hyper-deflationary force, and this could be particularly effective in delivering quality health care through more effective channels such as mobile apps.

Investments in the digital health space have increased significantly in the past two years. This is largely possible because of improved low-power sensors and user-friendly cloud platforms that interface with those hardware devices. The Rock Health Funding Database shows a $4.5 billion increase in venture funding in digital health from 2014 to 2015.

Smart contract technology is built on top of virtual currencies such as Bitcoin and is a hallmark of “Bitcoin 2.0” platforms. Blockchain is the fundamental infrastructure needed for Bitcoin transactions to work, and an enabling technology for the next generation of asset-based platforms.

Read more

With apologies to Isaac Asimov, the most exciting phase to hear in science isn’t “Eureka,” but “That’s funny…”

A “that’s funny” moment in a Colorado State University physics lab has led to a fundamental discovery that could play a key role in next-generation microelectronics.

Publishing in Nature Physics April 25, the scientists, led by Professor of Physics Mingzhong Wu in CSU’s College of Natural Sciences, are the first to demonstrate using non-polarized light to produce in a metal what’s called a spin voltage — a unit of power produced from the quantum spinning of an individual electron. Controlling electron spins for use in memory and logic applications is a relatively new field called spin electronics, or spintronics, and the subject of the 2007 Nobel Prize in Physics.

Read more

Nice

SAN DIEGO, Calif.—()— SLANTRANGE, pioneers of a smarter approach to aerial remote sensing and analytics for agriculture, today announced its $5 million Series A equity financing from a consortium of investors led by The Investor Group, a leading San Diego based investment firm. The funding will accelerate the development and scaling of SLANTRANGE’s proprietary drone sensor and analytics technology to help farmers improve operations amid a rapidly transforming business landscape.

“Farmers are continually seeking ways to improve crop yields with minimal risk. Drones offer an exciting solution, but historically haven’t been built for the precise needs of the agriculture industry,” said Mike Ritter, CEO of SLANTRANGE. “SLANTRANGE delivers on the promise of drones with an intelligence system that combines hardware and software to bring farmers crop information they need to make better operational decisions. This investment enables us to scale our technology and team to meet the soaring demand we’re seeing from the agricultural community in the United States and beyond.”

Read more

Ninety-five percent of the universe is still considered unexplored. Scientists at CERN, the world’s largest particle physics research center, located in Geneva, are working on solving these mysteries. In May 2012, researchers there discovered the so-called Higgs Boson, whose prediction won Peter Higgs and François Englert the Nobel prize in physics. One of the things CERN scientists are researching at the moment is dark matter: Although it may well have five times the mass of visible matter in the universe, this extent can only be indirectly proved. With a bit of luck, CERN will also succeed in generating dark matter.

A unique sensor chip can contribute to proving the existence of : It is eight inches or 15 cm x 10 cm and was developed jointly by Infineon Technologies Austria and the Austrian Academy of Sciences’ Institute of High Energy Physics (HEPHY). Tens of thousands of these silicon components could be used at CERN in the near future. They are not only more economical to produce than previous sensors, which measured up to six inches. The components also stand up better to constant radiation and thus age slower than the previous generation. Planned experiments will scarcely be possible without resistant sensors.

The experiments at CERN are analyzing the structure of matter and the interplay among elementary particles: Protons are accelerated almost to the speed of light and then made to collide, giving rise to new particles whose properties can be reconstructed with various detectors. “In and cosmology, there are many questions that are still open and to which mankind still has no answer,” says Dr. Manfred Krammer, head of the Experimental Physics Department at CERN. “To make new advances in these areas, we need a new generation of particle sensors. Cooperation with high-tech companies like Infineon allows us to develop the technologies we need for that.”

Read more