Lifeboat Foundation

Space launch startup Orbex has secured a customer for its forthcoming Prime space launch vehicle: TriSept, a provider of launch integration services for both commercial and government customers. TriSept has booked the full capacity of a rideshare mission aboard an Orbex Prime rocket to take off sometime in 2022, which should work schedule-wise, provided Orbex meets its target of flying its initial missions starting next year.

Orbex is leaning on 3D printing to expedite its launch vehicle production process, while also keeping costs low. The U.K.-based company is also in the process of working on final approvals and construction of a new spaceport in Sutherland, located in the Scottish highlands, which, when complete, will be the first mainland space launch facility in Europe.

TriSept, which provides launch management and brokerage services in addition to integration for payloads loaded into the launch vehicle, has been operating in the U.S. space market for years now, and it’ll also be setting up a full-time presence in the U.K. ahead of the Sutherland spaceport’s opening later this year, at Harwell Space Campus in Oxford.

We are all aware of the health benefits of regular exercise, but what if we could reap the rewards of a good workout without any of the effort? Michigan Medicine researchers have found that a conserved class of proteins known as Sestrins can mimic many of the beneficial effects of exercise on metabolism in flies and mice, and boost their physical endurance. The findings could eventually help scientists to devise strategies that combat muscle wasting due to aging or disease. “These results indicate that Sestrin is a key integrating factor that drives the benefits of chronic exercise to metabolism and physical endurance … Sestrin may serve as a promising therapeutic molecule for obtaining exercise-like benefits such as improving mobility and metabolism,” commented the researchers, headed by Myungjin Kim, PhD, a research assistant professor in the department of molecular & integrative physiology, and first author of the team’s published paper in Nature Communications, which is titled, “Sestrins are evolutionarily conserved mediators of exercise benefits.”

As the percentage of older members in the population continues to increase, so do concerns about keeping an aging population healthy and mobile. In fact, elderly people put mobility as their biggest age-related concern, the authors stated. “Mobility is important both for direct health reasons (e.g., preventing falls, retaining access to relatives and health care providers) and for psychological reasons, as it is highly correlated with retained morale personal satisfaction and morale.”

One promising therapeutic intervention that can help to hold back age-related functional decline is endurance exercise, they noted. But endurance exercise isn’t suitable for everyone. While evidence in humans and other animals suggests that endurance exercise has substantially protective effects on measures of healthspan, not everyone can train to the level needed to achieve the resulting health benefits, perhaps due to age, injury, or illness. “Therefore, generation of therapeutic mimetics to induce the benefits of exercise could provide broad ranging benefits to the medical community,” the researchers suggested.

Google announced today that it is buying AppSheet, an eight-year-old no-code mobile-application-building platform. The company had raised more than $17 million on a $60 million valuation, according to PitchBook data. The companies did not share the purchase price.

With AppSheet, Google gets a simple way for companies to build mobile apps without having to write a line of code. It works by pulling data from a spreadsheet, database or form, and using the field or column names as the basis for building an app.

It is integrated with Google Cloud already integrating with Google Sheets and Google Forms, but also works with other tools, including AWS DynamoDB, Salesforce, Office 365, Box and others. Google says it will continue to support these other platforms, even after the deal closes.

Holly Jean Buck is a fellow at UCLA’s Institute of the Environment and Sustainability. This is an adapted excerpt from her upcoming book After Geoengineering: Climate Tragedy, Repair, and Restoration (September 2019, Verso Books).

“These are novel living machines,” says Joshua Bongard, the University of Vermont expert who co-led the new research. “They’re neither a traditional robot nor a known species of animal. It’s a new class of artifact: a living, programmable organism.”

In the popular book The Demon in the Machine, physicist Paul Davies argues that what’s missing in the definition of life is how biological processes create “information,” and such information storage is the stuff of life, like a bird’s ability to navigate or a human’s ability to solve complex problems. The “Demon” Davies refers to is Maxwell’s Demon, as proposed by 19th century physicist James Clerk Maxwell as a thought experiment. Maxwell’s hypothetical “demon” controls a gate between two chambers of gas and knows when to open the gate only to allow gas molecules moving faster than average to pass through it. This way, a chamber could be heated and create “energy” to be put to work. Such a demon would amount to a workaround of the Second Law of Thermodynamics. And that, as we know, is impossible. We also know, of course, that demons don’t exist.

However, living things use many protein devices called enzymes that mimic such a demon each time a muscle contracts or when any chemical reaction needs to be driven uphill and away from thermodynamic equilibrium like the gas molecules chosen by the demon. How these dynamic machines work has long been puzzling. Over the past 75 years, scientists have chipped away at this problem without identifying precise details of how any of these enzyme machines accomplishes the sleight of hand that sustains living things, such as humans who live in a chemical state far from equilibrium.

For the first time, in a paper published in Proteins: Structure, Function, and Bioinformatics by Charlie Carter, Ph.D., professor in the Department of Biochemistry and Biophysics at the UNC School of Medicine, and supported by the National Institute of General Medical Sciences, describes the details that enable one such machine to work like Maxwell’s demon.

Artificial Intelligence can now detect over 50 eyes diseases as accurately as doctors!

In a new report published on Scientific Reports, Milan M. Milošević and an international research team at the Zepler Institute for Photonics and Nanoelectronics, Etaphase Incorporated and the Departments of Chemistry, Physics and Astronomy, in the U.S. and the U.K. Introduced a hyperuniform-disordered platform to realize near-infrared (NIR) photonic devices to create, detect and manipulate light. They built the device on a silicon-on-insulator (SOI) platform to demonstrate the functionality of the structures in a flexible, silicon-integrated circuit unconstrained by crystalline symmetries. The scientists reported results for passive device elements, including waveguides and resonators seamlessly integrated with conventional silicon-on-insulator strip waveguides and vertical couplers. The hyperuniform-disordered platform improved compactness and enhanced energy efficiency as well as temperature stability, compared to silicon photonic devices fabricated on rib and strip waveguides.

Academic and commercial efforts worldwide in the field of silicon photonics have led to engineer optical data communications at the Terabit-scale at increasingly lower costs to meet the rapidly growing demand in data centers. Explosive growth in cloud computing and entertainment-on-demand pose increasingly challenging costs and energy requirements for data transmission, processing and storage. Optical interconnects can replace traditional copper-based solutions to offer steadily increasing potential to minimize latency and power consumption, while maximizing the bandwidth and reliability of the devices. Silicon photonics also leverage large-scale, complementary metal-oxide semiconductor (CMOS) manufacturing processes to produce high-performance optical transceivers with high yield at low-cost. The properties allow applications of optical transceivers (fiber optical technology to send and receive data) to be increasingly compelling across shorter distances.

More than three decades ago, physicist Richard Soref identified silicon as a promising material for photonic integration. Leading to the present-day steady development and rapid production of increasingly complex photonic integrated circuits (PICs). Researchers can integrate large numbers of massively-parallel compact energy-efficient optical components on a single chip for cloud computing applications from deep learning to artificial intelligence and the internet of things. Compared to the limited scope of commercial silicon photonic systems, photonic crystal (PhC) architectures promise smaller device sizes, although they are withheld by layout constraints imposed by waveguide requirements along the photonic crystal’s axis. Until recently, photonic band gap (PBG) structures that efficiently guide light were limited to photonic crystal platforms. Now, newer classes of PBG structures include photonic quasicrystals, hyperuniform disordered solids (HUDs) and local self-uniform structures.

Launching in late 2021, Lucy will be the first space mission to explore the Trojan asteroids. These are a population of small bodies that are left over from the formation of the solar system. They lead or follow Jupiter in their orbit around the Sun, and they may tell us about the origins of organic materials on Earth.

Lucy will fly by and carry out remote sensing on six different Trojan asteroids and will study surface geology, surface color and composition, asteroid interiors/bulk properties, and will look at the satellites and rings of the Trojans.