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Personally; I have heard this several years ago from some medical researchers. Glad that more have concluded this tie.

Genetic mutations on several genes including BRCA2 have been associated with prostate cancer; while in a separate study, a BRCA1 mutation has been linked to a particular form of uterine cancer.

The first study, published in the New England Journal of Medicine, found that 12 percent of men with advanced prostate cancer had inherited mutations in genes involved in the repair of damaged DNA.

Professor Johann de Bono of the Institute of Cancer Research in London and the Royal Marsden NHS Foundation Trust, who led the study, said: ‘Our study has shown that a significant proportion of men with advanced prostate cancer are born with DNA repair mutations – and this could have important implications for patients.

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Hmmm; okay.

As it turns out, the answer is not 42, it’s 42.3 — thousand. That’s how many discrete transistors spread across the 30 m2 room housing this massive computation machine. [James Newman’s] Megaprocessor, a seriously enlarged version of a microprocessor, is a project we’ve been following with awe as it took shape over the last couple of years.

[James] documented his work in great detail, and by doing so, took us on a journey through the inner workings of microprocessors. His monumental machine is now finished, and it’s the ultimate answer to how a processor – and pretty much everything that contains a processor – works.

Everyone of the ~42,300 transistors were hand-soldered to one of the massive PCBs, which look more like interactive circuit diagrams than actual circuit boards. This incredible amount of discrete transistors makes up the thousands of logic gates that eventually form the Megaprocessor’s registers, its arithmetic logic unit, its sequence control and also: its 256 bytes of RAM. Each logic gate displays the current IO state through LEDs, which also turns the RAM into a gigantic LED wall on which you can play Tetris. Despite its complexity, the Megaprocessor is pretty much self-documenting. [James] mounted all PCBs on large frames, which add up to a 10m long and 2m tall “computation display”. Detailed diagrams show the information flow between the functional blocks – and through the room.

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Nice read by Microsoft on their BMI efforts.

I have been reading a lot about brain interfaces and that the Tesla S can be summoned with the brain and that people have started having competitions with drones controlled by brain waves. I have recently acquired an Emotiv Insight® as shown in Figure 1 and have been doing some testing with it.

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Figure 1, brain interface Emotiv Insight® Microsoft Azure

Continue reading “Uploading my brain waves to the cloud, Azure IoT Hub and Emotiv brain interface” | >

Good article overall; and yes QC is still evolving. However, to state Quantum networking is in its infancy is a wrong & misleading comment. Since 2009, Quantum Internet has been in beta at Los Alamos Labs. And, researchers will tell you that QC development can as far back as 1970s and the first official QC was introduced in 2009 when the first universal programmable quantum computer was introduced by University of Toronto’s Kim Luke.

Google has launched a two-year Chrome trial aimed at safeguarding the Internet against quantum computers, which security experts predict will shred all data.

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Faster and better method around Q-dots development which ultimately extends the quality of Quantum Dots plus mass production of Q-Dots is much faster through this new method. Hoping this causes the costs of new cameras, phone displays, monitors/ video displays are now able to be created more cheaply and in larger quantities.

Materials researchers at North Carolina State University have fine-tuned a technique that enables them to apply precisely controlled silica coatings to quantum dot nanorods in a day — up to 21 times faster than previous methods. In addition to saving time, the advance means the quantum dots are less likely to degrade, preserving their advantageous optical properties.

Quantum dots are nanoscale semiconductor materials whose small size cause them to have electron energy levels that differ from larger-scale versions of the same material. By controlling the size of the quantum dots, researchers can control the relevant energy levels — and those energy levels give quantum dots novel optical properties. These characteristics make quantum dots promising for applications such as opto-electronics and display technologies.

But quantum dots are surrounded by ligands, which are organic molecules that are sensitive to heat. If the ligands are damaged, the optical properties of the quantum dots suffer.

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The Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) will set up seven new Research Units and one new Clinical Research Unit. This was decided by the Senate of the DFG in its summer session during the DFG Annual Meeting in Mainz. In addition to the already established Units, another Research Unit is now in a position to start work. This Unit is funded jointly by the DFG and the Austrian Science Fund (FWF). The DFG Senate had already supported this Unit in March 2016 and approval has now been obtained from the Austrian partner organisation.

The research collaborations will offer researchers the possibility of pursuing current and pressing issues in their research areas and establishing innovative work directions. Clinical Research Units are also characterised by the close connection between research and clinical work. The maximum funding duration of Research Units and Clinical Research Units is two periods of three years. In the initial funding period, the nine new groups will receive approximately €23 million in total. As a result, the DFG will be funding a total of 190 Research Units and 19 Clinical Research Units.

The new Research Units.

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Children with a rare neurological disease were recently given the chance to walk for the first time thanks to a new robotic exoskeleton. These devices – which are essentially robotic suits that give artificial movement to a user’s limbs – are set to become an increasingly common way of helping people who’ve lost the use of their legs to walk. But while today’s exoskeletons are mostly clumsy, heavy devices, new technology could make them much easier and more natural to use by creating a robotic skin.

Exoskeletons have been in development since the 1960s. The first one was a bulky set of legs and claw-like gloves reminiscent of the superhero, Iron Man, designed to use hydraulic power to help industrial workers lift hundreds of kilogrammes of weight. It didn’t work, but since then other designs for both the upper and lower body have successfully been used to increase people’s strength, help teach them to use their limbs again, or even as a way to interact with computers using touch or “haptic” feedback.

These devices usually consist of a chain of links and powered joints that align with the user’s own bones and joints. The links are strapped securely to the user’s limbs and when the powered joints are activated they cause their joints to flex. Control of the exoskeleton can be performed by a computer – for example if it is performing a physiotherapy routine – or by monitoring the electrical activity in the user’s muscles and then amplifying the force they are creating.

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