terça-feira, 9 de setembro de 2014

Could Deep-Brain Stimulation Fortify Soldiers’ Minds?

 

By S. Matthew Liao | September 4, 2014

The views expressed are those of the author and are not necessarily those of Scientific American.

 


As many as 20 percent of war veterans return from combat in Afghanistan and Iraq with post-traumatic stress disorder (PTSD) or major depression, according to a 2008 report from the RAND Corporation. Many experience constant nightmares and flashbacks and many can’t live normal lives. For significant number of veterans, available medications do not seem to help. In 2010, at least 22 veterans committed suicide each day, according to the Department of Veterans Affairs. In her book, Demon Camp, the author Jen Percy describes damaged veterans who have even resorted to exorcism to alleviate their PTSD symptoms.

U.S. Army Soldiers with the 4th Brigade, 1st Infantry Division stand guard at a market in Al Doura in Baghdad, Iraq, April 5, 2007, providing security for Ryan Crocker, U.S. ambassador to Iraq. (U.S. Army photo by Sgt. Curt Cashour via Flickr)

As part of President Obama’s BRAIN Initiative, the federal Defense Advanced Research Projects Agency (DARPA) plans to spend more than $70 million over five years to develop novel devices that would address neurological disorders such as PTSD. DARPA is particularly interested in a technology called Deep Brain Stimulation (DBS). DBS involves inserting a thin electrode through a small opening in the skull into a specific area in the brain; the electrode is then connected by an insulated wire to a battery pack underneath the skin; the battery pack then sends electrical pulses via the wire to the brain.

About 100,000 people around the world today have a DBS implant to ameliorate the effects of Parkinson’s disease, epilepsy and major depression. There is evidence that DBS can also help with PTSD. Functional neuroimaging studies indicate that amygdala hyperactivity is responsible for the symptoms of PTSD and that DBS can functionally reduce the activity of the amygdala. In animal PTSD models, DBS has been found to be more effective than current treatment using selective serotonin reuptake inhibitors.

DARPA’s SUBNETS program seeks new neurotechnology for analyzing neuronal activity across sub-networks of the brain to enable next-generation therapies tailored to individual patients. (DARPA image)

DARPA wants to develop the next-generation, deep brain stimulators (call them DBS+) that do not require user input and that can a) read and monitor the brain’s activities in real-time using neural recording, and b) intervene in these activities in an automatic way through electrical stimulation.

DARPA’s officially stated goal is to treat soldiers who have PTSD and other related neurological disorders. However, once DBS+ is developed, theoretically it could also be used to fortify soldiers’ minds. For example, DBS+ could be used to pre-empt PTSD. Suppose that a soldier has just experienced a potentially traumatic event. DBS+ could be used to detect and categorize the emotional reaction in the amygdala. Like tsunami warnings, there could be different categories. If DBS+ detected a Category 4 reaction, it would automatically reduce the activity in the amygdala to a certain degree. If DBS+ detected a Category 5 reaction, it would slow the amygdala to a halt.

When the emotional strength of one’s memory is reduced, the memory tends not to get consolidated as strongly into long-term memory. Indeed, in both military and non-military settings, the beta-blocker propranolol has been used to dampen the emotional strength of one’s memory as a means of reducing potential trauma. By monitoring the brain in real time and intervening when necessary, DBS+ has the potential to be more precise and efficient while having fewer side effects.

The research team led by Massachusetts General Hospital will use a combination of commercial-off-the-shelf electrodes and custom technology developed by Draper Labs to create novel systems. The proposed design will focus on an ultra-low-profile, hermetically sealed interface device capable of being recharged through inductive coupling. (DARPA image courtesy of Massachusetts General Hospital and Draper Labs)

Once DBS+ is developed, it could also be used to modulate other emotions. Suppose that a soldier is about to enter combat. DBS+ could be used to reduce/remove fear and/or increase courage by increasing adrenaline in the soldier, much like psychotropic drugs such as amphetamine that some soldiers now use. In animal models, DBS reduces fear expressions when applied to the dorsal area of the ventral striatum.

The development of DBS+ will raise familiar but important questions that pertain to the development of all new biotechnologies, including safety and risks. Also, DBS+ is likely to raise some of the same ethical issues that current DBS faces, such as those of authenticity and alienation. For instance, after using DBS, some patients have said things like “During those years of illness, I was asleep. But now I’m going to take my life back.” Others have said things like “I don’t recognize myself anymore.”

The benefits of DBS+ will therefore need to be weighed against its damaging potential to distort or disturb our sense of self. Moreover, DBS has been known to have unintended negative and positive effects. In some patients with Parkinson’s disease, DBS has taken away their tremors but also their passion to lead an active life. In other patients with Parkinson’s disease, DBS has made these patients feel ‘well’ and ‘happy’ even though DBS has not reduced their symptoms. These issues will make DBS+ a future technology that is likely to generate serious public debates.

But even if DBS+ is safe, some people will rightly be concerned that soldiers may be forced to use this kind of brain modification. Suppose soldiers were only equipped with DBS+ on condition of their informed consent after being properly informed of the various risks and benefits. Would all the ethical concerns have been addressed? Perhaps not.

Even if there were informed consent, there could be subtler forms of coercion. The military command structure is hierarchical. This could make “consent” less than fully voluntary. If a commanding officer were to strongly urge the use of DBS+, would this not influence the choices of subordinate officers? Also, there may be subtle or not-so-subtle forms of peer pressure. A soldier may agree to use DBS+ because the soldier does not want to let fellow soldiers down. Moreover, if a soldier does not use DBS+, the soldier may be at a competitive disadvantage. Soldiers with DBS+ may be more reliable under pressure than soldiers without DBS+ and may therefore be more likely to be called upon and shouldered with responsibility.

Could we just ban the use of DBS+ in the military, just as we ban the use of steroids in sports? It is not clear that this is a viable option. Soldiers are already enhanced in other ways. They have access to night vision goggles, Apache helicopters and drugs such as Modafinil to improve alertness and Ritalin to enhance attention. Also, banning doping in sports is usually done for considerations of fairness, but these reasons are unlikely to sway any soldier/state institutions. Would any soldier voluntarily give up advanced military weaponry just to level the playing field? Moreover, if one’s enemies have acquired the technology and are using it, this will undoubtedly provide a strong incentive for its use.

Others might worry that using DBS+ would lead to conscienceless soldiers who would kill indiscriminately in ways that are out of reasonable proportion. This is a serious and important concern. Interestingly, this may be a “technical” problem.

Brain implants that reduce or eliminate our sense of morality are morally undesirable and are not really enhancements as such. Efforts should therefore be made to ensure that the kind of brain implants we develop do not have these unwanted side effects. In the short term, the brain implants we develop may well be imperfect in just such a way. If so, this would be a good reason to ban such devices in the short term. The interesting theoretical issue is what happens when we have perfected the technology and have brain implants that would enable a soldier to kill at the right time, for the right reasons, and in a proportionate manner? Would we still have ethical problems with soldiers using such a technology?

Samsung Galaxy Note 4 vs. LG G3

 

Not long ago, Samsung's Galaxy Notes were pretty much the only phablets worth paying attention to. But with super-sized phones becoming more and more common, the Note series has more competition than ever. Let's see how Samsung's latest, the Galaxy Note 4, stacks up next to one of its biggest rivals, the LG G3.

Dimensions

The Galaxy Note 4 lives up to its phablet moniker a bit more than the LG G3 does. Not only does the Note have a bigger screen, but it's about 5 percent longer and 5 percent wider.

Though the Note 4 is a bit thicker than last year's model, it is still 5 percent thinner than the G3.

Weight

Weight

That smaller size could make the G3 slide into your pocket a little easier, but it has also another advantage: it's 15 percent lighter.

Build

Build materials

Nothing is what it seems ... at least in this category. The Galaxy Note 4 has a leathery finish (almost identical to what we saw on the Note 3), but it's still made of plastic. And that brushed metal look that you see on the G3? Yep, that's plastic too.

The exception is the metallic band that wraps around the edge of the Note 4. This time around, it's really made of metal.

Colors

Color options

We're looking at four color options for the Note 4, and five for the G3. For the G3, though, only black, white and gold options are currently available in the US.

Display (size)

Display (size)

The G3 gives you 93 percent as much screen real estate as the Galaxy Note 4.

Display (resolution)

Display (resolution and pixel density)

One of the Note 4's biggest upgrades over the Note 3 is its leap to a Quad HD display. You could argue that the difference between 1080p and Quad HD amounts to overkill, but my eyes can usually appreciate the extra pixels.

Display (type)

Display type

The Galaxy Note 4 is the first Quad HD device that we've played with that uses Super AMOLED screen tech. It was hard to get a great read on the display's appearance in the hands-on area at Samsung's launch event, but AMOLED screens typically have richer colors and greater contrast.

Stylus

Stylus

It wouldn't be a Galaxy Note without something to take notes with, would it? Samsung's S Pen is back for the latest model, with some improvements in tow. Though its design hasn't changed much, Samsung did double the pressure sensitivity in the new Note's stylus.

Tap-on display

Tap-on display (Knock-On and Knock-Code)

The G3 brings back the same Knock-On feature that we first saw in the G2. It lets you turn on your display just by rapping twice on it.

Knock Code, also on the G3, takes the same concept and marries it to your phone's security. Just set a series of taps across a quadrant, and use that unique pattern to unlock your G3.

Fingerprint sensor

Fingerprint scanner

Like the Galaxy S5, the Note 4 has a (swipe-based) fingerprint sensor.

Heart rate monitor

Heart rate monitor

The Galaxy Note 4 also borrowed the GS5's heart rate monitor, which sits on its backside.

Water resistance

Water resistance

The Note 4 doesn't, however, have a water resistance rating. I'm guessing that's because the S Pen's slot would require some sort of cover, making the phablet a lot less convenient to use.

Battery

Battery capacity

We'll have to wait to see what battery life looks like in the Galaxy Note 4, but Samsung is saying that it will last longer than the Note 3 did.

When we tested the G3, it delivered solid enough battery life – but it also wasn't its killer feature.

Ultra Power Saving Mode

Ultra Power Saving Mode

Samsung's Ultra Power Saving Mode lets you stay on the grid by severely limiting the phone's available processes (and turning the screen black & white) when you're almost out of juice. By temporarily turning your expensive phablet into a glorified feature phone, it can stretch just 10 percent remaining battery life into an extra 24 hours of uptime.

Fast charging

Fast charging

Samsung says that, as long as you're using the default Samsung charger, the Note 4 can jump from 0 to 50 percent battery life in "about 30 minutes."

Camera

Cameras (megapixel counts)

The Note 4's camera wins on megapixels, but we'll need to put its camera through the paces before jumping to conclusions.

One thing I hope that Samsung improved on over its little brother is the camera's launch time. The Galaxy S5's shooter is conspicuously slow to launch.

Laser focus

Laser-based auto-focus

The G3's laser-based autofocusing makes focusing and shooting quick and easy. Just tap the point on the screen where your subject is, and the G3 will (almost instantly) snap a shot with it in focus.

OIS (Optical Image Stabilization)

Both phones' cameras have Optical Image Stabilization onboard.

Infrared

IR blaster

Both phones include built-in IR blasters, so you can use your handset as a universal remote control for your TV or cable/satellite box.

Split-screen multitasking

Split-screen multitasking

Though each company uses a different marketing term, both devices have their own versions of side-by-side multitasking.

For the first time, with the Note 4 Samsung integrated its Multi-Window feature into the recent apps button. The company says it's also now easier to choose between single-window, multi-window and pop-up window modes.

One-handed mode

One of the biggest downsides of a huge screen is that it's tricky to use with one hand. Both of these devices offer their own ways of dealing with that.

One the Note 4, you can perform a quick gesture to shrink the entire screen down to a manageable size for one hand. On the G3, LG opted to just shrink the size of keyboards for its one-handed mode.

Virtual reality

Okay, so the Note 4 doesn't have any magic VR powers on its own, but it is the only phone that's compatible with Samsung's new Gear VR headset. If you buy the Oculus-powered accessory, you can slide the Note 4 in to provide the headset's display and processing power.

The G3 can play nicely with Google Cardboard, but it's technically a developer kit and not designed for consumer use.

Storage

We're looking at different storage tiers for each handset. They both have microSD slots, though, if the internal storage isn't enough for you.

Processor

Though the performance of most high-end mobile devices passed the point of concern long ago, the LG G3 had a noticeable amount of lag out-of-the-box. Switching to Android runtime pretty much took care of the problem, but, with a Quad HD display of its own, we'll be keeping an eye on this when we review the Galaxy Note 4.

You'll want to note that we're only showing the processor for the LTE version of the Note 4. For the HSPA/international variant, you'll get a Samsung Exynos octa-core processor in place of the Snapdragon.

If you buy the 32 GB version of the LG G3, then it will have the same 3 GB of RAM as the Note 4. If you opt for the 16 GB model, then you'll just have 2 GB.

Software

Both phones run Android 4.4 KitKat, with their respective manufacturer UIs layered on top.

Release

The G3 launched in Korea way back in May, but has only been available in the US since July. The Galaxy Note 4 will start shipping sometime in October.

Starting price (off-contract)

We still don't know what the Note 4 will cost, but I'd guess we'll be looking at the same US$700 off-contract (usually $300 on-contract) price that the Note 3 originally rang up for.

For more on these two beasts, you can hit up our full LG G3 review and our hands-on with the Galaxy Note 4. We also got some hands-on time with the Note 4's curved-display sibling, the Galaxy Note Edge.

World's first 110-inch curved UHD TV unveiled in Europe

 

TCL's 110-inch China Star Curved Ultra-HD TV at IFA 2014 in Berlin (Photo: Chris Wood/Gizm...

TCL's 110-inch China Star Curved Ultra-HD TV at IFA 2014 in Berlin (Photo: Chris Wood/Gizmag)

Image Gallery (5 images)

There's no denying it, it's a monster. TCL has given its flagship Ultra High Definition television announced at CES back in January a more immersive new bed-fellow in the shape of the 110-inch China Star Curved Ultra-HD TV. The company hasn't offered much in the way of details, but read on for what we do know.

The 110-inch China Star Curved Ultra-HD TV felt more like the display you might find in a small cinema setup rather than something you would expect to see in someone's living room. The 3,840 x 2,160 resolution curved LED display boasts a high image depth that's said to create a "near glasses-free 3D effect" and offers a reflection-free 55 degree field of view from 3 m (10 ft) away.

The inclusion of intelligent backlight technology aims to improve the image by dimming certain areas of the display while keeping others bright for improved overall viewing, and a CMI figure of 400 Hz promises seamless and sharp motion resolution. The high brightness (800 nit) TV is backed by the power of a multi-core processor, offers UHD upscaling and comes with HDMI and USB ports.

Unfortunately, we couldn't persuade the TCL reps at IFA to part with any more details or disclose when we might see this behemoth on the market, or at what price. So for the moment, you'll just have to take our word for it that the new China Star model is rather captivating.

Source: TCL

Dyson 360 Eye robotic vacuum cleaner "sees" its environment

 

By Stu Robarts

September 5, 2014

 

The Dyson 360 Eye on display at IFA 2014 in Berlin (Photo: Paul Ridden/Gizmag)

The Dyson 360 Eye on display at IFA 2014 in Berlin (Photo: Paul Ridden/Gizmag)

Image Gallery (12 images)

Dyson revolutionized the vacuum cleaner industry when it introduced its bagless vacuum cleaner. Now, the company hopes to do the same again, with the introduction of a robot that cleans without human assistance. The Dyson 360 Eye "sees" its environment and can be controlled using a mobile app

Dyson originally announced plans to launch a robot vacuum cleaner back in 2004 with its DC06, but the project was eventually binned. It was announced last year, though, that the company was still working to produce a robotic vacuum cleaner.

The 360 Eye is said to be the culmination of 16 years of research by more than 200 engineers and £28m (US$46m) of investment. According to Dyson, a team of 31 robotic software engineers spent over 100,000 hours creating the device's navigation system, using algebra, probability theory, geometry and trigonometry.

Dyson says that other existing robotic vacuum cleaners have a number of failings, including lack of suction power, navigating environments without actually "seeing" them, use of rotating sweepers that do not lift dirt particles adequately, and using wheels that do not allow them to move around as well as might be possible.

A bottom view of the 360 Eye (Photo: Paul Ridden/Gizmag)

A bottom view of the 360 Eye (Photo: Paul Ridden/Gizmag)

Dyson has sought to remedy each of these issues with the 360 Eye. It uses a V2 Dyson digital motor and Dyson's Radial Root Cyclone technology to deliver suction that the company says will not lose power and will capture particles down to 0.5 microns in size. A 360-degree panoramic camera coupled with infrared sensors allows the cleaner to visualize the room and work out its location. It then uses landmarks in the room, such as pieces of furniture, to navigate its way around.

A carbon fiber brush bar is used, which Dyson says will remove fine dust on hard floors, and stiff nylon bristles are employed to work their way into and clean carpets. The 360 Eye also uses tank tracks instead of wheels to move around, which are said to better maintain speed and direction, as well as help the device to overcome small obstacles. That said, it should be noted that at the demo we saw at IFA, the Dyson reps admitted that it cannotreach dirt in the very corners of rooms.

A cut-away view of the 360 Eye (Photo: Paul Ridden/Gizmag)

A cut-away view of the 360 Eye (Photo: Paul Ridden/Gizmag)

The cleaner's camera images at up to 30 frames per second to provide an accurate visualization of its surrounding environment. Dyson says the device is accurate to within millimeters. It weighs 2.37 kg (5.22 lb) and can hold up to 0.4 l (0.09 gal) of dust and dirt. It is powered by a lithium-ion battery, which can be fully charged in two hours on its slimline dock and will give about 30 - 40 minutes of cleaning time. The machine will self-dock and recharge itself when the battery runs low.

In addition to setting the 360 Eye going manually, users can program it via an iOS mobile app. Dyson Link allows users to schedule it to clean at a specific time (for example, before they return from holiday) or on a recurring schedule.

The Dyson 360 Eye will be available in Japan from spring 2015, with the rest of the world to follow. There's no word yet on pricing.

Source: Dyson