Friday, April 15, 2016

New Tech Toy, BIG-i robot!

Here is a new one for you kids! The BIG-I robot is a new attempt to make tomorrow of butler robots, today. He can do a lot of things, and unlike a lot of consumer robots on the market, this little guy is a lot more functional than fun. With its unique operating system designed by the company NXROBO, you can teach BIG-i to do different things based on voice commands and visual cues.


What BIG-i can do

“If you see Tommy grabbing the fruit, remind him to wash his hands.”
This command shows off a lot of BIG-i’s features: The robot can see Tommy with its face-recognizing camera, identify that Tommy is grabbing fruit and speak to Tommy after seeing him grab the fruit.
Depending on your needs, BIG-i can be a few different things. For kids in school, BIG-i can be a tutor and help with homework through its Internet connectivity and encyclopedia access. For people who are looking for a fun pet that they don’t need to feed, BIG-i can learn tricks like dancing and play hide and seek. For everyday convenience, BIG-i can be your own personal butler or assistant by taking phone calls, scheduling appointments or reminding you to turn off the oven when you leave the kitchen.
The robo-butler wouldn’t be much of a butler if it just sat in the corner of your room — it has wheels to move around your space and built-in obstacle avoidance.
To make BIG-i respond to specific commands and perform actions, you’ll have to teach it yourself. You can make it look at the couch and say, “This is ‘couch.’” Then you can tell it to perform an action when you sit down on the couch, like turn on the TV. It may take some time to set up and teach BIG-i what everything is, but once you do it’ll have a big range of actions it can perform for you.

BIG-i won’t just take commands from anyone — it will recognize your voice and treat other people as strangers and won’t listen to their commands. This is helpful if you’re a parent with a young child, and you don’t want little Tommy overriding your orders.
Apps are also available to get for BIG-i through its own app store, which you download through your computer or smartphone, making it even more customizable.

http://mashable.com/2016/04/12/big-i-robot-butler/#.xHK9Pd31iq7




Monday, April 11, 2016

New Tech Toys, Bloodstream Robots?

Soon, the term "little swimmers" will refer to more than what, um, it usually refers to right now, with the latest development in nanorobot technology — namely nanoswimmers, robots that can swim through the bloodstream to deliver drugs.

This latest advent in nanotechnology would be entirely medical (so, sorry, intravenous drug users, I guess?), primarily used to treat diseases where drugs would need to be delivered to localized points in the body, rather than pumping the entire bloodstream full of chemicals, explained a press release issued by the American Chemical Society (ACS). 

Headed by scientists Bradley J. Nelson, Salvador Pané and Yizhar Or, nanoswimmers would revolutionize the treatment of diseases like cancer: instead of radiation or traditional chemo, these robots could be preprogrammed like drones to seek and destroy cancer cells (but cute baby drones, ones that probably won't take over the world one day and kill us all).
Nanoswimmers would also "lower the risk of complications, reduce the need for invasive surgery and lead to faster recoveries," stated the release.

There are, however, complications: because the consistency of blood to something as micro as a nanorobot is comparable to molasses, moving through it can prove to be quite difficult. To battle it, the team of researchers linked three rings (polymer and two nanowires), and to test it, inserted the microscopic devices in a fluid with a heavier texture than blood. Activated with a magnetic field, the nanoswimmers propelled themselves in an S-like pattern at the speed of one body length per second.

Here is the original post: http://www.techtimes.com/articles/61705/20150618/tiny-robots-will-swim-through-bloodstream-deliver-drugs.htm


New Tech Toy, Owlet

Back to the good ol' tech toy! This time I wanted to show you something that will be a practical, and gadget that will make nights with babies that much safer. Owlet makes socks for your little one, that will monitor it's vitals!



The Owlet empowers you with the same technology hospitals use, pulse oximetry. There’s a reason hospitals use pulse oximetry in place of other monitoring options. It’s safe, proven, and accurate. So why not bring the safety of pulse oximetry home from the hospital with your baby? You might recognize pulse oximetry as the clip they put on your finger at the hospital. A small light shines through your skin and the amount of blood flow and oxygen levels are estimated based on how much light is transmitted to the sensor. We combined this technology with a cuddly Smart Sock to give you an extra set of eyes on your baby while they’re asleep.
Why do you get an alert when someone “likes” your status but not when your baby stops breathing? It’s time for a change. Glancing at a traditional monitor doesn’t give you the whole story of your baby’s well being. The Owlet is designed to alert you if your baby stops breathing. This isn’t just accessory, it’s a necessity. It’s not just a necessity for your baby, it’s a necessity for you as a parent because parents need sleep too. You can’t bring your “A-game” to parenting if you’re sleep deprived. Let us be up all night, so you don’t have to be.
Your Owlet Monitor will come with three sock sizes. Owlet will fit your little one until his or her first birthday, and fits most babies up to a year and a half.
Over the river and through the woods to Grandmother’s house we go! If Grandma doesn’t have Wi-Fi, your monitor will still work because the Base Station connects directly to the smart sock and acts as your primary alarm, making it even more reliable. Your Apple device is just a convenience so you can check in on your baby in real time, even when you’re on a date. You need an Apple device to set up the Owlet Monitor. However, Owlet is expecting. Android will be available June 6th and will work with Owlets purchased today.
You can look at this product, and order from http://www.owletcare.com/


Thursday, April 7, 2016

xenotransplantation in humans... FROM A PIG?!?!

Recently, researchers at the National Institutes of Health (NIH) in Bethesda, Maryland, has housed baboons with pig hearts beating in their abdomens. They’re part of an experiment that researchers hope will help develop pig organs safe for transplant into people, this process is known as xenotransplantation. About 22 people die each day in the United States alone while waiting for human organs, that are in short supply. Today, those NIH researchers and their collaborators report record-setting survival data for five transplanted pig hearts, one of which remained healthy in a baboon for nearly 3 years.

“People used to think that this was just some wild experiment and it has no implications,” says Muhammad Mohiuddin, a cardiac transplant surgeon at National Heart, Lung, and Blood Institute in Bethesda, who led the study. “I think now we’re all learning that [xenotransplantation in humans] can actually happen.”

Simply moving an organ from one animal species into another provokes a violent and immediate attack from the host’s immune system. In early cross-species transplants, “we measured the survivals in minutes,” says David Sachs, a transplant immunologist at Harvard Medical School in Boston, who has worked on xenotransplantation for several decades. In pigs—the most likely candidate for human replacement tissue, in part because their organs are similar in size—a carbohydrate called α 1,3-galactosyltransferase (gal) on the surface of blood vessel cells would prompt the human body to make antibodies that latch onto it and cause blood clots. Once scientists developed a genetically engineered pig lacking the gal gene in 2001, porcine organs began to survive for months in baboons and other nonhuman primates. But these animals still had to be kept on a drug regimen that protected the foreign organ by suppressing their immune systems, leaving them vulnerable to infections.

Instead of swapping out a baboon’s original heart, the researchers hooked up the pig heart to blood vessels in the baboon’s abdomen. That way, they could study immune rejection without doing a more elaborate heart surgery—and without needlessly killing a baboon if their approach was a flop. The engineered hearts combined with immunosuppression soon smashed the existing record for pig-to-baboon heart transplants—179 days. “Every [scientific] meeting, we’d go and say, ‘Oh, we got the first 236-day survival, the first 1-year survival, the first 2-year survival,’” Mohiuddin says. “It was losing its charm.” His audiences started asking whether the baboons had developed tolerance—whether they could now sustain these hearts without high doses of immunosuppression.

So the researchers began to taper the baboons off the anti-CD40 antibody. That turned out to be the end of the experiments—the baboons rejected the hearts once the anti-CD40 antibodies left their systems, the team reports online today in Nature Communications. They found that in two baboons who had been on immunosuppression for a year before tapering off, the hearts could survive with lower doses of the drug. But two baboons tapered off the drugs 100 days postsurgery began to reject their hearts almost immediately. (One baboon died from an antibiotic-resistant infection about 5 months after the transplant.) The tapering experiments suggest that a lower “maintenance dose” might be effective, Mohiuddin says. But it also means this transplant approach would require lifelong immune suppression.


In human patients that would confer an increased risk of infection, says Sachs, whose own lab is working on ways to induce long-term tolerance after organ transplants. “Somebody might feel [that] if you can save a person’s life but you have to leave them on long-term immunosuppression … that’s OK,” says Sachs, “but that’s something that has to be decided.”

Another major caveat, says transplant immunologist and physician Daniel Salomon of Scripps Research Institute in San Diego, California, is that the results don’t prove the hearts would function well in the chest. “Having to actually do the pump work to keep the animals alive … is a big deal,” he says. “Just contracting in the abdomen and doing nothing physiological is much easier.” Mohiuddin and his team are gearing up for true heart replacement surgeries in a new group of baboons.

I got all of the information from http://www.sciencemag.org/news/2016/04/researchers-keep-pig-hearts-alive-baboons-more-2-years

Tuesday, April 5, 2016

Tampa Bay Seawater Desalination Plant

Tampa Bay Seawater Desalination Plant


There is a new water plant in Tampa that is converting that SALTY SEAWATER into fresh and tasty water that you can drink without any negative side affects! These plants are called Desalination Plants, and they are cropping up to help provide fresh water to the local residents. Lets see how this works!

How the Plant Works

The Tampa Bay Seawater Desalination Plant uses a process called reverse osmosis (RO) to produce drinking water from seawater.
The desalination plant is located next to Tampa Electric’s (TECO) Big Bend Power Station, which already withdraws and discharges up to 1.4 billion gallons a day of seawater from Tampa Bay, using it as cooling water for the power plant. The Tampa Bay Seawater Desalination plant “catches” up to 44 million gallons per day (mgd) of that warm seawater, separates it into drinking water and concentrated seawater and dilutes the twice-as-salty seawater before returning it to the bay.

You can click on the picture to enlarge the image!

Pretreatment

Before the RO process, seawater entering the desalination plant flows through screens that remove debris, then goes through a traditional treatment process called coagulation and flocculation. In this process, chemicals are added to the seawater to make algae, organic materials and particles clump together so they can be removed more easily in the sand filtration stage.  
After sand filtration, the salty water goes through diatomaceous earth filters to remove silt and fine particles. Cartridge filters just before the RO membranes serve as a backstop, removing any particles that may be remaining after the diatomaceous earth filters.  

Reverse Osmosis 

Next is the RO process. High pressure forces the pretreated water through semi-permeable membranes to separate the freshwater, leaving twice-as-salty seawater and other minerals behind.
The size of each RO membrane pore is about .001 microns, which is about 1/100,000th the diameter of a human hair.

Post-treatment, Blending and Delivery

After the RO process, chemicals are added to stabilize the desalinated seawater. The high-quality water is delivered to Tampa Bay Water’s regional facilities site where it is blended with treated drinking water from other supply sources before being delivered to Tampa Bay Water’s members. 

Concentrate Return

At full capacity, the RO process leaves about 19 mgd of twice-as-salty seawater behind which is returned to Big Bend’s cooling water stream and blended with up to 1.4 billion gallons of cooling water, achieving a blending ratio of up to 70-to-1. At this point before entering and mixing with any bay water, the salinity is already only 1.0 to 1.5 percent higher, on average, than water from Tampa Bay. This slight increase falls within Tampa Bay’s normal, seasonal fluctuations in salinity.
The cooling water mixture moves through a discharge canal, blending with more seawater, diluting the discharge even further. By the time the discharged water reaches Tampa Bay, its salinity is nearly the same as the Bay’s. And, the large volume of water that naturally flows in and out of Tampa Bay near Big Bend provides more dilution, preventing any long-term build-up of salinity in the bay. 
Tampa Bay Water’s comprehensive hydrobiological monitoring program collects thousands of samples including continuous salinity measurements every 15 minutes near the desalination facility. This and other water quality monitoring since 2003 shows no measurable salinity changes in Tampa Bay related to plant production.

Is this not INCREDIBLE!?! It's a lot of work, but the outcome is truly wonderful.
Now, every fluid ounce of this information and more is from their website, you can even request a tour!

Friday, January 30, 2015

New Tech Toy Wind Tree

This is a new concept from France, a tree that creates energy from wind.

The tree run silently, and also looks tasteful! "The idea came when we observe the rustling of leaves in calm weather. Energy is taken from the air and converted in watts.
The device uses a small plate in the form of twisted leaves, which convert wind energy into electrical energy. And regardless of the direction of air flow" However, I would not be looking to have one of these bad boys in your back yard. This tree of metal costs about 30 thousand euros.
 

Michaud-Larivière hopes that the “tree” will be used to power street lamps or charging stations for electric vehicles. In the future he plans to improve the installation and connect it to the energy-efficient homes. Perfect “tree” must be  the leaves of natural fibers, “roots” in the form of geothermal generator and a “crust” with photocells.

New Tech Toy Mouse PC


This may look like an everyday computer mouse to you, but it is not! This is a new tech toy that is still under development. This little guy is actually a full computer in the shape of a mouse.
http://itechfuture.com/concept-mini-pc-in-the-housing-of-computer-mouse/

 "The only, required for use with this gadget the peripheral device – a monitor or projector, which  connected to the Mouse-Box by means of a standard HDMI-cable. The amount of memory a computer is at the level of smartphones iPhone 6, and increase its memory is impossible.

 But, according to the creators, this situation can be easily solved with the help of cloud storage. In addition, Mouse-Box is equipped a gyroscope and an accelerometer. Among the advantages is also the fact, that Mouse-Box charged without wires. To charge applies inductive charger, which serves as a mouse pad, whereby for such a computer a charge will never run dry."