Sukka Kuy Wa Uyka Kuy Henne Anne Netopa Eramat. Ingar Mak E=ki.

Sukka kuy wa uyka kuy henne anne netopa eramat. Ingar mak e=ki.

(Acid urine and alkaline urine do not mean a healthy body. Watch what you do.) If you hear about seemingly beneficial claims for or against a product, please look carefully into them & examine.

Scishow: Is Alkaline Water Really Better For You?

A new health trend is claiming that it can rebalance your internal chemistry and help prevent cancers and bone loss, but what are the real health benefits of drinking alkaline water? 

Hosted by: Olivia Gordon

Sikanna katu pirka cikoykip okay.

(Dragons are beautiful creatures.)

reblog if you are a NERD who loves DRAGONS

I MEAN…

Who

Doesnt

like dragons?

They can be loyal

or they can be firce

How can you not love dragons?

They are like huge cats

These should be taken in both, as me & my editor can agree upon. Know the benefits and drawbacks of both and take them in a complementary way for the best results.

I’m both pro herbal medicine and pro vaccination because you can treat burns with aloe vera juice and sore throats with lavender infused honey but you can’t rid a country of polio with plants. 

Easiri katomap an! Cirkoykitonosisi, Ummacirkoyki, wa ummacep cikoykip tuwar okay.

(How cute! Griffins, hippogriffs, and seaponies are cool creatures.)

Sandbar: I don’t see the logic to the naming conventions, really. It just seems to be a pick of your parts.

Ocellus: Yeah. In most cases it’s based around the head of the creature. Which is why Hippogriffs are “Chicks”, Minotaurs are “Calves” and Hydras are “Hatchlings”

Gallus: We probably do it just to spite you.

Yona: Griffon isn’t very nice! Changeling friend!”

Gallus: No, I mean “We” as Griffons overall. We excel at being inconvenient.

Silverstream: Sounds about right.

Smolder: So confusing. Why can’t you be normal like the rest of us?

I heard from my editor that the sturdiness & versatility of this plant stems from the large amount of sand in it, making it possible to build entire homes from the stuff. Across many cultures with this in range, this is extremely handy to know & would recommend using it if you’re intending to grow this grass kind.

Building sites in Hong Kong often show a collision between tradition and modernity: bamboo scaffolds, some thirty stories high, envelop skyscrapers under construction (Figure 1; Waters 1998; also Sky-high scaffolds; Bamboo spider-men). The virtues of the material are that it is “primitive without being old-fashioned, time-saving without being insecure, and economical without being impracticable” (Waters 1998:20). Less eloquent explanations are that, unlike scaffolds of metal, bamboo can be stored in the open without risk of theft; the material is also inexpensive, sustainable, flexible, reusable (up to three times, depending on conditions of storage), quickly erected, and cantilevered with relative ease over empty spaces (Waters 1998:26, 30).

Figure 1. Bamboo scaffolding, Causeway Bay neighborhood, Hong Kong (Photograph by Claire Gribbin, Creative Commons License).

Bamboo tends to be seen as quintessentially oriental. Its tender shoots, processed to remove toxins (cyanogenic glycosides, also in cassava), find their way into many dishes, and an entire sub-genre of Chinese painting, the “Four Gentlemen” or “Noble Ones,” focuses on its depiction along with peers like the plum blossom, chrysanthemum, and orchid (bamboo embodies the summer, the others, respectively, winter, autumn, spring; see also Cahill 1997:187–192; see also Bickford 1999:147, on literary and visual traditions of bamboo and other plants; Hsü 1996:25, on links to gentlemanly virtue). The experience of a bamboo forest, as Houston has experienced it on the outskirts of Kyoto, figures among the “100 Soundscapes of Japan” under protection by the Japanese Ministry of the Environment (Torigoe 1999).

But bamboo occurs more widely than that, and with consequences for understanding the ancient Maya. According to one source, “New World bamboos account for approximately half of the total generic and specific bamboo diversity” (Clark 1990:126; for Guatemala, see McClure 1973:88, 105, 106). An ethnobotany of the Tzotzil in Zinacantán, Chiapas, accords a page to them, and gives the plants a full array of local terms: bix (the generic category, “all bamboos, reeds or sprawling, reed-like plants,” Breedlove and Laughlin 2000:150), muk’ta ne kotom, yaxal otot, antzil bix, ton bix, chanib, and k’ox ne kotom (Figure 2; re: muk’ta ne kotom, “large coati tail,” there is a ko-to-ma on La Rejolla Stela 1:I9 [files at the Corpus of Maya Hieroglyphic Inscriptions, Peabody Museum, Harvard University], but the context is unclear; note, too, that the term “bamboo,” evidently of Malay origin, did not enter European languages until the 1590s or later, etymology). Some grow to over 20 m long, within “ravines in the understory of tropical deciduous forests in the lower temperate and lowland areas” (Breedlove and Laughlin 2000:150). Others are cut by men but brought home to women for use in looms, or do service as banner poles or the staffs of shamans (Breedlove and Laughlin 2000:150). A vigorous shake of a staff will protect the shaman from watchdogs. Many native species are known in Guatemala (bamboo in Guatemala). Today, in the Peten, the northernmost province, workers on archaeological projects used saplings or bamboo in equal measure, depending on proximity (Andrew Scherer, personal communication, 2017).

Figure 2. Bamboos among the Tzotzil Maya (Breedlove and Laughlin 2000:plate 10).

Keep reading

These would be handy to know that space programs can be useful for improvement of life on Earth. After all, multiple groups would do well to learn from this & make more discoveries.

6 Ways NASA Technology Makes You Healthier

An important part of our mission is keeping astronauts strong and healthy during stays in space, but did you know that our technology also helps keep you healthy? And the origins of these space innovations aren’t always what you’d expect.

As we release the latest edition of NASA Spinoff, our yearly publication that celebrates all the ways NASA technology benefits us here on Earth, let’s look at some ways NASA is improving wellness for astronauts—and everyone else.

1.      Weightless weight-lifting

Without gravity to work against, astronauts lose bone and muscle mass in space. To fight it, they work out regularly. But to get them a good burn, we had to get creative. After all, pumping iron doesn’t do much good when the weights float.

The solution? Elastic resistance. Inventor Paul Francis was already working on a portable home gym that relied on spiral-shaped springs made of an elastic material. He thought the same idea would work on the space station and after additional development and extensive testing, we agreed.

Our Interim Resistive Exercise Device launched in 2000 to help keep astronauts fit. And Francis’ original plan took off too. The technology perfected for NASA is at the heart of the Bowflex Revolution as well as a new line of handheld devices called OYO DoubleFlex, both of which enable an intensive—and extensive—workout, right at home.

2.      Polymer coating keeps hearts beating

A key ingredient in a lifesaving treatment for many patients with congestive heart failure is made from a material a NASA researcher stumbled upon while working on a supersonic jet in the 1990s.

Today, a special kind of pacemaker that helps synchronize the left and right sides of the heart utilizes the unique substance known as LaRC-SI. The strong material can be cast extremely thin, which makes it easier to insert in the tightly twisted veins of the heart, and because it insulates so well, the pacemaker’s electric pulses go exactly where they should.

Since it was approved by the FDA in 2009, the device has been implanted hundreds of thousands of times.

 3.  Sutures strong enough for interplanetary transport

Many people mistakenly think we created Teflon. Not true: DuPont invented the unique polymer in 1938. But an innovative new way to use the material was developed to help us transport samples back from Mars and now aids in stitching up surgery patients.

Our scientists would love to get pristine Martian samples into our labs for more advanced testing. One complicating factor? The red dust makes it hard to get a clean seal on the sample container. That means the sample could get contaminated on its way back to Earth.

The team building the cannister had an idea, but they needed a material with very specific properties to make it work. They decided to use Polytetrafluoroethylene (that’s the scientific name for Teflon), which works really well in space.

The material we commonly recognize as Teflon starts as a powder, and to transform it into a nonstick coating, the powder gets processed a certain way. But process it differently, and you can get all kinds of different results.

For our Mars sample return cannister prototype, the powder was compressed at high pressures into a block, which was then forced through an extruder. (Imagine pressing playdough through a mold). It had never been done before, but the end result was durable, flexible and extremely thin: exactly what we needed.

And since the material can be implanted safely in the human body—it was also perfect as super strong sutures for after surgery.

4.      Plant pots that clean the air

It may surprise you, but the most polluted air you breathe is likely the air inside your home and office. That’s especially true these days with energy-efficient insulation: the hot air gets sealed in, but so do any toxins coming off the paint, furniture, cooking gas, etc.

This was a problem NASA began worrying about decades ago, when we started planning for long duration space missions. After all, there’s no environment more insulated than a spaceship flying through the vacuum of space.

On Earth, plants are a big part of the “life support” system cleaning our air, so we wondered if they could do the same indoors or in space.

The results from extensive research surprised us: we learned the most important air scrubbing happens not through a plant’s leaves, but around its roots. And now you can get the cleanest air out of your houseplants by using a special plant pot, available online, developed with that finding in mind: it maximizes air flow through the soil, multiplying the plant’s ability to clean your air.

5.      Gas sensor detects pollution from overhead

Although this next innovation wasn’t created with pollution in mind, it’s now helping keep an eye on one of the biggest greenhouse gasses: methane.

We created this tiny methane “sniffer” to help us look for signs of life on Mars. On Earth, the biggest source of methane is actually bacteria, so when one of our telescopes on the ground caught a glimpse of the gas on Mars, we knew we needed to take a closer look.

We sent this new, extremely sensitive sensor on the Curiosity Rover, but we knew it could also be put to good use here on our home planet.  We adapted it, and today it gets mounted on drones and cars to quickly and accurately detect gas leaks and methane emissions from pipelines, oil wells and more.

The sensor can also be used to better study emissions from swamps and other natural sources, to better understand and perhaps mitigate their effects on climate change.

6.      DNA “paint” highlights cellular damage

There’s been a lot of news lately about DNA editing: can genes be changed safely to make people healthier? Should they be?

As scientists and ethicists tackle these big questions, they need to be sure they know exactly what’s changing in the genome when they use the editing tools that already exist.

Well, thanks to a tool NASA helped create, we can actually highlight any abnormalities in the genetic code with special fluorescent “paint.”

But that’s not all the “paint” can do. We actually created it to better understand any genetic damage our astronauts incurred during their time in space, where radiation levels are far higher than on Earth. Down here, it could help do the same. For example, it can help doctors select the right cancer treatment by identifying the exact mutation in cancer cells.

You can learn more about all these innovations, and dozens more, in the 2019 edition of NASA Spinoff. Read it online or request a limited quantity print copy and we’ll mail it to you!