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Aside from Frankenstein, previous attempts to make synthetic life have focused on genes. Geneticist Craig Venter and his colleagues, for example, announced in 2010 that they had created a one-celled creature by inserting an artificial genome in an existing cell that reproduced.

Now a separate team of scientists from Harvard University and the California Institute of Technology have built an eight-armed jellyfish by inserting muscle cells from a rat into a sheet of silicone. The resulting "medusoid," as they called it, could offer insights into tissue engineering -- such as re-building a heart. And show that when building tissues, there might be several ways or materials to use other than those found in nature.

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To build the medusoid, the scientists mapped out the protein networks in a real jellyfish's muscle cells. They then looked at how electrical current triggers the muscle contraction.

Another piece of the puzzle was uncovering the mechanics at how jellyfish move. The animals squeezes a muscle to propel itself through the water, but it was important to study the biomechanics of the stroke in order to duplicate it.

The scientists also found that a sheet of cultured heart muscle tissue from a rat would contract when electrically stimulated in a liquid environment. By incorporating the muscle cells with a silicone polymer membrane, they were able to create a jellyfish-shaped body with eight appendages. The artificial creature was put into a container of salt water and hit with an electrical current. It started swimming just like a real animal.

The next step is making a jellyfish that engages in ordinary behaviors, such as seeking food and responding to its environment.

BLOG: Artificial Skin Made From Spider Silk

Study co-author Kevin Kit Parker, professor of bioengineering and applied physics at Harvard, said he got interested in the project in 2007, when he started thinking about muscular pumps such as hearts. Seeing jellyfish at the New England Aquarium inspired him: he saw that there were similarities between jellyfish and human hearts.

Parker worked with Collaborating with Janna Nawroth, a doctoral student in biology at Caltech and lead author. They also worked with Nawroth’s adviser, John Dabiri, a professor of aeronautics and bioengineering at Caltech, and an expert in biological propulsion. The study was published in the journal Nature Biotechnology on July 22.

Credit: Harvard University, Caltech

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Spider-Man has had a rough summer. Recent news of his impending death and an overwrought, injury-prone musical have left the web-slinging community with a few black eyes. Yet like any great origin story, resurrection often rises out of the ashes. Case in point: recent news of spiders coming to the rescue of burn victims.

DNEWS VIDEO: SYNTHETIC LIFE, ENGINEERING TISSUE AND MORE …

Hanna Wendt, a tissue engineer in the Department of Plastic, Hand and Reconstructive Surgery at Medical School Hannover in Germany, along with her colleagues, recently published a study that suggests spider silk may hold the key to creating artificial skin for burn victims and other patients requiring skin grafts.

BLOG: Synthetic Skin Gets A Second Life

Wendt says previous materials, like collagen, used to create artificial skin did not seem strong enough, so she and her team turned to a material 5 times stronger than Kevlar: spider dragline silk.

"Spider silks display excellent mechanical features that even rival man-made, high-tech fibers," the study explains.

The researchers essentially milked the silk glands of golden orb web spiders, spooling the silk fibers as they came out. Next, the dragline silk was woven onto a rectangular steel frame, 0.7 mm thick, resulting in an easy-to-handle meshwork frame that could be sterilized.

Wendt and her colleagues found that human skins cell types could flourish on these meshwork frames if they were properly nurtured with nutrients, warmth and air.

"After two weeks of cultivating single single fibroblasts, keratinocytes were added to generate a bilayered skin model, consisting of dermis and epidermis equivalents," the study states.

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Depspite being impressed by how human cells responded to spider silk, Wendt thinks the use of synthetic fibers must be considered, especially since harvesting large amounts of spider silk is not practical.

"I think in the long term, for widespread daily clinical use, synthetic silk fibers providing the same mechanical -- and cell culture -- properties will be needed," Wendt told LiveScience.

[Via TechNewsDaily]

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The brain is an enormously complex machine whose processing power is unmatched by even the most advanced supercomputer. In fact, as evidenced by IBM’s famed ‘cat brain’ project, the best supercomputers are required just to simulate the basic behavior of biological neural circuits.

A major difference between the brain and a supercomputer is that the brain handles memory and processing at the same time -- on what is essentialy a parallel circuit. But even the best computers are built with physically separate ‘memory’ and ‘processing’ components. The back and forth transmission of data between these two subsystems makes the machines inherently non-parallel.

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However, this month in the scientific journal Advanced Materials, a study led by David Wright of the University of Exeter in England has shown how semiconductor ‘phase-change materials’ have just the right properties to build a machine that can store memory and process information at the same time. 

The curious property of phase-change materials -- which can be designed to melt at one temperature and solidify at another, releasing enormous amounts of energy in the process -- is not new. In fact, it's used in optical drive technology such as Blue-Ray discs.

In this latest application, phase change materials are  used to create computationally sophisticated processors. The team built a 'phase-change processor' that was able to perform arithmetic operations such as addition, subtraction, multiplication and division. They hope that simulations of neurons that use these processors as artificial neurons will be able to more closely mimic the behavior of biological neurons.

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Write tells PC Pro that in the next stage of project they are “planning on making a small demonstrator with 10 to 100 of these cells connected together to work on pattern recognition or maze solving.”

Credit: PASIEKA/Getty Images

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UPDATE: We think we may have gotten duped! Like many other webites, we picked up on the story below that a Japanese researcher had found a way to turn human feces into an edible protein. One of our commenters on Facebook suggested that this story was a hoax and after some investigation, we think he might be right. We emailed the researcher for clarification, but have not yet heard back. But in the meantime, we did find this piece on Salon by Justin Elliot, who traced the origin of this story back to a Youtube video and also found several similar headlines that popped up online in the 1990s. We'll let you know if we hear back from the researcher. In the meantime, our apologies.

We're all familiar with what you do if life hands you a lemon. You make lemonade, right? But what if life literally hands you a turd? Well, if you're Japanese researcher, Mitsuyuki Ikeda, you do this: create an edible steak made from human feces.

We've previously reported on some colorful bowel movements, but this bowel-to-plate movement is way beyond colorful. In fact, it's almost beyond the pale. However, once your dry-heaves subside, what's even more absurdly stomach-churning is this idea is not only plausible, its already been taste-tested.

When Tokyo Sewage approached Mitsuyuki Ikeda, a researcher from the Okayama Laboratory, and asked him to explore potential uses for an overabundance of sewage mud, Ikeda found that, because of all the bacteria, the mud contained large amounts of proteins.

WIDE ANGLE: Poo Power

DNEWS VIDEO: SYNTHETIC LIFE, ENGINEERING TISSUE AND MORE …

Ikeda and his team isolated those proteins, combined them with a reaction enhancer and put it in an exploder, thereby creating le cuisine de merde. The lab-grown steak is made from 63 percent proteins, 25 percent carbohydrates, 3 percent lipids, 9 percent minerals (and 100 percent you've-got-to-be-kidding-me). Researchers enhanced the flavor with soy protein and used red coloring to give the poo-burger that appetizing, meaty charm. According to DigitalTrends, initial taste-tasters have said the butt steaks even tastes like beef.

But is this meat safe?

Experts say, in theory, yes. But to kill any toxic pathogens, the meat must obviously be cooked.

WIDE ANGLE: Tissue Engineering

"In the food safety world we say, 'don't eat poop," Douglas Powell, a professor of food safety at Kansas State University, told MyHealthNewsDaily. "But if you're going to, make sure it's cooked."

Powel did say there was a potential for cross contamination in the lab where the bowel loaf was developed, but said the idea in not that different from eating vegetables that have been fertilized with manure or other excrement.

"Theoretically, there's nothing wrong with this," Powell added."It could be quite safe to eat, but I'm sure there's a yuck factor there."

Bon appétit!

[Via Yahoo News]

Credit: Lew Robertson/Corbis

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Imagine getting sprayed with DNA when you walked into a private business. If that sounds crazy, you must not be living in the Netherlands, where spray-on DNA mist is an increasingly popular form of theft prevention. The system uses newly created synthetic DNA, and probably wouldn't work with 419-million year-old DNA.

The DNA sprayer goes above a private business's entrance, usually accompanied by an ominous sign that says something like, "You Steal, You’re Marked.”

The idea is that if someone is robbing a private business, an employee would activate the DNA sprayer without attracting the thief's attention, much like how you would active a silent alarm. The invisible spray permeates the air and settles onto the thief without his knowing it. The local police department is automatically alerted to a possible crime in progress.

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Visible only under ultraviolet light, the mist carries synthetic DNA markers unique to the location, allowing the police to match the thief with the place burgled. The DNA mist is imperceptible to those who come into contact with it. The manager of one business that now uses the technology told the New York Times, “You don’t smell it; you don’t see it; nobody knows it’s there.”

The technology is more about keeping potential thieves at bay, rather than actually capturing a burglar once the crime has been committed. At least, that's what one company behind DNA mist technology is saying.

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Donald van der Laan's company, the Rhine Group, distributes this DNA spray to Dutch businesses. He says the devices aren't supposed to capture crooks so much as they are supposed to scare away potential thieves. As he told the New York Times, “The whole thing is prevention, not about recovering stolen goods or capturing criminals."

The company claims to have helped drastically reduce the crime in the areas where the technology has been deployed. Before you get too excited, however, the company hasn't released any figures to prove that assertion. The local police department says it hasn't made any arrests using the DNA spray, even though several crimes have occurred.

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This is quite a crustacean. It's called a mantis shrimp. Colorful little devil, huh? Well, get this. Humans see in three colors, but some species of mantis shrimp can see in as many as twelve. Yeah, I know. That's cool. Dr. Nicholas Roberts thinks so too. He's with the Ecology of Vision Group at the University of Bristol in the United Kingdom. He's part of a team that's been studying the eyesight of one of the 250 or so known species of mantis shrimp in the world.

The idea is to get a better handle on just how the eyes of the mantis shrimp manage to see so many different kinds of light. To what end, you might ask? Well, for that, you'll need to listen in. Suffice to say that if you're a Netflix fan, it might mean a better playback and viewing experience for your DVDs...you know, down the road a ways. My first question to Nick: What was it about the mantis shrimp's eyes that got your scientific juices flowing? 

A Conversation with Nick Roberts of The University of Bristol

(Photo by Jenny via Wikipedia)

Whether you're against animal testing or not, at a certain point other mammals can't stand in for humans. Biologists in Germany hope the artificial organs they're developing can do the job instead.