On the surface, ants and the Internet don’t seem to have much in common. But two Stanford researchers have discovered that a species of harvester ants determine how many foragers to send out of the nest in much the same way that Internet protocols discover how much bandwidth is available for the transfer of data. The researchers are calling it the “anternet.”

Expectant mothers are used to fuzzy images on ultrasound monitors and blood tests to screen for potential health problems in their unborn babies. But what if one of those blood tests came back with a readout of the baby’s entire genome? What if a simple test gave parents every nuance of a baby’s genetic makeup before birth?

Recent studies show that it’s possible to decode an entire fetal genome from a sample of the mother’s blood. In the future, doctors may be able to divine a wealth of information about genetic diseases or other characteristics of a fetus from the pregnant mother’s blood. Such tests will raise ethical questions about how to act on such information. But they could also lead to research on treating diseases before birth, and leave parents and their doctors better prepared to care for babies after birth.

Read more

A bionic eye has given an Australian woman partial sight and researchers say it is an important step towards eventually helping visually impaired people get around independently.

Dianne Ashworth, who has severe vision loss due to the inherited condition retinitis pigmentosa, was fitted with a prototype bionic eye in May at the Royal Victorian Eye and Ear Hospital.

"It was really funny when it switched on I was waiting, waiting … I had these goggles on and I didn’t know what to expect, and I don’t know if anyone did know what I was going to see … Then all of a sudden I went ‘yep’ I could see a little flash and it was like a little, I suppose, a splinter … There were different shapes and dark black, lines of dark black and white lines together … Then that turned into splotches of black with white around them and cloud-like images … I can remember when the first bigger image came I just went ‘Wow,’ because I just didn’t expect it at all but it was amazing," she said.

The bionic eye, designed, built and tested by the Bionic Vision Australia, a consortium of researchers partially funded by the Australian government, is equipped with 24 electrodes with a small wire that extends from the back of the eye to a receptor attached behind the ear.

Robots that can read and respond to brain waves will eventually help stroke patients regain movement, using new neural interfaces that can re-train damaged motor pathways. Neuroscientists have made great strides in brain-machine interfaces that can respond to a person’s thoughts — a new generation will drive a non-invasive robotic orthotic, retraining the patient’s own body.

Patients who have suffered a stroke or other injury can lose the active use of their limbs, rendering them unable to simply think about moving an arm or hand and then do it. Sometimes it’s possible to re-establish the lost connection, with time and repetitive physical therapy. Researchers at Rice University are using a robotic exoskeleton and a neural interface to improve matters.

Britain’s first bionic veteran has a new brain-controlled robotic arm that is transforming his life.

Andrew Garthwaite, 25, had his right arm blown clean off by a rocket-propelled grenade during a firefight with the Taliban in Afghanistan in September 2010. In January he had the state-of-the-art limb wired to his nervous system during a six-hour operation in Vienna, Austria.

Now he is getting to grips with his new body part and is able to ride his motorcycle and drive a car again. Mr Gathwaite, who lives with his new wife Kailey, also 25, in South Shields, Tyneside, said:

'It's been incredible. I thought I might never be the same. But my life is starting to get back to normal - I'm on my motorbike and I'm back in a car. I can do things that I never thought I would have been able to do'.

Harvard scientists have created a type of cyborg tissue by embedding a three-dimensional network of functional, biocompatible, nanoscale wires into engineered human tissues.

The research addresses a concern that has long been associated with work on bioengineered tissue: how to create systems capable of sensing chemical or electrical changes in the tissue after it has been grown and implanted. The system might also represent a solution to researchers’ struggles in developing methods to directly stimulate engineered tissues and measure cellular reactions.

The process of building the networks is similar to that used to etch microchips. Beginning with a two-dimensional substrate, researchers laid out a mesh of organic polymer around nanoscale wires, which serve as the critical sensing elements. Nanoscale electrodes, which connect the nanowire elements, were then built within the mesh to enable nanowire transistors to measure the activity in cells without damaging them. Once completed, the substrate is then dissolved, leaving researchers with a netlike sponge, or a mesh, that can be folded or rolled into a host of three-dimensional shapes. Finally, the networks are porous enough to allow seeding them with cells and encourage those cells to grow in 3-D cultures.

Using heart and nerve cells, the Harvard research team successfully engineered tissues containing embedded nanoscale networks without affecting the cells’ viability or activity. Using the embedded devices, the researchers were then able to detect electrical signals generated by cells deep within the tissue, and to measure changes in those signals in response to cardio- or neuro-stimulating drugs.

A new study from the Lighting Research Center (LRC) at Rensselaer Polytechnic Institute shows that a two-hour exposure to electronic devices with self-luminous “backlit” displays causes melatonin suppression, which might lead to delayed bedtimes, especially in teens.

The research team, led by Mariana Figueiro, associate professor at Rensselaer and director of the LRC’s Light and Health Program, tested the effects of self-luminous tablets on melatonin suppression. In order to simulate typical usage of these devices, 13 individuals used self-luminous tablets to read, play games, and watch movies.

The actual melatonin suppression values after 60 minutes were very similar to those estimated using a predictive model of human circadian phototransduction for one-hour light exposures. “Based on these results, display manufacturers can use our model to determine how their products could affect circadian system regulation,” said Figueiro.

The results of this study, together with the LRC predictive model of human circadian phototransduction, could urge manufacturers to design more “circadian-friendly” electronic devices that could either increase or decrease circadian stimulation depending on the time of day — reducing circadian stimulation in the evening for a better night’s sleep, and increasing in the morning to encourage alertness.

SOLITAIRE, which was approved by the U.S. Food and Drug Administration in March, is among an entirely new generation of devices designed to remove blood clots from blocked brain arteries in patients experiencing an ischemic stroke. It has a self-expanding, stent-like design, and once inserted into a blocked artery using a thin catheter tube, it compresses and traps the clot. The clot is then removed by withdrawing the device, reopening the blocked blood vessel.

Researchers at Carnegie-Mellon University (CMU) are working with a Canadian startup called Autonomous ID to develop biometric shoes that can identify who you are by the way you walk.

The BioSoles can record the pressure points of someone’s feet, track their gait and use a microcomputer to compare that to a master file already made for that person. If the patterns match, the BioSoles stay silent. If they don’t, they transmit a wireless alarm message.

Since the devices are designed to detect changes in gait, some think they could end up being used to help spot early signs of Alzheimer’s disease.