U.S. Army veteran Richard Neider is able to walk again after suffering a spinal-cord injury in Iraq thanks to a robotic exoskeleton. Neider, who is the first veteran in Phoenix to receive the ReWalk Personal 6.0 Exoskeleton through a Veterans Affairs program, was unable to walk after being injured in an explosion in Iraq and has spent almost ten years in a wheelchair. The battery-powered, motorized device has sensors that detect when he shifts his weight and then tells Neider's other leg to move - creating a walking motion. The light exoskeleton helps to stabilize his knees and hip. 'I can't ever stop smiling when I'm in it,' the former Army sergeant, who saw his May 2005 injury worsen over time, tells AZFamily.

The combination of mental effort and state-of-the-art technology have allowed a man with immobilized limbs to communicate by text at speeds rivaling those achieved by his able-bodied peers texting on a smartphone. Stanford University investigators have coupled artificial-intelligence software with a device, called a brain-computer interface, implanted in the brain of a man with full-body paralysis. The software was able to decode information from the BCI to quickly convert the man's thoughts about handwriting into text on a computer screen. The man was able to write using this approach more than twice as quickly as he could using a previous method developed by the Stanford researchers, who reported those findings in 2017 in the journal eLife. The new findings, published online May 12 in Nature, could spur further advances benefiting hundreds of thousands of Americans, and millions globally, who've lost the use of their upper limbs or their ability to speak due to spinal-cord injuries, strokes or amyotrophic lateral sclerosis, also known as Lou Gehrig's disease, said Jaimie Henderson, MD, professor of neurosurgery.

Almost exactly a year ago, in April 2010, professional motocross rider Randy Childers sustained serious injuries after a crash in the last race of the day at Cowboy Badlands in West Beaumont, Texas. He suffered broken ribs and a fractured wrist, but most seriously a crushed vertebra in his neck (C3) that required him to be airlifted to Houston, where surgeons inserted an artificial vertebra and fused two others together (C4 and C5) during a marathon operation that lasted 12 hours. Today, the 24-year-old is the star in a single-patient trial of Rice University's RiceWrist robot, a wearable exoskeleton that mimics the joints from his shoulder to his hand. After months of traditional physical therapy, Childers had recovered enough by October to walk (albeit slowly) into the basement lab at Rice and begin to use the RiceWrist, which is built to reconnect motor pathways in the brain through repetitive movement. After just two weeks, Rice Professor Marcia O'Malley says, Childers was doing most of the work himself.

For more than a decade, neuroscientist Grégoire Courtine has been flying every few months from his lab at the Swiss Federal Institute of Technology in Lausanne to another lab in Beijing, China, where he conducts research on monkeys with the aim of treating spinal-cord injuries. The commute is exhausting -- on occasion he has even flown to Beijing, done experiments, and returned the same night. But it is worth it, says Courtine, because working with monkeys in China is less burdened by regulation than it is in Europe and the United States. And this week, he and his team report the results of experiments in Beijing, in which a wireless brain implant -- that stimulates electrodes in the leg by recreating signals recorded from the brain -- has enabled monkeys with spinal-cord injuries to walk. "They have demonstrated that the animals can regain not only coordinated but also weight-bearing function, which is important for locomotion. This is great work," says Gaurav Sharma, a neuroscientist who has worked on restoring arm movement in paralysed patients, at the non-profit research organization Battelle Memorial Institute in Columbus, Ohio.