Future Culture

Futurist Writer Lei Kalina writes her tongue-in-cheek musings and ramblings on the growing worldwide phenomenon of the growth of the Future Culture in the 21st Century

Future Culture In The 21st Century

Future Culture In the 21st Century

Futures Studies, Foresight, or Futurology , according to Wikipedia, is the science, art and practice of postulating possible, probable, and preferable futures and the worldviews and myths that underlie them. Futures studies (colloquially called "Futures" by many of the field's practitioners) seeks to understand what is likely to continue, what is likely to change, and what is novel. Part of the discipline thus seeks a systematic and pattern-based understanding of past and present, and to determine the likelihood of future events and trends. Futures is an interdisciplinary field, studying yesterday's and today's changes, and aggregating and analyzing both lay and professional strategies, and opinions with respect to tomorrow.

Thursday, June 26, 2014

"Bionic Olympics" for Global Parathletes By October 2016








WHEN  CELEBRATED CASE AND    QUADRIPLEGIC PATIENT Cathy  Hutchinson, paralyzed from the neck down  seventeen years ago    and later  dubbed by international  scientists  as “Patient S3” last 2012   --     successfully  picked up a flask of coffee  and sipped through its straw   via    thought-controlled   robotic arms and brain-computer interface   --  advanced science enthusiasts  knew that  the best  is  about  to come.


Hutchinson’s case was an exceptional breakthrough,  which celebrated the success of  enabling people with severe paralysis to  maneuver thought-controlled  robotic arms,  using brain-to-computer neural implants,  which the  technological process,  called BrainGate II  --  the updated version used on Hutchinson --  made possible.


In the initial stages six years ago  (2006),  paralyzed patients could have only moved a curser on the computer screen monitor using their thoughts.  Whats the secret behind this  breakthrough?   No secret. A surgically-implanted electrode on the patient's brain the size of a baby aspirin interprets the electric  signals it relays -- enabling the movements to take place.   





The
 wearers of the assistive devices will be known as pilots and the technology they use can be available commercially or developed for them as a prototype in a lab. A bionic hand called the iLimb, which is commercially available from Touch Bionics is pictured











Lead researcher  and neuroscientist  John Donoghue from Brown University,  noting that “we now show that people with longstanding, profound paralysis can move complex real-world machines like robotic arms, and not just virtual devices, like a dot on a computer

BrainGateII  as  process later transforms into a muti-million company with its  noble mission  “to improve of the quality of life for all disabled humans,  (and)  additionally seeking “ to increase the usage of BrainGate related technology in both medical and non-medical applications and facilitate innovation in invasive and non-invasive brain research.”



Further,  it  is  geared  “to create technology that will allow severely disabled individuals—including those with traumatic spinal cord injury and loss of limbs—to communicate and control common everyday functions literally through thought…  teaming up with a seasoned team of enterpreneurs  aiming to advance movement through thought alone “ achieved through partnership with leading academic institutions institutions, corporations, and various non-profit and government organizations working on the research, science, and development of applied commercial technology.”


Meantime,  the likes of Cathy Hutchinson who were disabled by accidents or by birth have something more to look forward to.



By  October  2016,  all roads lead to the first-ever   Cybathlon  ---  an international  sporting  event  for for  parathletes wherein athletic events  actively encourage the use and development of  pioneering robotic technology  --   with the use of  leg prosthetics ,   powered exoskeletons and powered wheelchairs,      brain-computer interface , and  functional electrical stimulation (FES)  via bike races, and more. 


A clear first for all-time:   to be held at the  Kolping Arena  in Kloten, Zurich, Switzerland, wherein parathletes worldwide can be given the opportunity to compete internationally  using robot-assisted technology and  showcase the maximum performance and practical functionality of  artificial intelligence for persons with disabilities (PWD).  






From powered exoskeleton races to competitions using brain power (illustrated), the first Olympics for bionic athletes, called the Cybathlon, will take place in Switzerland in October 2016
+7
Photos  via  YouTube Screengrab
From powered exoskeleton races to competitions using brain power (illustrated), the first Olympics for bionic athletes, called the Cybathlon, will take place in Switzerland in October 2016





Event  organizers ,  including  Swiss National Competence Center of Research in Robotics (NCCR Robotics) ,  one of the main goals of the  Cybathlon is  “to provide a platform for the development of  novel-assistive technologies  that are useful for daily life…  Through the organization of the Cybathlon we want to help removing barriers between the public, people with disabilities and science. It is hoped that  the competition will spur interest in human performance-enhancing technology.”


Prizes will be awarded to both the winning athletes in each event and to the company behind the software or technological device used.   Organized on behalf of the Swiss National Competence Center of Research in Robotics (NCCR Robotics), the competition is open to technology already available on the market, or to research development projects by laboratories.


Earlier reports mentioned that   a variety of disciplines  would be applying  state-of-the-art technology for the most modern  “powered knee prostheses, wearable arm prostheses, powered exoskeletons, powered wheelchairs, electrically stimulated muscles and novel brain-computer interfaces…   Even  totally paralyzed people will be able to take part, using brain-computer interface.”









“The assistive devices can include commercially available products provided by companies, but also prototypes developed by research labs. There will be two medals for each competition, one for the pilot, who is driving the device, and one for the provider of the device.”



In a  recent BBC news report,   University of Switzerland Professor Robert Riener,  also part of the event organizing team, explained that "much too often,   there  is  disconnect between  patients and technology.  The idea is that we want to push development of assistive technologies towards devices that patients can really use in everyday life.  While some of the current technologies look very fancy but are a long way from being practical and user-friendly,  we would want technology  to be useful for daily living for these persons with disabilities.”


 “Further  ,  we are allowing use of technology in this event,  which has previously been excluded from the Paralympics. By making it a public event,  we want to get rid of the borders between patients, society and the technology community. Our other main aim for the games is to allow people to compete who have never had the opportunity before,” Reiner says.






From  website  Sophimania.lamula.pe

+7
Photo via  YouTube Screengrab

Pilots with leg amputation will be equipped with machine operated prostheses and will have to successfully complete a race course (pictured) as quickly as possible, which will include obstacles such as slopes, a staircase, cobblestones and a seesaw







In the Powered Exoskeleton Race (pictured), pilots with complete thoracic or lumbar Spinal Cord Injuries (SCI) will be equipped with actuated exoskeletal devices, which will enable them to walk along a particular race course

Photo via  YouTube Screengrab
In the Powered Exoskeleton Race (pictured), pilots with complete thoracic or lumbar Spinal Cord Injuries (SCI) will be equipped with actuated exoskeletal devices, which will enable them to walk along a particular race course




Meantime,  The Verge News reports:

“Unlike the Olympics, where athletes can use prosthetics only to make themselves as good as able-bodied athletes and not better, Cybathlon competitors are encouraged to use the best technology. Dual prizes will be awarded, one to the athlete and one to the company that created the prosthetic, device, or software.”


"The rules of the competition are made in such way that the novel technology will give the pilot an advantage over a pilot that would use a comparable but less advanced or conventional assistive technology," the organization says on its website. "There will be as few technical constraints as possible, in order to encourage the device providers to develop novel and powerful solutions."


“Of course, the races will be slower than their Olympic counterparts, but they're also arguably more mind-boggling. The exoskeleton competitors, for example, must walk over a slope, up steps, around pillars, over a see-saw, across a narrow beam, then pick up a bag and carry it, go around tight corners, and then sprint to the finish line.”



Pilots with forearm or upper arm amputations will be equipped with actuated exoprosthetic devices and will have to successfully complete two hand-arm task courses as quickly as possible (illustrated). A close-up camera view will be used to life-display the shoot on the stadium screens. At least two participants will start at the same time on two identical courses,
 to make the event more exciting
+7
Photo via  YouTube Screengrab

Pilots with forearm or upper arm amputations will be equipped with actuated exoprosthetic devices and will have to successfully complete two hand-arm task courses as quickly as possible (illustrated). A close-up camera view will be used to life-display the shoot on the stadium screens. At least two participants will start at the same time on two identical courses, to make the event more exciting



Parathletes at Cybathlon,  however, will be called “pilots”,  using exoskeletons like those by Ekso Bionics,   to  trudge through obstacle courses,  powered  wheelchairs  will be seeing action as well,   while  FES  ( Functional Electrical Stimulation) of nerves for paralyzed limbs  assist the parathletes competing in the bike race.   Meantime,  arm  amputees  use robotic prosthetics “to navigate a wire course as quickly and nimbly as possible without touching the wire.”


SingularityHub.com  further reports: 


“Robotic prosthetics (arm and leg), like those from the Rehabilitation Institute of Chicago and Case Western Reserve University, use computers to recognize electrical patterns in muscles and nerves and allow patients to control bionic limbs with thoughts alone. Some are even beginning to send rudimentary sensory touch information back to the brain.”


“The Cybathlon wouldn’t be possible without these technologies, but perhaps it wouldn’t be quite as urgent if they weren’t still confined to labs and clinical trials. The hope is the Cybathlon can add another incentive to speed things along.”



+7
The Powered Wheelchair Race (illustrated) will allow pilots with different disability levels (e.g. quadriplegics, paraplegics, amputees) to be equipped with power wheelchairs, which will enable them to steer along a particular race course. The course will be defined by cones between which the pilots will have to manoeuvre the chair both forward and backward. In addition, obstacles of different sizes will be used.


In one of the six disciplines at the games, participants will use powered wheelchairs to steer along a race course with slopes
 and uneven (illustrated) surfaces as well as a slalom


+7

THE SIX DISCIPLINES AT THE 2016 CYBATHLON 

Powered arm prostheses race: Pilots with arm amputations will be equipped with robotic prostheses and will have to successfully complete two hand-arm task courses as quickly as possible.
One of the challenges will see pilots holding a wire loop which they will use to navigate a metal wire without touching it. Another race will see participants pick up differently shaped objects in order to demonstrate the dexterity of their prostheses.
Brain computer interface race: Pilots will be equipped with technology that lets them control an avatar in a racing game played on computers using their brains. They will race along a track with obstacles.
Functional electrical stimulation bike race: Pilots with spinal cord injuries will use functional electrical stimulation devices, which will enable them to perform a pedaling movement on a cycling device that drives them on a circular course. There will be two categories - a sprint race, over a distance of 200metres and an endurance race over the distance of 1000metres.
Powered leg prostheses race: Pilots with transfemoral amputation will be equipped with machine operated prostheses and will have to successfully complete a race course as quickly as possible, which will include obstacles such as slopes, a staircase, cobblestones and seesaw.
Powered exoskelton race: Pilots with spinal cord injuries (SCI) will use powered exoskeletons to negotiate a race course with obstacles of around 100metres.
Powered wheelchair race: Participants will use powered wheelchairs to steer along a race course with slopes and uneven surfaces as well as a slalom