The first ‘smart hand’ has come into being, employing muscles composed of wires powered by electric charges that cause them to move, tensing and relaxing, and allowing the user to perform manual tasks.
Creating the ultimate in biomimicry, researchers are able to present not only a realistic look, but also true function due to the fibers entwined within the prosthetic. Able to perform quite impressively, the 3D printed devices are deemed powerful by the use of nickel-titanium wire which is extremely dense. Movement is even completely possible in more restricted spaces.
Entering into what many consider to be the next dimension of 3D printing, materials like this 3D printed smart hand are able to perform a function and then revert back to their original shape. Shape memory in the case of the 3D printed bionic hand means that it is charged by the electricity and comes to life in a lattice shape as it contracts and offers mobility to the user, all controlled by a single semiconductor chip.
“This enables us to build particularly lightweight systems, and the fact that they come in the form of wires enables us to use them as artificial muscles, or artificial tendons,” explained Professor Stefan Seelecke from Saarland University and at the Center for Mechatronics and Automation (ZeMA). “So we can build systems with those that can be like bio-inspired, look-to-nature for a successful prototype, and that’s what we realized with this first prototype of a robotic hand using shape-memory alloy wires.”
The bundling of wires is key to the success of this prototype, which was initially demonstrated through the rudimentary example of a bat beating its wings, using only two wires. For the hand design, researchers copied from life–and true human anatomy–to achieve the desired result. Groups of the wires, bundled, are able to imitate real muscles due to contractions caused by heat.
“The movement of the hand is done by the wire. This wire, when activated, they contract. And we are able to exploit this contraction to make the finger move. And we can move each phalanx independently,” explained Engineer Filomena Simone, a PhD student and co-developer of the 3D printed bionics.
“I think if you look down the road to future prostheses generations, you’d like to see this integrated with the human body in a way that you can actually sense the nerve stimuli and then can feed that into a micro-controller which there will be translated to a corresponding signal to activate the muscle,” said Seelecke. “So, eventually you need to couple nerves with proper electrodes and combine that with the actuation of the muscles so you can create some integrated, biologically inspired actuation system for prostheses.”
How do you think 3D printing and bionics will change the future of medicine–and the lives of those in need of prosthetics? Discuss in the 3D Printed Smart Hands forum over at 3DPB.com.