biomechatronics
Differences
This shows you the differences between two versions of the page.
| Next revision | Previous revision | ||
| biomechatronics [2011/07/19 15:07] – created hagalaz | biomechatronics [2011/07/24 02:42] (current) – [History] hagalaz | ||
|---|---|---|---|
| Line 1: | Line 1: | ||
| ====== Note ====== | ====== Note ====== | ||
| - | This is a placeholder page until RP Staff hammers out the final details. | + | //This page is intended to provide |
| - | + | ||
| - | * Metal is NOT better than meat, just different. Autologous cloned body parts are available in a number of situations. | + | |
| - | * In addition to being vulnerable to taser-style electrical effects, cybernetic implants, including limbs, are also vulnerable to things like EMP and induction heating. | + | |
| - | * Artificial limbs may be stronger than their meat counterparts, | + | |
| - | * Cybernetic technology, while impressive in some cases, has not advanced to the stage where it can replace damaged/ | + | |
| ====== Biomechatronics ====== | ====== Biomechatronics ====== | ||
| - | |||
| Biomechatronics is an applied interdisciplinary science that aims to integrate mechanical elements, electronics and parts of biological organisms. Biomechatronics includes the aspects of biology, mechanics, and electronics. It also encompasses the fields of robotics and neuroscience. The goal of this branch of science is to make devices that interact with human muscle, skeleton, and nervous systems. The end result is that the devices will help with human motor control that was lost or impaired by trauma, disease or birth defects. | Biomechatronics is an applied interdisciplinary science that aims to integrate mechanical elements, electronics and parts of biological organisms. Biomechatronics includes the aspects of biology, mechanics, and electronics. It also encompasses the fields of robotics and neuroscience. The goal of this branch of science is to make devices that interact with human muscle, skeleton, and nervous systems. The end result is that the devices will help with human motor control that was lost or impaired by trauma, disease or birth defects. | ||
| + | ====== History ====== | ||
| The first experiment with a healthy individual appears to have been that by the British scientist Kevin Warwick. In 2002, an implant was interfaced directly into Warwick' | The first experiment with a healthy individual appears to have been that by the British scientist Kevin Warwick. In 2002, an implant was interfaced directly into Warwick' | ||
| Claudia Mitchell, a former Marine and amputee, tested a prosthetic arm developed by Dr. Todd Kuiken at the Rehabilitation Institute of Chicago. A plastic surgeon, Dr. Gregory Dumainian at Northwestern Memorial Hospital in Chicago re-directed the nerves that control her missing arm to her chest. The nerves re-grew close to the skin of her chest. Tiny electrodes on her skin picked up the electrical activity of these nerves and sent signals to the motors in the arm. She was able to control the arm's movements by thinking about it. | Claudia Mitchell, a former Marine and amputee, tested a prosthetic arm developed by Dr. Todd Kuiken at the Rehabilitation Institute of Chicago. A plastic surgeon, Dr. Gregory Dumainian at Northwestern Memorial Hospital in Chicago re-directed the nerves that control her missing arm to her chest. The nerves re-grew close to the skin of her chest. Tiny electrodes on her skin picked up the electrical activity of these nerves and sent signals to the motors in the arm. She was able to control the arm's movements by thinking about it. | ||
| - | //OOC Note: As of 2011, the prosthetic arm is not truly biomechatronic in that signals only go one way, from Claudia to the arm. Dr. Kuiken is working on the next step of having the arm provide feedback to her, including sensations such as pain and pressure. Note also that this is different than a myoelectric prosthesis | + | //OOC Note: As of 2011, the prosthetic arm is not truly biomechatronic in that signals only go one way, from Claudia to the arm. Dr. Kuiken is working on the next step of having the arm provide feedback to her, including sensations such as pain and pressure. Note also that this is different than a myoelectric prosthesis |
| - | As always, RP Staff has final say over what's possible. | + | With the advent of modern microneurosurgical techniques, it became possible to map the terminii of the brachial and lumbosacral nerve plexuses, allowing for prostheses with more precise movement control, kinesthetic sense, and even limited |
| - | - Hagalaz | + | One thing that has not changed is the requirement for rehabilitation and training in a controlled environment to allow the host body and new limb to become a single functional unit. |
| - | |||
| Keywords: | Keywords: | ||
| * biomechatronics | * biomechatronics | ||
| - | * sieve integrated circuit electrode | ||
| * biomedical engineering | * biomedical engineering | ||
| * multielectrode array | * multielectrode array | ||
| - | * Kevin Warwick | + | * Kevin Warwick, PhD, D.Sc. |
| + | * Todd Kuiken, MD | ||
| * Claudia Mitchell | * Claudia Mitchell | ||
| * Rehabilitation institute of Chicago | * Rehabilitation institute of Chicago | ||
biomechatronics.1311088065.txt.gz · Last modified: 2011/07/19 15:07 by hagalaz