Prosthetic hand: Difference between revisions

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A '''prosthetic hand''' is a device that substitutes for a missing human hand and part of the forarm in the case of [[transradial amputees]].  
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A '''prosthetic hand''' is a device that substitutes for a missing human hand and part of the forearm in the case of [[transradial amputees]].  


An ideal prosthetic hand is highly dexterous, controllable, provides sensory feedback, and is aesthetically pleasing. Modern prosthetic hands have great dexterity and aesthetics but control and sensory feedback are still limited. It is also very important that a prosthetic is instinctive to control so the patient accepts it as a part of their body. Currently the best control systems available commercially use [[myoelectrics]]. Electrodes placed on the patient’s arm measure muscle activations and use these signals to control the prosthetic. Two main advantages of this system include its un-invasiveness and its low cost. Among the disadvantages are the lack of sensory feedback and limited bandwidth. Researchers are currently looking at neuroprosthetics as a new control system in which electrodes are surgically connected to the patient’s nerves. Signals from the nerves can be processed and turned into commands to move the prosthetic. This system could also provide sensory feedback by simulating nerve signals that would be generated by an intact hand.  
An ideal prosthetic hand is highly dexterous, controllable, provides sensory feedback, and is aesthetically pleasing. Modern prosthetic hands have great dexterity and aesthetics but control and sensory feedback are still limited. It is also very important that a prosthetic is instinctive to control so the patient accepts it as a part of their body. Currently the best control systems available commercially use [[myoelectrics]]. Electrodes placed on the patient’s arm measure muscle activations and use these signals to control the prosthetic. Two main advantages of this system include its un-invasiveness and its low cost. Among the disadvantages are the lack of sensory feedback and limited bandwidth. Researchers are currently looking at neuroprosthetics as a new control system in which electrodes are surgically connected to the patient’s nerves. Signals from the nerves can be processed and turned into commands to move the prosthetic. This system could also provide sensory feedback by simulating nerve signals that would be generated by an intact hand.  
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==References==
==References==
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Revision as of 16:27, 10 April 2011

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A prosthetic hand is a device that substitutes for a missing human hand and part of the forearm in the case of transradial amputees.

An ideal prosthetic hand is highly dexterous, controllable, provides sensory feedback, and is aesthetically pleasing. Modern prosthetic hands have great dexterity and aesthetics but control and sensory feedback are still limited. It is also very important that a prosthetic is instinctive to control so the patient accepts it as a part of their body. Currently the best control systems available commercially use myoelectrics. Electrodes placed on the patient’s arm measure muscle activations and use these signals to control the prosthetic. Two main advantages of this system include its un-invasiveness and its low cost. Among the disadvantages are the lack of sensory feedback and limited bandwidth. Researchers are currently looking at neuroprosthetics as a new control system in which electrodes are surgically connected to the patient’s nerves. Signals from the nerves can be processed and turned into commands to move the prosthetic. This system could also provide sensory feedback by simulating nerve signals that would be generated by an intact hand.

Control and Sensory Feedback

Myoelectrics

Myoelectrics or electromyography is a very popular choice for controlling prosthetics. To control prosthetic hands electrodes are placed on the skin of the patient's forearm. The electrodes measure muscle activation potentials in the patient's arm. These signals indicate which muscles the patient is willing to activate and with what force. One study found that after a patient has been familiarized with the use of the myoelectric controlled prosthetic, the system can correctly perform the type of grasp the patient wants with an accuracy of 87.67%[1]

There are two main limitations with myoelectrics. Myoelectrics have a limited bandwidth so it can only control a couple of degrees of freedom[2]. People have forearms of various strengths, shapes, and sizes. The muscles in the forearm are not just involved in the motion of the hand they also control the arm. All of these variables decrease the accuracy and consistency of myoelectrics. Also some people have too much of their arm amputated and they do not have enough remaining muscle to control the device. Muscle atrophy is another problem, atrophied muscles do not produce strong enough electric signals to control the device[3].

Among the many advantages of myolecectrics is that it is non-invasive; electrodes are placed on the surface of the skin. Simpler myoelectric systems are very affordable while complicated ones that control more degrees of freedom are more expensive. Most amputees live in developing and third world countries [3]. Myoelectrics is inexpensive and accessible financially for people in these poorer countries.

One of myoelectrics’ greatest shortcomings is its lack of sensory feedback[2]. Researchers have placed sensors on the fingertips of a robotic hand that detect when they are in contact with an object. These sensors then trigger servo motors that apply pressure on the skin at the end of the amputee’s arm. The pressure applied by the servos is proportional to the grasping force measured on the robotic hand. These servos are placed in a pattern corresponding to the fingertips; this provides a similar but displaced sensation on the amputee’s skin[2]. This technology however is not yet available commercially.

Neuroprosthetics

Neuroprosthetics directly read and interpret neural signals as well as produce artificial neural signals. Tactile feedback from a sensorized prosthetic is achieved by characterizing neural signals that are produced in an intact limb and simulating them through electrical stimulation of the residual peripheral nerves[4]. There are several types of receptors in the hands that send various neural signals. All of these signals must be analyzed so a computer model can reproduce them based on inputs from the prosthetic hand[4].

Signals from the amputee’s brain can be read from the efferent nerves and translated into commands to control a prosthetic hand. The control algorithms sort the spikes and noise and generate the commands. Testing has been performed on animals and the results are very promising[5]. A 26 year old human male had his arm amputated after a car accident. He had several electrodes implanted in the remaining part of his arm for four weeks. There weren’t any complications from the procedure and the subject was able to control three different grasps with over 85% accuracy[5].

Neuroprosthetics have great potential but are not commercially available yet. Neuroprosthetics use the body’s nervous system thus the control and feedback mechanisms are very natural. Neuroprosthetics will give an amputee unprecedented control and sensory feedback along with a greater feeling of ownership. Another advantage of neuroprosthetics is the bandwidth, more information can be transmitted using neuroprosthetics than electromyography[5]. This will allow the user to control more degrees of freedom. The greatest disadvantage of neuroprosthetics is that it is invasive. Surgery is required to attach the electrodes to the nerves in the patients arm.

Shear Sensors

In order to provide a sense of touch, sensors are needed on prosthetic hands. Basic touch sensors can detect when they are in contact with an object and how much pressure is being applied. Researchers have recently developed a new sensor to detect shear forces which are lateral forces applied parallel to the surface of the hand. The shear sensors will be able to detect if an object is slipping or deforming. This is crucial when grabbing delicate and oddly shaped objects such as eggs[6]. [5] Accuracy, repeatability, and cost are very important for tactile sensors. This shear sensor is designed for forces up to four Newtons, is accurate, and repeatable. These shear sensors only cost $2 when made in small quantities. If these sensors are mass produced it would drive the cost down[6].

References

  1. Claudio Castellini, Patrick van der Smag, “Surface EMG in advanced hand prosthetics,” Biological Cybernetics, vol. 100, no. 1, pp. 35-47, January 2009.
  2. 2.0 2.1 2.2 Christian Cipriani, Christian Antfolk, Christian Balkenius, Birgitta Rosen, Goran Lundborg, Maria Chiara Carrozza, Fredrik Sebelius, “A Novel Concept for a Prosthetic Hand With a Bidirectional Interface: A Feasibility Study,” IEEE Transactions on Biomedical Engineering, vol. 56, no. 11, November 2009.
  3. 3.0 3.1 Naser Hamdi, Yazan Dweiri, Yousef Al-Abdallat, Tarek Haneya, “A Practical and Feasible Control System for Bifunctional Myoelectric Hand Prosthesis,” Prosthetics and Orthotics International, vol. 34, no. 2, pp. 195-205, June 2010.
  4. 4.0 4.1 Sung Soo Kim, Arun P. Sripati, R. Jacob Vogelstein, Robert S. Armiger, Alexander F. Russell, and Sliman J. Bensmaia, “Conveying Tactile Feedback in Sensorized Hand Neuroprostheses Using a Biofidelic Model of Mechanotransduction,” IEEE Transactions on Biomedical Circuits and Systems, vol. 3, no. 6, December 2009.
  5. 5.0 5.1 5.2 Silvestro Micera, Luca Citi, Jacopo Rigosa, Jacopo Carpaneto, Stanisa Raspopovic, Giovanni Di Pino, Luca Rossini, Ken Yoshida, Luca Denaro, Paolo Dario, and Paolo Maria Rossini, “Decoding Information From Neural Signals Recorded Using Intraneural Electrodes: Toward the Development of a Neurocontrolled Hand Prosthesis,” Proceedings of the IEEE, vol. 98, no. 3, pp. 407-417, March 2010.
  6. 6.0 6.1 Mohsin I. Tiwana, Arridh Shashank, Stephen J. Redmond, Nigel H. Lovell, “Characterization of a Capacitive Tactile Shear Sensor for Application in Robotic and Upper Limb Prostheses,” Sensors and Actuators, vol. 165, no. 2, pp. 164-172, February 2011.