Making Prosthetics More Lifelike
Making Prosthetics More Lifelike
David Brockman, a retired CalFire captain and avid outdoorsman, built a deck in the backyard of his home last year, without the use of his dominant right hand, which he lost in an accident. The prosthetic hand he used instead was a crude but functional steel hook-and-harness device.
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Brockman has tried other artificial limbs, including a high-tech prosthesis called a myoelectric. It looks like a hand and works by using electrical signals from muscles in the forearm. But that one just didnt work for him.
Its uncomfortable, and it doesnt function well, Brockman said. It looks nice. Itll open and close, and I dont have to wear a harness. But to be what I am very physical and to be outside working in the yard, raking, doing things like that, it doesnt work.
David Brockman, a retired firefighter and hand amputee, shows off his new myoelectric prosthetic device. UC Davis surgeons performed targeted muscle reinnervation surgery and used smart prosthetics to provide better muscle control, improved sensory feedback and less limb pain for amputees. (Gregory Urquiaga/UC Davis)Rejecting his myoelectric wasnt unusual. Despite the advancements in robotics and other high-tech prosthetics, a recent study found that 44% of arm amputees abandon their devices.
Even though theres amazing dexterous devices that can move in all sorts of ways and look similar and operate similar to an intact limb, being able to tell all of that robotic system how to move and what you want it to do is really where a big barrier is currently in the field, said Jonathon Schofield, assistant professor in the Department of Mechanical and Aerospace Engineering at UC Davis.
Schofield is part of a team of engineers, scientists and surgeons at UC Davis working to make life easier for amputees through a combination of surgery, advanced machine learning and smart prosthetics. Their goal is prosthesis embodiment, to get these devices to mimic a biological limb so amputees gain better muscle control and sensory feedback without increased complexity.
Were trying to fill that gap, Schofield said. Were asking how can we allow someone to think about making a pinching motion or think about making a fist with their missing hand and just let the prosthetic limb do that for them.
Advancing Prosthetics in the Lab at UC DavisBrockman is taking part in an experiment to help the UC Davis group and other researchers advance prosthetics. He now has a new myoelectric prosthetic hand, one much closer to the real thing. It looks like a glove and its fingers can move independently.
Brockman said the new prosthetic hand will make a huge difference in his life.
For me, I love the outdoors. This is a dream come true because Ill be able to grab my fishing pole and reel and grab things again instead of trying to hook it and it keeps slipping off, he said.
Advanced prosthetics difficult to operate
But myoelectric devices, which use muscle activity from the remaining limb to operate, still require a lot of effort to get them to work, said Laduan Smedley, a certified prosthetist orthotist at UC Davis Health.
I describe it somewhat like Morse code, Smedley said. Amputees have to memorize these kinds of patterns of flexion and extension or co-contraction to operate the hand.
One of the newer myoelectric prosthetic hands sits on a workshop table at UC Davis Health. The smarter prosthetic operates like a bionic hand, with five fingers that can move independently. (Gregory Urquiaga/UC Davis) UC Davis Health certified prosthetist orthotist Laduan Smedley is making sure the sleeve of David Brockmans prosthetic hand fits correctly. (Gregory Urquiaga/UC Davis)Some of the more advanced myoelectric hands are more intuitive but require a smartphone app to select the desired type of grasp, such as pinching or gripping.
The UC Davis research group wants to incorporate what scientists know about how humans learn and control movement, said Wilsaan Joiner, a neuroscientist and professor in the Department of Neurobiology, Physiology and Behavior in the College of Biological Sciences.
If youre not utilizing what is a natural ability or natural infrastructure of our motor system to control an external device, its probably going to be incredibly difficult and nonintuitive to learn how to do, Joiner said.
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Amputations improved by targeted muscle reinnervation
Surgeons have led the way to make myoelectric devices easier to use. Not long ago, the standard amputation could still leave patients in a lot of pain. Surgeons cut bone, muscle and nerves to remove a limb. They buried those nerves under muscle or in bone to prevent their endings from growing toward the surface of the skin.
The idea was that if you bury it far away from the skin then patients dont get pain, said Clifford Pereira, an associate professor in the Department of Surgery at UC Davis Health. We found that despite doing that, people still get chronic pain and phantom pain.
Phantom pain can feel like cramps or burning where the limb used to be. Many patients still develop neuromas, where nerves can grow to form a lump of painful disorganized nerve tissue. The pain from neuromas can also make wearing a prosthetic device impossible.
Surgeon Andrew Li shakes the prosthetic hand of former patient David Brockman, a retired fire captain, who had targeted muscle re-innervation surgery on his amputated hand. (Gregory Urquiaga/UC Davis) Cliff Pereira and Andrew Li are both with the Department of Surgery at UC Davis Health. They have performed targeted muscle re-innervation surgery to help amputees control prosthetic limbs more intuitively. (Gregory Urquiaga/UC Davis)Recently, UC Davis surgeons began using a procedure called targeted muscle re-innervation, or TMR. The surgery reroutes severed nerves so that signals from the brain that once controlled the missing limb are picked up by a nearby muscle.
Pereira said its like converting a dumb muscle into a smarter muscle. Amputees only need to think about making a fist or opening their fingers for the movement to occur.
It was originally done to increase the number of muscle signals that a patient could generate after an amputation so there could be more degrees of control of a prosthetic device, said Andrew Li, an assistant professor in the Department of Surgery at UC Davis Health. An unintended benefit was that those patients also tended to have reduced phantom pain and neuroma pain as well.
Advancing Prosthetics in the Hospital at UC Davis HealthArtificial intelligence now used in prosthetic technology
Brockman had TMR surgery at UC Davis Health and is now using a smarter prosthetic device.
They actually call it a bionic hand, Brockman said. Its a working, functional hand. It has five fingers. Its got like 13 sensors built into the sleeve. And it works off a muscle reaction in my arm. So, when I twitch my thumb nerve, which is still there, the prosthetic senses that and the thumb will move.
The prosthetic hand must first learn how to read these signals. This is where artificial intelligence, or AI, plays a role.
The UC Davis researchers are examining the muscle firing patterns of Brockman and others who have had TMR surgery.
Neuroscientist Wilsaan Joiner points to an ultrasound machine. Scientists are using both ultrasound and electromyography, combined with AI, to make prosthetics easier to control. (Gregory Urquiaga/UC Davis) Engineer Jonathon Schofield, left, and neuroscientist Wilsaan Joiner, right, are both working to make prosthetic limbs more intuitive by incorporating what scientists know about how humans learn and control movement. (Gregory Urquiaga/UC Davis)Inside a UC Davis lab, Schofield attached electrodes to Brockmans forearm using an electromyography machine, which records the muscles electrical activity. He asked Brockman to make several different hand gestures, and the computers programming begins to recognize those patterns.
Electromyography can sometimes confuse electrical signals from other muscles, so the scientists are also using ultrasound machines that use sound waves to produce images. When Brockman contracts a muscle, it becomes denser and bounces back more sound.
The researchers are combining all this technology and data with AI in the hope that prosthetics will become more intuitive for the user.
Were leveraging artificial intelligence, machine learning algorithms that are looking at the muscles that remain in that persons residual limb, Schofield said. Its learning what that activity looks like when amputees wanted to pinch or make a fist or make a pointing motion.
Can prosthetics feel?
Surgeons are hoping to advance prosthesis embodiment by enabling users who lost their sensory nerves to gauge temperature and pressure. They may be able to do with sensory nerves what they did with motor nerves in the targeted muscle re-innervation surgery connect the severed ones with those in the overlying skin. If the artificial hand is touched or gets hot, it sends that signal to the skin of the amputee.
Amputees also have difficulty sensing body position and movement with a prosthetic device. But researchers said one way to overcome that is to integrate prosthetic devices into the body, like a human machine. The concept, called osseointegration, is the next step in smart prosthetics.
Peyton Young, a UC Davis Ph.D. candidate in Jonathon Schofields lab, demonstrates how electromyography works using a robotic arm. The robotic arm recognizes the electrical signals from his forearm muscles and it moves accordingly. (Gregory Urquiaga/UC Davis)Osseointegration is making the prosthetic device essentially heal into the bone and become a weight bearing proprioceptive structure, said Li, the UC Davis hand surgeon. You can still take it off, but its much more a solid component of your body that could potentially make things a lot more intuitive, a lot more natural, like picking up heavy things, doing pull-ups potentially.
The Integrum OPRA osseointegrated implant for above knee amputations is Food and Drug Administration approved and allows direct integration between bone and the surface of a prosthetic device. UC Davis is now actively recruiting patients for the surgery.
David Brockman with his wife, Tereasa Brockman, at UC Davis after David had a fitting for his prosthetic hand. (Gregory Urquiaga/UC Davis)Related Stories
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Clifford Pereira (Plastic Surgery), Gavin Pereira (Orthopedic Surgery) and Jonathon Schofield (College of Engineering) invented and successfully tested a novel device to reconnect blood vessels for revascularization during surgery.
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Life and Limb | Harvard Medicine Magazine
You wont see World War II veterans with these injuries. You wont really see Korea or Vietnam veterans with these injuries, says Gregory Galeazzi. Plenty of them got them; they just didnt survive them. Even though medicine has advanced, the majority of people who get these injuries still die on the battlefield.
But for a select few, he adds, theyre able to piece us back together. They send us out to be socially active and return to the workforce.
Galeazzi, MD , was a captain in the U.S. Army when he became one of the select few. During a routine patrol in Afghanistans Kandahar Province in May , a roadside bomb blew off both his legs and nearly severed his right arm at the shoulder. Without the swift action of his fellow soldiers, who applied tourniquets and rushed their semiconscious platoon leader into a medevac, Galeazzi would have perished.
Instead, after more than fifty surgeries and hundreds of hours of physical therapy, Galeazzi is completing his first year as a medical student at HMS.
The estimated 1,800 U.S. military amputees returning home from recent conflicts in Iraq and Afghanistan have been injured to an extent rarely seen before. Although the technical sophistication of prostheses has grown over the centuries, artificial limbs have yet to attain the capabilities of natural ones. To support work toward that goal, the Department of Veterans Affairs and the Department of Defense fund the lions share of prosthetics research in the United States.
While Galeazzi attends class and clinic, scientists and clinicians throughout the HMS community are furthering the national effort by engineering prosthetic arms and legs that behave more like natural ones, pioneering brain-machine interfaces that create more intuitive connections between the nervous system and the prosthesis, and developing surgical techniques that allow for unprecedented prosthesis control and sensory feedback. Their work could benefit not only veterans but the other 98 percent of the two million people in the United States with limb loss due to diabetes, congenital conditions, cancer, and trauma, including accidents.
Perspective Shift
As innovations move from investigational stages to approval by the U.S. Food and Drug Administration, the broadening menu of options for amputees is changing millennia of clinical thinking.
Historically, amputation has been viewed in the medical realm as a failure, says Matthew Carty, an HMS associate professor of surgery at Brigham and Womens Hospital, who is pushing the frontiers of amputation techniques and limb transplantation. We need to talk about it as a reconstructive procedure and even a form of limb salvage. Physicians and patients need to consider the fact that amputation may be a faster and more effective pathway to better function and better life.
The biggest change Ive seen in recent years is the societal understanding that losing a limb is not the end, says David Crandell, an HMS assistant professor of physical medicine and rehabilitation at Spaulding Rehabilitation Hospital. Crandell managed the care of fifteen patients who underwent amputations following the Boston Marathon bombing. People accept that technology can be part of the solution.
In Search of the Natural
Because of his battlefield injuries, Galeazzi ended up with two transfemoralabove the knee, through the femuramputations. Doctors salvaged his arm and fused the elbow. He worked up to wearing prosthetic legs for a few hours each day until a series of health setbacks and the demands of premedical studies derailed his progress. He lost so much bone density in his hips and spine that he fractured two vertebrae in a fall in early . Now he uses a wheelchair, and hes concerned that his reduced physical activity will affect his overall fitness.
It took a ridiculous amount of energy to move those prostheses around, he says. I was sweating just going from the couch to the bathroom and back.
The Empower ankleAmputees confront dozens of potential health complications, from muscle atrophy and residual-limb infection, to low back pain and osteoarthritis from unnatural movement, to cardiovascular and metabolic disease from inactivity. Amputees who lose limbs in sudden events, losses known as traumatic amputations, often struggle with additional serious injuries, such as hearing damage, burns, and traumatic brain injury.
Developers of modern prostheses aim to alleviate some of these consequences and reduce pain by better mimicking the bodys natural biomechanics and improving walking efficiency. Experts estimate, for example, that walking with a traditional prosthesis takes about twice as much effort and is one-third slower than walking on two natural legs. Each step jars the body and dissipates energy by sending it into the ground rather than helping it rebound into the body. The advent of springy modern materials like carbon fiber started returning some of that energy to the wearer. Moreover, in the past fifteen years robotic components have begun to restore a physiological pattern of motion, says Paolo Bonato, an HMS associate professor of physical medicine and rehabilitation at Spaulding and director of the hospitals Motion Analysis Laboratory.
One prothesis with robotic components, the PowerFoot BiOM, was created by Hugh Herr, PhD 98, an HMS lecturer on physical medicine and rehabilitation at Spaulding and director of the MIT Media Labs Biomechatronics group. Bonato was involved in testing of it.
When an amputee steps down on this bionic prosthesis, springs that mimic tendons compress and store energy; when the wearer pushes off the ground, a battery-powered motor taps that stored energy and, like a muscle, propels the user forward with twice the energy of a natural leg. The device, which melds biology with technology, was the first to allow the prosthetic foot to flex in a physiological manner. It also incorporated microprocessors that adjust for speed and incline. Studies by Bonato and others indicate that the prosthesis, marketed as the Empower ankle, improves walkers balance, speed, and energy expenditure.
Imagine youre forced to walk around in clunky, stiff cowboy boots, and then suddenly youre given lightweight Nikes and you can use your ankles again, says Herr, who uses the BiOM. Its as distinct as going through the airport and hitting the moving walkway. Its exhilarating. Herr has been a world leader in bionic limb development since he lost both legs below the knee to frostbite in a mountain climbing trip.
Herrs group continues to collaborate with Bonatos to conduct complex analyses of human movement and energy expenditure, both to inform limb design and to gauge the success of those designs. Sometimes that means generating data on the intricate mechanics of a knee or studying muscle synergies in a reaching arm. More often, it involves measuring and modeling patient kinetics in the lab or sending patients home with wearable sensors to determine how well their prostheses work for them.
Not only will analyses inform the next generation of prosthetic limbs, but evidence of their health benefits could also expand access to them.
Restricted Movement
As medical director of the amputee care and adaptive sports programs at Spaulding, Crandell has seen his share of insurance denials for high-end prostheses. He chafes at some of the decisions on who deserves the best technology.
Function and fairness are real societal issues, he says.
When a computerized, battery-powered titanium leg can cost $75,000, only about 15 percent of amputees in the country, mainly those with amputations covered by VA or workers compensation policies, have a chance of having the cost covered. That group, however, is far outnumbered by the 54 percent of U.S. amputees who, according to the Amputee Coalition, have lost limbs to diabetes and other vascular diseases.
So far, people with diabetes who have had a lower-limb amputation, often older and in poor health, are not considered good candidates for advanced prostheses. Crandell and Bonato challenge this view. Theyre experimenting with providing such patients with the best available technology, hoping that an easier-to-use prosthesis will encourage them to move more. If the program reduces complications such as second amputations, which occur in about 60 percent of people who lose one foot to diabetes, the researchers think insurance companies might reconsider their calculations.
Their hope may not be misplaced. Herr and colleagues nationwide recently got the U.S. Centers for Medicare & Medicaid Services to create a reimbursement code for bionic prostheses. The scientists plan to gather more data demonstrating improved gait and health to convince CMS to finalize coverage and pricing.
By Leaps and Bounds
Just before Darth Vader delivers shocking news to Luke about the Skywalker family tree in Star Wars: The Empire Strikes Back, he slices off Lukes hand with a lightsaber. Vaders revelation seems more traumatic for Luke than the loss of an extremity. It helps that hes quickly fitted with a lifelike bionic prosthesis, one so sensitive it can detect the prick of a needle.
Shriya Srinivasan (left) and Matthew CartyThe scene made a lasting impression on Crandell, who first saw the movie while in high school. The future the scene depicted may, in fact, be near. I cant prescribe it yet, but I think the capacity for sensory feedback will exist in upper-limb prostheses in the next five years, Crandell says.
Although upper-limb prostheses have had their breakthroughs in the past half-century, they largely havent progressed beyond hook hands. Amputees still give up on them at significantly higher rates than they do on legs. To close that gap, since DARPA has put more than $100 million into its Revolutionizing Prosthetics program for projects that focus on upper-limb development. That effort produced the DEKA Arm, renamed the LUKE Arm in honor of Skywalker. Approved by the FDA in , the motor-powered above-elbow prosthesis has 10 degrees of freedom, six different hand grips, sensor-assisted feedback on grip strength, and the capacity to respond to wearer needs by moving multiple powered parts simultaneously rather than sequentially. Researchers are exploring new ways to control the DEKA Arm; HMS engineers are using it in brainmachine studies. A second arm being funded by DARPA uses electrodes implanted in both the brain and the residual limb to attempt neural control and sensory feedback.
At Spaulding, Bonato is collaborating with colleagues at Northeastern University on the development of a National Science Foundation-funded prosthetic hand controlled by a combination of muscle signals from the residual limb and electrical activity in the brain, as captured by electrodes embedded in a cap. The team is also adding cameras to prosthetic arms and using image-processing software to create prosthetic hands that anticipate what the wearer wants to do.
If Im approaching a button, Bonato says. I probably want to push it. You begin to narrow down the likely movements a person might want to perform.
For legs as well as arms, the higher the amputation occurs on the limb, the harder it is to restore full function.
Knees and elbows make all the difference in the world, says Galeazzi.
A shorter residual limb has more prosthesis to haul around and fewer muscles and nerves with which to manipulate it. Multiple jointselbow and wrist and fingers, or knee and anklemust coordinate, and legs often need to coordinate with each other. The Herr lab is working on a power knee to join the Empower ankle as well as prosthetic leg enhancements that scan the terrain ahead and preemptively adjust power and angle.
"The blistering rate of miniaturization of cell and computer technology means engineers can pack a lot into the small space of a prosthesis."
The blistering rate of miniaturization of cell and computer technology, with incredibly powerful microprocessor capabilities and accelerometers and so on, means engineers can pack a lot into the small space of a prosthesis, says surgeon Carty.
Re-enabling basic activities may not be enough as amputees demand higher performance from their prostheses. Adults and children are 3-D printing limbs with custom features like water guns and vital-sign monitors. Kids are building and programming modules made of Legos to make their bionic hands perform different tasks. Typically young and fit, traumatic amputees itch to dive back into their active lives. The number of amputee soldiers able to requalify for active service rose from 2 percent in the s to 16.5 percent by , according to a study in The Journal of Trauma: Injury, Infection, and Critical Care.
A lot of elderly amputation patients just want to walk between the bed and the toilet, says Galeazzi. We want to walkand climb mountains, and snowboard, and run marathons, and surf. Ive seen guys with the most advanced prostheses on the market come back after a weekend with the things snapped in half. They tell their prosthetists, You have to do better.
Redirects
Although survival rates and prosthetic technologies have improved over the centuries, the surgical procedure for amputation has remained essentially the same.
"We see surgical manuals from the Civil War era and from a textbook and the surgical techniques are nearly identical."
We see surgical manuals from the Civil War era and from a textbook and the surgical techniques are nearly identical, says Shriya Srinivasan, a PhD candidate in the MIT-Harvard Program in Health Sciences and Technology, who is based in the Herr lab.
The standard technique of cutting a cross-section through the soft tissues before sawing off the bone means that severed nerves in the residual limb become unmoored, firing confused signals and often forming painful growths, while muscles that normally act in concert get disconnected. This shattering of physiology also prevents patients from taking full advantage of sophisticated prostheses.
We havent asked much of the residual limb in the past, says Carty. Todays technology demands more from it.
Carty has joined forces with Srinivasan, Herr, and others to develop an alternative technique that preserves more of the limb s normal tissue relationships. They started with below-knee amputations. Carty takes tendons from the amputated ankle, anchors them to the residual tibia, and uses them to stitch together the ends of two muscles from the front and back of the leg so that when one contracts, the other stretches, as would occur in a normal leg.
The nerves that supply these muscles send clearer signals than those in traditional amputation and can receive basic signals in return. Implanted electrodes facilitate crosstalk between muscles, nerves, and prosthesis.
Following the Civil War, the artificial legs manufactured by the Salem Leg Company were recommended for Army use by the U.S. government. The companys president was Edward Brooks Peirson, Class of .The researchers named the procedure AMI (pronounced Amy), for agonist-antagonist myoneural interface. They published a proof of concept in rats in and have now performed the operation on six human patients. What theyre seeing is promising. Patients have less pain and more natural function when using standard prostheses than do individuals with traditional amputations. Those who try advanced prostheses enjoy more intuitive control and greater range of motion. The procedure also restores a measure of proprioception, giving patients who wear a prosthesis a sense of its position without having to look. The team hopes it will also reduce phantom-limb pain.
Herr recalls the moment when the first AMI recipient attempted stairs in a lab test. The toe of his Empower ankle automatically pointed down to meet each step.
We were shocked, Herr says. He could feel the prosthetic joint, and his brain and spinal cord knew what to do.
Carty says the AMI technique may be able to be done as revision surgery in old amputations or in traumatic amputations. The main limitations are that it can t be performed on patients with nerve or vascular problems, such as diabetes. Because the procedure doesnt involve any new or difficult surgical techniques, Carty is optimistic that it could be broadly adopted.
Carty and colleagues now have a proposal in IRB review to combine AMI with osseointegration, an experimental technique that attaches a titanium post directly to the bone in the residual limb. In place of the typical sleeve-and-socket attachment worn over the limb, the prosthesis latches onto a portion of the post that extends through the skin. The technique, devised by a pioneer of dental implants, Per-Ingvar Brånemark, has been undergoing tests with patients in Europe. In legs, osseointegration allows bone rather than soft tissue to bear the bodys weight and transmits a better feel for whats underfoot. In arms and legs, the method could ease pain, reduce skin chafing and breakdown, and allow wearers to pursue activities that might cause a suction-adhered prosthesis to fall off. The main concern is risk of infection. The first U.S. trial to assess safety and feasibility began at the VA Salt Lake City Health Care System in .
Mind Meld
Some HMS researchers seek to link prosthesis control directly with the brain.
Leigh Hochberg, an HMS senior lecturer on neurology, part-time, and director of the Center for Neurotechnology and Neurorecovery at Massachusetts General Hospital who also holds appointments at Brown University and the Providence VA Medical Center in Rhode Island, is principal investigator on an investigational brain-computer interface called BrainGate, a technology that aims to restore communication between the brain and either external devices or muscles in patients with conditions such as spinal-cord injury, brain-stem stroke, and amyotrophic lateral sclerosis.
To achieve the interface, a small electrode chip is implanted in the participants motor cortex, located at the top of the brain, to record the activity in a few dozen neurons. A small titanium pedestal attached to the skull conveys the neurons low-microvolt signals, which are then amplified and sent to a computer, where algorithms decipher the participants intention, for example, to move their hand up and to the right. The commands then get transmitted to a computer screen, a robotic or prosthetic arm not connected to the body, or to the participants own arm muscles via a separate muscle stimulation system.
The technology is exciting but still in its early days, Hochberg and others note. To capture all the data being transferred, the titanium pedestal is thus far physically connected to a computer. Although these trials are taking place in participants homesexactly where, Hochberg says, clincially relevant technologies need to prove their utilityHochberg and his BrainGate colleagues are actively working toward wireless implementation, a fully implantable version of the system, and improvements that would enable patients to use the system without research-team supervision.
Synthesis
Crandell sees more trainees each year who come into physical medicine and rehabilitation wanting to work with amputee populations. Interest also appears to be growing in other parts of the medical community. In addition to serving patient needs and driving new technologies, some are drawn to prosthetics development for the opportunity to collaborate with a range of specialists: mechanical, electrical, and tissue engineers; physicians and surgeons; neuroscientists, biologists, bioinformaticians, roboticists, nanotechnology specialists; prosthetists; and physical and occupational therapists.
While the bulk of projects are designed to improve devices and the way they interface with the body, others aim to reduce the need for prosthetic limbs. HMS surgeons have conducted successful single- and double-arm transplants. Carty now leads an effort to perform the nations first lower-limb transplant. Stem cell scientists are pursuing regenerative medicine to one day grow biological limbs.
Significant as those changes would be, people who have already had amputations dont want to be left behind if they dont want or do not qualify for advanced procedures, or if they represent too small a market for prosthetics development. We dont want to become the lost generation, says Galeazzi.
The outlook among HMS researchers is optimistic for all amputees for at least two reasons. First, no single solution will be right for everyone.
We have to ask what will give each patient the highest level of function and quality of life: multiple surgeries for limb salvage, a prosthesis, a transplant? says Carty.
Second, some hold that biology isnt necessarily better than synthetics.
Im not cellular- or tissue-centric, says Herr. Prostheses are part of the human story. Its not something well eliminate when we figure out how to do it with cells. In the future, we'll be hybrid.
In many ways, were already hybrid. Prosthesesdevices that support or replace body parts or functionsinclude not only limbs but hearing aids, cochlear implants, eyeglasses, dentures, pacemakers, and artificial knees and hips. Massachusetts Eye and Ear ophthalmologist Claes Henrik Dohlman developed an artificial cornea, the Boston Keratoprosthesis, in . Neurosurgeon Shelley Fried at Massachusetts General Hospital and the Boston VA is designing retinal implants. An HMS team at Beth Israel Deaconess Medical Center pioneered 3-D printed molds for airway prostheses, stents that hold open patients tracheas. Last year, Harvard engineers built artificial muscles for soft robots. As much as half the human body can be replaced right now with artificial components.
For his part, Galeazzi wants the option of switching between a wheelchair and prosthetic legs; the first helps him travel long distances, the second would make it easier for him to navigate narrow exam rooms.
Although prostheses and alternatives have come far, theres still ground to cover before every patient shares the sentiments of the amputee featured in The One-Legged Man, a poem by English poet Siegfried Sassoon. After losing a limb in the Great War, the poems narrator reflects in his elder years: Thank God they had to amputate!
Stephanie Dutchen is a science writer in the HMS Office of Communications and External Relations.
Images: iStock; courtesy of Ottobock (Empower ankle); John Soares (Carty and Srinivasan); Francis A. Countway Library/Boston Medical Library collection
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