One of the first things people do
before starting their day is take a shower. It is a relatively simple task that
starts with stepping into the shower stall. However, for some, that first step
is a hurdle. For reasons like complications from diabetes or cardiovascular disease,
around 150,000 Americans undergo lower extremity amputation per year (Molina
& Faulk, 2020). According to the National Institutes of Health, lower
extremity amputation is a surgical procedure defined by the removal of limbs
below the hip (Molina & Faulk, 2020).
People with limb differences are
challenged daily from their first step of the day to their last. Fortunately,
research is being conducted to help alleviate their difficulties. Since the late
15th century, prosthetic limbs have been steadily improving. Prosthetic
technology has advanced to the point that healthy individuals with mid-calf
amputation can participate in a full range of normal responsibilities (Marks & Michael, 2001).
However, there are still drawbacks. An above-the-knee prosthetic leg requires 60% more metabolic energy to walk with than a normal leg (Murphy et al, 2017). This is due to the prosthetic limb's passive nature. It cannot generate more mechanical energy than its spring structure can store (Murphy et al, 2017). Thus, despite the strong mechanical dexterity of artificial limbs,
they are still unable to operate without being physically manipulated.
Enter BCIs. Brain-computer
interfaces (BCIs) decode movement intention from the brain to control
movement-evoking stimulation (Samejima et al, 2021). Simply put, BCIs
acquire brain signals, analyze them, and then translate them into commands that
can be picked up by output devices that carry out the desired actions. This
means that with proper integration, a BCI can communicate with a prosthetic
limb. This will allow a person with limb difference to mentally control their artificial
appendage.
The use of BCIs to restore limb
function is not novel. Dr. Soshi Samejima and his colleagues have explored the
use of BCIs to restore upper limb function in rats after a debilitating spinal
cord injury. Using a local field potential-based BCI, Samejima et al decoded
forelimb movement from the sensorimotor cortex, a major brain player in the
execution of movement, and triggered spinal stimulation to restore forelimb
movement (Samejima et al, 2021). Simply put, the spinal cord injury that
paralyzed the rats was overcome.
Now take that idea and implement it
on individuals with amputations. With a BCI, the brain can send the movement signal
to the prosthetic leg, and the prosthetic leg will interpret the data and execute
the movement. This means that instead of the artificial limb reacting passively
to the user’s movement, it will be proactively moving with the person! Not only
that, further improvements on the BCI could allow for dynamic adjusting of the
prosthesis allowing the user to respond effectively to complex environmental
situations.
However, more research is needed. Although
BCIs hold the potential to open the functionality of prosthetic limbs, BCI-controlled
prosthesis still has a long way to go in terms of reliability, dependability,
and adaptability. In addition, prosthetic technology is still not up to par
with the full range of movement of a human leg. Despite this, there is hope
that in the future, individuals with limb differences can start their day
without hurdles and take that first step into the shower stall without a second
thought.
References
Marks, L. J., & Michael, J. W. (2001). Artificial
limbs. BMJ : British Medical Journal, 323(7315), 732–735.
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1121287/
Molina, C. S., & Faulk, J. (2024). Lower extremity
amputation. In StatPearls. StatPearls Publishing.
http://www.ncbi.nlm.nih.gov/books/NBK546594/
Murphy, D. P., Bai, O., Gorgey, A. S., Fox, J.,
Lovegreen, W. T., Burkhardt, B. W., Atri, R., Marquez, J. S., Li, Q., &
Fei, D.-Y. (2017). Electroencephalogram-based brain–computer interface and
lower-limb prosthesis control: A case study. Frontiers in Neurology, 8,
696. https://doi.org/10.3389/fneur.2017.00696
Restoring amputees’ natural
functionality with brain-controlled interfaces. (2021, July 13). MIT News |
Massachusetts Institute of Technology.
https://news.mit.edu/2021/restoring-amputees-natural-functionality-brain-controlled-interfaces-0713
Samejima, S., Khorasani, A., Ranganathan, V., Nakahara,
J., Tolley, N. M., Boissenin, A., Shalchyan, V., Daliri, M. R., Smith, J. R.,
& Moritz, C. T. (2021). Brain-computer-spinal interface restores upper limb
function after spinal cord injury. IEEE Transactions on Neural Systems and
Rehabilitation Engineering: A Publication of the IEEE Engineering in Medicine
and Biology Society, 29, 1233–1242.
https://doi.org/10.1109/TNSRE.2021.3090269
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