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A prosthesis is an artificial substitute for a missing body part.
A lower limb prosthesis refers to a prosthesis that replaces any part of the lower limb to restore the functional and/or cosmetic purpose of the lower limb. This may include artificial components that replace the hip, thigh, knee, ankle and foot.
(Photo credit Hanger Clinic)Pre- prosthetic training
After the patient has an amputation in the lower extremity, they will remain in the acute care hospital until they are medically stable. After that time they may be either transferred to a skilled nursing facility (SNF), acute inpatient rehabilitation facility or discharged home with homecare services. The patients that are discharged to acute rehabilitation facilities often have better functional outcomes than those patients with any other discharge destination.(1) During the initial time after the acute care hospital the focus is to determine if the patient is a candidate for a prosthesis based on their functional level, potential for progress and to prepare the residual limb for a prosthesis if the patient is a candidate. This includes training in mobility and activities of daily living (ADLs) without the prosthesis, education in skin care, muscle strengthening, pain reduction and management and also shaping and shrinking of the residual limb. Specifically, early range of motion and desensitization of the scar from the amputation are important. There are many different options for discharge after the acute hospital care stay, however, receiving inpatient rehabilitation care immediately after acute care was associated with reduced mortality, fewer subsequent amputations, greater acquisition of prosthetic devices, and greater medical stability than for patients who were sent home or to an SNF.(1) Acute inpatient rehabilitation facilities stabilize chronic problems such as renal failure and diabetes and optimize surgical wound management which may lead to improved outcomes.
Prosthetic Evaluation
Initial evaluation to determine if a patient is a candidate for a lower limb prosthesis should include the following assessment of the patients history:
The patient must also be physically and mentally evaluated to determine the appropriate prosthetic prescription, complete assessment includes:
Based on the above gathered information, physical examination, and potential for progress, the amputee patient is classified to a particular functional level. The K levels were adopted by the federal government to clarify which lower limb prosthetic components (knee, foot, and ankle) should be used for patients depending on their functional levels. The higher the K level the more potential for prosthetic ambulation.
K level Description K0 Does not have the ability or potential to ambulate or transfer safely with or without assistance, and a prosthesis does not enhance quality of life or mobility. K1 Has the ability or potential to use a prosthesis for transfers or ambulation on level surfaces at fixed cadence. Typical of the limited and unlimited household ambulator. K2 Has the ability or potential for ambulation with low-level environmental barriers such as curbs, stairs, and uneven surfaces. Typical of the limited community ambulator. K3 Has the ability or potential for ambulation with variable cadence. Typical of the community ambulator who can traverse most environmental barriers and has vocational, therapeutic, or exercise activity that demands prosthetic utilization beyond simple locomotion. K4 Has the ability or potential for prosthetic ambulation that exceeds basic ambulation skills, exhibiting high-impact, stress, or energy levels. Typical of the prosthetic demands of the child, active adult, or athlete.The initial prosthetic fitting
When preparing a patients residual limb for a prosthesis the process includes healing, shrinking and shaping the residual limb appropriately with the use of ace wraps and eventually an elastic shrinker. During this period often the patients residual limbs are protected in a rigid protective device.
(Photo credit Hanger Clinic)The goal of the shrinking and shaping process varies depending on the type of amputation. When there is a plateau in the day to day change in shape of the residual limb the patient with a lower-limb amputation is prescribed and measured for their initial prosthesis. In the past, this was referred to as preparatory or temporary prosthesis, although with the advancement of prosthetic technology this prosthesis is still custom made and can be used for quite some time. It is designed to be strong and can be adjusted for alignment, fit, componentry, etc. With this prosthesis, the patient typically will work with physical and occupational therapists with the goal of achieving independence in ambulation and ADLs with the prosthesis. While the patient uses this initial prosthesis, the residual limb is expected to continue to shrink, but at a slower pace, and sometimes the shape will change as well. The prosthetic socket often needs to be replaced as the residual limb shrinks, usually within the first 6 months to a year after amputation. When needed, a definitive prosthesis is prescribed. This term was often used in the past to describe when the socket, alignment and componentry were no longer requiring change, so that a cosmetic cover could be applied. Most patients at this time choose not to cover their prostheses but to leave the componentry visible. The general publics acceptance has grown, and this is much more practical for prosthetic management, as continued changes are often necessary. Currently, the semantics of temporary and definitive prosthesis have fallen by the way-side, as most patients will use their initially prescribed prosthesis until a new one is needed.
The prosthesis prescription
The level of amputation determines which components of the lower extremity prosthesis will need to be prescribed. The two most common lower extremity amputations are the transfemoral (above the knee- AK) and the transtibial (below the knee- BK). The major components of a lower limb prosthesis include the socket, interface (where the liner contacts the skin), suspension, pylon/frame, knee unit (if applicable), foot/ankle complex, hip joint (if applicable).
Prosthetic interface: The interface is where the prosthesis contacts the residual limb; this can be made of either a soft or hard material. Some common interface options are: pelite liners, urethane liners, thermogel/gel liners, silicone liners, or a hard interface directly with the socket.
Pylon/frame: The prosthetic frame is the method of connecting the prosthetic components together. There are two main types: exoskeletal or endoskeletal. The exoskeletal construction is infrequently used in current practice. This design uses a rigid exterior lamination from the socket down and has a light-weight filler inside. The endoskeletal construction is the most commonly used type of prosthetic frame. This construction uses pipes called pylons to connect the prosthetic components. The pylons can be constructed from aluminum, titanium, stainless steel or any hybrid of these materials.
Hip disarticulation and hemipelvectomy prostheses
The socket encases bilateral iliac crests in the hip disarticulation patient and utilizes abdominal compression in the hemipelvectomy patient. These prostheses must include a hip joint, which may be a ball-and-socket joint or single-axis.
Transfemoral Prostheses
Transfemoral Socket Designs
1. Quadrilateral socket is an older socket design that is relatively narrow anterior-to-posterior, with a posterior shelf to enable weight bearing on the ischium.
(Photo credit Hanger Clinic)2. Ischial containment socket is more ovoid in shape, with a smaller mediolateral dimension. The posterior and medial walls encase the ischial tuberosity. When compared with the quadrilateral design, the ischial containment socket may distribute pressures more evenly. There are also several variations of this socket, including a flexible inner socket within a rigid frame. One example is the comfortflex socket from Hanger Clinic.
3. Sub-ischial socket the trimline of this socket falls distal to the ischial tuberosity and relies completely on the thigh musculature for weight bearing.
Transfemoral Suspension
1. Suction is a common choice for transfemoral suspension, utilizing a one-way valve and liner with concentric rings.
2. Elevated Vacuum Suspension is a derivative of the suction suspension; air is actively drawn from within the socket environment.
3. Distal suspension with a pin or lanyard is another option.
4. A pelvic band or silesian belt may be used as the primary suspension or as auxiliary suspension in some patients.
Prosthetic Knees
Knee disarticulation prostheses
This level of amputation preserves the femoral condyles, which allows for supracondylar suspension and a long lever arm. However, the functional length of the thigh becomes much longer when the socket and prosthetic knee are added. This can be partially compensated for by utilizing a low-profile polycentric knee.
Transtibial Prostheses
Transtibial Socket Designs
1. Patellar tendon-bearing socket has an inward contour that uses the patellar ligament as a partial weight-bearing surface. Despite the name, this socket design aims for a total-contact fit and involves weight-bearing throughout the pressure-tolerant areas of the residual limb, including the medial tibial flare and the popliteal fossa region. Raising the proximal trim line of the medial-lateral dimension to above the condyles, additional support for the residual limb is provided with added suspension this raised trim line is classified as a supracondylar/suprapatellar socket.
2. Total surface-bearing socket is designed to distribute pressure more equally across the entire surface of the residual limb, including carrying some of the load on pressure-sensitive areas.
Transtibial Suspension
1. Supracondylar cuff or strap may be helpful for patients with very short residual limbs or may be used as auxiliary suspension in some patients.
2. As noted above, a supracondylar/suprapatellar socket provides supracondylar suspension by encompassing the medial and lateral femoral epicondyles within the socket.
3. Supracondylar Pelite liner with compressible or removable wall: pelite is a type of expanded cross-linked sponge foam which is shaped to fit to residual limb to provide cushioning inside the socket.
4. Auxiliary suspension sleeve, provides additional support to the primary suspension and holds the prosthesis on with material such as neoprene or gel type sleeves.
If you are looking for more details, kindly visit hip axis.
Additional reading:5. Liner with pin-locking mechanism, a silicone liner with a distal pin system is donned over the residual limb. The pin system consists of a metal or plastic disc with a metal pin in the center. The pin then locks into the bottom of the prosthetic socket.
6. Suction with or without liner, utilizes a one-way valve and slight negative pressure to hold the prosthesis on the residual limb. Another option is a special liner with several concentric rings to create the seal; this eliminates the need for an additional suspension sleeve.
7. Electric vacuum pumps: Suction creates a very secure fit but can be compromised by small holes in the suspension sleeve; the suspension sleeve also increases bulk behind the knee, especially in positions of knee flexion.
8. Thigh corset with side joints may be considered in long-time prosthesis wearers who prefer this style, or those with poor mediolateral stability due to derangement of the knee ligaments. This is an older mode of suspension. It is sometimes considered where additional off-loading of the residual limb is needed such as in a patient with a hypersensitive residual limb, or a residual limb that does not tolerate full weight bearing
Symes and ankle disarticulation prostheses
This amputation level has the advantage of a long lever arm and allows some distal weight-bearing without a prosthesis. The distal residual limb is bulbous due to the presence of the malleoli. Because of the increased length of the residual limb, fitting a prosthetic foot can be challenging. Fortunately, there are several options of low profile feet.
Prosthetic Foot/Ankle
Partial foot prostheses
The various levels of foot amputations may require toe fillers and shoe modifications. Many studies have demonstrated that these can assist in gait mechanics and prevent skin break down and peak plantar pressures specifically studies have recommended: the full length shoe, total contact insert, and Rigid Rocker Bottom sole for most patients with Diabetes Mellitus and Transmetatarsal amputations.(4) One group also described the benefits of a transmetatarsal prosthesis with a carbon fiber plate that improved functional outcomes as well.(5)
Additional componentry considerations
Vertical shock pylons decrease the impact of initial contact.(6) Torsional adapters allow motion in the transverse plane to simulate tibial rotation.(7)
The Genium
(Photo credit Hanger Clinic)by Otto Bock has several features that have biomechanical advantages over the older microprocessor knee designs, including the ability to ascend stairs step over step. A military-grade version of this knee joint, the X3 is ideal for physically demanding occupations, an active family life, swimming, sports activities, and situations where you encounter water, dust, sand, dirt or grime.
Microprocessor feet are becoming more widely used, as well as those that are powered.
Osseointegration is the practice of placing a titanium implant directly into the long bone of the residual limb after amputation, extending outside of the skin. The prosthetic limb can attach directly to it, eliminating the socket-skin interface. This is still in the development stage in the United States and mostly performed in the United Kingdom, Germany, and Canada.
Sports prostheses can include specialized components for running, cycling, swimming, and many other activities. Prescription and fabrication of these prostheses requires close collaboration between the physiatrist, prosthetist, and patient, in order to meet the demands of the athletic activity and the patients desired outcome.
3D printing and Lower extremity prosthetics
3D printing for prosthetic fitting and fabrication began with Ivan Owen, a Bellingham, Washington puppet-maker and Richard Van As, a South African carpenter that had lost some of his fingers. The two developed the first 3D printed prosthetic hand. Initially, 3D printing began with upper extremity prostheses, recently this has progressed to lower extremity prostheses. Currently, some components of the lower extremity prostheses are able to be 3D printed. SHC Design is a Japanese company with a focus on manufacturing prostheses using 3D printing technologies.(8) Another company Art4Leg is designed to work with an amputees current, standard prosthetic leg and designs custom artistic covers for lower extremity prostheses.(8)
Bionic prostheses
Össurs commercially available Bionic prostheses are smart limbs capable of real-time learning and automatically adjusting to their users walking style (gait), speed and terrain.(9) Walking with a Bionic prosthesis, however, still typically requires some conscious, intentional thought from the user. Recently, two amputees were the first people in the world able to control their Bionic prosthetic legs with cortical control. This was accomplished via tiny implanted myoelectric sensors (IMES) that have been surgically placed in their residual muscle tissue.(9) The IMES, instantaneously triggers the desired movement, via a receiver located inside the prosthesis. This process occurs subconsciously, continuously and in real-time.(9)
Cambridge Bioaugmentation Systems (CBAS) and their prosthetic interface
The Prosthetic Interface Device (PID) is like a USB connector for the body.(10) This integrates with a residual limb through direct implantation into the bone (osseointegration) and electronic connection with the nerves. The hope from this company for this device is to allow full functionality through conscious control of the prosthetic limb and allows sensation to be fed back to the brain.(10)
It is important for physicians caring for patients with amputations to understand the evidence base for their prescriptions and determine the best prosthesis for each patient. Many decisions are made based on expert opinion and the best practice of the experienced prosthetic team. It will be important for physicians to be involved in continued research to demonstrate the advantages and disadvantages of various prosthetic components, especially from a functional and clinical perspective.
There is much about the prosthetic componentry that has been elucidated, but more that still remains to be discovered, such a building a more affordable prostheses, more comfortable, and more durable. One study described comfort and durability being most important to patients with amputations. (11) These are areas that can continued to be improved. Also, from a monetary standpoint many prostheses that are currently available are a significant sum of money, further research needs to be done as to how to create more affordable options. As technology advances it is key that the practitioner utilize an evidence-based approach to best care for their patients with amputations, depending on the etiology of the amputation there different health concerns that need to be addressed (e.g. in patients with amputations caused by diabetic ulcers, wound healing may be more of a concern than a patient with a traumatic amputation). In conjunction with new materials for prosthetics being available there have also been additional methods of gait training.(12) Overall, the practitioner and the patient remain a team, with the common goal of achieving the best overall outcomes.
Bradeigh S. Godfrey, MD. Lower Limb Prosthetics. 9/20/
Karen M. Pechman, MD
Nothing to Disclose
Tiffany M. Lau, MD
Nothing to Disclose
The technological advancement in the architecture of prosthetic legs is amazing. One hundred years ago, they could never imagine the intuitiveness or sleek look of prosthetics and would not have had the materials to make anything that worked well. They would resort to something as simple as a wooden table or chair leg. As you can imagine, they werent very comfortable or clean. Now there are many different kinds to choose from, based on the activity level one is seeking. To understand prosthetic legs, these are the four basic components you should know.
1. Socket
A socket is a device situated between the residual limb and the prosthesis. Its highly specialized to an individuals needs for comfort based on the structure of the residual limb. Its very important that this fits perfectly to maximize comfort. Often, when getting fitted for a socket, you will first wear a clear socket in order to have a better picture of the fit.
It will also come with a liner that will make the socket more comfortable, just as a sock would for a shoe.
2. Limb
This is the main part of the prosthesis. There are two common types that are used for legs.
The design of it will be dependent on each individual and their preferences.
3. Knees and Feet
Knees are only needed with the above the knee limbs (AK). There are a variety of knee options based upon preference. The two most basic kinds are called: single-axis and polycentric axis. The single-axis is designed so that the knee only bends backward and forward. Polycentric axis knees can move in multiple ways.
The feet are typically designed to be very light, to compensate for the heavier weight of the rest of the prosthesis. It should be small enough to fit in a shoe, but durable enough to keep up with each individuals level of activity whether its walking, running, hiking or jumping.
4. Structural Components
The structural components of artificial legs are simpler than an upper limb. They have the advantage of gravity to do a lot of the natural motions. For those who desire more advanced structures, there are microprocessor-controlled ankles and knees. Adjustments are made frequently to ensure comfort and safety. For example, some may not like the vacuumed feeling in the socket and may prefer a belt or a strap to hold the prosthesis in place.
Our goal is to bring you comfort, security and continued independence. Contact BioAdvance today to learn more about our services.
For more information, please visit locking of knee joint.
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