Prosthetic Modifications for the Treatment of Marginally Viable Below-Knee Amputations
Kevin S. Garrison, C.P.
Fig 1. A maginally viable below the knee amputation showing slow healing suture line and pressure sore.
When one is confronted with a marginally viable below-knee amputation which has an open suture line or other epidermal problems related to post-operative treatment, what is the best prescription for these patients prior to temporary prosthetic fitting? This type of residual limb is found mostly with geriatric amputees, and is often complicated by paraesthesias associated with Diabetes Mellitus (Fig. 1 ).
The ultimate goal for the prosthetist is to produce a snugly fitting, carefully contoured socket, which offers the maximum amount of area for weight bearing. This leads to better control and comfort while ambulating on a lightweight prosthesis. This is a goal which may be achieved by utilizing special modifications to the prosthesis, thus allowing these types of amputees to progress rapidly and comfortably throughout their prosthetic rehabilitation.
Joints and Corsets
Fig 2. A completed below the knee prosthesis utilizing polypropylene knee joints and Velcro® closures. Fig 3. A thigh corset with Velcro® closures is easily adjusted by the patient. Fig 4. Nylon (left) and Polypropylene (right) knee joints work well in supporting weight of up to 180 pounds.
One modification, allowing early ambulation for the amputee with a slow healing suture line, is the addition of a thigh corset using either polypropylene or nylon knee joints. (Fig. 2 ). The thigh corset offers some control of weight bearing on the distal one-third of the residual limb. With the addition of two or three two inch Velcro® closures, the corset is easily adjusted by the patient (Fig. 3 ). The polypropylene or nylon knee joints offer the advantages of lightness and ease of workability (Fig. 4 ). These joints work quite well in supporting weights of up to 180 pounds. However, one must take caution when setting the shape of the uprights on heavier patients. A gradual bend in the upright will support weight better than a radical bend will. This will also lead to less problems of breakage. These knee joints should also only be used on patients with a sound knee joint, as they offer limited medio-lateral stability. The joints can be used on a long term basis with a moderately active patient. This modification to the prosthesis can work well, but only with a qualified physical therapist routinely monitoring the patient’s progress on the prosthesis until healing has occurred.
In addition to, or apart from the thigh corset and side joints preparation, specially fabricated inserts should be created on an individual basis when dealing with an asensitive residual limb of a geriatric amputee.
If a patient’s weight is 120 pounds or less, and he has a moderate activity level, a very soft insert composed of an inner layer of 1/8 inch Plastazote®, and an outer layer of 1/8 inch PPT2 produces an equitable environment for the residual limb. The Plastazote® will stay compressed after use in the most dense tissue areas, where pressures are concentrated, while constantly adjusting to changes. This is backed by a layer of PPT, which offers continual protection for the residual limb, and resists compression. Due to the combined total durometer of the Plastazote(TM) and PPT insert, adequate support effectively helps patients who fall in the lightweight and moderately active category.
Patients who weigh 130 pounds or more and who are moderately to highly active, can benefit from an insert composed of an inner layer of 1/8 inch PPT and an outer layer of Pelite. PPT offers direct tissue shear stress protection while being backed by the firm durometer of the Pelite. This combination of materials offers an environment that will protect the residual limb throughout the entire day by relieving the tissues of stress which could lead to skin breakdown. The typical patient requiring this type of insert might be a moderately active 200 pound, six foot tall man with a four inch residual limb. This residual limb would be subjected to intense pressure at all times, thus necessitating this type of insert.
Young, highly active below-knee amputees can also benefit from the control of tissue breakdown. This type of insert absorbs a majority of the compound torques and pressures on the residual limb under stressful conditions, while still offering little increase in the overall weight of a sport-type prosthesis.
An insert made solely of 1/4 inch PPT offes excellent protection for the patient with a very short, predominantly bony, well atrophied below-knee residual limb with very little or no protective tissue. Patients with moderate activity levels and weighing up to 130 pounds can benefit from this tissue supplemental material. This material can prevent tissue irritation, which is so common amongst these patients. This insert also allows the patient to ambulate comfortably without the need for a multiple prosthetic sock fitting. As normal atrophy occurs, this type of insert aids in the protection of the residual limb, even as the initially intimate fit begins to fade.
Fig 5. Plastazote(TM) forms similarly to Pelite around a positive model. Fig 6. Starting at a point on the anterior of the positive mold, contour the PPT by carefully applying it around the posterior where the PPT can be trimmed to permit one seam.
The Plastazote®-PPT insert can be fabricated quite rapidly and simply. A suggested method is to cut out a measured area of 1/8″ Plastazote® just as you would in producing a standard Pelite insert. Complete and apply this to the positive mold as you would with a Pelite insert, only use much less heat (Fig. 5 ). After it has been adequately shaped to the positive mold, cover it completely with a thin coat of Barge®, or similar type contact cement. Then apply a coat of the adhesive to an equal area of 1/8 PPT. Starting at a point on the anterior of the positive model, contour the PPT by carefully applying it around to the posterior where the PPT can be trimmed to show only one seam in the posterior (Fig. 6 ). Proceed to cap the insert as desired. Caution should be taken when gluing the PPT so as not to apply adhesive to the coated side of the material, marked with the brand name, as the adhesive will remove the coating from the material leaving a weak bond. It is preferable to obtain uncoated PPT material and avoid this problem.
The PPT-Pelite type insert is fabricated differently than the above type, but is still very easy and quick to create. Cut an appropriate area of 1/8″ Pelite and an equal area of PPT and bond the two materials together with a thin coat of adhesive. Skive the edges approximately 1/2″ as you would in constructing a Pelite insert. Sanding the skive is recommended over cutting a skived edge. Prepare a cone as in the standard Pelite insert technique. Heat the Pelite, which is on the outside, until it is slightly pliable, and carefully pull the inverted cone over the positive model and shape as you would a standard Pelite insert. Again, cap the insert as you normally would (Note: It is suggested that the A.P. modification of the positive model be tightened by 1/8″ to 3/16″.
Fabricating the 1/4″ PPT insert is different from the others mentioned above, as by itself it is not thermal molding and tends to maintain its original shape. Produce this insert in the same manner as a standard Pelite insert, except that the application over the positive model is done without the use of heat. It is simply pulled carefully into place. It is suggested that you modify the positive mold to produce a one-ply fit.Fig 7. Mark the insert for trimming with the patient in the prosthesis to allow for approximately l/2 inch of displacement under loading.
All three insert types should be laminated into the socket using the same vacuum settings and techniques as with a standard Pelite insert. Care must be taken on the breakout of the positive model so as to protect the finished insert. Socket pulling as a means of separating the socket from the positive model is not recommended, due to possible damage to the insert. The inserts should always be marked for trimming after the patient has been ambulating and is still in the prosthesis, and the nonconforming PPT is pushed into place. There is approximately 1/2″ of displacement in the material under loading as it is made to conform to the socket shape (Fig. 7 ). These lightweight special inserts can easily be fabricated and replaced when necessary and the longevity is similar to that of a Pelite insert. Modifications can be made by adhering Pelite to the outside of the insert in the appropriate areas, thereby accommodating volume changes of the residual limb. A thin coat of adhesive works quite well in the bonding of all these materials.
In conclusion, if careful attention is taken in fitting special below-knee residual limbs, higher success rates and more rapid prosthetic rehabilitation can be achieved. Use of special materials and fabrication techniques can assist the prosthetist in this endeavor.
- Nylong prosthetic knee joint is available through American Prosthetics, Inc., 406 Cookson Drive, West Branch, Iowa 52358
- Polypropylene knee joints are available through United States Manufacturing Company, P.O. Box 100, 623 South Central Avenue, Glendale, California 91209
- PPT is available through Professional Technology, Inc., 21 East Industry Court, Deer Park, New York 11729
Technical Note: The Soft Socket
Arthur Forman, B.S., M.A.
Oftentimes we are presented with an above-knee amputee who poses difficult problems for a successful prosthetic fitting. Some of these problems include advanced age, atrophy, trigger points, bony prominences, surgical implants, cardiopulmonary problems, short residual limbs, and other complications. Any one of these conditions might make for a difficult fitting, but any combination of these could contribute to an unsuccessful fitting, or a situation which precludes ambulation.
It is my contention that given the current generally accepted practices and when presented with an involved patient as indicated above, we are doomed to failure, in terms of comfort and ambulation. Further, it is my contention that very often, although these patients may be confined to a wheelchair even after prosthetic fitting, it is of paramount importance that they be fitted as comfortably as possible. Although they have lost a limb, they may be just as motivated as any other patient and can suffer psychological stigma.
Therefore, it is our duty as prosthetists to provide a prosthesis that will allow these patients to ambulate as much as possible, resulting in both psychological and physical benefits.
Soft Socket Rationale
As we all know, the quadrilateral above-knee socket was originally designed and fitted for World War II traumatic amputees. They were fairly young, usually with no other complications, good musculature, and in many cases of long length. Today we are faced with a high geriatric amputee population with conditions quite different than the World War II veteran. The quadrilateral above-knee socket design impinges directly on the neurovascular bundle in the area of the Scarpa’s triangle. The posterior seat area bears directly on an anatomical area which is usually atrophied to the point of being uncomfortable. These features alone call into question the viability of the quadrilateral design when considering an involved patient as described previously. The soft socket design as described, owes its inception to the CATCAM design.
The soft socket is almost an exact anatomical negative duplication of the residual limb without extreme scarpas impingement and without concentrated ischial weight bearing. It is lined with 1/2″ thick Plastizote, or similar forgiving material that enhances soft tissue bearing, hence “soft socket.” It is compatible with all existing above-knee components, far more cosmetic, aligned using current practices, and is fabricated only in a slightly different fashion. Also, it will allow the amputee to ambulate in a comfortable non-restrictive manner.Fig 1. The Berkeley brim above the AK prosthesis with hip joint and pelvic band. Note presence of Plastazote pad in the ischial seat area. Fig 2. The completed prosthesis.
A seventy-six year old man was presented for prosthetic fitting. He was a traumatic amputee who had lost his leg during the Korean War and was left with a four inch length femur. He had been wearing an exoskeletal system with an hydraulicly controlled knee, conventional quadrilateral socket, hip joint, and pelvic belt. The prosthesis weighed approximately 13 pounds. The lateral wall of the socket was modified at mid-femoral length to impinge on the femoral shaft. The patient had recently undergone surgery to repair a fractured femoral head on the amputated side due to a fall. He had also recently developed emphysema and had lost a significant amount of weight. During weight bearing on the sound leg, he exhibited extreme fatigue and loss of breath. Despite these contraindications to prosthetic fitting, he expressed great motivation.
I proceeded with the standard impression technique using the Berkeley brim. The patient experienced discomfort while suspended in the Berkeley brim. He indicated specific areas of discomfort including the ischial/gluteal area and the lateral femoral area. This continued despite angular adjustments to the brim. An impression was taken. Upon examination of the impression and after discussion with colleagues, it was decided that a conventional fitting would not work. After mulling over the situation, it was decided to hand wrap a new impression, while the patient laid on his sound side. This was done in a very particular way, encompassing the gluteals, and hand forming the medial and posterior wall. A very anatomic impression was obtained. Modification was minimal and consisted mainly of smoothing up and adding a layer of 1/2″ Plastizote (Fig. 1) after lamination. The prosthesis weighed 7 1/2 pounds. This included a modular safety knee, extension assist, hip joint, pelvic belt, foam cover, foot, and shoe (Fig. 2). The patient has been wearing this prosthesis and is quite satisfied.
It is my belief that we, as prosthetists, should approach our patients as individuals and if necessary, modify or completely discard commonly accepted techniques in order to successfully fit the uncommon patient. We should continue to examine our techniques in order to upgrade our profession and better serve the community.
Kevin S. Garrison, CP., Mahnke’s Prosthetics-Orthotics, Inc., Fort Lauderale, Florida; Joseph Leal, C.P., Custom Prosthetics of Tucson, Arizona; John Sabolich, C.P.O., Sabolich, Inc., Oklahoma City; Thomas Guth, C.P., R.G.P. Orthopedic Appliance Co., Inc., San Diego, California; Ivan Long, C.P., Polycadence, Inc., Arvada, Colorado; Timothy B. Staats, C.P., Director of Prosthetics, education training programs, UCLA.