Gait in prosthetic rehabilitation: Difference between revisions

Normal Gait [edit | edit source]

Gait is a term used to describe a walking pattern. ‘Normal gait’ is used to define a pattern which has been generalised from the general public across many variables, including age and sex^[1].

A complete cycle of gait begins at initial contact of one limb and ends at the repeated initial contact of the same limb, performing all phases of gait in doing so. This full cycle can be described as a stride. A step is sometimes incorrectly used to describe this cycle. A step however, is different; it is described as the distance of heel strike from one leg to the heel strike of the opposite leg^[2].

Figure1. Step and stride in human gait (http://nbviewer.ipython.org/github/demotu/BMC/blob/master/notebooks/SpatialTemporalCharacteristcs.ipynb)

The gait cycle can be split into 2 stages;

1. Stance Phase -Time the foot is in contact with the floor, weight acceptance and single leg stance, which makes up 60% of the cycle^[1] 
2. Swing Phase – The period of time where the limb is lifted from the floor, limb advancement. This makes up 40% of the cycle^[1]

In order to describe the elements of gait, the cycle can be broken down further into 8 sub factors^[1][2]:

• Initial contact
• Loading response
• Midstance
• Terminal stance
• Preswing
• Initial swing
• Midswing
• Terminal swing

The diagram demonstrates this division of gait cycle.

Figure 2. Divisions of gait cycle. Perry and Burnfield (2012) (http://www.bing.com/images/search?q=devisions+of+gait+cycle&FORM=HDRSC2#view=detail&id=820384A171C83C6FDE1E37CDDCE6DC22C556A462&selectedIndex=5 )

Initial contact[edit | edit source]

Also known as heel strike. This is the first moment the foot comes into contact with the floor. The hip is flexed approximately to 30 degrees , knee extended between 0-5 degrees and ankle dorsiflexed to a neutral position, giving contact with the floor at approximately a 25 degree angle. This is the first phase of double limb support. The aim of initial contact is to stabilise the limb in preparation for it to take the impending forward translation of body weight^[2][3].

Loading response[edit | edit source]

The foot flattens on the floor through pronation. The hip begins to extend and propels the body forwards and over the foot, using the heel as a ‘rocker’. The knee then flexes to allow shock absorption. The aim of this phase is shock absorption, weight bearing stability and preservation of progression^[2][3]. 

Mid stance[edit | edit source]

This is the first half of single limb support. Weight is aligned fully over the supporting foot through ankle dorsiflexion, while the hip and knee extend, as the other foot lifts of the floor. The body weight is fully supported on one leg^[2][3]. 

Terminal stance[edit | edit source]

This is the second half of single leg support; it begins as the other leg lifts of the floor. The heel of the loaded limb lifts off the floor and the body weight moves forward past the forefoot, as the hip increases in extension. The knee gains full extension and begins to flex again. This phase is completed when the non-loaded limb makes contact with the floor^[2][3].

Pre-swing[edit | edit source]

Also known as ‘toe off’ and is the final phase of stance. The other limb has now begun a new stance phase and is in the initial contact phase. The limb is rapidly off loaded with a forward push to transfer the weight onto the opposite limb. The knee is flexed and the ankle plantarflexes as the toe leaves the ground^[2][3]. 

Initial swing[edit | edit source]

The foot is lifted off the floor by hip and knee flexion, as the ankle begins to dorsiflex. The other foot will be in midstance phase. When the off loading limb is level with the leg in stance phase the initial swing phase is complete^[2][3]. 

Mid swing[edit | edit source]

The limb swings forward of the body through hip flexion as the knee begins to extend. The foot is clear of the floor^[2]

Terminal swing[edit | edit source]

Also known as late swing, the knee becomes fully extended and the ankle dorsiflexes to neutral as the foot prepares to make contact with the floor^[2].

The diagram below demonstrates the 8 phases of the gait cycle;

Figure 3. The faculty of Engineering and Applied Sciences Mechanical and Materials Engineering (http://me.queensu.ca/People/Deluzio/Gait.html)

Video link; https://www.youtube.com/watch?v=VYVyoFdJHdU

Pathological Gait [edit | edit source]

Pathological gait is an altered gait pattern due to deformities, weakness or other impairments, for example, loss of motor control or pain^[1].  Deviations can broadly be divided into neurological or musculoskeletal causes^[4]. 

Musculoskeletal Causes[edit | edit source]

Pathological gait patterns resulting from musculoskeletal are often caused by soft tissue imbalance, joint alignment or bony abnormalities. Infliction of these on one joint often then impacts on other joints, affecting the gait pattern as a result^[4]. The common deviation can be categorised broadly as^[4]:

• Hip Pathology
• Knee pathology
• Foot and ankle pathology
• Leg length discrepancy
• Pain

Hip pathology[edit | edit source]

Arthritis is a common cause of pathological gait. An arthritic hip has reduced range of movement during swing phase which causes an exaggeration of movement in the opposite limb ‘hip hiking^[4].

Excessive hip flexion can significantly alter gait pattern most commonly due to; • Hip flexion contractures • IT band contractures, • Hip flexor spasticity, • Compensation for excessive knee flexion and ankle DF, • Hip pain • Compensation for excess ankle plantar flexion in mid swing^[2].  The deviation of stance phase will occur mainly on the affected side. The result is forward tilt of the trunk and increased demand on the hip extensors or increased lordosis of the spine with anterior pelvic tilt. A person with reduced spinal mobility will adopt a forward flexion position in order to alter their centre of gravity permanently during gait^[2]. 

Hip abductor weakness. The abductor muscles stabilise the pelvis to allow the opposite leg to lift during the swing phase. Weak abductor muscles will cause the hip to drop towards the side of the leg swinging forward. This is also known as Trendelenburg gait^[5]

Hip adductor contracture. During swing phase the leg crosses mid line due to the weak adductor muscles, this is known as ‘scissor gait’^[5]

Weak hip extensors will cause a person to take a smaller step to lessen the hip flexion required for initial contact, resulting in a lesser force of contraction required from the extensors. Overall gait will be slower to allow time for limb stabilisation. Compensation is increased posterior trunk positioning to maintain alignment of the pelvis in relation to the trunk^[2][5]

Hip flexor weakness results in a smaller step length due to the weakness of the muscle to create the forward motion. Gait will likely be slower and may result in decreased floor clearance of the toes and create a drag^[2]

Knee pathologies[edit | edit source]

Weak quadriceps. The quadriceps role is to eccentrically control the knee during flexion through the stance phase. If these muscles are weak the hip extensors will compensate by bringing the limb back into a more extended position, reducing the amount of flexion at the knee during stance phase. Alternatively heel strike will occur earlier increasing the ankle of plantar flexion at the ankle, preventing the forward movement of the tibia, to help stabilise the knee joint^[2][5].

Severe quadriceps weakness or instability at the knee joint will present in hyperextension during the initial contact to stance phase. The knee joint will ‘snap’ back into hyperextension as the body weight moves forwards over the limb^[2][5] 

Knee flexion contraction will cause a limping type gait pattern. The knee is restricted in extension, meaning heel strike is limited and step length reduced. To compensate the person is likely to ‘toe walk’ during stance phase. Knee flexion contractures of more than 30 degrees will be obvious during normal paced gait. Contractures less then this will be more evident with increased speeds^[2][4][5]. 

Ankle Pathologies[edit | edit source]

Ankle dorsi flexion weakness results in a lack of heel strike and decreased floor clearance. This leads to an increased step height and prolonged swing phase^[2][5]. 

Calf tightening or contractures due to a period of immobilisation or trauma will cause reduced heel strike due to restricted dorsiflexion. The compensated gait result will be ‘toe walking’ on stance phase, reduced step length and excessive knee and hip flexion during swing phase to ensure floor clearance^[2][4].

Leg length discrepancy[edit | edit source]

Leg length discrepancy can be a result of an asymmetrical pelvic, tibia or femur length or for other reasons such as a scoliosis or contractures. The gait pattern will present as a pelvic dip to the shortened side during stance phase with possible ‘toe walking’ on that limb. The opposite leg is likely to increase its knee and hip flexion to reduce its length^[4].

Antalgic Gait[edit | edit source]

Antalgic gait due to knee pain presents with decreased weight bearing on the affected side. The knee remains in flexion and possible toe weight bearing occurs during stance phase^[4]

Antalagic gait due to ankle pain may present with a reduced stride length and decreased weight bearing on the affected limb. If the problem is pain in the forefoot then toe off will be avoided and heel weight bearing used. If the pain is more in the heel, toe weight bearing is more likely. General ankle pain may result in weight bearing on the lateral border^[2][4][5].

Antalgic gait due to hip pain results in reduced stance phase on that side. The trunk is propelled quickly forwards with the opposite shoulder lifted in an attempt to even the weight distribution over the limb and reduce weight bearing. Swing phase is also reduced^[2][4]. 

Common neurological causes of pathological gait[edit | edit source]

Hemiplegic gait, often seen as a result of a stroke. The upper limb is in a flexed position, adducted and internally rotated at the shoulder. The lower limb is internally rotated, knee extended and the ankle inverted and plantar flexed. The gait is likely to be slow with circumduction or hip hitching on the affected limb to aid floor clearance^[6][4].

Diplegic gait. Spasticity is normally associated with both lower limbs. Contractures of the adductor muscles can create a ‘scissor’ type gait with a narrowed base of support. Spasticity in the lower half of the legs results in plantarflexed ankles presenting in ‘tip toe’ walking and often toe dragging. Excessive hip and knee flexion is required to overcome this^[6][4]. 

Parkinsonian gait often seen in Parkinson’s disease or associated with conditions which cause parkinsonisms. Rigidity of joints results in reduced arm swing for balance. A stooped posture and flexed knees are a common presentation. Bradykinesia causes small steps which are shuffling in presentation. There may be occurrences of freezing or short rapid bursts of steps known as ‘festination’ and turning can be difficult^[6][4]. 

Ataxic gait is seen as uncoordinated steps with a wide base of support and staggering/variable foot placement. This gait is associated with cerebellar disturbances and can be seen in patients with longstanding alcohol dependency^[6][4] 

People withsensory disturbances may present with a sensory ataxic gait. Presentation is a wide base of support, high steps and slapping of feet on the floor in order to gain some sensory feedback. They may also need to rely on observation of foot placement and will often look at the floor during mobility due to lack of proprioception^[6][4]. 

Myopathic gait. Due to hip muscular dystrophy, if it is bilateral the presentation will be a ‘waddling gait’, unilaterally will present as a Trendelenburg gait^[6]. 

Neuropathic gaits. High stepping gait to gain floor clearance often due to foot drop^[6]

Below are links to videos demonstrating normal gait and various gait abnormalities; https://www.youtube.com/watch?v=b5rIEx9SsCo&list=PLB01F8C5F8133A9DD https://www.youtube.com/watch?v=VvpgVxIUrvo https://www.youtube.com/watch?v=lQzAKxYBZWc&index=6&list=PLz27Rlp3y6XsLLUPyxScdJnjCqqpD6n2h www.youtube.com/watch?v=VYVyoFdJHdU

Prosthetic Gait [edit | edit source]

After an amputation the amputee uses different muscle groups in order to create a smoother gait pattern. Overall energy consumption required is higher, due to the increased effort required to compensate for the lose of the limb. The amount of metabolic oxygen consumption in a non amputee correlates directly to increased walking distance and speeds. In the amputees, however, this metabolic cost is higher even at normal speed. On average these increased requirements are^[7]:

• Traumatic Transtibial gait - 25% increased energy requirement
• Vascular Transtibial gait- 40 % increase
• Traumatic Transfemoral gait-68% increase
• Vascular transfemoral gait -100% increase

Transtibial Gait[edit | edit source]

The average gait pattern will vary dependent on the type of prosthesis used for mobility, however generalisations can be made. The ankle of the prosthesis has a reduced range of movement compared to the anatomical ankle. This results in prolonged heel strike and weight bearing through the heel before flat foot contact, with delayed forefoot loading^[8] 

Knee flexion is decreased at initial contact and the overall maximum flexion achieved is reduced as the foot moves to floor contact to^[8]. During swing phase of the non prosthetic limb the body weight begins to move forward over the prosthetic limb, which is in stance phase. In order to gain adequate step length of the non prosthetic limb, heel rise on the prosthesis occurs earlier. The heel rise achieved is greater than that of a normal gait pattern^[8]. This creates an elevation of the body and results in a greater loading force on the non prosthetic side (approx 130% compared to average 111%) as the body weight drops more rapidly onto the limb. Greater quadriceps contraction is needed to absorb the force^[7][8]. The ‘toe off’ force generated from the prosthetic limb is reduced, which is compensated for by the hip flexors. Flexion of the knee on the prosthetic limb occurs with some hamstring contraction but mainly eccentric contraction of the quadriceps^[9] 

During the stance phase the energy generated by the prosthetic limb is reduced by 50% to that which would be generated by the normal limb, this is compensated by greater energy expenditure in muscles higher up the limb. The rocker effect of the prosthesis results in increased instability and the reduced knee flexion achieved on the prosthetic side requires hip muscles to generate greater energy to ensure stability. As the body transfers weight in a forward motion this energy generation is then transmitted to the trunk muscles in order to generate enough force to propel the body forward and to compensate for the loss of energy through the prosthesis^[7].

Due to the reduced ankle movement of the prosthesis the range of extension at the hip is reduced to approx half of that of the opposite limb. The stance time on the non prosthetic side is also increased compared to the non prosthetic side^[8].

Video Link; https://www.youtube.com/watch?v=bZUpFoMhH2g

Transfemoral gait[edit | edit source]

A person with a transfemoral amputation has to compensate for the loss of both the knee and ankle joint^[7]. The gait cycle is affected by the quality of the surgery, the type and alignment of prosthesis, the condition of the stump and the length of the remaining muscular structure and how well these are reattached^[9].

The main focus of the gait cycle is to prevent the knee from buckling during stance phase. A ‘fixed knee’ prosthesis will counteract this issue. A ‘free knee’ will need to remain in extension for longer throughout the stance phase approx 30-40% to ensure buckling does not occur^[7]. This extension causes prolonged heel strike and the body will move forward over the prosthetic leg as one unit for stance phase. The hip extensors on the prosthetic side will work to stabilise the limb in prosthetic weight bearing^[7]. 

During swing phase of the prosthetic limb the hip extensors and calf muscles on the non prosthetic side help to generate force for the non prosthetic limb to gain swing forwards. Hip flexors on the prosthetic limb must generate the same force required during normal gait. Although the prosthesis is generally 30% lighter than the limb would be, speed generated by the hip flexors is required in order to snap the prosthesis of a ‘free knee’ into extension for heel strike^[7][8]. General control and strength is reduced in a transfemoral amputation due to the shortened lever length of the thigh muscles, which reduces the force of contraction^[7].  For amputees with a fixed knee prosthesis floor clearance is reduced during swing phase, due to the lack of knee flexion and ankle dorsi flexion. Elevation of the hip using trunk and hip muscles is required to prevent dragging on the floor known as ‘hip hitching’ or ‘hip hiking’^[8]. Stance time on the non prosthetic limb is increased as it is for transtibial amputees, because of the instability resulting from the prosthesis and the reduced range of motion available. Overall energy expenditure is higher than is required for a transtibial amputee due to the energy which is lost through the prosthesis over two joints and not one. Greater compensation is required by the hip and trunk muscles and the contra lateral limb to generate the energy required for stability and movement throughout the gait cycle^[7].

Video links; https://www.youtube.com/watch?v=sWqLh0aK7A0

Gait Deviations [edit | edit source]

While assessing amputee gait it is important to be aware of normal gait and how normal gait in the amputee is affected. Furthermore there may be deviations which an amputee will adopt to compensate for the prosthesis, muscle weakness or tightening, lack of balance and fear. These deviations create an altered gait pattern and it is important that these are recognised, as rehabilitation of the gait will need to encompass corrections of these deviations^[9][8].

Common deviations are;

Transtibial[edit | edit source]

External rotation of the prosthesis at heel strike

Causes; heel to hard, too hard a plantar flexion bumper, socket too loose. (10)

Knee fully extended at heel strike

Causes; faulty suspension of the prosthesis- too soft heel cushion or plantar flexor bumpers, foot placement too far forward on stepping, lack of pre-flexion of the socket, discomfort/pain, quads weakness^[8] (9)(11)

Increased Knee flexion at heel strike

Causes; faulty suspension of prosthesis, prosthetic foot too set in too much dorsiflexion, stiff heel cushion, flexion contracture of the knee, foot to posterior in relation to socket^[8](9)(10)(11)

Rotation of foot at heel strike

Causes; heel too hard, loose socket (11)

Unequal stride length

Causes; faulty suspension limiting knee flexion, poor gait pattern^[8] 

Knee flexion ‘jerky’ in presentation during heel strike to foot flat

Causes; weak quadriceps^[8]

Abrupt knee flexion as foot moves in flat foot contact with the floor;

Causes; excessive dorsiflexion of the prosthetic foot, foot too posterior in relation to socket of the prosthesis, lack of suspension in the prosthesis, lack of cushion due to the shoe, heel of the shoe too high^[8].

Knee stays extended from heel strike to flat foot contact

Causes; Step length too long, foot too anterior on the prosthesis, foot too planter flexed on the prosthesis, heel too soft, discomfort when flexing the knee in the prosthesis, not enough heel on the shoe^[8]. (9)(10)

Amputee drops into the socket as the foot moves into flat foot

Causes; lack of prosthetic socks, suspension loose, faulty socket.

Medio or lateral shift during stance phase

Causes; foot placement (medial placement causes lateral thrust and vice versa), foot alignment on the prosthesis, socket loose^[8] (9) (11)

Heel off occurs too early causing early knee flexion (drop off)

Causes; foot too posterior on the prosthesis in relation to the socket, excessive dorsiflexion of the foot on the prosthesis, soft heel bumper on the prosthesis^[8]. (9) (11)

Delayed heel causing hyperextension of the knee- walking up hill sensation

Causes; foot set too far forward on the prosthesis in relation to socket, too hard a heel cushion, too much plantar flexion on the foot. (9)(10)

The socket drops down off the limb after ‘toe off’

Causes; socket too lose, not enough prosthetic socks^[8] 

During swing phase foot ‘whips’ laterally or medially

Causes; poor suspension, knee internally or externally rotated^[8] (9) (11)

Transfemoral gait deviations[edit | edit source]

Rotation of the heel at heel strike

Causes; socket too loose, poor limb control, alignment of foot on the prosthesis, heel of the prosthesis too hard. (12)

Knee instability (with ‘free knee’ prosthesis)

Causes; knee set too far anterior, heel cushion too firm, weak hip extensors, heel of the shoe too high causing the pylon of the prosthesis to move anteriorly, severe hip flexion contracture^[8] (9)(11)

Foot slap

Causes; patient forcing foot contact to gain knee stability, heel cushion too soft, plantar flexion cushion too soft, excessive dorsiflexion^[8] (9)(11)(12)

Abducted gait- increased base of support during mobility, prosthetic foot placement is lateral to the normal foot placement during the gait cycle (12)

Causes; prosthesis too long, socket too small, suspension belt may be insufficient-band may be too far from the ileum, pain in the groin or medial wall of the prosthesis, hip abductor contractures, lateral wall of the prosthesis not supporting the femur sufficiently, socket of prosthesis abducted in alignment, fear/lack of confidence transferring weight onto prosthesis, alignment of the lower half of the pylon of the prosthesis in relation to socket^[8]. (9)(11)(12)

Lateral trunk bending- Trunk flexes towards prosthesis during prosthetic stance phase

Causes: prosthesis too short, short stump length, weak or contracted hip abductors, foot outset excessively in relation to socket, lack of prosthetic lateral wall support, pain on the lateral distal end of the stump, lack of balance, habit^[8] (9)(11)(12)

Excessive pelvic lift on heel lift on prosthetic side

Causes; toe lever too long^[8] 

Pelvic dip on heel lift on prosthetic side

Causes; toe lever too short^[8] 

Increased lumbar lordosis

Causes; poor shaping of posterior wall of the prosthesis or pain on ischial weight bearing, resulting in anterior pelvic rotation, flexion contracture at the hip, weak hip extensor, habit, poor abdominal muscles, lack of support from the anterior wall of the socket, insufficient socket flexion^[8] (9)(11)(12)

Whip during swing phase

Causes; prosthetic knee alignment, incorrect donning of the prosthesis i.e. applied internally rotated or externally rotated weakness around femur, prosthetic too tight^[8]. (9)(12)

Socket dropping of when prosthesis lifted

Causes; insufficient suspension, socket too loose^[8] • Delayed knee flexion during toe off (‘free knee only’) Causes; increased resistance of the prosthesis, Alignment of prosthesis^[8]. 

Excessive heel rise

Causes; lack of friction on prosthetic knee, amputee generating more force then required to gain knee flexion, poor/lack of extension aid^[8] (9) (11) (12)

Reduced heel rise

Causes; locked knee, lack of hip flexion, too much friction on free knee, extension aid to tight (11)

Circumduction-lateral curvature of swing phase of prosthesis

Causes; prosthesis too long, fixed knee and poor hip hitching, poor suspension causing prosthesis to slip, excessive plantar flexion of the foot, abduction contractures, habit, weak hip flexors, socket too small, insufficient knee flexion^[8] (9)(11)(12)

Vaulting, amputee rises onto toe of the non prosthetic limb during prosthetic swing phase

Causes; prosthesis too long, habit, fear of catching toe on the floor, insufficient knee flexion (free knee) due to decreased confidence, lack of ‘hip hitching’ with a ‘locked/fixed knee’, poor suspension prosthesis-slips off during swing phase, socket too small, excessive friction on knee flexion of the prosthesis^[8] (9)(10)(11)(12)

Forcible impact as knee goes into extension at end of terminal swing phase, just before heel strike

Causes; lack of friction of knee flexion, extension aid too excessive, absent extension bumper, amputee deliberately snaps knee into extension by excessive force to ensure extension^[8] (9)(12)

Both Transfermoral and Transtibial[edit | edit source]

Uneven step length

Causes; fixed flexion deformity at knee, insufficient friction of prosthetic knee creating an increased step length on prosthetic side, hip flexion contracture, pain leading to decreased weight bearing on prosthetic side^[8],(9)(12)

Uneven arm swing- arm on the prosthetic side is held close to the body

Causes; poor prosthetic fit, poor balance, fear and habit (12)

Unequal weight bearing/reduced stance phase on prosthesis

Causes; poor fitting socket leading to reduced stability, pain, muscle weakness, poor balance, fear and insecurity, poor extension aid or insufficient knee friction resulting in early excessive heel off and reduce stance time on prosthesis, inadequate prosthetic foot position (12)

This is not an exhaustive list and the deviation described for each level of amputation is not exclusive to that level, but is more likely to occur for that amputation.

Video links; https://www.youtube.com/watch?v=fol4gSdI128&list=PL9GyQ0cHOlOUQwy21068SQSJ0AkAYfC6A&index=4 https://www.youtube.com/watch?v=6gTCYMaZUmk https://www.youtube.com/watch?v=b2n0USprXmQ&list=PLC4C0A7332DA05CFF www.youtube.com/watch?v=N_lufFd0EoI

Prosthetic Rehabilitation
[edit | edit source]

The aim of the rehabilitation is to aid the amputee to gain independence at the highest level they can, with the most efficient gait possible. The assessment must take into account the physical capabilities, level of amputation, psychological status, pre-amputation function, existing medical conditions and the patient’s expectations. Rehabilitation should begin 5 days post surgery. (14) A crucial element of constructing a rehabilitation programme is sound gait analysis. This will largely be observational. Validated outcome measures are available to aid goal setting and measure function. Gait analysis consists of observation of the gait, which should occur from all angles. Knowledge of normal gait patterns for the prosthetic and non prosthetic user is required to help analysis of movement. On observation of the gait the assessor compares the function of the amputee to expected patterns of gait and look for deviations^[9]. Analysis of the gait pattern will help determine why these deviations are occurring. This will then help to formulate the rehabilitation programme, which includes correction of the deviations. Outcomes measures can be used to monitor progress^[9].

Amputees should perform pre-prosthetic exercises to help maintain ROM and improve muscle strength in the lower limb and residual limb in preparation for using the prosthetic limb. Abdominal and back exercises should also be considered to help trunk control and reduce back pain. Pre-prosthetic limb exercises can help prevent occurrence of prosthetic gait deviations (13)

Due to the loss of the limb the amputee will automatically shift their centre of gravity over the foot of the non-prosthetic side. After an amputation there will be a period of time where the amputee is without a prosthesis. This is due to the timeframe of the assessments required to decide if the provision of a limb is appropriate. During this period the amputee will become familiar with the shifted centre which will increase the difficulty of reorientation of the centre of gravity once they receive a prosthetic limb. (13)

Orientation of Centre of Gravity and Weight Bearing on the Prosthesis[edit | edit source]

Prosthetic training should include orientation of centre of gravity and improve weight bearing on the prosthetic side (13). There are a number of technique/exercises which can be employed to facilitate the rehabilitation of this;

Lateral weight shifting[edit | edit source]

Stand between parallel bars with two handed support. The amputee practices shifting the weight from the non-prosthetic limb to the prosthetic side. This an be performed with pelvis only initially and progress to full body movement when the amputee becomes more confident. A pair of scales under the feet can help to determine the weight transference. Two handed support can be reduced to one handed (alternating hands to thee contralateral side of the weight shift) and fingertip support, for progression. (13)(16)

Forward and back weight shifting[edit | edit source]

Weight transference can be practiced forwards and backwards to help balance and orientation. The exercise is performed as for lateral weight shifting but the body weight is moved forwards and back. This can begin with pelvic movements only to build confidence and progress to entire body weight. Reduced hand support will be a progression of this exercise. (13)

High stepping[edit | edit source]

Single leg stance on the prosthetic side can be improved by high stepping with the non-prosthetic side. With 2 handed support, the amputee steps the non-prosthetic limb onto a stool of approx. 4-8 inches. This exercise can be progressed by increasing the height of the step and/or reducing the hand support required. As the amputee becomes more confident and weight bearing improves the step of the non-prosthetic limb will be slower and more controlled (13)

Balance board[edit | edit source]

A balance board can be used to help weight bearing and balance where they shift body weight forward and back and laterally bewteen the prosthetic and non-prosthetic side. This can be performed between parallel bars with 2 handed support. (16)

Throwing and catching[edit | edit source]

Stood between parallel bars or with supervision, as required the amputee performs throwing and catching with the therapist. This encourages the amputee to adjust their weight bearing as they reach outside their base of support over the prosthetic and non-prosthetic limb. This exercise can be progressed by the non-prosthetic limb being placed on a step or balance cushion. (16)

Obstacle stepping[edit | edit source]

Between parallel bars or with supervision, the action of stepping over obstacles leading with the non-prosthetic limb can help encourage weight bearing on the prosthesis, (16)

Football[edit | edit source]

With or without hand support, standing on the prosthetic side, the amputee kicks a ball with the non-prosthetic leg to promote weight shift onto the prosthesis.

Braiding[edit | edit source]

The amputee stands with 2 handed support and swings one leg across the front of the body and then behind. This is performed with both the prosthetic and non-prosthetic side. To advance this exercise the amputee performs this action with more speed meaning they must adjust their weight bearing and balance to compensate for the speed of the movement. (16)

Single leg standing[edit | edit source]

Practice balancing on the prosthetic limb will help improve balance on that side. This can be performed with varying levels of hand support. (13)

Gait Re-Education[edit | edit source]

Specific gait re-education and facilitation is important during rehabilitation in order to ensure the correct biomechanics of gait are achieved. Recommendations are that gait re-education commences between parallel bars (13)

Pneumatic post Amputation Mobility Aid (PPAM Aid)[edit | edit source]

This is an aid that can be used to encourage early mobilisation before the amputee has a prosthetic limb. It can be used from 5 days post op providing there are no complications with the wound. Trial inflations should occur until the patient is able to tolerate the sleeve. The sleeve should be applied and slowly inflated from 5 minutes to a maximum of 2 hours twice daily. The maximum pressure of inflation which should not exceed 40 mm Hg. The sleeve can be placed over soft dressings, plaster cast or bandaging. The wound should be checked before and after using the PPAM aid. The PPAM aid is designed as a short term mobility aid, for partial weight bearing and is not a substitute for a long term prosthetic limb (15)

Specific Gait re-education[edit | edit source]

The gait cycle can be broken down and each segment practiced with the amputee. With 2 handed support begin with heel strike of the non-prosthetic limb while weight bearing on the prosthetic side, encouraging correct foot placement. This is then practiced with the opposite leg. Step by step progression of the gait should commence once heel strike is achieved. Forward weight transference onto and off the prosthetic limb to allow floor contact of the prosthetic foot and weight acceptance, without the swing through of the opposite leg, is the next step. This again is practised with both sides. Once this is satisfactory, swing through of the opposite leg can be practised when the leading foot/prosthesis is in stance. This process is followed with each step to help encourage a rhythmical, reciprocal gait pattern with appropriate weight shift. Regular proprioceptive facilitation to aid correct pelvic and trunk movements and help facilitate weight transference along with verbal feedback is used to reinforce correct movement. (13)(16)

Walking aids[edit | edit source]

Rehabilitation should begin between parallel bars. However once the amputee becomes confident and a good gait pattern is achieved walking aids should be introduced to aid progression of mobility and to encourage mobility in the amputee home environment. Aids should be provided to promote the maximum level of independence and encourage the amputee to be as full weight bearing as possible. The patient’s pre-amputation level of function, current abilities, level of progression, overall health and medical status should be considered when selecting and progressing walking aids.(13) (14)

Sidestepping[edit | edit source]

This can be performed at any stage in the rehabilitation programme. The aim is to encourage lateral weight shifting and strengthen the abductors, The exercise can be performed with 2 hand support in the parallel bars and progress by the amputee moving around furniture/obstacles as a patient would in their own environment. (13)(16)

Backward walking[edit | edit source]

This activity is more difficult for transfemoral amputees than transtibial due to the lack of knee flexion of the prosthesis. However with practise the transfemoral amputee can perform this action with confidence. They will commonly need to plantarflex the ankle, come onto the toes, of on the non-prosthetic limb as they bring the prosthetic limb back. (16)

Multidirectional changes[edit | edit source]

This will help improve prosthetic control and balance. Often changes in direction will prove difficult for amputees and practice will help improve mobility in more challenging environments such as crowded public places. (16)(14)

Tandem walking[edit | edit source]

This can help improve co-ordination, foot placement and weight bearing. A strip is placed on the floor. The exercise can be progressed through 3 stages 1) Foot placement on each side of the line 2) Foot placement heel toe along the line 3) Foot placement crossing over onto opposite sides of the line- for the more advanced amputee^[7] (8)(16)

Functional tasks[edit | edit source]

In addition to specific weight bearing and gait training, prosthetic rehabilitation should also include practice of more functional tasks of daily living. These should be centred on the patient’s individual goals. (14)

Stairs[edit | edit source]

The technique for performing stairs is the same for above and below knee amputees. Leading with the non-prosthetic limb ascending the stairs and descending with the prosthetic limb first. This can be progressed from 2 handed to non handed support, dependent on the ability of the amputee. Walking aids can also be used to help amputees manage stairs. (13)(16)

Slopes/hills[edit | edit source]

Walking up and down slopes can be difficult for amputee patients. Often forward trunk flexion is required and shorted stride lengths. Some amputees will find it easiest ascending and descending slopes through side stepping. Aids and rails can aid with slopes. The same techniques in terms of stepping are applied to slopes as it is for stairs. (13)

Curb[edit | edit source]

The limb sequence applied to walking up and down stairs can be adopted for curbs. Walking aids are useful for assisting with curbs, however more advanced amputee will manage without. Balance and good single limb support is necessary for this. For the more advanced transtibial amputee the prosthetic limb can also be used to ascend curb and control descent^[7](8) (16)

Weight carrying[edit | edit source]

Practise walking with a weight on the prosthetic side or with objects in the hand. This may require a walking aid dependent on the patient’s ability. (13)

Uneven surfaces[edit | edit source]

Walking over various terrains helps improve awareness and proprioception. It encourages the amputee to make use of their vision to compensate for the reduced proprioception on the prosthetic side.

Running[edit | edit source]

For advanced amputee running can be incorporated in to the rehabilitation programme and can help amputees to increase participation in recreational activities. (13)

Link to International Committee of Red Cross Exercises for prosthetic rehabilitation;

https://www.icrc.org/eng/assets/files/other/icrc_002_0936.pdf

Amputees should have a full functional and physical assessment and rehabilitation should be based around personalised functional goals. Individualised exercise programmes are developed thorough assessment. An awareness of normal gait and the deviations and their cause formulates the basis of the correct rehabilitation of the individual.(13) (14)There are numerous techniques that can be used during rehabilitation and not all of them will be appropriate for each individual, therefore the programme and technique must be applied to each individual and reviewed regularly to ensure it remains adequate^[8]. (9)(13)The amputee’s previous level of activity, overall health and potential to improve needs to be taken into consideration when formulating a rehabilitation programme and should aim at translating the function gained in a controlled environment into their own home functional environment.(13)(14)

Links to International Committee of the Red Cross Amputee Exercises; https://www.icrc.org/eng/assets/files/other/icrc_002_0936.pdf

References[edit | edit source]

9) 

10) Berger N. Analysis of Amputee Gait. Chapter 14. Atlas of limb prosthetics: Surgical, Prosthetic and rehabilitation Principles. Abridged version. O&P Virtual library http://oandplibrary.org/alp/chap14-01.asp (accessed 5 February 2015)

11) HUNTER NEW ENGLAND. NSW Health Duff K. Prosthetic gait deviations. Page link on Australian Physiotherapist in Amputee Rehabilitation. http://www.austpar.com/portals/gait/docs-and-presentations/ProstheticGaitDeviations.pps (accessed 6 February 2015)

12) Evans S. Prosthetics Education Session. July 2012. Ottobock

13) Gailey R, S & Curtis R, C. Physical Therapy Management of Adult Lower-Limb Amputees. Atlas of Limb Prosthetics; Surgical Prosthetic and Rehabilitation Principles. Chapter 23. Abridged version. O&P Virtual Library http://www.oandplibrary.org/alp/chap23-01.asp (accessed 5 February 2015)

14) British association of Chartered Physiotherapists in Amputee Rehabilitation. Evidenced Based Clinical Guidelines for the Physiotherapy Management of Adults with Lower limb Prosthesis. CSP Clinical Guideline 03. November 2012

15) Bouch E, Burns K, Geer E. British association of Chartered Physiotherapists in Amputee Rehabilitation. University of Bradford. Guidance for the multi-disciplinary team on the management of postoperative residuum oedema in lower limb amputees.

16) International Committee of the Red Cross. Exercises for Lower Limb Amputees Gait Training. https://www.icrc.org/eng/assets/files/other/icrc_002_0936.pdf (accessed 7 February 2015)

References[edit | edit source]

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