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LECTURE 12 th

LECTURE 12 th. EARLY AMBULATION AND GAIT TRAINING FOR PATIENT WITH LOWER EXTREMITY BURN. EARLY AMBULATION AND GAIT TRAINING FOR PATIENT WITH LOWER EXTREMITY BURN.

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LECTURE 12 th

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  1. LECTURE 12th EARLY AMBULATION AND GAIT TRAINING FOR PATIENT WITH LOWER EXTREMITY BURN

  2. EARLY AMBULATION AND GAIT TRAINING FOR PATIENT WITH LOWER EXTREMITY BURN The ability to stand and ambulate efficiently is an integral part of human activity. The lower extremity must provide a strong flexible base for ambulating activities when a person sustains a burn injury to lower extremities this mobile base can be compromised severely. A careful and comprehensive burn rehabilitation program must be developed to restore a patient's foundation for efficient ambulating. This part attempts to consolidate the current treatment philosophies of rehabilitation for the patient with lower extremity burn into a treatment setting.

  3. Evaluation for the patient with lower extremity burn: The first step in gait training program for the patient with lower extremity burn is a comprehensive evaluation.(This evaluation should be performed during the first ambulation session following skin "grafting and re-evaluated frequently as ambulation progress The history should include details of the patients pre-burn mobility level, preexisting lower extremity problems such as peripheral vascular disease, joint jnjuries and strength deficits should be determined. Object measurements of passive and active ROM and strength should be completed.)

  4. Goals of Ambulation Program: The ultimate goal of ambulation for the patient with a lower extremity burn is the ability to walk efficiently so that all daily activities can be accomplished easily .”Normal gait pattern without any deviation is essential for efficient ambulation and includes control of head and trunk, arm swing, and pelvic movement. Early ambulation is an essential part of rehabilitation program whether or not the patient has burn on the lower extremities. It decreases the risk of thromboemboli formation, maintains lower extremity strength and ROM and to increase a patient's functional independence"

  5. Initial treatment program This program includes positioning exercise and ambulation,as with all bums positioning is independent on the surface areaaffected. Usually,(with a lower extremity bum, the anti deformity position includes hip extension with neutral rotation andapproximately 20 to 30 of abduction, the knee must frequently isplaced in extension and the ankle in neutral. Possibleinterventions to attain these positions include the use of splints,wedges, foot boards and prone position. To enhance lower extremity circulation, ankle pump indicated while the patient is on bed rest. Quadriceps and gluteal muscles isometrics can help to maintain strength when the patient is prohibited to move due to recent skin grafting. When movement is allowed lower extremity exercises may include hip extension, straight leg raising heel slides and squatting.

  6. Ambulation program and timing: Early ambulation is an essential part of rehabilitation program) whether or not the patient has bum on the lower extremities,(however there can be problems associated with early ambulation including pain, bleeding, increased edema, venous stasis and delayed or poor wound healing.

  7. Factors influence ambulation

  8. Ambulation following skin graft: The initiation of ambulation following lower extremity skin grafting usually is dependent upon the establishment of competent circulation to the grafted area. The graft probably remains at risk for at least 10 to 20 days after skin grafting. For this reason ambulation protocols following skin grafting "usually have not been initiated until the tenth to fourteenth postoperative day. The graft should be inspected carefully following eachambulation trial. Prior to ambulation, the burned, lower extremity must first be provided with elastic bandage support for thevascular system and help to controLejderna. venous stasis and dependent pain.

  9. Severe discomfort or pain during or after ambulation can bean indicator of potential graft problems. If discoloration, yXfibleeding breakdown, or edema occur, the frequency or distance^; the patient ambulates may need to be decreased or the vascular support to the lower extremities may need to be increased. Following skin grafting, some patient will be unable to safely stand due to Orthostatic hypotension; if immobilization and bed^ reslhas occurred. These patients may require the use of(a~tilting^ ^JabJe)to gradually achieve an upright position. The PatientbTood pressure should be monitored during this procedure.

  10. Once patients are able to tolerate standing on the tilting table, they can ambulate from the table)Patient who have been allowed to sit out of bed prior to dangling usually doesn't require the use of tilting table. Some patients may need to begin ambulation in the parallel bars while other can begin from bed side or chair. Once ambulation has been initiated following skin grafting, the patient should be advanced to independent ambulation as rapidly as possible. Walkers ,canes and crutches can be used but they should be discontinued as soon as possible to facilitate normal gait pattern. The next step is to increase the distance of ambulation and improve the quality of gait. Patient often exhibits an antaligic gait characterized by flexion at the knees, hips and trunk

  11. Emphasizing a heel to toe gait pattern with equal step lengths, reciprocal body motion and good body alignment will help to maintain the quality of gait and to prevent long term postural changes. A wide variety of physical equipment (e.g treadmill, BAPS board, bicycle, ramps) can 'be used to enhance gait training, Several gait deviations occur frequently in the patient with a lower extremity burn although many may correct themselves once the patient's wounds heal and pain diminishes.

  12. Common gait deviations following burn injuries: Increase hip flexion Decrease Weight bearing on affected lower extremity Stance phase on affected lower extremity Swing phase on non affected lower extremity. Wide base of support Trunk rotation Pelvic mobility • Improve step alteration • Forward trunk Position* • Inadequate hip abduction • Hip external rotation. • Knee flexion or extension maintained throughout cycle • Ankle planter flexion with no heel strike. • Poor weight shift.

  13. Some of these deviations can be minimized by proper positioning and aggressive exercise during the acute phase of, burn care Problems that remain after the initiation of ambulation often can be corrected with an appropriate exercise program The use of mirrors will provide the patient with visual feed back -about postural and gait deviations.

  14. Gait Training Suggestions for Lengthening Gastrocnemius & Soleus Muscles: Burns on the posterior lower extremity from popliteal space to Achilles tendon areas after result in atypical standing posture and gait pattern. This distribution frequently results in temporary shortening of the gastrocnemius- soleus muscles. Current treatment approaches for lengthening gastrocnemius-soleus muscles may gradually classified as static or dynamic innature

  15. Static stretching of these muscles can be achieved by splinting, use of tilting tables-towel stretch or standing on wedge. A more dynamic stretching of these muscTesTcan often be derived from stair climbing, ramp ambulation or the use of shoe wedges. Shoe wedges are not commonly used during acute burn "^refiabilitation because pedal edema or occurrence of sensitive foot toe burns negate the use of constructive foot wear. An alternative technique for stretching gastrocnemius-soleus muscles essentially incorporates a portable human "Wedge block" (i.e. shoe) that facilitates dynamic heel cord lengthening by taking advantage of gravity and weight shift.

  16. Three Criteria are Recommended for Selecting this Method: First: The patient should be trusting and light weight relative to Physiotherapist. Second: The patient should have been non-weight bearing on the involved extremity for a period of seven days or less. Third: The therapist should wear comfortable foot wear that will disperse the compression forces from the partial, body weight of the patient. Technique: To begin this gait training technique both Patient and therapist should stand facing each other in a large room. The Patient and therapist grasp each other arms.

  17. STRETCHING EXERCISES Definition of stretching: A general term used to describe any(therapeutic maneuver designed to lengthen (elongate) pathologically shortened soft-tissue structures and thereby to increase range of motion (Agre, 1978). Stretching is a term sometimes used interchangeably with flexibility (Extensibility) which refers to the ability of muscle to relax and yield to a stretch force (Basmajian, 1973). Stretching exercise is considered one of the physical therapy modalities designed to treat contracture. Definition of contracture: It means shortening of muscle or other tissues that cross a joint which results in limitation of joint motion, and it is described by identifying the tight muscle action i.e. tight elbow flexor equal elbow flexion contracture and limitation of extension of elbow (Kendall and McCreay, 1983).

  18. Types of contracture: A. Reversible contracture: 1. Myostatic contracture: It means significant loss of range of motion due to adaptive shortening, it occur particularly in two joint muscle such as hamstrings, rectus femoris or gastrocnemius. However there is no tissue pathology present. 2. Scar tissue adhesions: It means laying down scar tissue between normal tissues, which results in scar tissue adhesions. 3. Fibrotic adhesions: It means fibrotic changes of soft tissues as a result of chronic inflammation. 4. Pseudomyostatic contracture: It means limitation of motion due to hypertonicity caused by a central nervous system lesion.

  19. B. Irreversible contracture: It means a permanent loss of extensibility of soft tissues that cannot be released by non-surgical treatment (Cummings et al.,1983). Types of contracture • Reversible contracture (Released by stretching ex's) Myostatic Cont. Scar Tissue Fibrotic Adhesion Pseudomyostatic contracture • Irreversible contracture - Released by surgical ttt) In relation to bum, patients may be susceptible to different types of soft tissue tightness with varying times of onset (table 3) (Cummings et al., 1983).

  20. Table (3): Timeline for development of various tissue tightness.

  21. Contracture is defined as the lack of full of passive range of motion resulting from joint, muscle, or soft tissue limitations. Contracture can be divided into 3 categories according to the anatomical location of pathological changes: Arthrogenic, Myogenic (muscular) and connective tissue contracture (table 4). (Kottke and Lehmann, 1990).

  22. Table (4): Effects of immobility and musculoskeletal conditions on the development of contracture.

  23. Burn patient's exercises especially stretching exercises are designed primarily to prevent the development of burn scar contracture and to avoid the deleterious effects of in-patient hospitalization. An understanding of the qualities of contractile and noncontractile tissues and their responses to immobilization and stretch will assist the therapist in selecting the safest and most effective stretching procedures for patients (Richard and Staley, 1994).

  24. TYPES OF STRETCHINCFirst classification:Stretching • Passive stretching • Manual S. • Mechanical S. • Cyclic mechanical S • Active inhibition • Hold - Relax. • Hold-Relax-Contract. • Agonist contraction. • other types • Self-stretching • Selective S. • Over S.

  25. I. Passive Stretching: While the patient is relaxed, an external force applied either manually or mechanically, lengthens the shortened tissues. 1. Manual passive stretching: External force (intensity): applied by the therapist. Speed: Slow. Duration: Applied for at least 15, 30 sec but up till now there is no specific time has been determined to be the most effective duration for passive stretching. The intensity and duration of the stretch are dependent on the patient's tolerance and the therapist's strength and endurance. Manual passive stretching is a rather short duration stretch. The gains achieved in range of motion are transient and are attributed to temporary sarcomere give (elastic changes in actin-myosin overlap) (Cherry, 1980).

  26. Maintained versus ballistic stretch:Maintained or static stretch: The stretch force is maintained for 15, 30 or 45 sec or longer, a slow, maintained stretch is less likely to facilitate the stretch reflex. Ballistic stretching: On the other hand, ballistic stretching is a high intensity, very short duration (bouncing stretch). A ballistic stretch quickly lengthens the muscle spindle and facilitates the stretch reflex (Sady et al., 1982). 2. Mechanical passive stretching: External force (intensity): 5 to 15 lb applied by pulley system cast or splint. Duration: from 20 to 30 min. or as long as several hours (Kottke, 1966). Manual versus mechanical stretching: Mechanical stretching (5 to 15 lb) stretch force applied 1 hour per day) has been shown to be significantly more effective than manual passive stretching over a 4 week period in patients with long standing bilateral knee flexion contracture. The gains achieved in range of motion are permanent lengthening (plastic changes) in contractile and noncontractile tissues. (Light etal.1984).

  27. 3. Cyclic mechanical stretching: Passive stretching using a mechanical device such as the Autorange can be done in a cyclic mode. Starring reported significant increases in hamstring muscle flexibility using a 20 sec, high intensity (up to patient's pain tolerance) mechanical stretching. The intensity of the stretch, the length of each stretch cycle, and the number of stretch cycles per minutes can be adjusted on the mechanical stretching unit.

  28. II. Active inhibition: The patient reflexively relaxes the muscle to be elongated prior to the stretching maneuver. This type of stretching is only possible if the m.s to be elongated is normally innervated and under voluntary control. There are 3 variations of active inhibition techniques: 1- Contract -Relax (Hold - Relax): The patient performs an isometric contraction of the tight m.s before it is passively lengthened. This technique depends on autogenic inhibition, the Golgi tendon organ (GTO) may fire and inhibit tension in the muscle so that it can more easily lengthened. 2. Contract - Relax- Contract (Hold - Relax - Contract): The patient performs an isometric contraction of the tight m.s then relaxation followed by a concentric contraction of the m.s opposite the tight m.s. As the muscle opposite the tight m.s shortens, the tight m.s lengthens. This technique combines autogenic inhibition and reciprocal inhibition to lengthen a tight m.s.

  29. 3. Agonist contraction: The term Agonist refers to the m.s opposite the tight m.s and antagonist therefore refers to the tight m.s. The patient dynamically contracts (shortens) the m.s opposite the tight m.s against resistance. This causes a reciprocal inhibition of the tight m.s, and the tight m.s lengthens more easily as the extremity moves (Sady et al., 1982; Tannigawa, 1972). III. Self stretching: The patient may passively stretch out his own contractures by using his body weight as the stretch force (Kisner and Colby, 2002).

  30. IV. Selective stretch: By applying stretching techniques selectively and allowing limitation of motion in specific joints. For example: in cervical and thoracic lesions the patients will not have active control of the back extensors, so that moderate tightness will increase the stability of the trunk. (Kisner and Colby, 2002). V. Over stretch: Over stretch is a stretch well beyond the normal range of joint motion and the surrounding soft tissues, resulting in hypermobility. Over stretch may be necessary for people participating in sports such as gymnastics (Kottke, 1971).

  31. Second classification: Stretching Ballistic stretchingStatic stretching Dynamic, Fast, isotonic Isometric, controlled or kinetic or slow.

  32. 1-Ballistic stretching: Ballistic stretching is usually associated with bouncing. Ballistic stretching helps to develop dynamic flexibility because most activities and movements are dynamic in nature. During ballistic stretching procedure if a sudden stretch is applied to a m.s, a reflex action is set into motion that causes the m.s to contract. As a result, muscular tension will increase, making it more difficult to stretch out the connective tissues. To use ballistic stretching under safe condition, Zachazewski (1989) recommends Progressive velocity flexibility programs (PVFP) (table 5).

  33. Table (5): Progressive velocity flexibility program. Static stretching SSER- Slow, short end range stretching SFR- slow, full range stretching FSER- Fast, short end range stretching FFR- fast, full range stretching

  34. 2- Static stretching: Static stretching involves a position that is held for a period of time. Static stretching helps to develop static flexibility. Short bouts of static stretching reduced electrical activity within the muscle, which theoretically facilitates stretching. Arguments against static stretching: Some claims that static stretching is boring. Some claim that static stretching "may be practiced exclusively, at the expense of ballistic exercise. An optimal blending of both stretching methods is the solution to this problem (Schultz, 979).

  35. Indications of stretching: ROM is limited due to • Contractures • Adhesions. • Scar tissue formation • Anticipated deformities (Agre, 1978) Procedures for applying passive stretching: 1. Evaluation of the patient: • Detect the cause of decreased motion (joint stiffness or soft tissue contracture). • Evaluate m.s strength of m.s opposing tissue tightness. • Detect exposed tendon, dystrophic calcification, and IV lines.

  36. 2. Preparation of patient for stretching: Detect the best type of stretching technique. Explain the purpose of stretching to the patient. Position the patient in comfortabie and stable position that will allow the therapist to do the stretching technique properly. Explain the procedure to the patient. Ask the patient to avoid restrictive cloths. Ask the patient to use relaxation techniques. Apply heat to tight soft tissue; heat will increase the extensibility of soft tissues.

  37. Procedure of stretching: Hand placement: • Grasp proximal and distal to the joint where motion is to occur. • The grasp with the palm of the hand. • The grasp must be firm but not to cause pain. • To avoid compressive force over the joint apply distraction force. • Move the extremity slowly through the free range to the point of restriction. • Then apply the stretch force in a gentle, slow and sustained maneuver, take the joint to the point of tightness and then move just beyond. • Hold the patient in the stretched position at least 15 to 30 sec. or longer. • If the tension under your hand decreases, move the joint a little further. • Gradually release the stretch force. • Ask the patient to rest then repeat the technique.

  38. N.B: • Don't attempt to gain the full range in one ttt session. • To stretch 2 joint m.s, stretch the m.s at one joint at a time, then over all joints simultaneously until optimum length of soft tissue is achieved (Beaulieu, 1981).

  39. Precautions and contraindications to stretching: A. Precautions of stretching: • Osteoporosis due to disease, prolonged bed rest, prolonged use of steroids and age. • After immobilization for long periods avoids vigorous stretching because the tissue looses it s tensile strength. • Avoid stretching of edematous tissue, as it is more susceptible to injury than normal tissue. • Avoid stretching of weak m .s. • Avoid stretching exposed tendon because it is more susceptible to rupture. • Take care of IV lines during stretching.

  40. B. Contraindications of stretching: • Bony block. • Recent. • Evidence of acute inflammatory or infectious process. • Sharp pain (acute stage of bum). • Evidence of tissue trauma. • When contracture is needed to develop stability. • Exposed joints. • Exposed tendon. • Thrombophlebitis. • D.V.T • Compartment syndrome. • Fresh skin graft (Kottke, 1971).

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