JBJS | Gait Characteristics After Limb‐Sparing Surgery with Sciatic Nerve Resection : A Report of Two Cases

The Journal of Bone & Joint Surgery, Volume 84, Issue 2

Case Reports | February 01, 2002

Gait Characteristics After Limb‐Sparing Surgery with Sciatic Nerve Resection : A Report of Two Cases

Akira Kawai, MD; Takeshi Miyakawa; Masuo Senda, MD; Hirosuke Endo, MD; Noriko Naito, MD; Minori Umeda; Hajime Inoue, MD

Investigation performed at the Department of Orthopaedic Surgery, Okayama University Medical School, Okayama, Japan

Akira Kawai, MD
Masuo Senda, MD
Hirosuke Endo, MD
Noriko Naito, MD
Hajime Inoue, MD
Department of Orthopaedic Surgery, Okayama University Medical School, 2-5-1 Shikata-cho, Okayama 700-8558, Japan. E-mail address for A. Kawai: akirak@md.okayama-u.ac.jp

Takeshi Miyakawa
Department of Health and Sports Science, Kawasaki University of Medical Welfare, 577 Matsushima, Kurashiki 701-0192, Japan

Minori Umeda
Okayama Southern Institute of Health, 408-1 Hirata, Okayama 700-0952, Japan

In support of their research or preparation of this manuscript, one or more of the authors received grants or outside funding through the Grant-in-Aid for Cancer Research (12-11) from the Ministry of Health and Welfare. None of the authors received payments or other benefits or a commitment or agreement to provide such benefits from a commercial entity. No commercial entity paid or directed, or agreed to pay or direct, any benefits to any research fund, foundation, educational institution, or other charitable or nonprofit organization with which the authors are affiliated or associated.

The Journal of Bone & Joint Surgery. 2002; 84:264-268

5 Recommendations (Recommend) | 3 Comments | Saved by 3 Users Save Case

text A A A

Introduction

Introduction | Case Reports | Discussion | References

Limb-sparing surgery may be considered for the treatment of soft-tissue sarcoma even when resection of a major neurovascular bundle is necessary to achieve a satisfactory surgical margin^1,2. Function of an upper extremity with loss of one major nerve is often superior to function with use of a prosthesis after amputation³. In the lower extremity, limb-sparing surgery may be considered even when the sciatic nerve must be resected because of tumor involvement. Resection of the sciatic nerve results in a sensory loss distal to the knee and motor dysfunction of the knee, foot, and ankle. However, an analysis of functional loss after sciatic nerve resection for the treatment of soft-tissue sarcoma has been reported only once to our knowledge⁴.

We treated two patients with a soft-tissue sarcoma with a limb-sparing procedure that included resection of the sciatic nerve. During rehabilitation, both patients walked very slowly with excessive lateral displacement of the trunk along the line of progression. Very slight improvement in their gait was noted at the two and five-year follow-up examinations. We assessed walking function and gait characteristics of the two patients with use of a nonparametric objective evaluation system and a subjective gait analysis technique to obtain quantitative measures of functional loss^5-8. The results were compared with those of patients with a hip disarticulation who used a prosthesis and with the findings in healthy individuals.

View Large | Download Slide(.ppt)
Add to My JBJS

Fig. 1:: Ground-reaction force diagrams, with the broken line indicating a healthy subject and the solid line indicating the involved limb of a patient with resection of the sciatic nerve. A: Vertical force. The healthy subject showed a distinctive bimodal curve representing the loading response peak after heel-strike and the terminal-stance peak before toe-off of a normal gait. The curve for the involved limb shows a plateau instead of the two separate peaks. B: Anteriorly and posteriorly directed forces. The healthy subject showed an anteriorly directed force at the loading response phase and a posterior directed force at the terminal-stance phase. The curve for the involved limb shows a decrease in these forces.

View Larger

TABLE I: Clinical Assessment According to the System of the International Society of Limb Salvage

*Mean values for the six subjects. †P < 0.01 for the difference between the patients with sciatic nerve resection and those with hip disarticulation (Student t test). ‡P < 0.001 for the difference between the patients with sciatic nerve resection and those with hip disarticulation (Student t test).

	Pain	Function	Emotional Acceptance	Supports	Walking Ability	Gait	Total
Case 1	5	1	4	3	3	1	17 (57%)
Case 2	5	1	4	1	3	1	15 (50%)
Hip disarticulation*	3.9	1.1	0.9†	1.0	1.6†	0.5	??9 (30%)‡

Add to My JBJS

TABLE I: Clinical Assessment According to the System of the International Society of Limb Salvage

	Pain	Function	Emotional Acceptance	Supports	Walking Ability	Gait	Total
Case 1	5	1	4	3	3	1	17 (57%)
Case 2	5	1	4	1	3	1	15 (50%)
Hip disarticulation*	3.9	1.1	0.9†	1.0	1.6†	0.5	??9 (30%)‡

View Larger

TABLE II: Stride Characteristics

*The values are given as the mean and the standard deviation. †P values for the difference between the patients with sciatic nerve resection and the normal subjects (Student t test). ‡P values for the difference between the patients with sciatic nerve resection and those with hip disarticulation (Student t test).

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Velocity (m/min)	29.7 4.6	?83.4 9.2	51.1 10.3	<0.001	0.035
Stride (m)	0.70 0.05	?1.39 0.09	1.32 0.24	<0.001	0.018
Cadence (steps/min)	86.9 10.2	119.6 7.6	81.6 5.9	<0.001	0.402
Stance-time asymmetry	0.65 0.15	None	0.71 0.10	None	0.528

Add to My JBJS

TABLE II: Stride Characteristics

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Velocity (m/min)	29.7 4.6	?83.4 9.2	51.1 10.3	<0.001	0.035
Stride (m)	0.70 0.05	?1.39 0.09	1.32 0.24	<0.001	0.018
Cadence (steps/min)	86.9 10.2	119.6 7.6	81.6 5.9	<0.001	0.402
Stance-time asymmetry	0.65 0.15	None	0.71 0.10	None	0.528

View Larger

TABLE III: Arc of Pelvic Displacement During a Stride

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Lateral displacement (mm)	84.1 0.63	57.1 14.2	116.0 8.7	0.033	0.015
Vertical displacement (mm)	35.6 10.3	56.2 8.5	?80.5 10.6	0.017	0.050
Arc of pelvic rotation (deg)	12.4 1.5	27.1 2.3	?23.4 1.9	<0.001	<0.001

Add to My JBJS

TABLE III: Arc of Pelvic Displacement During a Stride

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Lateral displacement (mm)	84.1 0.63	57.1 14.2	116.0 8.7	0.033	0.015
Vertical displacement (mm)	35.6 10.3	56.2 8.5	?80.5 10.6	0.017	0.050
Arc of pelvic rotation (deg)	12.4 1.5	27.1 2.3	?23.4 1.9	<0.001	<0.001

Case Reports

Introduction | Case Reports | Discussion | References

A fifty-one-year-old man (Case 1) and a twenty-six-year-old woman (Case 2) had a limb-sparing operation with sciatic nerve resection. Both patients had a malignant peripheral nerve-sheath tumor that developed in the sciatic nerve in the proximal half of the posterior aspect of the thigh. The surgical stage according to the Musculoskeletal Tumor Society Classification⁹ was IIB in each patient. Wide resection of the tumor involving the sciatic nerve (both the tibial nerve and common peroneal nerve branches) was performed. The muscles that were resected included the semimembranosus, semitendinosus, and long head of the biceps femoris in both patients. There were no postoperative complications. At the time of gait analysis, at five years for one patient and at two years for the other, neither patient had distant metastasis or local recurrence.

Because of the sciatic nerve resection, neither patient had muscle strength, sensation, or proprioception distal to the ankle joint of the affected limb. In Case 1, the muscle strengths of the involved limb measured by manual muscle testing¹⁰ were 5 for the knee extensors, 3 for the knee flexors, 0 for the ankle and foot extensors, and 0 for the ankle and foot flexors. In Case 2, the strength was 5 for the knee extensors, 3 for the knee flexors, 0 for the ankle and foot extensors, and 0 for the ankle and foot flexors. The functional score according to the functional evaluation system of the International Society of Limb Salvage (ISOLS)¹¹ was 17 (57%) for Case 1 and 15 (50%) for Case 2 (Table I).

The patients had no pain or phantom sensation in the treated limb (ISOLS pain score of 5) and were satisfied with the treatment result (ISOLS emotional acceptance score of 4). However, they had partial occupational restriction (ISOLS function score of 1) and a major cosmetic gait abnormality with obvious stance-time asymmetry (ISOLS gait score of 1). Although they could walk outside, walking on stairs or slopes was difficult (ISOLS walking ability score of 3). Because both patients required an ankle-foot orthosis to support the ankle, the highest score that they could be assigned in the supports category was 3 of 5 (the ISOLS supports score was 3 for Case 1 and 1 for Case 2). One patient (Case 2) used a cane for walking outside. She preferred to use a cane for walking a distance because she felt that it reduced fatigue. During gait analysis sessions, both patients walked while wearing a plastic ankle-foot orthosis but not with a cane or crutches.

Gait Analysis

Six individuals with a hip disarticulation (four men and two women; mean age, twenty-three years) who used a Canadian hip disarticulation prosthesis with a satisfactory fit and eight healthy subjects (four men and four women; mean age, twenty-four years) who did not have neuromuscular or skeletal disease were studied for comparison.

The temporal-distance parameters and kinematic data on walking were obtained with a motion analyzer¹² (ELITE Plus; BTS [Bioengineering Technology and Systems], Milan, Italy). The system included four 100-hertz television cameras, and it detected the positions of reflective markers glued on the subjects. The markers were placed bilaterally on the acromion, the anterior superior iliac crest, the center of the greater trochanter, the lateral joint line of the knee, the lateral malleolus of the ankle, the lateral side of the base of the calcaneus, and the lateral side of the base of the fifth metatarsal. The three-dimensional coordinates of each marker were computed, and the temporal-distance and kinematic variables (lateral and vertical displacements and arc of rotation) were calculated with original software written by one of us (T.M.).

Gait analysis showed that the walking velocity of our two patients with sciatic nerve resection was slow, the stride length was short, and the stance-time asymmetry resembled that of the subjects with hip disarticulation (Table II). Both patients had excessive lateral displacement of the single sinusoidal curve for each gait cycle along the line of progression. In contrast, the vertical displacement of the pelvis during a stride was small. The patients reduced forward displacement of the uninvolved limb during the stance-time-period of the involved limb. The arc of pelvic rotation during a stride was also reduced (Table III).

Ground reaction forces were measured with a force-plate (Kistler, Winterthur, Switzerland) built into the walkway (Fig. 1). There were two distinct peaks (at the loading response and terminal stance phases) separated by a mid-stance valley in the vertical force of the unaffected limb of the two patients and of both limbs of the healthy controls. The curve for the the involved limb of the patients with sciatic nerve resection showed a plateau. In the horizontal fore-aft plane, the anteriorly directed loading response and the posteriorly directed driving force of the involved limb were reduced in both patients.

To clarify the role of the quadriceps muscles during walking in these patients, dynamic electromyograms were made with an electromyographic amplifier (Omniace RT3200N; NEC, Tokyo, Japan) and the use of telemetric surface electrodes. Cathodes were placed on the motor point of selected muscles, near the center of the muscle, and anodes were placed 3 cm distal to the cathode. As expected, there were no major activities in the tibialis anterior and gastrocnemius muscles of the involved limb of the patients. The rectus femoris muscle of the involved limb had prolonged excessive waves in amplitude and density during the stance phase.

Discussion

Introduction | Case Reports | Discussion | References

Limb-sparing is now widely accepted as a treatment option for the majority of soft-tissue sarcomas of the extremities^3,13. There are numerous reports about the low recurrence rates after resection of the tumors with adequately wide margins^14-17. However, studies about the functional loss following the procedure are scarce^4,18. In the present study, the walking function and gait characteristics of two patients who had had limb-sparing surgery with sciatic nerve resection were analyzed with use of a nonparametric objective evaluation system and a subjective method of gait analysis.

According to the evaluation system of the ISOLS¹¹, the functional level of the patients with sciatic nerve resection was as low as 50% of normal. The functional level of these patients was inferior to that achieved by prosthetic knee replacement or rotationplasty, which has been reported to be about 80% of normal6,7,19. However, their results were better than those of the patients with a hip disarticulation and a well-fitting prosthesis in our comparison group.

Among parameters of gait analysis, free-walking velocity is one of the most useful indicators of the overall walking efficiency20. Decreased velocity associated with a reduced stride length is consistent with a more unstable and inefficient gait pattern. Patients with arthritis at either the hip or the knee joint decrease the walking velocity in an effort to relieve pain. Although our patients had no pain during walking, they walked much more slowly than controls did, and they even walked more slowly than subjects with a hip disarticulation and those with an above-the-knee amputation (as reported in the literature21,22). Proprioceptive impairment obstructs walking because it prevents the patient from knowing the position of the leg and the type of contact with the floor. As a result, the patient is unsure when it is safe to transfer body weight onto the limb. Muscle weakness may also contribute to the slow walking velocity. We thought that the slow walking velocity of our patients was due mainly to the combined loss of the sensory and motor function of the foot and ankle.

The magnitude of the vertical ground reaction force changes with variations in gait speed23. The decreased walking velocity of our patients may have been responsible for the changes of the vertical ground reaction force. The reduced fore-aft force on the involved limb was considered to be the result of both the decreased walking velocity and the loss of motor function of the foot and ankle. The anteriorly directed force at the loading response phase was reduced secondary to the slower walking velocity. A loss of motor function of the flexors in the foot decreases the driving force during toe-off and was probably the primary reason for the reduction of the posteriorly directed force at terminal stance.

The electromyograms of the patients demonstrated excessive activity in the quadriceps muscles of the involved limb during stance phase; this may be the compensatory action required to stabilize the knee and ankle, which were unstable because of the sensory and motor impairments following the resection of the sciatic nerve and the hamstring muscles. Additional inefficient muscle work is likely to increase energy consumption^6,24-26, so patients with sciatic nerve resection may walk with unnecessarily high energy consumption. Studies of the energy cost of walking for subjects with sciatic nerve resection would be useful.

As has been demonstrated in patients with proximal femoral replacement²⁷, an assistive device such as a cane might alter the patterns and efficiency of the gait of patients with sciatic nerve resection. Kinematic and kinetic studies of the effects of assistive devices on the walking ability of such patients are warranted.

Surgery for malignant tumors can be radical, involving the sciatic nerve, without necessarily depriving the patient of the lower limb. The present study showed, however, that such limb-sparing surgery results in a major walking disability. This observation is in accordance with the findings of Suzuki et al., who reported the importance of normal foot function for successful limb salvage²⁸. Both patients in the current study walked more slowly than did subjects with a hip disarticulation. Amputation has a major cosmetic disadvantage, but it offers greater opportunities for sports participation^29,30. Nevertheless, both of our patients stated that, despite the functional limitation, the limb-sparing was preferable to an amputation. The type of operation (limb-sparing or amputation) must be decided with each patient. The results of this study may help surgeons and patients to make a decision regarding limb-sparing surgery with sciatic nerve resection for the treatment of a soft-tissue sarcoma.

Note: The authors thank Cherie McCown and Aki Yoshida for assistance with the preparation of this manuscript.

References

Introduction | Case Reports | Discussion | References

Hohenberger P, Allenberg JR, Schlag PM,Reichardt P.. Results of surgery and multimodal therapy for patients with soft tissue sarcoma invading to vascular structures. Cancer,1999;85: 396-408. 85396 1999 [PubMed]

Kawai A, Hashizume H, Inoue H, Uchida H,Sano S. Vascular reconstruction in limb salvage operations for soft tissue tumors of the extremities. Clin Orthop,1996;332: 215-22. 332215 1996 [PubMed]

O’Connor MI. Surgical management of malignant soft-tissue tumors. In: Simon MA, Springfield D, editors. Surgery for bone and soft-tissue tumors. Philadelphia: Lippincott-Raven; 1998. p 555-65.

Fuchs B, Davis AM, Wunder JS, Bell RS, Masri BA, Isler M, Turcotte R,Rock MG. Sciatic nerve resection in the thigh: a functional evaluation. Clin Orthop,2001;382: 34-41. 38234 2001 [PubMed]

Otis JC, Backus SI, Barr AE, Peterson MGE, Dayan AJ. Quantitative assessment of patient performance after major limb reconstruction. In: Brown KLB, editor. Complications of limb salvage, prevention, management and outcome. Rennes, Montreal: International Society of Limb Salvage; 1991. p 25-31.

Kawai A, Backus SI, Otis JC,Healey JH. Interrelationships of clinical outcome, length of resection, and energy cost of walking after prosthetic knee replacement following resection of a malignant tumor of the distal aspect of the femur. J Bone Joint Surg Am,1998;80: 822-31. 80822 1998 [PubMed]

Hillmann A, Rosenbaum D, Schröter J, Gosheger G, Hoffmann C,Winkelmann W. Electromyographic and gait analysis of forty-three patients after rotationplasty. J Bone Joint Surg Am,2000;82: 187-96. 82187 2000 [PubMed]

Romano CL, Frigo C, Randelli G,Pedotti A. Analysis of the gait of adults who had residua of congenital dysplasia of the hip. J Bone Joint Surg Am,1996;78: 1468-79. 781468 1996 [PubMed]

Enneking WF. A system of staging musculoskeletal neoplasms. Clin Orthop,1986;204: 9-24. 2049 1986 [PubMed]

Hislop HJ, Montgomery J.Muscle testing. Philadelphia: WB Saunders; 1995. p 2-9.

Enneking WF, Dunham W, Gebhardt MC, Malawar M,Pritchard DJ. A system for the functional evaluation of reconstructive procedures after surgical treatment of tumors of the musculoskeletal system. Clin Orthop,1993;286: 241-6. 286241 1993 [PubMed]

Baroni G, Ferrigno G. Real-time motion analysis by means of passive markers. In: Miyashita M, Fukunaga T, editors. XVIth ISB Tokyo Congress Book of Abstracts. 1997. p 1.

Baldini EH, Goldberg J, Jenner C, Manola JB, Demetri GD, Fletcher CD,Singer S. Long-term outcomes after function-sparing surgery without radiotherapy for soft tissue sarcoma of the extremities and trunk. J Clin Oncol,1999;17: 3252-9. 173252 1999 [PubMed]

Fleming JB, Berman RS, Cheng SC, Chen NP, Hunt KK, Feig BW, Respondek PM, Yasko AW, Pollack A, Patel SR, Burgess MA, Papadopoulos NE, Plager C, Zagars G, Benjamin RS, Pollock RE,Pisters PW. Long-term outcome of patients with American Joint Committee on Cancer stage IIB extremity soft tissue sarcomas. J Clin Oncol,1999;17: 2772-80. 172772 1999 [PubMed]

Lewis JJ, Leung D, Casper ES, Woodruff J, Hajdu SI,Brennan MF. Multifactorial analysis of long-term follow-up (more than 5 years) of primary extremity sarcoma. Arch Surg,1999;134: 190-4. 134190 1999 [PubMed]

Lewis JJ, Leung D, Espat J, Woodruff JM,Brennan MF. Effect of reresection in extremity soft tissue sarcoma. Ann Surg,2000;231: 655-63. 231655 2000 [PubMed]

Pisters PW, Leung DH, Woodruff J, Shi W,Brennan MF. Analysis of prognostic factors in 1,041 patients with localized soft tissue sarcomas of the extremities. J Clin Oncol,1996;14: 1679-89. 141679 1996 [PubMed]

Keus RB, Rutgers EJ, Ho GH, Gortzak E, Albus-Lutter CE,Hart AA. Limb-sparing therapy of extremity soft tissue sarcomas: treatment outcome and long-term functional results. Eur J Cancer,1994;30A: 1459-63. 30A1459 1994 [PubMed]

Kawai A, Muschler GF, Lane JM, Otis JC,Healey JH. Prosthetic knee replacement after resection of a malignant tumor of the distal part of the femur. Medium to long-term results. J Bone Joint Surg Am,1998;80: 636-47. 80636 1998 [PubMed]

Zohman GL, Boardman DL, Eckardt JJ,Lane JM. Stride analysis after proximal tibial replacement. Clin Orthop,1997;339: 180-4. 339180 1997 [PubMed]

Harris IE, Leff AR, Gitelis S,Simon MA. Function after amputation, arthrodesis, or arthroplasty for tumors about the knee. J Bone Joint Surg Am,1990;72: 1477-85. 721477 1990 [PubMed]

Otis JC, Lane JM, Kroll MA, Backus SI, Healey JH. Kinesiological measurements in patients with various limb salvage or amputation procedures for tumor removal. In: Yamamuro T, editor. New developments for limb salvage in musculoskeletal tumors. Kyocera Orthopaedic Symposium. Tokyo: Springer; 1989. p 3-7

Perry J. Gait analysis, normal and pathological function. Thorofare, NJ: Slack; 1992. p 413-21

McClenaghan BA, Krajbich JI, Pirone AM, Koheil R,Longmuir P. Comparative assessment of gait after limb-salvage procedures. J Bone Joint Surg Am,1989;71: 1178-82. 711178 1989 [PubMed]

Otis JC, Lane JM,Kroll MA. Energy cost during gait in osteosarcoma patients after resection and knee replacement and after above-the-knee amputation. J Bone Joint Surg Am,1985;67: 606-11. 67606 1985 [PubMed]

Waters RL, Perry J, Antonelli D,Hislop H. Energy cost of walking of amputees: the influence of level of amputation. J Bone Joint Surg Am,1976;58: 42-6. 5842 1976 [PubMed]

Kawai A, Backus SI, Otis JC, Inoue H,Healey JH. Gait characteristics of patients after proximal femoral replacement for malignant bone tumour. J Bone Joint Surg Br,2000;82: 666-9. 82666 2000 [PubMed]

Suzuki R, Hirano T, Fujita M, Matsusaka N. Gait analysis in patients with osteosarcoma treated by limb salvage procedures. Compared with those treated with amputation. In: Yamamuro T, editor. New developments for limb salvage in musculoskeletal tumors. Kyocera Orthopaedic Symposium. Tokyo: Springer; 1989. p 9-15

Sugarbaker PH, Barofsky I, Rosenberg SA,Gianola FJ. Quality of life assessment of patients in extremity sarcoma clinical trials. Surgery,1982;91: 17-23. 9117 1982 [PubMed]

Weddington WW Jr, Segraves KB,Simon MA. Psychological outcome of extremity sarcoma survivors undergoing amputation or limb salvage. J Clin Oncol,1985;3: 1393-9. 31393 1985 [PubMed]

Topics

View Large | Download Slide(.ppt)
Add to My JBJS

View Larger

TABLE I: Clinical Assessment According to the System of the International Society of Limb Salvage

	Pain	Function	Emotional Acceptance	Supports	Walking Ability	Gait	Total
Case 1	5	1	4	3	3	1	17 (57%)
Case 2	5	1	4	1	3	1	15 (50%)
Hip disarticulation*	3.9	1.1	0.9†	1.0	1.6†	0.5	??9 (30%)‡

Add to My JBJS

TABLE I: Clinical Assessment According to the System of the International Society of Limb Salvage

	Pain	Function	Emotional Acceptance	Supports	Walking Ability	Gait	Total
Case 1	5	1	4	3	3	1	17 (57%)
Case 2	5	1	4	1	3	1	15 (50%)
Hip disarticulation*	3.9	1.1	0.9†	1.0	1.6†	0.5	??9 (30%)‡

View Larger

TABLE II: Stride Characteristics

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Velocity (m/min)	29.7 4.6	?83.4 9.2	51.1 10.3	<0.001	0.035
Stride (m)	0.70 0.05	?1.39 0.09	1.32 0.24	<0.001	0.018
Cadence (steps/min)	86.9 10.2	119.6 7.6	81.6 5.9	<0.001	0.402
Stance-time asymmetry	0.65 0.15	None	0.71 0.10	None	0.528

Add to My JBJS

TABLE II: Stride Characteristics

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Velocity (m/min)	29.7 4.6	?83.4 9.2	51.1 10.3	<0.001	0.035
Stride (m)	0.70 0.05	?1.39 0.09	1.32 0.24	<0.001	0.018
Cadence (steps/min)	86.9 10.2	119.6 7.6	81.6 5.9	<0.001	0.402
Stance-time asymmetry	0.65 0.15	None	0.71 0.10	None	0.528

View Larger

TABLE III: Arc of Pelvic Displacement During a Stride

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Lateral displacement (mm)	84.1 0.63	57.1 14.2	116.0 8.7	0.033	0.015
Vertical displacement (mm)	35.6 10.3	56.2 8.5	?80.5 10.6	0.017	0.050
Arc of pelvic rotation (deg)	12.4 1.5	27.1 2.3	?23.4 1.9	<0.001	<0.001

Add to My JBJS

TABLE III: Arc of Pelvic Displacement During a Stride

	Sciatic Nerve Resection*	Normal*	Hip Disarticulation*	P Value†	P Value‡
Lateral displacement (mm)	84.1 0.63	57.1 14.2	116.0 8.7	0.033	0.015
Vertical displacement (mm)	35.6 10.3	56.2 8.5	?80.5 10.6	0.017	0.050
Arc of pelvic rotation (deg)	12.4 1.5	27.1 2.3	?23.4 1.9	<0.001	<0.001