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Gait deviations

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Abnormal gait
Other namesGait abnormality, 走路外八字 (Taiwanese Chinese), Penguin-like walking
Though not an amputee, this subject displays spatiotemporal step variability and slight rotation of the upper body and pelvis.
SpecialtyOrthopedics

PM&R

Neurology
CausesNormal pressure hydrocephalus, Hydrocephalus, Parkinson's disease, Spinocerebellar Atrophy, Spinocerebellar Ataxia

Gait deviations are nominally referred to as any variation of standard human gait, typically manifesting as a coping mechanism in response to an anatomical impairment. Lower-limb amputees are unable to maintain the characteristic walking patterns of an able-bodied individual due to the removal of some portion of the impaired leg. Without the anatomical structure and neuromechanical control of the removed leg segment, amputees must use alternative compensatory strategies to walk efficiently. Prosthetic limbs provide support to the user and more advanced models attempt to mimic the function of the missing anatomy, including biomechanically controlled ankle and knee joints. However, amputees still display quantifiable differences in many measures of ambulation when compared to able-bodied individuals. Several common observations are whole-body movements, slower and wider steps, shorter strides, and increased sway.

Presentation and causes

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Patients with musculoskeletal pain, weakness or limited range of motion often present conditions such as Trendelenburg's sign, limping, myopathic gait and antalgic gait.

Patients who have peripheral neuropathy also experience numbness and tingling in their hands and feet. This can cause ambulation impairment, such as trouble climbing stairs or maintaining balance. Gait abnormality is also common in persons with nervous system problems such as cauda equina syndrome, multiple sclerosis, Parkinson's disease (with characteristic Parkinsonian gait), Alzheimer's disease, vitamin B12 deficiency, myasthenia gravis, normal pressure hydrocephalus, and Charcot–Marie–Tooth disease. Research has shown that neurological gait abnormalities are associated with an increased risk of falls in older adults.[1]

Orthopedic corrective treatments may also manifest into gait abnormality, such as lower extremity amputation, healed fractures, and arthroplasty (joint replacement). Difficulty in ambulation that results from chemotherapy is generally temporary in nature, though recovery times of six months to a year are common. Likewise, difficulty in walking due to arthritis or joint pains (antalgic gait) sometimes resolves spontaneously once the pain is gone.[2][3] Hemiplegic persons have circumduction gait, where the affected limb moves through an arc away from the body, and those with cerebral palsy often have scissoring gait.[citation needed]

Lower-limb amputations

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Human leg bones labeled
An athlete with a single below-knee amputation using a running blade prosthetic

Over 185,000 amputations occur annually, with approximately 86% of incidents being lower-limb amputations.[4] The majority of cases are reportedly caused by vascular disease (54%) and trauma (45%).[5] Lower-limb amputees are further categorized by where the amputation occurs with respect to the knee joint. However, 34.5% of individuals with an initial foot or ankle amputation experience a progression of symptoms leading to subsequent amputations at higher levels of limb loss.[6] Out of these reamputation cases, diabetic patients had a higher likelihood of requiring further amputations, regardless of initial amputation location.[6] The rate of amputation has decreased significantly with the introduction and optimization of revascularization to combat vascular disease.[7] An increasingly studied trend in amputation rates is the gender disparity of women receiving more surgical revascularization treatments and less amputations than male counterparts.[8][9]

Transtibial

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An amputation between the knee and ankle joints transecting the tibia, or shinbone, is referred to as a transtibial amputation. In this situation, the patient may retain volitional control over the knee joint. The cause of amputation may dictate the length of the residual limb and the corresponding level of control of the prosthesis. The main impairment for transtibial amputees is the lack of adjustment of the foot and ankle. The foot acts as a lever arm directly attached to the calf muscle, but more than that, it absorbs the impulse from the ground and adapts dynamically to changes in the ground's surface. Transtibial amputees lose the muscle activation pathways necessary for the physical ability to generate work about the ankle joint, as well as the somatosensory and proprioceptive pathways of the lower leg.[10]

Transfemoral

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Unlike transtibial amputations, transfemoral amputations occur between the hip and the knee joints, along the length the femur. Therefore, the patient's residual limb is controlled solely by the hip joint. Implementing a prosthetic leg requires the user to mechanically control the behaviors of the prosthetic knee and ankle joints through gross adjustments of the hip, rather than the finer and more precise movements of the missing joints.[11] Simple tasks such as walking on level ground, sit-to-stand transfers, and climbing stairs[12] require complex alternative muscle activation patterns[13] because the amputee cannot generate a moment about the prosthetic knee.[14] This poses a problem when knee flexion is required, especially during the transition from the stance phase to the swing phase. Transfemoral amputees, on average, have more variability in stride length and walking speed, more asymmetry in temporal measures between limbs, and have an overall slower walking speed than transtibial amputees.[15]

Compensatory Behaviors

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A man with two prosthetic legs uses a hands-free harness walking gait training device during a therapy session

Unimpaired human gait is characterized by its symmetry about the sagittal plane. In impaired individuals such as amputees, gait abnormalities are visible to the naked eye. Amputees often employ strategies known as protective gait behaviors to compensate for their impaired balance and control. These behaviors are most commonly categorized into increased general [body] and [torso] movement and increased variability of strides. The variability can manifest as a combination of differences in the length and width of the strides in comparison to the intact limb.

Bodily involvement

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Before microprocessor-controlled prosthetic joints, the major findings were that the most noticeable movements could be seen in the shoulders, not the hips, and all subjects had uneven pelvic rotations, with more rotation on the prosthetic side.[16] On average, the pelvic inclination is highest in transfemoral amputees in static non-walking studies.[17] The integration of motion capture technology has been beneficial to more recent dynamic walking studies. Rotation of the pelvis is especially essential in transfemoral amputees for lifting the prosthesis and providing foot clearance. This behavior is colloquially known as 'hip-hiking'. As such, rotation and obliquity of the pelvis have been determined to be instrumental in producing more symmetric gait, even when the rotation itself is asymmetric between intact and impaired limbs.[18] Torso or trunk motion is also linked to amputee gait, specifically increasing upper-body ranges of motion with decreasing walking velocity.[19] Another study observed a coupling of torso and pelvis rotations. They noted that the 'hip-hiking' behavior made the rotations of the upper and lower body 'in' or 'out' of phase depending on the severity of the walking impairment, with the amputee subjects having a near-fully coupled bodily rotation.[20] Torso involvement is not as readily apparent in able-bodied individuals. It is hypothesized that this gait deviation could lead to lower back pain.[19][21][20][22]

Stride length

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Stride length refers to the distance in the direction of forward motion that is between heel strikes of successive footfalls or steps. During the gait cycle, amputees have characteristically shorter time spent in the stance phase on the prosthetic limb compared to the intact limb.[23][24][25] Stride length is arguably the most visible of the changes in amputee gait because it creates such an asymmetry between the intact and impaired limbs. However, the shorter stance time may help the amputee compensate for the greater margin of error of the prosthetic limb, and several sources suggest the shorter strides are beneficial towards maintaining a straight walking path.[25]

Step width

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Step width refers to the distance between the feet. A connection exists between step width and gait instability, though it is difficult to discern the difference between correlation and causation. Increased step width is commonly accepted as an indicator of gait instability because it is a coping mechanism to deal with external or environmental balance perturbations.[26][27] A similar widening of step width and concordant slowing of gait speed[28] has been observed between populations of elderly,[29][30] obese,[31][32] pregnant women,[33][34] and amputees.[35] Physically widening the distance between feet in a standing posture increases the structural stability of the body by widening the base of support or foundation.[36] External lateral support mechanisms have been used to isolate the variable of balance in able-bodied subjects and succeeded in reducing both metabolic cost and step width.[37] A similar experimental setup was used on transtibial and transfemoral amputees: transtibial amputees had reduced energy cost and step width, but transfemoral subjects had increased cost and a more marginal reduction in step width, possibly due to the harness interfering with necessary pelvic movements.[38]

Gait Deviations

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A man with a single prosthetic leg exercising on a treadmill

The compensatory behaviors listed above describe the observable differences in ambulation between amputees and able-bodied individuals. The following gait deviation measurements quantify differences using gait analysis and other tests that typically necessitate specialized instrumentation or clinical environments.

Metabolic cost

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Energy expenditure is commonly used as a measure of gait quality and efficiency. Human metabolic rates are usually recorded via measuring the maximal oxygen consumption (VO2 max) during controlled incremental exercise under observation. Treadmills are used for gait analysis and standard walking tests. Able-bodied and athletic individuals on average have smaller metabolic costs than impaired individuals performing identical tasks.[39][40]

The values from a theoretical model[41] and experimental analyses[38][42][43][44][45] are listed below:

  • Transtibial amputees experience 9-33% increase
  • Transfemoral amputees experience 66-100% increase

Another source[46] compiled a list of average metabolic cost increases categorized by amputation location and by cause of amputation:

  • Transtibial (traumatic) amputees experience 25% increase[47][48][49]
  • Transtibial (vascular) amputees experience 40% increase[47][48][49]
  • Transfemoral (traumatic) amputees experience 68% increase[50][18]
  • Transfemoral (vascular) amputees experience 100% increase[50][18]

Comfortable walking speed

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Although heavily related to the metabolic cost and overall optimization of the gait, the self-selected walking speed of amputees is significantly lower than able-bodied individuals.[43] Average values for comfortable walking speeds drastically vary between subjects because it is a personal measure. The speeds can be lower than 0.60 m/s[51] or as high as 1.35 m/s.[40] In comparison, self-selected elderly walking speeds are commonly below 1.25 m/s,[29][30][52] and the reported comfortable walking speed of the able-bodied subjects is approximately 1.50 m/s.[53][40]

Mechanical work

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To compensate for the amputated segment of the limb, the residual joints are used for behaviors such as foot placement and general balance on the prosthetic limb. This increases the mechanical work generated by the residual joints on the amputated side. The intact limb is typically more adept at maintaining balance and is therefore relied upon more drastically, such as the behavior in a limping gait. Accordingly, the joint torques and general power of the intact side must increase as compared to an able-bodied individual.[49][54] Even with the advanced computerized knee joint of Otto Bock's C-Leg transfemoral prosthesis,[55] the subjects experienced increased braking and propulsive impulses than that of the standard double inverted pendulum model of normal human gait.[40]

Other deviations

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  • Lateral sway
  • Step variability
  • Internal rotation

Similar to decreased stride length and increased step width, lateral sway is generally postulated to be an indication of gait instability. The gait naturally widens to account for a greater instability or external perturbations to balance. Step variability is also related to balance and lateral stability. The variability in length and width of steps can be attributed to a level of responsiveness to external factors and perturbations, or an indication of inherent instability and lack of control.[56] This has been a common discussion in analysis of elderly gait as well.[30][29] Internal rotation is a culmination of measures of the hip and knee joints as well as the pelvic rotation and obliquity during gait. Typically, this has to be measured through motion capture and ground reaction force. Individual parameters can be calculated with inverse kinematics.[18]

Influential Factors

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Prosthetic leg being fitted to young man

Across the field of research, many studies are focused on assessing how different factors can influence the overall gait of amputee subjects. The following list shows examples of factors that are believed to influence the gait characteristics of lower-limb amputees:

  • Weight of prosthesis
  • Distribution of weight
  • Alignment of components
  • Overall fit of prosthesis

Prosthetic weight and distribution

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A common trend in modern technology is the push to create lightweight devices. A 1981 collection of studies on amputees showed a 30% increase in metabolic cost of walking for an able-bodied subject with 2-kg weights fixed to each foot.[57] Correspondingly, transfemoral prostheses are on average only about one third of the weight of the limb they are replacing. However, the effect of added mass appears to be less significant for amputees. Small increases in mass (4-oz and 8-oz) of a prosthetic foot had no significant effect[58] and, similarly, adding 0.68-kg and 1.34-kg masses to the center of the shank of transfemoral prostheses did not alter metabolic cost at any of the tested walking speeds (0.6, 1.0, and 1.5 m/s).[59] In another study, muscular efforts were significantly increased with added mass, yet there was no significant impact on walking speeds and over half of the subjects preferred a prosthetic that was loaded to match 75% weight of the sound leg.[60] In fact, it has been reported in several articles that test subjects actually prefer heavier prostheses, even when the load is completely superficial.[61]

Alignment and fit

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Initial alignment of a prosthetic leg is conducted by a prosthetist or physician to ensure proper use of the limb. The length of the residual limb is related to the amount of asymmetry in the walking pattern, with longer stumps on average having greater control.[21] Misalignment of joints could result in postures similar to those seen in congenital malformations such as bow-leggedness, knock-knee, pigeon toe, and club foot. Misaligned sockets can simulate excessive hip and knee flexion and extension. As individuals get more experience on the limb, it is expected that they will optimize the alignment for their own preference.

Transtibial

In transtibial amputees, the adjustment of the foot is highly influential to gait changes. Proper alignment of the prosthetic foot about the ankle joint causes metabolic cost[48] and gait symmetry at the anatomical hip and knee joints to improve, with hip flexion-extension motion being the most sensitive to alignment.[62] Excessive rotational misalignment of the foot is compensated by internal rotation of the residual hip joint.[63] Proper alignment of the transtibial prosthesis socket significantly reduced the loading on the intact limb during an 11-meter walk test, indicating that a misaligned limb could have drastic long-term consequences on the sound side of the body.[64]

Transfemoral

Systematic changes to transfemoral prosthetic alignment altered the flexion-extension behavior of the hip, changing fore-aft ground reaction forces and the antero-posterior moments at the knee and ankle joints.[65] The sole reliance on the hip joint to control the entire prosthetic limb makes fine-tuning foot placement difficult. Lowering the knee joint height was found to effectively increase the hip joint's lever arm, thereby increasing precision control of the hip joint to improve gait symmetry and increase running velocity by 26% on average.[66]

See also

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References

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  1. ^ Verghese, Joe; Ambrose, Anne F.; Lipton, Richard B.; Wang, Cuiling (2010-03-01). "Neurological gait abnormalities and risk of falls in older adults". Journal of Neurology. 257 (3): 392–398. doi:10.1007/s00415-009-5332-y. ISSN 0340-5354. PMC 2838981. PMID 19784714.
  2. ^ "Gait Abnormality Coding Checklist by Jun Mapili, PT, MA13212503469Ed". Selmanholman.com. Archived from the original on 2014-07-14. Retrieved 2014-06-10.
  3. ^ ICD-9-cm Chrisenders Archived May 21, 2005, at the Wayback Machine
  4. ^ "Amputation Statistics: Fact Sheet" (PDF). Center for Orthotic & Prosthetic Care.
  5. ^ Ziegler-Graham, K; MacKenzie, EJ; Ephraim, PL; Travison, TG; Brookmeyer, R (Mar 2008). "Estimating the prevalence of limb loss in the United States: 2005 to 2050". Arch Phys Med Rehabil. 89 (3): 422–429. doi:10.1016/j.apmr.2007.11.005. PMID 18295618.
  6. ^ a b Dillingham, TR; Pezzin, LE; Shore, AD (Mar 2005). "Reamputation, mortality, and health care costs among persons with dyvascular lower-limb amputations". Arch Phys Med Rehabil. 86 (3): 480–486. doi:10.1016/j.apmr.2004.06.072. PMID 15759232.
  7. ^ Egorova, NN; Guillerme, S; Gelijns, A; Morrissey, N; Dayal, R; McKinsey, JF; Nowygrod, R (Apr 2010). "An analysis of the outcomes of a decade of experience with lower extremity revascularization including limb salvage, lengths of stay, and safety". J Vasc Surg. 51 (4): 878–885. doi:10.1016/j.jvs.2009.10.102. PMID 20045618.
  8. ^ Lo, RC; Bensley, RP; Dahlberg, SE; Matyal, R; Hamdan, AD; Wyers, M; Chaikof, EL; Schermerhorn, ML (Feb 2014). "Presentation, treatment, and outcome differences between men and women undergoing revascularization or amputation for lower extremity peripheral arterial disease". J Vasc Surg. 59 (2): 409–418. doi:10.1016/j.jvs.2013.07.114. PMC 3946884. PMID 24080134.
  9. ^ Peek, ME (July 2011). "Gender differences in diabetes-related lower extremity amputations". Clin Orthop Relat Res. 469 (7): 1951–1955. doi:10.1007/s11999-010-1735-4. PMC 3111773. PMID 21161738.
  10. ^ Smith, Douglas G (Jul–Aug 2003). "Transtibial Amputations: Successes and Challenges" (PDF). InMotion. 13 (4): 57–63.
  11. ^ Berke, Gary M; Buell, Noelle C; Fergason, John R; Gailey, Robert S; Hafner, Brian J; Hubbard, Sharon M; Smith, Douglas G; Willingham, Laura L (2008). Transfemoral Amputation: The Basics and Beyond (PDF). Prosthetics Research Study. ISBN 978-0-6152-6870-5.
  12. ^ Bae, TS; Choi, K; Mun, M (2009). "Level walking and stair climbing gait in above-knee amputees". J Med Eng Technol. 33 (2): 130–135. doi:10.1080/03091900701404043. PMID 19205992. S2CID 684443.
  13. ^ Wentink, Eva C; Prinsen, Erik C; Rietman, Johan S; Veltink, Peter H (Aug 2013). "Comparison of muscle activity patterns of transfemoral amputees and control subjects during walking". J Neuroeng Rehabil. 10 (87): 87. doi:10.1186/1743-0003-10-87. PMC 3750514. PMID 23914785.
  14. ^ Smith, Douglas G (Mar–Apr 2004). "The Transfemoral Amputation Level, Part 1" (PDF). InMotion. 14 (2): 54–58.
  15. ^ Highsmith, M Jason; Schulz, Btain W; Hart-Hughes, Stephanie; Latlief, Gail A; Phillips, Sam L (Jan 2010). "Differences in the Spatiotemporal Parameters of Transtibial and Transfemoral Amputee Gait". J Prosthet Orthot. 22 (1): 26–30. doi:10.1097/JPO.0b013e3181cc0e34. S2CID 57442354.
  16. ^ Tazawa, E (Aug 1997). "Analysis of torso movement of trans-femoral amputees during level walking". Prosthetics and Orthotics International. 21 (2): 129–140. doi:10.3109/03093649709164541. PMID 9285957.
  17. ^ Gaunaurd, Ignacio; Gailey, Robert; Hafner, Brian J; Gomez-Marin, Orlando; Kirk-Sanchez, Neva (June 2011). "Postural asymmetries in transfemoral amputees". Prosthet Orthot Int. 35 (2): 171–180. doi:10.1177/0309364611407676. PMID 21697199. S2CID 10632865.
  18. ^ a b c d Sjodahl, C; Jarnlo, GB; Soderberg, B; Persson, BM (Dec 2003). "Pelvic motion in trans-femoral amputees in the frontal and transverse plane before and after special gait re-education". Prosthet Orthot Int. 27 (3): 227–237. doi:10.1080/03093640308726686. PMID 14727704.
  19. ^ a b Goujon-Pillet, Helene; Sapin, Emilie; Fode, Pascale; Lavaste, Francois (Jan 2008). "Three-Dimensional Motions of Trunk and Pelvis During Transfemoral Amputee Gait". Arch Phys Med Rehabil. 89 (1): 87–94. doi:10.1016/j.apmr.2007.08.136. PMID 18164336.
  20. ^ a b Williams, Matthew R; D'Andrea, Susan; Herr, Hugh M (June 2016). "Impact on gait biomechanics of using an active variable impedance prosthetic knee". J Neuroeng Rehabil. 13 (1): 54–64. doi:10.1186/s12984-016-0159-0. PMC 4901431. PMID 27283318.
  21. ^ a b Jaegers, Sonja MHJ; Arendzen, J Hans; de Jongh, Henry J (Aug 1995). "Prosthetic gait of unilateral transfemoral amputees: A kinematic study". Arch Phys Med Rehabil. 76 (8): 736–743. doi:10.1016/S0003-9993(95)80528-1. PMID 7632129.
  22. ^ Devan, Hemakumar; Carman, Allan; Hendrick, Paul; Hale, Leigh; Ribeiro, Daniel C (2015). "Spinal, pelvic, and hip movement asymmetries in people with lower-limb amputation: Systematic review". J Rehabil Res Dev. 52 (1): 1–19. doi:10.1682/JRRD.2014.05.0135. PMID 26186283.
  23. ^ Nolan, L; Wit, A; Dudzinski, K; Lees, A; Lake, M; Wychowanski, M (2003). "Adjustments in gait symmetry with walking speed in trans-femoral and trans-tibial amputees". Gait & Posture. 17 (2): 142–151. doi:10.1016/S0966-6362(02)00066-8. PMID 12633775.
  24. ^ Gard, SA (Jan 2006). "Use of quantitative gait analysis for the evaluation of prosthetic walking performance". J Prosthet Orthot. 18 (6): 93–104. doi:10.1097/00008526-200601001-00011.
  25. ^ a b Hof, AL; van Bockel, RM; Schoppen, T; Postema, K (Feb 2007). "Control of lateral balance in walking. Experimental findings in normal subjects and above-knee amputees" (PDF). Gait & Posture. 25 (2): 250–258. doi:10.1016/j.gaitpost.2006.04.013. hdl:11370/d721bb4e-2e81-4c60-a4ae-e0f2cb54428c. PMID 16740390.
  26. ^ Dingwell, JB; Marin, LC (2006). "Kinematic variability and local dynamic stability of upper body motions when walking at different speeds". J Biomech. 39 (3): 444–452. doi:10.1016/j.jbiomech.2004.12.014. PMID 16389084.
  27. ^ Hak, L; Houdijk, H; Steenbrink, F; Mert, A; van der Wurff, P; Beek, PJ; van Dieen, JH (June 2012). "Speeding up or slowing down?: Gait adaptations to preserve gait stability in response to balance perturbations". Gait Posture. 36 (2): 260–264. doi:10.1016/j.gaitpost.2012.03.005. PMID 22464635.
  28. ^ Jordan, Kimberlee; Challis, John H; Newell, Karl M (June 2007). "Walking speed influences on gait cycle variability". Gait & Posture. 26 (1): 128–134. doi:10.1016/j.gaitpost.2006.08.010. PMID 16982195.
  29. ^ a b c Barak, Y; Wagenaar, RC; Holt, KG (Nov 2006). "Gait characteristics of elderly people with a history of falls: a dynamic approach". Phys Ther. 86 (11): 1501–1510. doi:10.2522/ptj.20050387. PMID 17079750.
  30. ^ a b c Mbourou, GA; Lajoie, Y; Teasdale, N (Jan–Feb 2003). "Step length variability at gait initiation in elderly fallers and non-fallers, and young adults". Gerontology. 49 (1): 21–26. doi:10.1159/000066506. PMID 12457046. S2CID 25700608.
  31. ^ Peyrot, Nicolas; Thivel, David; Isacco, Laurie; Morin, Jean-Benoit; Duche, Pascale; Belli, Alain (Feb 2009). "Do mechanical gait parameters explain the higher metabolic cost of walking in obese adolescents?". J Appl Physiol. 106 (6): 1763–1770. doi:10.1152/japplphysiol.91240.2008. PMID 19246657. S2CID 9365122.
  32. ^ Browning, RC; Kram, R (Sep 2007). "Effects of obesity on the biomechanics of walking at different speeds". Med Sci Sports Exerc. 39 (9): 1632–1641. doi:10.1249/mss.0b013e318076b54b. PMID 17805097.
  33. ^ McCrory, Jean L; Chambers, April J; Daftary, Ashi; Redfern, Mark S (Oct 2011). "Ground reaction forces during gait in pregnant fallers and non-fallers". Gait & Posture. 34 (4): 524–528. doi:10.1016/j.gaitpost.2011.07.007. PMID 21820902.
  34. ^ McCrory, Jean L; Chambers, April J; Daftary, Ashi; Redfern, Mark S (Sep 2014). "The pregnant "waddle": An evaluation of torso kinematics in pregnancy". J Biomech. 47 (12): 2964–2968. doi:10.1016/j.jbiomech.2014.07.009. PMID 25108664.
  35. ^ Hak, Laura; van Dieen, Jaap H; van der Wurff, Peter; Prins, Maarten R; Mert, Agali; Beek, Peter J; Houdijk, Han (Nov 2013). "Walking in an Unstable Environment: Strategies Used by Transtibial Amputees to Prevent Falling During Gait". Arch Phys Med Rehabil. 94 (11): 2186–2193. doi:10.1016/j.apmr.2013.07.020. hdl:1871.1/92f14628-5411-4984-b0b8-dec8c79c86df. PMID 23916618.
  36. ^ Hof, AL; Gazendam, MGJ; Sinke, WE (Jan 2005). "The condition for dynamic stability". J Biomech. 38 (1): 1–8. doi:10.1016/j.jbiomech.2004.03.025. PMID 15519333.
  37. ^ Donelan, JM; Shipman, DW; Kram, R; Kuo, AD (June 2004). "Mechanical and metabolic requirements for active lateral stabilization in human walking". J Biomech. 37 (6): 827–835. doi:10.1016/j.jbiomech.2003.06.002. PMID 15111070.
  38. ^ a b Ijmker, T; Noten, S; Lamoth, CJ; Beek, PJ; van der Woude, LH; Houdijk, H (Sep 2014). "Can external lateral stabilization reduce the energy cost of walking in persons with a lower limb amputation?". Gait Posture. 40 (4): 616–621. doi:10.1016/j.gaitpost.2014.07.013. PMID 25108643.
  39. ^ Waters, Robert L; Mulroy, Sara (July 1999). "The energy expenditure of normal and pathologic gait". Gait & Posture. 9 (3): 207–231. doi:10.1016/S0966-6362(99)00009-0. PMID 10575082.
  40. ^ a b c d Houdijk, H; Pollmann, E; Groenewold, M; Wiggerts, H; Polomski, W (July 2009). "The energy cost for the step-to-step transition in amputee walking". Gait & Posture. 30 (1): 35–40. doi:10.1016/j.gaitpost.2009.02.009. PMID 19321343.
  41. ^ Hoffman, Martin D; Millet, Guillaume Y; Canau, Robin B; Rouillon, Jean-Denis (May 2004). "Evaluation of a theoretical model to quantify the sources of metabolic cost in walking". Am J Phys Med Rehabil. 83 (5): 353–362. doi:10.1097/01.PHM.0000124438.04443.DE. PMID 15100624. S2CID 9410648.
  42. ^ Waters, RL; Perry, J; Antonelli, D; Hislop, H (Jan 1976). "Energy cost of walking of amputees: the influence of level of amputation". J Bone Joint Surg Am. 58 (1): 42–46. doi:10.2106/00004623-197658010-00007. PMID 1249111.
  43. ^ a b Wezenberg, D; van der Woude, LH; Faber, WX; de Haan, A; Houdijk, H (Sep 2013). "Relation between aerobic capacity and walking ability in older adults with a lower-limb amputation". Arch Phys Med Rehabil. 94 (9): 1714–1720. doi:10.1016/j.apmr.2013.02.016. PMID 23466292.
  44. ^ Gailey, RS; Wenger, MA; Raya, M; Kirk, N; Erbs, K; Spyropoulos, P; Nash, MS (Aug 1994). "Energy expenditure of trans-tibial amputees during amputation at self-selected pace". Prosthet Orthot Int. 18 (2): 84–91. doi:10.3109/03093649409164389. PMID 7991365.
  45. ^ Schmalz, Thomas; Blumentritt, Siegmar; Jarasch, Rolf (Dec 2002). "Energy expenditure and biomechanical characteristics of lower limb amputee gait: The influence of prosthetic alignment and different prosthetic components". Gait & Posture. 16 (3): 255–263. doi:10.1016/S0966-6362(02)00008-5. PMID 12443950.
  46. ^ Kishner, Stephen (2018-12-12). "Gait Analysis After Amputation". Medscape.
  47. ^ a b Selles, R; Bussmann, J; Van Soest, AJ; Stam, H (Jun 2004). "The effect of prosthetic mass properties on the gait of transtibial amputees: a mathematical model". Disabil Rehabil. 26 (12): 694–704. doi:10.1080/09638280410001704296. PMID 15204491. S2CID 38149995.
  48. ^ a b c Chow, DH; Holmes, AD; Lee, CK; Sin, SW (Aug 2006). "The effect of prosthesis alignment on the symmetry of gait in subjects with unilateral transtibial amputation". Prosthet Orthot Int. 30 (2): 114–128. doi:10.1080/03093640600568617. hdl:10397/26631. PMID 16990222. S2CID 25107336.
  49. ^ a b c Nadollek, H; Brauer, S; Isles, R (2002). "Outcomes after trans-tibial amputation: the relationship between quiet stance ability, strength of hip abductor muscles and gait". Physiother Res Int. 7 (4): 203–214. doi:10.1002/pri.260. PMID 12528576.
  50. ^ a b Tokuno, CD; Sanderson, DJ; Inglis, JT; Chua, R (Dec 2003). "Postural and movement adaptations by individuals with a unilateral below-knee amputation during gait initiation". Gait Posture. 18 (3): 158–169. doi:10.1016/S0966-6362(03)00004-3. hdl:2429/12255. PMID 14667949.
  51. ^ Shirota, Camila; Simon, Ann M; Kuiken, Todd A (Sep 2015). "Transfemoral amputee recovery strategies following trips to their sound and prosthesis sides throughout swing phase". J Neuroeng Rehabil. 12: 79. doi:10.1186/s12984-015-0067-8. PMC 4564965. PMID 26353775.
  52. ^ Bohannon, Richard W (1997). "Comfortable and maximum walking speed of adults aged 20-79 years: reference values and determinants". Age and Ageing. 26 (1): 15–19. doi:10.1093/ageing/26.1.15. PMID 9143432.
  53. ^ Hausdorff, JM; Mitchell, SL; Firtion, R; Peng, CK; Cudkowicz, ME; Wei, JY; Goldberger, AL (Jan 1997). "Altered fractal dynamics of gait: reduced stride-interval correlations with aging and Huntington's disease". J Appl Physiol. 82 (1): 262–269. doi:10.1152/jappl.1997.82.1.262. PMID 9029225. S2CID 7976761.
  54. ^ Seroussi, Richard E; Gitter, Andrew; Czerniecki, Joseph M; Weaver, Kelly (Nov 1996). "Mechanical Work Adaptations of Above-Knee Amputee Ambulation". Arch Phys Med Rehabil. 77 (11): 1209–1214. doi:10.1016/S0003-9993(96)90151-3. PMID 8931539.
  55. ^ Schaarschmidt, Margrit; Lipfert, Susanne W; Meier-Gratz, Christine; Scholle, Hans-Christoph; Seyfarth, Andre (Aug 2012). "Functional gait asymmetry of unilateral transfemoral amputees". Human Movement Science. 31 (4): 907–917. doi:10.1016/j.humov.2011.09.004. PMID 22248566.
  56. ^ Arellano, Christopher J; McDermott, William J; Kram, Rodger; Grabowski, Alena M (Jan 2015). "Effect of Running Speed and Leg Prostheses on Mediolateral Foot Placement and Its Variability". PLOS ONE. 10 (1): e0115637. Bibcode:2015PLoSO..1015637A. doi:10.1371/journal.pone.0115637. PMC 4295868. PMID 25590634.
  57. ^ American Academy of Orthopaedic Surgeons (1981). Atlas of Limb Prosthetics: Surgical, Prosthetic, and Rehabilitation Principles (2 ed.). St. Louis, MO: CV Mosby. ISBN 978-0-8016-0209-2.
  58. ^ Godfrey, CM; Brett, R; Jousse, AT (Jun 1977). "Foot mass effect on gait in the prosthetic limb". Arch Phys Med Rehabil. 58 (6): 268–269. PMID 860910.
  59. ^ Czerniecki, JM; Gitter, A; Weaver, K (Sep–Oct 1994). "Effect of alterations in prosthetic shank mass on the metabolic costs of ambulation in above-knee amputees". Am J Phys Med Rehabil. 73 (5): 348–352. doi:10.1097/00002060-199409000-00008. PMID 7917165. S2CID 32713979.
  60. ^ Hale, SA (1990). "Analysis of the swing phase dynamics and muscular effort of the above-knee amputee for varying prosthetic shank loads". Prosthet Orthot Int. 14 (3): 125–135. doi:10.3109/03093649009080338. PMID 2095530.
  61. ^ Meikle, Ben; Boulias, Chris; Pauley, Tim; Devlin, Michael (Nov 2003). "Does Increased Prosthetic Weight Affect Gait Speed and Patient Preference in Dyvascular Transfemoral Amputees?". Arch Phys Med Rehabil. 84 (11): 1657–1661. doi:10.1053/S0003-9993(03)00279-X. PMID 14639566.
  62. ^ Hannah, RE; Morrison, JB; Chapman, AE (Apr 1984). "Prosthesis alignment: effect on gait of persons with below-knee amputations". Arch Phys Med Rehabil. 65 (4): 159–162. PMID 6712431.
  63. ^ Fridman, A; Ona, I; Isakov, E (Apr 2003). "The influence of prosthetic foot alignment on trans-tibial amputee gait". Prosthet Orthot Int. 27 (1): 17–22. doi:10.3109/03093640309167973. PMID 12812324.
  64. ^ Pinzur, Michael S; Cox, William; Kaiser, James; Morris, Ted; Patwardhan, Avinash; Vrbos, Lori (Nov 1995). "The Effect of Prosthetic Alignment on Relative Limb Loading in Persons with Trans-Tibial Amputation: A Preliminary Report". J Rehabil Res Dev. 32 (4): 373–377. PMID 8770802. ProQuest 215298715.
  65. ^ Yang, L; Solomonidis, SE; Spence, WD; Paul, JP (1991). "The influence of limb alignment on the gait of above-knee amputees". J Biomech. 24 (11): 981–997. doi:10.1016/0021-9290(91)90016-G. PMID 1761584.
  66. ^ Burkett, B; Smeathers, J; Barker, T (Dec 2001). "Optimising the trans-femoral prosthetic alignment for running, by lowering the knee joint". Prosthet Orthot Int. 25 (3): 210–219. doi:10.1080/03093640108726604. PMID 11860095. S2CID 26966757.
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