Abstract
Because of the physical length of the arms and the relatively large range of motion in the shoulder and elbow in gait, any deviation from normal is detected immediately and attracts attention. The deviation can consist of increased flexion in the elbow, decreased range of motion, movement out of phase with the lower extremities, and asymmetry between the movement of right and left arms, either in isolation or in many more or less noticeable combinations. Although human evolution means that we no longer walk on our arms, arm movement has impact on our stability, balance, and appearance while walking. In addition, we can carry things, make gestures, or do other things with the arms and hands while walking. Despite an evolution toward corticospinal control of arm and hand movements, quadrupedal limb coordination persists during locomotion. We do not think about how we coordinate our arms and legs when walking. It just happens.
Individuals with deformity, limited range of motion, or movement disorders affecting the arm show a disturbance of the normal arm pendulum in gait. It can be difficult to understand the consequences of the primary pathology and the influence on the movement pattern as well as the possible development of compensation mechanisms. Studying the arm pendulum is important for diagnosis and treatment and to follow progression over time. In addition, our sensitivity to deviations from normal highlights the importance of arm movement for communication and appearance.
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Arellano CJ, Kram R (2011) The effects of step width and arm swing on energetic cost and lateral balance during running. J Biomech 44:1291–1295
Baker R, Mcginley JL, Schwartz MH, Beynon S, Rozumalski A, Graham HK, Tirosh O (2009) The gait profile score and movement analysis profile. Gait Posture 30:265–269
Ballesteros ML, Buchthal F, Rosenfalck P (1965) The pattern of muscular activity during the arm swing of natural walking. Acta Physiol Scand 63:296–310
Behrman AL, Teitelbaum P, Cauraugh JH (1998) Verbal instructional sets to normalise the temporal and spatial gait variables in Parkinson’s disease. J Neurol Neurosurg Psychiatry 65:580–582
Bonnefoy-Mazure A, Turcot K, Kaelin A, De Coulon G, Armand S (2013) Full body gait analysis may improve diagnostic discrimination between hereditary spastic paraplegia and spastic diplegia: a preliminary study. Res Dev Disabil 34:495–504
Bonnefoy-Mazure A, Sagawa Y Jr, Lascombes P, De Coulon G, Armand S (2014) A descriptive analysis of the upper limb patterns during gait in individuals with cerebral palsy. Res Dev Disabil 35:2756–2765
Braune W (1895) Der gang des Mencschen I. Abh K Sachs Ges Wiss Math-Phys 21:153
Brown WM, Cronk L, Grochow K, Jacobson A, Liu CK, Popovic Z, Trivers R (2005) Dance reveals symmetry especially in young men. Nature 438:1148–1150
Brown WM, Price ME, Kang J, Pound N, Zhao Y, Yu H (2008) Fluctuating asymmetry and preferences for sex-typical bodily characteristics. Proc Natl Acad Sci U S A 105:12938–12943
Chouchourelou A, Matsuka T, Harber K, Shiffrar M (2006) The visual analysis of emotional actions. Soc Neurosci 1:63–74
Collins SH, Adamczyk PG, Kuo AD (2009) Dynamic arm swinging in human walking. Proc Biol Sci 276:3679–3688
Corry IS, Cosgrove AP, Walsh EG, Mcclean D, Graham HK (1997) Botulinum toxin A in the hemiplegic upper limb: a double-blind trial. Dev Med Child Neurol 39:185–193
Decety J, Grezes J (2006) The power of simulation: imagining one’s own and other’s behavior. Brain Res 1079:4–14
Dietz V (2011) Quadrupedal coordination of bipedal gait: implications for movement disorders. J Neurol 258:1406–1412
Elftman H (1939) The function of arms in walking. Hum Biol 11:529–535
Esquenazi A, Mayer N, Garreta R (2008) Influence of botulinum toxin type A treatment of elbow flexor spasticity on hemiparetic gait. Am J Phys Med Rehabil 87:305–310 quiz 311, 329
Fahn S, Oakes D, Shoulson I, Kieburtz K, Rudolph A, Lang A, Olanow CW, Tanner C, Marek K, Parkinson Study Group (2004) Levodopa and the progression of Parkinson’s disease. N Engl J Med 351:2498–2508
Goudriaan M, Jonkers I, Van Dieen JH, Bruijn SM (2014) Arm swing in human walking: what is their drive? Gait Posture 40:321–326
Hill H, Pollick FE (2000) Exaggerating temporal differences enhances recognition of individuals from point light displays. Psychol Sci 11:223–228
Hirsch MA, Westhoff B, Toole T, Haupenthal S, Krauspe R, Hefter H (2005) Association between botulinum toxin injection into the arm and changes in gait in adults after stroke. Mov Disord 20:1014–1020
Ikeda H, Watanabe K (2009) Anger and happiness are linked differently to the explicit detection of biological motion. Perception 38:1002–1011
Jackson KM, Joseph J, Wyard SJ (1983) The upper limbs during human walking. Part 2. Function. Electromyogr Clin Neurophysiol 23:435–446
Jaspers E, Feys H, Bruyninckx H, Klingels K, Molenaers G, Desloovere K (2011) The Arm Profile Score: a new summary index to assess upper limb movement pathology. Gait Posture 34:227–233
Johansson G (1973) Visual perception of biological motion and a model for its analysis. Percept Psychophys 14:201–211
Kadaba MP, Ramakrishnan HK, Wootten ME (1990) Measurement of lower extremity kinematics during level walking. J Orthop Res 8:383–392
Kubo M, Ulrich B (2006) A biomechanical analysis of the ‘high guard’ position of arms during walking in toddlers. Infant Behav Dev 29:509–517
Kuhtz-Buschbeck JP, Jing B (2012) Activity of upper limb muscles during human walking. J Electromyogr Kinesiol 22:199–206
Lewek MD, Poole R, Johnson J, Halawa O, Huang X (2010) Arm swing magnitude and asymmetry during gait in the early stages of Parkinson’s disease. Gait Posture 31:256–260
Lundh D, Coleman S, Riad J (2014) Movement deviation and asymmetry assessment with three dimensional gait analysis of both upper- and lower extremity results in four different clinical relevant subgroups in unilateral cerebral palsy. Clin Biomech (Bristol, Avon) 29:381–386
Meeren HK, Van Heijnsbergen CC, De Gelder B (2005) Rapid perceptual integration of facial expression and emotional body language. Proc Natl Acad Sci U S A 102:16518–16523
Meyns P, Desloovere K, Van Gestel L, Massaad F, Smits-Engelsman B, Duysens J (2012a) Altered arm posture in children with cerebral palsy is related to instability during walking. Eur J Paediatr Neurol 16:528–535
Meyns P, Van Gestel L, Bruijn SM, Desloovere K, Swinnen SP, Duysens J (2012b) Is interlimb coordination during walking preserved in children with cerebral palsy? Res Dev Disabil 33:1418–1428
Meyns P, Bruijn SM, Duysens J (2013) The how and why of arm swing during human walking. Gait Posture 38:555–562
Mirelman A, Bernad-Elazari H, Thaler A, Giladi-Yacobi E, Gurevich T, Gana-Weisz M, Saunders-Pullman R, Raymond D, Doan N, Bressman SB, Marder KS, Alcalay RN, Rao AK, Berg D, Brockmann K, Aasly J, Waro BJ, Tolosa E, Vilas D, Pont-Sunyer C, Orr-Urtreger A, Hausdorff JM, Giladi N (2016) Arm swing as a potential new prodromal marker of Parkinson’s disease. Mov Disord 31(10):1527–1534
Montemare JM (1987) The identification of emotions from gait information. J Nonverbal Behavior 11:33–42
Murray MP, Sepic SB, Barnard EJ (1967) Patterns of sagittal rotation of the upper limbs in walking. Phys Ther 47:272–284
Nakakubo S, Doi T, Sawa R, Misu D, Tsutsumimoto K, Ono R (2014) Does arm swing emphasized deliberately increase the trunk stability during walking in the elderly adults? Gait Posture 40:516–520
Ortega JD, Farley CT (2015) Effects of aging on mechanical efficiency and muscle activation during level and uphill walking. J Electromyogr Kinesiol 25:193–198
Ortega JD, Fehlman LA, Farley CT (2008) Effects of aging and arm swing on the metabolic cost of stability in human walking. J Biomech 41:3303–3308
Perry J (1992) Gait analysis, normal and pathological function. Slack Incorporated, Thorofare
Riad J, Coleman S, Miller F (2007) Arm posturing during walking in children with spastic hemiplegic cerebral palsy. J Pediatr Orthop 27:137–141
Riad J, Coleman S, Lundh D, Brostrom E (2011) Arm posture score and arm movement during walking: a comprehensive assessment in spastic hemiplegic cerebral palsy. Gait Posture 33:48–53
Riad J, Brostrom E, Langius-Eklof A (2013) Do movement deviations influence self-esteem and sense of coherence in mild unilateral cerebral palsy? J Pediatr Orthop 33:298–302
Romkes J, Peeters W, Oosterom AM, Molenaar S, Bakels I, Brunner R (2007) Evaluating upper body movements during gait in healthy children and children with diplegic cerebral palsy. J Pediatr Orthop B 16:175–180
Russo RN, Goodwin EJ, Miller MD, Haan EA, Connell TM, Crotty M (2008) Self-esteem, self-concept, and quality of life in children with hemiplegic cerebral palsy. J Pediatr 153:473–477
Schneider S, Christensen A, Haussinger FB, Fallgatter AJ, Giese MA, Ehlis AC (2014) Show me how you walk and I tell you how you feel – a functional near-infrared spectroscopy study on emotion perception based on human gait. NeuroImage 85(Pt 1):380–390
Stephenson JL, De Serres SJ, Lamontagne A (2010) The effect of arm movements on the lower limb during gait after a stroke. Gait Posture 31:109–115
Trehan SK, Wolff AL, Gibbons M, Hillstrom HJ, Daluiski A (2015) The effect of simulated elbow contracture on temporal and distance gait parameters. Gait Posture 41:791–794
Umberger BR (2008) Effects of suppressing arm swing on kinematics, kinetics, and energetics of human walking. J Biomech 41:2575–2580
Uvebrant G (2000) Congenital hemiplegia. Mac Keith Press, London
Wake M, Salmon L, Reddihough D (2003) Health status of Australian children with mild to severe cerebral palsy: cross-sectional survey using the Child Health Questionnaire. Dev Med Child Neurol 45:194–199
Winogrodzka A, Wagenaar RC, Booij J, Wolters EC (2005) Rigidity and bradykinesia reduce interlimb coordination in Parkinsonian gait. Arch Phys Med Rehabil 86:183–189
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Riad, J. (2016). The Arm Pendulum in Gait. In: Müller, B., et al. Handbook of Human Motion. Springer, Cham. https://doi.org/10.1007/978-3-319-30808-1_56-1
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DOI: https://doi.org/10.1007/978-3-319-30808-1_56-1
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