Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
European Journal of Applied Physiology
Published in: European Journal of Applied Physiology 1/2010

01-01-2010 | Original Article

Coordination between upper- and lower-limb movements is different during overground and treadmill walking

Authors: Ilaria Carpinella, Paolo Crenna, Marco Rabuffetti, Maurizio Ferrarin

Published in: European Journal of Applied Physiology | Issue 1/2010

Login to get access

Abstract

Locomotion studies employ either treadmill (TW) or overground walking (OW), considering that differences between them are negligible. The present study tests this notion by comparing coordination between upper- and lower-limb movements in healthy individuals during OW and TW at matched speeds. Results indicated that TW induced a higher cadence, which highly influenced interlimb coordination, in terms of frequency coupling and relative phase between arm and thigh motion. At low speed, the 2:1 pattern (double arm swing per stride) displayed lower incidence in TW compared to OW, and this was correlated with a lower sagittal acceleration at the shoulders, at twice the stride frequency, in the former condition. The low occurrence of the 2:1 coupling in TW, moreover, was correlated to a preferential adoption of a cadence exceeding 80% of the arm’s resonant frequency, whereas higher incidence of this pattern in OW involved a preferential cadence below the 80% threshold. Results indicated also that the relative phase between arm and ipsilateral thigh swinging was smaller in TW, in relation to an earlier occurrence of maximum thigh extension, shortened stance phase, and increased cadence. These findings suggest that arm–leg coordination is different in OW and TW, and that difference can be mainly ascribed to condition-specific setting of central mechanisms for scaling stride frequency, for controlling dynamic axial posture (sagittal shoulder acceleration), and, possibly, for maintaining inter-limb synchrony. Awareness of a different “motor set” in TW and OW is critical if data from the two paradigms are used in physiological and patho-physiological studies.
Literature
Alton F, Baldey L, Caplan S, Morrissey MC (1998) A kinematic comparison of overground and treadmill walking. Clin Biomech (Bristol, Avon) 13:434–440CrossRef
Arsenault AB, Winter DA, Marteniuk RG (1986) Treadmill versus walkway locomotion in humans: an EMG study. Ergonomics 29:665–676CrossRefPubMed
Baev KV, Greene KA, Marciano FF, Samanta JE, Shetter AG, Smith KA, Stacy MA, Spetzler RF (2002) Physiology and pathophysiology of cortico-basal ganglia-thalamocortical loops: theoretical and practical aspects. Prog Neuropsychopharmacol Biol Psychiatry 26:771–804CrossRefPubMed
Buchthal F, Fernandez-Ballesteros ML (1965) Electromyographic study of the muscles of the upper arm and shoulder during walking in patients with Parkinson’s disease. Brain 88:875–896CrossRefPubMed
Callaghan JP, Patla AE, McGill SM (1999) Low back three-dimensional joint forces, kinematics, and kinetics during walking. Clin Biomech (Bristol, Avon) 14:203–216CrossRef
Carpinella I, Mazzoleni P, Crenna P, Rabuffetti M, Ferrarin M (2009) Arm and leg swing during overground and treadmill walking. Gait Posture 29:e29–e30CrossRef
Cavagna GA, Willems PA, Heglund NC (2000) The role of gravity in human walking: pendular energy exchange, external work and optimal speed. J Physiol 528:657–668CrossRefPubMed
Collett J, Dawes H, Howells K, Elsworth C, Izadi H, Sackley C (2007) Anomalous centre of mass energy fluctuations during treadmill walking in healthy individuals. Gait Posture 26:400–406CrossRefPubMed
Craik R, Herman R, Finley FR (1976) Human solutions for locomotion: interlimb coordination. In: Herman RM, Grillner S, Stein PSG, Stuart DG (eds) Neural control of locomotion. Plenum Press, New York, pp 51–64
Crenna P, Carpinella I, Lopiano L, Marzegan A, Rabuffetti M, Rizzone M, Lanotte M, Ferrarin M (2008) Influence of basal ganglia on upper limb locomotor synergies. Evidence from deep brain stimulation and l-DOPA treatment in Parkinson’s disease. Brain 131:3410–3420CrossRefPubMed
Donker SF, Beek PJ, Wagenaar RC, Mulder T (2001) Coordination between arm and leg movements during locomotion. J Mot Behav 33:86–102PubMedCrossRef
Donker SF, Daffertshofer A, Beek PJ (2005) Effects of velocity and limb loading on the coordination between limb movements during walking. J Mot Behav 37:217–230CrossRefPubMed
Durgin F, Reed C, Tigue C (2007) Step frequency and perceived self-motion. ACM Trans Appl Percept 4:1–23CrossRef
Eke-Okoro ST, Gregoric M, Larsson LE (1997) Alterations in gait resulting from deliberate changes of arm-swing amplitude and phase. Clin Biomech (Bristol, Avon) 12:516–521CrossRef
Fernandez Ballestreros ML, Buchthal F, Rosenfalck P (1965) The pattern of muscular activity during the arm swing of natural walking. Acta Physiol Scand 63:296–310CrossRef
Ford MP, Wagenaar RC, Newell KM (2007) Arm constraint and walking in healthy adults. Gait Posture 26:135–141CrossRefPubMed
Goldberg EJ, Kautz SA, Neptune RR (2008) Can treadmill walking be used to assess propulsion generation? J Biomech 41:1805–1808CrossRefPubMed
Gutnik B, Mackie H, Hudson G, Standen C (2005) How close to a pendulum is human upper limb movement during walking? Homo 56:35–49CrossRefPubMed
Hinrichs R (1990) Whole body movement: coordination of arms and legs in walking and running. In: Winter J, Woo S (eds) Multiple muscle systems: biomechanics and movements organization. Springer, New York, pp 694–705
Jackson KM, Joseph J, Wyard SJ (1978) A mathematical model of arm swing during human locomotion. J Biomech 11:277–289CrossRefPubMed
Konczak J (1994) Effects of Optic flow on the kinematics of human gait: a comparison of young and older adults. J Mot Behav 26:225–236PubMed
Korchounov A, Schipper HI, Preobrazhenskaya IS, Kessler KR, Yakhno NN (2004) Differences in age at onset and familial aggregation between clinical types of idiopathic Parkinson’s disease. Mov Disord 19:1059–1064CrossRefPubMed
Kubo M, Wagenaar RC, Saltzman E, Holt KG (2004) Biomechanical mechanism for transitions in phase and frequency of arm and leg swing during walking. Biol Cybern 91:91–98CrossRefPubMed
Larsson LE, Odenrick P, Sandlund B, Weitz P, Oberg PA (1980) The phases of the stride and their interaction in human gait. Scand J Rehabil Med 12:107–112PubMed
Lee SJ, Hidler J (2008) Biomechanics of overground vs. treadmill walking in healthy individuals. J Appl Physiol 104:747–755CrossRefPubMed
Li Y, Wang W, Crompton RH, Gunther MM (2001) Free vertical moments and transverse forces in human walking and their role in relation to arm-swing. J Exp Biol 204:47–58PubMed
Lindemann U, Najafi B, Zijlstra W, Hauer K, Muche R, Becker C, Aminian K (2008) Distance to achieve steady state walking speed in frail elderly persons. Gait Posture 27:91–96CrossRefPubMed
Matsas A, Taylor N, McBurney H (2000) Knee joint kinematics from familiarised treadmill walking can be generalised to overground walking in young unimpaired subjects. Gait Posture 11:46–53CrossRefPubMed
Murray MP, Sepic SB, Barnard EJ (1967) Patterns of sagittal rotation of the upper limbs in walking. Phys Ther 47:272–284PubMed
Murray MP, Spurr GB, Sepic SB, Gardner GM, Mollinger LA (1985) Treadmill vs. floor walking: kinematics, electromyogram, and heart rate. J Appl Physiol 59:87–91PubMed
Nymark JR, Balmer SJ, Melis EH, Lemaire ED, Millar S (2005) Electromyographic and kinematic nondisabled gait differences at extremely slow overground and treadmill walking speeds. J Rehabil Res Dev 42:523–534CrossRefPubMed
Ohsato Y (1993) Relationships between trunk rotation and arm swing in human walking. Nippon Seikeigeka Gakkai Zasshi 67:440–448PubMed
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(16):3303–3308
Pailhous J, Ferrandez AM, Fluckiger M, Baumberger B (1990) Unintentional modulations of human gait by optical flow. Behav Brain Res 38:275–281CrossRefPubMed
Park J (2008) Synthesis of natural arm swing motion in human bipedal walking. J Biomech 41:1417–1426CrossRefPubMed
Parvataneni K, Ploeg L, Olney SJ, Brouwer B (2009) Kinematic, kinetic and metabolic parameters of treadmill versus overground walking in healthy older adults. Clin Biomech (Bristol, Avon) 24:95–100CrossRef
Prokop T, Schubert M, Berger W (1997) Visual influence on human locomotion. Modulation to changes in optic flow. Exp Brain Res 114:63–70CrossRefPubMed
Rabuffetti M, Crenna P (2004) A modular protocol for the analysis of movement in children. Gait Posture 20:S77–S78
Regnaux JP, Roberston J, Smail DB, Daniel O, Bussel B (2006) Human treadmill walking needs attention. J Neuroeng Rehabil 3:19CrossRefPubMed
Riley PO, Paolini G, Della CU, Paylo KW, Kerrigan DC (2007) A kinematic and kinetic comparison of overground and treadmill walking in healthy subjects. Gait Posture 26:17–24CrossRefPubMed
Stolze H, Kuhtz-Buschbeck JP, Mondwurf C, Boczek-Funcke A, Johnk K, Deuschl G, Illert M (1997) Gait analysis during treadmill and overground locomotion in children and adults. Electroencephalogr Clin Neurophysiol 105:490–497CrossRefPubMed
Strathy GM, Chao EY, Laughman RK (1983) Changes in knee function associated with treadmill ambulation. J Biomech 16:517–522CrossRefPubMed
Tesio L, Rota V (2008) Gait analysis on split-belt force treadmills: validation of an instrument. Am J Phys Med Rehabil 87:515–526CrossRefPubMed
Umberger BR (2008) Effects of suppressing arm swing on kinematics, kinetics, and energetics of human walking. J Biomech 41:2575–2580CrossRefPubMed
Van Emmerik RE, Wagenaar RC (1996) Dynamics of movement coordination and tremor during gait in Parkinson’s disease. Hum Mov Sci 15:203–235CrossRef
Van Emmerik RE, Wagenaar RC, Van Wegen EE (1998) Interlimb coupling patterns in human locomotion: are we bipeds or quadrupeds? Ann N Y Acad Sci 860:539–542CrossRefPubMed
Van Ingen Schenau GJ (1980) Some fundamental aspects of the biomechanics of overground versus treadmill locomotion. Med Sci Sports Exerc 12:257–261PubMed
Varraine E, Bonnard M, Pailhous J (2002) Interaction between different sensory cues in the control of human gait. Exp Brain Res 142:374–384CrossRefPubMed
Vogt L, Pfeifer K, Banzer W (2002) Comparison of angular lumbar spine and pelvis kinematics during treadmill and overground locomotion. Clin Biomech (Bristol, Avon) 17:162–165CrossRef
Wagenaar RC, Van Emmerik RE (1994) Dynamics of pathological gait. Hum Mov Sci 13:441–471CrossRef
Wagenaar RC, Van Emmerik RE (2000) Resonant frequencies of arms and legs identify different walking patterns. J Biomech 33:853–861CrossRefPubMed
Warabi T, Kato M, Kiriyama K, Yoshida T, Kobayashi N (2005) Treadmill walking and overground walking of human subjects compared by recording sole-floor reaction force. Neurosci Res 53:343–348CrossRefPubMed
Wass E, Taylor NF, Matsas A (2005) Familiarisation to treadmill walking in unimpaired older people. Gait Posture 21:72–79CrossRefPubMed
Webb D, Tuttle RH (1989) The effects of stride frequency on the motion of the upper limbs in human walking. Am J Phys Anthropol 78:321–322
Webb D, Tuttle RH, Baksh M (1994) Pendular activity of human upper limbs during slow and normal walking. Am J Phys Anthropol 93:477–489CrossRefPubMed
White SC, Yack HJ, Tucker CA, Lin HY (1998) Comparison of vertical ground reaction forces during overground and treadmill walking. Med Sci Sports Exerc 30:1537–1542CrossRefPubMed
Zanetti C, Schieppati M (2007) Quiet stance control is affected by prior treadmill but not overground locomotion. Eur J Appl Physiol 100:331–339CrossRefPubMed
Zatsiorsky V, Seluyanov V (1983) The mass and inertia characteristics of the main segments of the human body. In: Matsui H, Kobayashi K (eds) Biomechanics VIII-B. Human Kinetics, Champaign, IL, pp 1152–1159
Zehr EP, Duysens J (2004) Regulation of arm and leg movement during human locomotion. Neuroscientist 10:347–361CrossRefPubMed
Zijlstra W, Rutgers AW, Hof A, Van Weerden TW (1995) Voluntary and involuntary adaptation of walking to temporal and spatial constraints. Gait Posture 3:13–18CrossRef
Metadata
Title
Coordination between upper- and lower-limb movements is different during overground and treadmill walking
Authors
Ilaria Carpinella
Paolo Crenna
Marco Rabuffetti
Maurizio Ferrarin
Publication date
01-01-2010
Publisher
Springer-Verlag
Published in
European Journal of Applied Physiology / Issue 1/2010
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-009-1168-5

Other articles of this Issue 1/2010

European Journal of Applied Physiology 1/2010 Go to the issue

Original Article

Bilateral deficit and EMG activity during explosive lower limb contractions against different overloads

Invited Reviews

Diastolic function in healthy humans: non-invasive assessment and the impact of acute and chronic exercise

Short Communication

Viscoelastic creep in the human skeletal muscle–tendon unit

Case Study

Measuring submaximal performance parameters to monitor fatigue and predict cycling performance: a case study of a world-class cyclo-cross cyclist

Original Article

No effect of prior caffeine ingestion on neuromuscular recovery after maximal fatiguing contractions

Original Article

Influence of crank length on cycle ergometry performance of well-trained female cross-country mountain bike athletes