Please use this identifier to cite or link to this item: http://hdl.handle.net/1942/15812
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dc.contributor.authorNARAIN, Faridi-
dc.contributor.authorVAN ZWIETEN, Koos Jaap-
dc.contributor.authorLAMUR, Kenneth S.-
dc.contributor.authorKOSTEN, Lauren-
dc.contributor.authorDE MUNTER, Stephanie-
dc.contributor.authorZOUBOVA, Irina-
dc.contributor.authorSCHMIDT, Klaus-
dc.date.accessioned2013-10-16T10:10:39Z-
dc.date.available2013-10-16T10:10:39Z-
dc.date.issued2013-
dc.identifier.citationFOLIA PRIMATOLOGICA, 84 (3-5), p. 305-305-
dc.identifier.issn0015-5713-
dc.identifier.urihttp://hdl.handle.net/1942/15812-
dc.description.abstractWe analysed videos (from the public domain) of a walking wombat, Lasiorhinus krefftii. From take-off, its foot’s lateral side stays continuously lifted, causing everted foot positions during most of the swing phase, as also observed in the opossum, Didelphis marsupialis. Here the cardan-like ankle joint transmits shank axial rotation to foot-eversion or foot-inversion (Narain et al., 2009). Only recently, have measurements from primates, viz. man, allowed extrapolating these data to bipedal gait. At the onset of swing, foot eversion clears the human foot from the ground (Legault-Moore et al., 2012).-
dc.description.sponsorshipUniversity of Hasselt, Scientific Contract Research, Project R-3500 Foot inversion and eversion movements in stance and swing - some comparative-anatomical and functional morphological aspects-
dc.language.isoen-
dc.rights© 2013 S. Karger AG, Basel-
dc.subject.otherFoot; Gait; Swing; Metatherians; Eutherians-
dc.titleNon-Sagittal Shank and Foot Movements in the Kinematic Articular Chain during the Swing Phase of Gait-
dc.typeJournal Contribution-
dc.identifier.epage305-
dc.identifier.issue3-5-
dc.identifier.spage305-
dc.identifier.volume84-
local.bibliographicCitation.jcatM-
dc.description.notesDetails of project R-3500 Title : Foot inversion and eversion movements in stance and swing - some comparative-anatomical and functional morphological aspects. Abstract: In the lower leg of the common opossum Didelphis marsupialis, the spatium interosseum cruris between tibia and fibula widens in stance during the power stroke, reflecting external rotations of these bones, coupled to extreme inversion of the foot, which lasts until the end of push-off. Although denied in marsupials until recently the strong ligamentum astragalocalcaneum interosseum underlines the importance of our observations. From the very onset of recovery the opossum foot shows eversion. This eversion is coupled to internal rotations of both fibula and tibia in the free leg as is also reflected by the narrowing of the spatium interosseum cruris in the opossum. The precise course of m. interosseus cruris in Didelphis ursina Shaw, suggests its possible active role in this process of repositioning before and during touchdown In man, the foot at the end of stance at push-off shows but a modest inversion which however can be exaggerated to a more extreme inversion of the foot. Then tarsal joints like Chopart's joint and sinus tarsi clearly show their joint spaces on routine radiography. Normally our ligamentum talocalcaneum interosseum restrains this widening. In normal gait, a foot landing after its recovery phase may accidentally do so in a position of inversion, risking a so-called inversion traumatism, the most common ankle sprain. Training proactively e.g. the peroneus muscles, the evertors of the foot, may prevent the incidence of such traumatisms, as suggested by a pilot-study in gymnasts. Extrapolating such methods to the disabled, e.g. in early diagnosed neuropathies, implies possibilities to train these muscles thus protecting Multiple Sclerosis patients from e.g. stumbling and falling. Period of project : 1-01-2012 to 31-12-2013-
dc.relation.references1. Narain, F. H. M., van Zwieten, K. J., Gervois, P., Lippens, P. L., Reyskens, A., Colla, P., Palmers, Y., Schmidt, K. P., Vandersteen, M., Biesmans, S., Robeyns, I., Op 't Eijnde, B., Zinkovsky, A. V., Varzin, S. A., Lamur, K. S. (2009) Human foot inversion prior to toe-off: an analysis by means of functional morphology, and comparative anatomical observation. Journal of Vibroengineering, 11 (3), 530-535. 2. Legault-Moore, D., Chester, V. L., de Vries, G. (2012) Multisegment foot kinematics during walking in younger and older adults. Journal of Clinical Medicine Research, 4 (4), 259-266. 3. Hubbard, K., Wilson, G. et al. (2012) Video: Filming the World’s Fastest Runner. National Geographic, November Issue. 4. van Zwieten, K. J., Lippens, P. L., Honinckx, M. (1991) Gripping mechanism in Didelphis includes prehensive patterns. Belgian Journal of Zoology, 121, S1, 49-50.-
local.type.refereedRefereed-
local.type.specifiedMeeting Abstract-
dc.identifier.doi10.1159/000354129-
dc.identifier.isi000323807400122-
item.fulltextWith Fulltext-
item.contributorKOSTEN, Lauren-
item.contributorVAN ZWIETEN, Koos Jaap-
item.contributorDE MUNTER, Stephanie-
item.contributorSCHMIDT, Klaus-
item.contributorNARAIN, Faridi-
item.contributorZOUBOVA, Irina-
item.contributorLAMUR, Kenneth S.-
item.fullcitationNARAIN, Faridi; VAN ZWIETEN, Koos Jaap; LAMUR, Kenneth S.; KOSTEN, Lauren; DE MUNTER, Stephanie; ZOUBOVA, Irina & SCHMIDT, Klaus (2013) Non-Sagittal Shank and Foot Movements in the Kinematic Articular Chain during the Swing Phase of Gait. In: FOLIA PRIMATOLOGICA, 84 (3-5), p. 305-305.-
item.accessRightsOpen Access-
crisitem.journal.issn0015-5713-
crisitem.journal.eissn1421-9980-
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