Biomechanics assessment of long term consequences of talocrural joint sprain in conservatively treated males

Czamara, A.; Emilianowicz, M.; Markowska, I.; Truszczyńska, A.; Trzaska, T.; Lewandowski, J.; Barinow-Wojewódzki, A.; Maciąg-Tymecka, I.

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Biomechanics assessment of long term consequences of talocrural joint sprain in conservatively treated males

Autorzy

Czamara A. , Emilianowicz M. , Markowska I. , Truszczyńska A. , Trzaska T. , Lewandowski J. , Barinow-Wojewódzki A. , Maciąg-Tymecka I.

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Abstrakty

The aim of the study was an assessment of isometric torque (IT) values under static conditions and relative torque (RT) for the plantar flexion muscles (PFM) and dorsal flexion muscles (DFM) and their mutual relations in males 5 years after talocrural joint sprain. IT measurements in PFM and DFM were performed using Biodex System 3. Group I consisted of 20 males on average 5 years after the sprain of the talocrural joint. Group II comprised 23 males with no history of talocrural joint injuries. The angles of measurement were: –15° of dorsiflexion (DF) and 0°, 15°, 30° and 45° for plantar flexion (PF) of the foot. In group I, the IT and RT obtained from PFM of involved leg were statistically significantly lower for most of the measured values of foot angle as compared to the contralateral joint and the results of the control group. The increase in the PF angle resulted in the decrease in IT values obtained from PFM, in favour of DFM. The IT values for PFM and DFM depend on the angle of foot and are represented by two different curves.

Słowa kluczowe

dorsiflexion muscles isometric torque plantar flexion muscles talocrural joint

mięśnie staw skokowo-goleniowy zgięcie grzbietowe

Wydawca

Oficyna Wydawnicza Politechniki Wrocławskiej

Czasopismo

Acta of Bioengineering and Biomechanics

Rocznik

2013

Tom

Vol. 15, no. 4

Strony

73--81

Opis fizyczny

Bibliogr. 34 poz., rys., tab., wykr.

Twórcy

autor

Czamara A.

a.czamara@wsf.wroc.pl

The College of Physiotherapy in Wrocław, Wrocław, Poland

autor

Emilianowicz M.

The College of Physiotherapy in Wrocław, Wrocław, Poland

autor

Markowska I.

The College of Physiotherapy in Wrocław, Wrocław, Poland

autor

Truszczyńska A.

Józef Piłsudski University of Physical Education in Warsaw, Warszawa, Poland

autor

Trzaska T.

University School of Physical Education in Poznań, Poznań, Poland

autor

Lewandowski J.

University School of Physical Education in Poznań, Poznań, Poland

autor

Barinow-Wojewódzki A.

University School of Physical Education in Poznań, Poznań, Poland

autor

Maciąg-Tymecka I.

The College of Physiotherapy in Wrocław, Wrocław, Poland

Bibliografia

[1] KADAKIA A.R., Overview of the Ankle in Essentional Orthopaedics, Saunders Elsevier, 2010.
[2] GOLANO P., VEGA J., DE LEEUW P.A.J., MALAGELADA F., MANZANARES M.C., GÖTZENS V., VAN DIJK C., Anatomy of the ankle ligaments: a pictorial essay, Knee Surg. Sports Traumatol. Arthrosc., 2010, Vol. 18(5), 557–569.
[3] DIGIOVANI CH.W., GREISBERG J., Foot & Ankle Core Knowledge in Orthopaedics, Elsevier 2007.
[4] RICHARDS J., Chapter 6. Biomechanics in Tidy’s Physiotherapy, Elsevier 2008.
[5] LUNDGREN P., NESTER C., LIU A., ARNDT A., JONES R., STACOFF A., WOLF P., LUNDBERG A., Invasive in vivo measurement of rear-, mid- and forefoot motion during walking, Gait Posture, 2008, Vol. 28(1), 93–100.
[6] ARNDT A., WOLF P., LIU A., NESTER C., STACOFF A., JONES R., LUNDBERG A., Intrinsic foot kinematics measured in vivo during the stance phase of slow running, J. Biomech., 2007, Vol. 40(12), 2672–2678.
[7] LEE S.S.M., PIAZZA S.J., Correlation between plantarflexor moment arm and preferred gait velocity in slower elderly men, J. Biomech., 2012, Vol. 45(9), 1601–1606.
[8] LENARDI A., BENEDETTI M.G., BERTI L., BETTINELLI D., NATIVO R., GIANNINI S., Rear-foot, mid-foot and fore-foot motion during the stance phase of gait, Gait Posture, 2007, Vol. 25, 453–462.
[9] COLLADO H., COUDREUSE J.M., GRAZIANI F., BENSOUSSAN L., VITON J.M., DELARQUE A., Eccentric reinforcement of the ankle evertor muscles after lateral ankle sprain, Scand. J. Med. Sci. Sports, 2010, Vol. 20(2), 241–246.
[10] MUNN J., BEARD D.J., REFSHAUGE K.M., LEE R.Y., Eccentric muscle strength in functional ankle instability, Med. Sci. Sports Exerc., 2003, Vol. 35(2), 245–250.
[11] GOHARPEY S.H., SADEGHI M., MAROUFI N., SHATERZADEH M.J., Comparison of Invertor and Evertor Muscle Strength in Patients with Chronic Functional Ankle Instability, J. Med. Sci., 2007, Vol. 7(4), 674–677.
[12] SEKIR U., YILDIZ Y., HAZNECI B., ORS F., AYDIN T., Effect of isokinetic training on strength, functionality and proprioception in athletes with functional ankle instability, Knee Surg. Sports Traumatol. Arthrosc., 2007, Vol. 15(5), 654–664.
[13] TRAPPE S.W., TRAPPE T.A., LEE G.A., COSTILL D.L., Calf muscle strength in human, Int. J. Sports Med., 2001, Vol. 22(3), 186–191.
[14] ARAMPATZIS A., KARAMANIDIS K., STAFILIDIS S., MOREYKLAPSING G., DEMONTE G., BRÜGGEMANN G.P., Effect of different ankle- and knee-joint positions on gastrocnemius medialis fascicle length and EMG activity during isometric plantar flexion, J. Biomech., 2006, Vol. 39(10), 1891–1902.
[15] SIMONEAU E.M., LONGO S., SEYNNES O.R., NARICI M.V., Human muscle fascicle behavior in agonist and antagonist isometric contractions, Muscle Nerve, 2012, Vol. 45(1), 92–99.
[16] CZAMARA A., Physiotherapeutic procedure after injuries of soft tissues of tarsal-crural jont, J. Orthop. Traum. Surg. Rel. Res., 2008, Vol. 4(12), 88–108.
[17] Biodex Advantage Software, Operations Manual (version 3.29 and 3.30), Biodex Medical Systems, Inc. New York, 2008.
[18] DVIR Z., Isokinetics. Muscle Testing, Interpretation and Clinical Applicaction, Elsevier 2004, 167–184.
[19] KAMIŃSKI T.W., BUCKLEY B.D., POWERS M.E., HUBBARD T.J., ORTIZ C., Effect of strength and proprioception training on eversion to inversion strength ratios in subjects with unilateral functional ankle instability, Br. J. Sports Med., 2003, Vol. 37(5), 410–415.
[20] HADZIC V., SATTLER T., TOPOLE E., JARNOVIC Z., BURGER H., DERVISEVIC E., Risk factors for ankle sprain in volleyball players: A preliminary analysis, Isokinet. Exerc. Sci., 2009, Vol. 17(3), 155–160. DOI 10.3233/IES-2009-0347.
[21] MÖLLER M., LIND K., MOVIN T., KARLSSON J., Calf muscle function after Achilles tendon rupture. A prospective, randomized study comparing surgical and non-surgical treatment, Scand. J. Med. Sci. Sports, 2002, Vol. 12(1), 9–16.
[22] SIMONEAU E., MARTIN A., VAN HOECKE J., Effects of joint angle and age on ankle dorsi- and plantar-flexor strength, J. Electromyogr. Kinesiol., 2007, Vol. 17(3), 307–316.
[23] SIMONEAU E.M., BILLOT M., MARTIN A., VAN HOECKE J., Antagonist mechanical contribution to resultant maximal torque at the talocrural joint in young and older men, J. Electromyogr. Kinesiol., 2009, Vol. 19, 123–131.
[24] HAHN D., OLVERMANN M., RICHTBERG J., SEIBERL W., SCHWIRTZ A., Knee and talocrural joint torque–angle relationships of multi-joint leg extension, J. Biomech., 2011, Vol. 44, 2059–2065.
[25] WYCHOWAŃSKI M., Wybrane metody oceny dynamiki układu ruchu człowieka, Studia Monografie, AWF, Warszawa, 2008, 73–78.
[26] DE OLIVEIRA L.F., MENEGALDO L.L., Input error analysis of an EMG-driven muscle model of the plantar flexors, Acta Bioeng. Biomech., 2012, Vol. 14(2), 75–81. DOI: 10.5277/abb120210.
[27] CZAMARA A., Moments of muscular strength of knee joint extensors and flexors during physiotherapeutic procedures following anterior cruciate ligament reconstruction in males, Acta Bioeng. Biomech., 2008, Vol. 10(3), 37–44.
[28] CZAMARA A., TOMASZEWSKI W., BOBER T., LUBARSKI B., The effect of physiotherapy on knee joint extensor and flexor muscle strength after anterior cruciate ligament reconstruction, Med. Sci. Monit., 2011, Vol. 17(1), 35–41.
[29] CZAMARA A., SZUBA Ł., KRZEMIŃSKA A., TOMASZEWSKI W., WILK-FRAŃCZUK M., Effect of physiotherapy on the strength of tibial internal rotator muscles in males after anterior cruciate ligament reconstruction (ACLR), Med. Sci. Monit., 2011, Vol. 17(9), 523–531.
[30] WATANABE K., KITAOKA H.B., BERGLUND L.J., ZHAO K.D., KAUFMAN K.R., AN K.N., The role of ankle ligaments and articular geometry in stabilizing the ankle, Clin. Biomech. (Bristol, Avon), 2012, Vol. 27(2), 189–195. Epub 2011 Oct 13.
[31] BROWN C., BOWSER B., SIMPSON K.J., Movement variability during single leg jump landings in individuals with and without chronic ankle instability, Clin. Biomech. (Bristol, Avon), 2012, Vol. 27(1), 52–63. Epub 2011 Aug 20.
[32] MENEGALDO L.L., DE OLIVEIRA L.F., Effect of muscle model parameter scaling for isometric plantar flexion torque prediction, J. Biomech., 2009, Vol. 42(15), 2597–2601. Epub 2009 Aug 8.
[33] HOPKINS J.T., COGLIANESE M., GLASGOW P., REESE S., SEELEY M.K., Alterations in evertor/invertor muscle activation and center of pressure trajectory in participants with functional ankle instability, J. Electromyogr. Kinesiol., 2012, Vol. 22(2), 280–285. Epub 2011 Dec 16.
[34] DAVIES G.J., A compendium of isokinetics in clinical usage and rehabilitation techniques, S&S Publishers Wisconsin, 1992.

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Bibliografia

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