Go to Home

Search

-Advanced Search   -Search Guidelines

Ann Rehabil Med.  2023 Aug;47(4):291-299. 10.5535/arm.23061.

Torque Onset Angle of the Knee Extensor as a Predictor of Walking Related Balance in Stroke Patients

Affiliations
  • 1Department of Rehabilitation Medicine, Bundang Jesaeng Hospital, Seongnam, Korea
  • 2Department of Rehabilitation Medicine, Gwangju Veterans Hospital, Gwangju, Korea

Abstract


Objective
To investigate the relationship between the torque onset angle (TOA) of the isokinetic test for knee extensors in the paretic side and walking related balance in subacute stroke patients.
Methods
We retrospectively reviewed patients with first-ever strokes who have had at least two isokinetic tests within 6 months of onset. 102 patients satisfied the inclusion criteria. The characteristics of walking related balance were measured with the Berg Balance Scale sub-score (sBBS), Timed Up and Go test (TUG), 10-m Walk Test (10MWT) and Functional Independence Measure sub-score (sFIM). The second isokinetic test values of the knee extensor such as peak torque, peak torque to weight ratio, hamstring/quadriceps ratio, TOA, torque stop angle, torque at 30 degrees, and peak torque asymmetry ratio between paretic and non-paretic limb were also taken into account. Pearson’s correlation, simple regression and multiple regression analysis were used to analyze the correlation between TOA and walking related balance.
Results
TOA of the knee extensor of the paretic limb showed significant correlations with BBS, sBBS, TUG, 10MWT, and sFIM according to Pearson’s correlation analysis. TOA also had moderate to good correlations with walking related balance parameters in partial correlation analysis. In multiple regression analysis, TOA of the paretic knee extensor was significantly associated with walking related balance parameters.
Conclusion
This study demonstrated that TOA of the paretic knee extensor is a predictable parameter of walking related balance. Moreover, we suggest that the ability to recruit muscle quickly is important in walking related balance.

Keyword

Stroke; Outcome prediction; Isokinetic parameters; Walking related balance; Rehabilitation

Figure

  • Fig. 1. Moment angle position curve. TA30, torque at 30°; TOA, torque onset angle; PTA, peak torque angle; TSA, torque stop angle.


Reference

1. Doussoulin A, Rivas R, Sabelle C. [Hospital discharges due to stroke in the period 2001-2010 in a southern Chilean region]. Rev Med Chil. 2016; 144:571–6. Spanish.
2. Bohannon RW. Muscle strength and muscle training after stroke. J Rehabil Med. 2007; 39:14–20.
Article
3. Harris JE, Eng JJ. Paretic upper-limb strength best explains arm activity in people with stroke. Phys Ther. 2007; 87:88–97.
Article
4. Horstman AM, Beltman MJ, Gerrits KH, Koppe P, Janssen TW, Elich P, et al. Intrinsic muscle strength and voluntary activation of both lower limbs and functional performance after stroke. Clin Physiol Funct Imaging. 2008; 28:251–61.
Article
5. Bohannon RW. Correlation of knee extension force and torque with gait speed in patients with stroke. Physiother Theory Pract. 1991; 7:185–90.
Article
6. Baltzopoulos V, Brodie DA. Isokinetic dynamometry. Applications and limitations. Sports Med. 1989; 8:101–16.
7. Kristensen OH, Stenager E, Dalgas U. Muscle strength and poststroke hemiplegia: a systematic review of muscle strength assessment and muscle strength impairment. Arch Phys Med Rehabil 2017;98:368-80. Erratum in: Arch Phys Med Rehabil. 2017; 98:1276.
8. Kannus P. Isokinetic evaluation of muscular performance: implications for muscle testing and rehabilitation. Int J Sports Med. 1994; 15 Suppl 1:S11–8.
9. Becker R, Awiszus F. Physiological alterations of maximal voluntary quadriceps activation by changes of knee joint angle. Muscle Nerve. 2001; 24:667–72.
Article
10. Kellis E, Baltzopoulos V. The effects of antagonist moment on the resultant knee joint moment during isokinetic testing of the knee extensors. Eur J Appl Physiol Occup Physiol. 1997; 76:253–9.
Article
11. Pohl PS, Duncan P, Perera S, Long J, Liu W, Zhou J, et al. Rate of isometric knee extension strength development and walking speed after stroke. J Rehabil Res Dev. 2002; 39:651–7.
12. Osawa Y, Studenski SA, Ferrucci L. Knee extension rate of torque development and peak torque: associations with lower extremity function. J Cachexia Sarcopenia Muscle. 2018; 9:530–9.
Article
13. Schlenstedt C, Paschen S, Kruse A, Raethjen J, Weisser B, Deuschl G. Resistance versus balance training to improve postural control in Parkinson's disease: a randomized rater blinded controlled study. PLoS One. 2015; 10:e0140584.
Article
14. Granacher U, Gollhofer A, Kriemler S. Effects of balance training on postural sway, leg extensor strength, and jumping height in adolescents. Res Q Exerc Sport. 2010; 81:245–51.
Article
15. Lanza MB, Balshaw TG, Folland JP. Explosive strength: effect of knee-joint angle on functional, neural, and intrinsic contractile properties. Eur J Appl Physiol. 2019; 119:1735–46.
Article
16. de Ruiter CJ, Kooistra RD, Paalman MI, de Haan A. Initial phase of maximal voluntary and electrically stimulated knee extension torque development at different knee angles. J Appl Physiol (1985). 2004; 97:1693–701.
Article
17. Maffiuletti NA, Aagaard P, Blazevich AJ, Folland J, Tillin N, Duchateau J. Rate of force development: physiological and methodological considerations. Eur J Appl Physiol. 2016; 116:1091–116.
Article
18. Lodha N, Patel P, Casamento-Moran A, Hays E, Poisson SN, Christou EA. Strength or motor control: what matters in high-functioning stroke? Front Neurol. 2019; 9:1160.
Article
19. Hall PS, Roofner MA. Velocity spectrum study of knee flexion and extension in normal adults: 60 to 500 deg/sec. Isokinet Exerc Sci. 1991; 1:131–7.
Article
20. Lima CA, Ricci NA, Nogueira EC, Perracini MR. The Berg Balance Scale as a clinical screening tool to predict fall risk in older adults: a systematic review. Physiotherapy. 2018; 104:383–94.
Article
21. Nordin E, Lindelöf N, Rosendahl E, Jensen J, Lundin-Olsson L. Prognostic validity of the Timed Up-and-Go test, a modified Get-Up-and-Go test, staff's global judgement and fall history in evaluating fall risk in residential care facilities. Age Ageing. 2008; 37:442–8.
Article
22. Green J, Forster A, Young J. Reliability of gait speed measured by a timed walking test in patients one year after stroke. Clin Rehabil. 2002; 16:306–14.
Article
23. Heinemann AW, Michael Linacre J, Wright BD, Hamilton BB, Granger C. Measurement characteristics of the Functional Independence Measure. Top Stroke Rehabil. 1994; 1:1–15.
Article
24. Portney LG, Watkins MP. Foundations of clinical research: applications to practice. 3rd ed. Pearson ‎Prentice Hall;2009.
25. Winters JD, Rudolph KS. Quadriceps rate of force development affects gait and function in people with knee osteoarthritis. Eur J Appl Physiol. 2014; 114:273–84.
Article
26. Olney SJ, Richards C. Hemiparetic gait following stroke. Part I: characteristics. Gait Posture. 1996; 4:136–48.
Article
27. Lieber RL, Steinman S, Barash IA, Chambers H. Structural and functional changes in spastic skeletal muscle. Muscle Nerve. 2004; 29:615–27.
Article
28. De Deyne PG, Hafer-Macko CE, Ivey FM, Ryan AS, Macko RF. Muscle molecular phenotype after stroke is associated with gait speed. Muscle Nerve. 2004; 30:209–15.
Article
29. Scherbakov N, Doehner W. Sarcopenia in stroke-facts and numbers on muscle loss accounting for disability after stroke. J Cachexia Sarcopenia Muscle. 2011; 2:5–8.
Article
30. Hachisuka K, Umezu Y, Ogata H. Disuse muscle atrophy of lower limbs in hemiplegic patients. Arch Phys Med Rehabil. 1997; 78:13–8.
Article
31. Ivanhoe CB, Reistetter TA. Spasticity: the misunderstood part of the upper motor neuron syndrome. Am J Phys Med Rehabil. 2004; 83(10 Suppl):S3–9.
32. Jung H, Ko CY, Kim JS, Lee B, Lim D. Alterations of relative muscle contribution induced by hemiplegia: straight and turning gaits. Int J Precis Eng Manuf. 2015; 16:2219–27.
Article
33. Rabita G, Dupont L, Thevenon A, Lensel-Corbeil G, Pérot C, Vanvelcenaher J. Differences in kinematic parameters and plantarflexor reflex responses between manual (Ashworth) and isokinetic mobilisations in spasticity assessment. Clin Neurophysiol. 2005; 116:93–100.
Article
34. Kelly-Hayes M, Wolf PA, Kase CS, Gresham GE, Kannel WB, D'Agostino RB. Time course of functional recovery after stroke: the Framingham study. J Neurol Rehabilit. 1989; 3:65–70.
35. Whittle MW. Three-dimensional motion of the center of gravity of the body during walking. Hum Mov Sci. 1997; 16:347–55.
Article
36. Finch L, Barbeau H, Arsenault B. Influence of body weight support on normal human gait: development of a gait retraining strategy. Phys Ther. 1991; 71:842–55. discussion 855-6.
37. Wei TS, Liu PT, Chang LW, Liu SY. Gait asymmetry, ankle spasticity, and depression as independent predictors of falls in ambulatory stroke patients. PLoS One. 2017; 12:e0177136.
Article
38. Prado-Medeiros CL, Silva MP, Lessi GC, Alves MZ, Tannus A, Lindquist AR, et al. Muscle atrophy and functional deficits of knee extensors and flexors in people with chronic stroke. Phys Ther. 2012; 92:429–39.
39. Nimphius S, McBride JM, Rice PE, Goodman-Capps CL, Capps CR. Comparison of quadriceps and hamstring muscle activity during an isometric squat between strength-matched men and women. J Sports Sci Med. 2019; 18:101–8.
40. Hewett TE, Myer GD, Zazulak BT. Hamstrings to quadriceps peak torque ratios diverge between sexes with increasing isokinetic angular velocity. J Sci Med Sport. 2008; 11:452–9.
Full Text Links
  • ARM
Actions
Cited
CITED
export Copy
Close
Share
  • Twitter
  • Facebook
Similar articles

Cited

Download

Close

Save citations to file

Download

Close

Email citations

Send Email
recaptcha 영역

Close

Copyright © 2024 by Korean Association of Medical Journal Editors. All rights reserved.     E-mail: koreamed@kamje.or.kr