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Parallel Walk Test

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The Parallel Walk Test is a quick and simple quantitative measuring tool for balance during walking[1] and could be a useful tool in clinical settings for assessing balance before and after treatments and to discriminate high fall risk potential.

The test takes 3-5 minutes and comprise of walking 6 meters between 2 parallel lines measured 8”, 12” and 15” across in width. The test is scored based on number of stepping errors, i.e. stepping on a line (+1) or stepping over a line (+2), where a higher score denotes decrease performance and total time to perform walk.[2] A warm-up walk of 20m can be performed as well as 1 practice walk.

It was created to address the significance lateral movement, during walking, has to balance and fall risk and is based on research that indicated increased lateral movement during walking corresponds to decrease dynamic stability.[3] Research has shown that testing balance function under narrow stance conditions provides adequate difficulty to help reveal insufficiency in balance control that could increase the risk of falls[4] and that differences between fallers and non-fallers were most pronounced for measures related to lateral stability.[5] Instability during walking is primarily in the medio-lateral direction and decrease in medio-lateral stability has been show to be a major risk factor for falls in older adults.[6] Further research has found that fallers tend to have wider step width and slower walking speeds.[7]

Falls in older adults occur most commonly during walking[8] so appropriate balance testing should contain walking to adequately test for stability during walking. Current measuring tools, like the Berg Balance Scale and the Timed Up and Go, may lack key components to measure balance during walking adequately. The Berg Balance Scale is considered the “gold standard” of balance testing but does not have a walking component. The Timed Up and Go is frequently used as well to measure balance and has a walking component but has only a temporal component and has no objective description of balance during the activity. The Parallel Walk Test provides quantitative data that describes the level of dynamic balance as well as gives temporal data during walking.[9] Research showed that the inter-rater reliability ICC range=0.93-0.99 and the test-retest reliability ICC range=0.63-0.90.[10] To determine validity, Lark and Sowjanya used tandem stance (one foot directly in front of the other), parallel stance (feet 20cm apart) and tandem walking for 6 meters. The Validity Co-efficient (percent correctly classified as faller)=0.70-0.84 for the balance score. There was a significant correlation between tandem stance mean time and scores of the Parallel Walk Test r=0.49 p<.001. The study showed non-fallers were able to stand 3 times longer compared to fallers and tandem standing is incorporated to several balance measurement tools, i.e. Berg Balance Scale.[11] The reliability of the Parallel Walk Test was also tested with people with strokes by Ng et.al.[12] They found intra-rater reliability ICC range=0.784-0.962, inter-rater and test-retest reliabilities ICC range=0.864-1.00. The sensitivity=84%-89% and specificity=71%-80%. They also found significant correlation between the PWT, all 3 width, and Berg Balance Scale r=-0.617--0.682, p<.05 and TUG r=0.466-0.658, p<0.05.[13] Variations of the Parallel Walk Test, referred to as Narrow Path Walking Test, have been used for identification of elderly fallers, and assessing balance in people with MS. Gimmons et.al used 50% of the distance between the subject’s ASIS (anterior superior iliac spine) plus the width of the subject’s shoe to normalize the challenge to different body morphologies. They used 3 trials and averaged the time and score. They also had the subjects perform the Tinetti Performance Oriented Mobility Assessment, POMA and fill out a questionnaire regarding fear of falling, FES-1. They found a significant difference in time between fallers and non-fallers F=11.498, P<0.001, when age, gender and fear of falling were adjusted. Overall, they found Narrow Path Walking Test was better able to identify fallers than the POMA and FES-1.[14] Rosenblum and Melzer used 50% ASIS distance plus shoe width in their study with people with Multiple Sclerosis. They found for concurrent validity, number of step errors correlated with Four Square Step Test, r=.75, p<.001 and with 2 minute Walk Test r=-0.51, p<0.01. For test-retest reliability, they found number of stepping error ICC=0.94 (0.87-0.97) and time ICC=0.64 (0.27-0.82). They found that the number of step errors and trial velocity were the most reliable parameters tested that detect instability during walking for people with Multiple Sclerosis.[15] Many studies have shown that the Parallel Walk Test, and its variation the Narrow Path Walk Test, is a valid and reliable measurement tools to assess balance while walking for a variety of conditions.[16][17][18][19][20]




References

  1. ^ Lark, SD; McCarthy, PW; Rowe, DA (2011). "Reliability of the Parallel Walk Test for the elderly". Arch Phys Med Rehabil. 92: 812-817. PMID: 21530730
  2. ^ Lark, SD; Sowjanya, P (2009). "Validity of a Functional Dynamic Walking Test for the elderly". Arch Phys Med Rehabil. 90: 470-474. PMID: 19254613
  3. ^ Maki, BE; McIllroy, WE (1996). "Postural control in the older adult". Clin Geriatr Med. 12: 635-658. PMID: 8890108
  4. ^ Melzer, I; Kurz, I; Oddsson, L (2010). "A retrospective analysis of balance control parameters in elderly fallers and non-fallers". Clinical Biomech. 25: 984-988. DOI: 10.1016/jclinbiomech.2010.07.007
  5. ^ Maki, BE; Holliday, PJ; Topper, AK (1994). "A prospective study of postural balance and risk of falling in an ambulatory and independent elderly population". J. Gerontol. 49(2): 72-84. PMID: 8126355.
  6. ^ Maki, BE (1997). "Gait changes in older adults: Predictors of falls or indicators of fear". J Am Geriatr Soc. 45(3): 313-320. PMID: 9063277
  7. ^ Mortaza, N; Abu-Osman, NA; Mehdikhani, N (2014). "Are the patio-temporal parameters of gait capable of distinguishing a faller from a non-faller elderly". Eur J Phys Rehabil Med. 50: 677-691. PMID: 24831570
  8. ^ Mortaza, N; Abu-Osman, NA; Mehdikhani, N (2014). "Are the patio-temporal parameters of gait capable of distinguishing a faller from a non-faller elderly". Eur J Phys Rehabil Med. 50: 677-691. PMID: 24831570
  9. ^ Lark, SD; Sowjanya, P (2009). "Validity of a Functional Dynamic Walking Test for the elderly". Arch Phys Med Rehabil. 90: 470-474. PMID: 19254613
  10. ^ Lark, SD; McCarthy, PW; Rowe, DA (2011). "Reliability of the Parallel Walk Test for the elderly". Arch Phys Med Rehabil. 92: 812-817. PMID: 21530730
  11. ^ Lark, SD; Sowjanya, P (2009). "Validity of a Functional Dynamic Walking Test for the elderly". Arch Phys Med Rehabil. 90: 470-474. PMID: 19254613
  12. ^ Ng, SS; Chan, LH; Chan, CS; Lai, SH; Wu, WW; Tse, MM; Fong, SS (2015). "Parallel Walk Test: Its correlation with balance and motor functions in people with chronic stroke". Arch Phys Med and Rehab. 96: 877-884. PMID 25461824
  13. ^ Ng, SS; Chan, LH; Chan, CS; Lai, SH; Wu, WW; Tse, MM; Fong, SS (2015). "Parallel Walk Test: Its correlation with balance and motor functions in people with chronic stroke". Arch Phys Med and Rehab. 96: 877-884. PMID 25461824
  14. ^ Gimmon, Y; Barash, A; Debi, R; Snir, Y; David, YB; Grinshpon, J; Melzer, I (2016). "Application of the clinical version of the narrow path walking test to identify elderly fallers". Arch Geron and Geriatr. 63: 108-113. PMID: 26586113
  15. ^ Rosenbaum, U; Melzer, I (2017). "Reliability and concurrent validity of the Narrow Path Walking Test in persons with multiple sclerosis". J Am Geriatr Soc. 45(3): 313-320. PMID: 9063277
  16. ^ Lark, SD; McCarthy, PW; Rowe, DA (2011). "Reliability of the Parallel Walk Test for the elderly". Arch Phys Med Rehabil. 92: 812-817. PMID: 21530730
  17. ^ Lark, SD; Sowjanya, P (2009). "Validity of a Functional Dynamic Walking Test for the elderly". Arch Phys Med Rehabil. 90: 470-474. PMID: 19254613
  18. ^ Ng, SS; Chan, LH; Chan, CS; Lai, SH; Wu, WW; Tse, MM; Fong, SS (2015). "Parallel Walk Test: Its correlation with balance and motor functions in people with chronic stroke". Arch Phys Med and Rehab. 96: 877-884. PMID 25461824
  19. ^ Gimmon, Y; Barash, A; Debi, R; Snir, Y; David, YB; Grinshpon, J; Melzer, I (2016). "Application of the clinical version of the narrow path walking test to identify elderly fallers". Arch Geron and Geriatr. 63: 108-113. PMID: 26586113
  20. ^ Rosenbaum, U; Melzer, I (2017). "Reliability and concurrent validity of the Narrow Path Walking Test in persons with multiple sclerosis". J Am Geriatr Soc. 45(3): 313-320. PMID: 9063277

Parallel Walk Test

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