The influence of diabetic peripheral neuropathy on local postural muscle and central sensory feedback balance control

Nima Toosizadeh, Jane Mohler, David G Armstrong, Talal K Talal, Bijan Najafi, Nima Toosizadeh, Jane Mohler, David G Armstrong, Talal K Talal, Bijan Najafi

Abstract

Poor balance control and increased fall risk have been reported in people with diabetic peripheral neuropathy (DPN). Traditional body sway measures are unable to describe underlying postural control mechanism. In the current study, we used stabilogram diffusion analysis to examine the mechanism under which balance is altered in DPN patients under local-control (postural muscle control) and central-control (postural control using sensory cueing). DPN patients and healthy age-matched adults over 55 years performed two 15-second Romberg balance trials. Center of gravity sway was measured using a motion tracker system based on wearable inertial sensors, and used to derive body sway and local/central control balance parameters. Eighteen DPN patients (age = 65.4±7.6 years; BMI = 29.3±5.3 kg/m2) and 18 age-matched healthy controls (age = 69.8±2.9; BMI = 27.0±4.1 kg/m2) with no major mobility disorder were recruited. The rate of sway within local-control was significantly higher in the DPN group by 49% (healthy local-controlslope = 1.23±1.06×10-2 cm2/sec, P<0.01), which suggests a compromised local-control balance behavior in DPN patients. Unlike local-control, the rate of sway within central-control was 60% smaller in the DPN group (healthy central-controlslope-Log = 0.39±0.23, P<0.02), which suggests an adaptation mechanism to reduce the overall body sway in DPN patients. Interestingly, significant negative correlations were observed between central-control rate of sway with neuropathy severity (rPearson = 0.65-085, P<0.05) and the history of diabetes (rPearson = 0.58-071, P<0.05). Results suggest that in the lack of sensory feedback cueing, DPN participants were highly unstable compared to controls. However, as soon as they perceived the magnitude of sway using sensory feedback, they chose a high rigid postural control strategy, probably due to high concerns for fall, which may increase the energy cost during extended period of standing; the adaptation mechanism using sensory feedback depends on the level of neuropathy and the history of diabetes.

Conflict of interest statement

Competing Interests: The authors have declared that no competing interests exist.

Figures

Fig 1. Differences in balance parameters among…
Fig 1. Differences in balance parameters among DPN and healthy groups, in eyes-open and eyes-closed conditions.
Local/central control balance parameters with highest effect sizes on average among eyes-open and eyes-closed conditions are illustrated. Significant differences are highlighted with asterisks.
Fig 2. A sample of stabilogram diffusion…
Fig 2. A sample of stabilogram diffusion plot from a healthy control participant.
The figure illustrates two separate regions, which are local-control and central-control regions. Fitted line slopes in each region (local-controlslope and central-controlslope) indicates the rate of change in magnitude of sway as a function of time-interval. The critical point (local-controltime-interval) is the intersection of these two lines.

References

    1. Guariguata L, Whiting D, Hambleton I, Beagley J, Linnenkamp U, Shaw J. Global estimates of diabetes prevalence for 2013 and projections for 2035. Diabetes research and clinical practice. 2014; 103: 137–149. 10.1016/j.diabres.2013.11.002
    1. Wallace C, Reiber GE, LeMaster J, Smith DG, Sullivan K, Hayes S, et al. Incidence of falls, risk factors for falls, and fall-related fractures in individuals with diabetes and a prior foot ulcer. Diabetes Care. 2002; 25: 1983–1986.
    1. Schwartz AV, Hillier TA, Sellmeyer DE, Resnick HE, Gregg E, Ensrud KE, et al. Older women with diabetes have a higher risk of falls A prospective study. Diabetes care. 2002; 25: 1749–1754.
    1. Maki BE, Holliday PJ, Topper AK. A prospective study of postural balance and risk of falling in an ambulatory and independent elderly population. Journal of Gerontology. 1994; 49: M72–M84.
    1. Lajoie Y, Gallagher S. Predicting falls within the elderly community: comparison of postural sway, reaction time, the Berg balance scale and the Activities-specific Balance Confidence (ABC) scale for comparing fallers and non-fallers. Archives of gerontology and geriatrics. 2004; 38: 11–26.
    1. Yamamoto R, Kinoshita T, Momoki T, Arai T, Okamura A, Hirao K, et al. Postural sway and diabetic peripheral neuropathy. Diabetes research and clinical practice. 2001; 52: 213–221.
    1. Horak FB, Dickstein R, Peterka RJ. Diabetic neuropathy and surface sway-referencing disrupt somatosensory information for postural stability in stance. Somatosensory & motor research. 2002; 19: 316–326.
    1. Collins JJ, De Luca CJ. Open-loop and closed-loop control of posture: a random-walk analysis of center-of-pressure trajectories. Experimental brain research. 1993; 95: 308–318.
    1. Newell K, Slobounov S, Slobounova E, Molenaar P. Stochastic processes in postural center-of-pressure profiles. Experimental Brain Research. 1997; 113: 158–164.
    1. Priplata A, Niemi J, Salen M, Harry J, Lipsitz LA, Collins J. Noise-enhanced human balance control. Physical Review Letters. 2002; 89: 238101
    1. Collins J, De Luca C. The effects of visual input on open-loop and closed-loop postural control mechanisms. Experimental Brain Research. 1995; 103: 151–163.
    1. Toosizadeh N, Mohler J, Lei H, Parvaneh S, Sherman S, Najafi B. Motor Performance Assessment in Parkinson’s Disease: Association between Objective In-Clinic, Objective In-Home, and Subjective/Semi-Objective Measures. 2015.
    1. Andersen H, Nielsen S, Mogensen CE, Jakobsen J. Muscle strength in type 2 diabetes. Diabetes. 2004; 53: 1543–1548.
    1. Beardwood D, Schumacher L. Delay of the Achilles reflex in diabetes mellitus. The American journal of the medical sciences. 1964; 247: 324–327.
    1. Gutierrez EM, Helber MD, Dealva D, Ashton-Miller JA, Richardson JK. Mild diabetic neuropathy affects ankle motor function. Clinical Biomechanics. 2001; 16: 522–528.
    1. Van Deursen R, Sanchez MM, Ulbrecht JS, Cavanagh P. The role of muscle spindles in ankle movement perception in human subjects with diabetic neuropathy. Experimental brain research. 1998; 120: 1–8.
    1. Armstrong DG, Lavery LA, Vela SA, Quebedeaux TL, Fleischli JG. Choosing a practical screening instrument to identify patients at risk for diabetic foot ulceration. Archives of internal medicine. 1998; 158: 289–292.
    1. Boulton AJ, Vinik AI, Arezzo JC, Bril V, Feldman EL, Freeman R, et al. Diabetic neuropathies a statement by the American Diabetes Association. Diabetes care. 2005; 28: 956–962.
    1. Boulton AJ, Armstrong DG, Albert SF, Frykberg RG, Hellman R, Kirkman MS, et al. Comprehensive Foot Examination and Risk Assessment A report of the Task Force of the Foot Care Interest Group of the American Diabetes Association, with endorsement by the American Association of Clinical Endocrinologists. Diabetes care. 2008; 31: 1679–1685. 10.2337/dc08-9021
    1. Yardley L, Beyer N, Hauer K, Kempen G, Piot-Ziegler C, Todd C. Development and initial validation of the Falls Efficacy Scale-International (FES-I). Age and ageing. 2005; 34: 614–619.
    1. Najafi B, Horn D, Marclay S, Crews RT, Wu S, Wrobel JS. Assessing postural control and postural control strategy in diabetes patients using innovative and wearable technology. Journal of diabetes science and technology. 2010; 4: 780–791.
    1. Toosizadeh N, Mohler J, Lei H, Parvaneh S, Sherman S, Najafi B. Motor Performance Assessment in Parkinson’s Disease: Association between Objective In-Clinic, Objective In-Home, and Subjective/Semi-Objective Measures. PLoS ONE. 2015; 10: e0124763 10.1371/journal.pone.0124763
    1. Toosizadeh N, Lei H, Schwenk M, Sherman SJ, Sternberg E, Mohler J, et al. Does Integrative Medicine Enhance Balance in Aging Adults Proof of Concept for the Benefit of Electroacupuncture Therapy in Parkinson's Disease. Gerontology. 2015; 61: 3–14. 10.1159/000363442
    1. Collins J, De Luca C, Burrows A, Lipsitz L. Age-related changes in open-loop and closed-loop postural control mechanisms. Experimental Brain Research. 1995; 104: 480–492.
    1. Sayer AA, Dennison EM, Syddall HE, Gilbody HJ, Phillips DI, Cooper C. Type 2 Diabetes, Muscle Strength, and Impaired Physical Function The tip of the iceberg? Diabetes Care. 2005; 28: 2541–2542.
    1. Gaster M, Vach W, Beck-Nielsen H, Schrøder H. GLUT4 expression at the plasma membrane is related to fibre volume in human skeletal muscle fibres. Apmis. 2002; 110: 611–619.
    1. Gatev P, Thomas S, Kepple T, Hallett M. Feedforward ankle strategy of balance during quiet stance in adults. The Journal of physiology. 1999; 514: 915–928.
    1. Vinik AI (2008) Diabetic neuropathies Controversies in Treating Diabetes: Springer; pp. 135–156.
    1. Tesfaye S, Boulton AJ, Dyck PJ, Freeman R, Horowitz M, Kempler P, et al. Diabetic neuropathies: update on definitions, diagnostic criteria, estimation of severity, and treatments. Diabetes care. 2010; 33: 2285–2293. 10.2337/dc10-1303
    1. LeRoith D, Vinik AI (2008) Controversies in Treating Diabetes: Springer.
    1. Nashner LM (1970) Sensory feedback in human posture control: Massachusetts: Institute of Technology.
    1. Zheng C, Zhu Y, Lu F, Xia X, Jin X, Weber R, et al. Diagnostic advantage of S1 foramen-evoked H-reflex for S1 radiculopathy in patients with diabetes mellitus. International Journal of Neuroscience. 2013; 123: 770–775. 10.3109/00207454.2013.801843
    1. Elkholy SH, Hosny HM, Shalaby NM, El-Hadidy RA, El-Rahim NTA, Mohamed MM. Blink Reflex in Type 2 Diabetes Mellitus. Journal of Clinical Neurophysiology. 2014; 31: 552–555. 10.1097/WNP.0000000000000103
    1. Wrobel JS, Edgar S, Cozzetto D, Maskill J, Peterson P, Najafi B. A proof-of-concept study for measuring gait speed, steadiness, and dynamic balance under various footwear conditions outside of the gait laboratory. Journal of the American Podiatric Medical Association. 2010; 100: 242–250.
    1. Mandelbrot BB, Van Ness JW. Fractional Brownian motions, fractional noises and applications. SIAM review. 1968; 10: 422–437.

Source: PubMed

Sponsorzy i współpracownicy

Warunki medyczne

Interwencje lekowe

3
Subskrybuj