Abstracts

Introduction

Brazil has a rapidly aging population, target to significant changes Data from the Brazilian Institute of Geography and Statistics (Instituto Brasileiro de Geografia e Estatística, IBGE) in 2010 has indicated that the Brazilian population over 60 years of age was fastest growing group in the last decade, increasing approximately 8% of the total population (14.5 million people) to approximately 10.8% (20 million). According to statistical projections of the World Health Organization, in the period from 1950 to 2025, the group of older people in Brazil is expected to increase approximately fifteen times, reaching, in 2025, about 32 million people aged 60 and older (Instituto Brasileiro de Geografia e Estatística, 2000, 2010).

According to Kirkwood (2002)Instituto Brasileiro de Geografia e Estatística [IBGE] (2010). Censo demográfico: Brasil. Access: 22/02/2012. Retrieved from http://www.ibge.gov.br/censo/
Retrieved from http://www.ibge.gov.br/ce... , aging is a process that begins at conception and continues throughout the lifespan. Aging causes physiological changes with various effects. Many of the physiological changes attributed to aging occur in a progressive manner and compromise independence and functional status of older individuals, leading, for example, to decreased strength and proprioception, (Alfieri & Moraes, 2008Alfieri, F. M.& Moraes, M. C. L. (2008). Envelhecimento e o controle postural. Saúde Coletiva, 4(19), 30-33. Retrieved from http://redalyc.uaemex.mx/pdf/842/84201907.pdf.
Retrieved from http://redalyc.uaemex.mx/... ), deficits of sensory systems (Nardone & Schieppati, 2010Nardone, A.& Schieppati, M. (2010). The role of instrumental assessment of balance in clinical decision making. European Journal of Physical and Rehabilitation Medicine, 46(2), 221-237.; Ricci, Gazzola, & Coimbra, 2009Ricci, N. A.; Gazzola, J. M., & Coimbra, I. B. (2009). Sistemas sensoriais no equilíbrio corporal de idosos. Arquivo Brasileiro de Ciências da Saúde, 34(2), 94-100. Retrieved from http://www.nepas.org.br/abcs/v34n2/34abcs094.pdf.
Retrieved from http://www.nepas.org.br/a... ) and changes in gait and balance (Abreu & Caldas, 2008Abreu, S. S. E.& Caldas, C. P. (2008). Velocidade de marcha, equilíbrio e idade: Um estudo correlacional entre idosas praticantes e idosas não praticantes de um programa de exercícios terapêuticos. Revista Brasileira de Fisioterapia, 12(4), 324-330. Retrieved from http://www.scielo.br/pdf/rbfis/v12n4/a12v12n4.pdf.
Retrieved from http://www.scielo.br/pdf/... ).

Among the most prominent physiological changes caused by aging is the decreased balance and its important functional limitations (Nascimento, Patrizzi, & Oliveira, 2012Nascimento, L. C. G.; Patrizzi, L. J., & Oliveira, C. C. E. S. (2012). Efeito de quatro semanas de treinamento proprioceptivo no equilíbrio postural de idosos. Fisioterapia e Movimento, 25(2), 325-331. doi: 10.1590/S0103-51502012000200010.
https://doi.org/10.1590/S0103-5150201200... ). Freitas Junior and Barela (2006)Freitas Jr, P. B. (2003). Características comportamentais do controle postural de jovens, adultos e idosos (Dissertação de Mestrado em Ciências da Motricidade, Universidade Estadual Paulista, Rio Claro). Retrieved from http://www.rc.unesp.br/ib/efisica/lem/pdf/dissertacao_paulo.pdf
Retrieved from http://www.rc.unesp.br/ib... observed that deficit of balance is one of the main cause of high rate of falls among older individuals, mainly due to the decreased ability of sensory (visual, somatosensory and vestibular) and motor systems to keep the body oriented.

The maintenance of stability is a dynamic process that involves adjustments between stabilization and destabilization forces. Here, the control strategies are dependent on interactions between the individual, the task at hand, and the environment. Such strategies are triggered by accurate and specific sensory input, and are influenced by the integrity of motor process (Duarte & Zatsiorsky, 2002Duarte, M.& Zatsiorsky, V. M. (2002). Effects of body lean and visual information on the equilibrium maintenance during stance. Experimental Brain Research, 146, 60-69. doi: 10.1007/s00221-002-1154-1.
https://doi.org/10.1007/s00221-002-1154-... ). Posture and balance involve, both, the ability to recover from instability, and the ability to anticipate and move in order to avoid instability (Leonardi, Lopes, Bezerra, & Borges, 2009Leonardi, M. M. (2009). Impacto do desequilíbrio estático e dinâmico no risco de quedas em indivíduos com ataxia espinocerebelar. Revista de Neurociências, 17(2), 178-182. Retrieved from http://www.revistaneurociencias.com.br/edicoes/2009/RN%2017%2002/16.pdf.
Retrieved from http://www.revistaneuroci... ).

Several studies have examined the effects of institutionalization (Aikawa, Braccialli, & Padula, 2006Aikawa, A. C., Braccialli, L. M. P., & Padula, R. S. (2006). Efeitos das alterações posturais e de equilíbrio estático nas quedas de idosos institucionalizados. Revista de Ciências Médicas, 15(3), 189-196. Retrieved from http://www.puc-campinas.edu.br/periodicocientifico/
Retrieved from http://www.puc-campinas.e... ; Alves & Scheicher, 2011Alves, N. B.& Scheicher, M. E. (2011). Equilíbrio postural e risco para queda em idosos da cidade de Garça, SP. Revista Brasileira de Geriatria e Gerontologia, 14(4), 763-768. Retrieved from http://revista.unati.uerj.br/pdf/rbgg/v14n4/v14n4a15.pdf
Retrieved from http://revista.unati.uerj... ), disease (Gazzola, Perracini, Ganança, & Ganança, 2006), and regular physical activity (Bruni, Granado, & Prado, 2008Bruni, B. M.; Granado, F. B., & Prado, R. A. (2008). Avaliação do equilíbrio postural em idosos praticantes de hidroterapia em grupo. O Mundo da Saúde, 32(1), 56-63. Retrieved from http://www.saocamilo-sp.br/pdf/mundo_saude/58/56a63.pdf.
Retrieved from http://www.saocamilo-sp.b... ) on static balance in older individuals. However, few studies have reported how aging affects stability over time in this age group.

Some recent studies have shown the effects of strength and multisensory training under different conditions of support and visual restrictions (Alfieri et al., 2010; 2012), and the impact of standing on one foot - regardless dominance of members - (Gil et al., 2011Gil, A. W. O., Oliveira, M. R., Coelho, V. A., Carvalho, C. E., Teixeira, D. C., & Silva, R. A. (2011). Relationship between force platform and two functional tests for measuring balance in the elderly. Revista Brasileira de Fisioterapia, 15(6), 429-435. doi: 10.1590/s1413-35552011005000024.
https://doi.org/10.1590/s1413-3555201100... ; Maciel & Guerra, 2005Maciel, A. C. C.& Guerra, R. O. (2005). Prevalência e fatores associados ao déficit de equilíbrio em idosos. Revista Brasileira de Ciência e Movimento, 13(1), 37-44. Retrieved from http://portalrevistas.ucb.br/index.php/RBCM/article/view/610/622.
Retrieved from http://portalrevistas.ucb... ) on the displacement of the center of pressure. However, the literature is sparse in analyzing balance in response to sensory factors such as different types of support and types of visual restriction in different age groups.

Studying the effects of sensory stimuli associated with three age groups is important because it attempts to identify stimuli that are more related to balance changes as age advances. From this perspective, the aim of this study was to compare static postural balance of healthy individuals of the three age groups in different conditions of support and vision.

Methods

Study design and sample

This work consisted in a cross-sectional and descriptive study conducted at the Laboratory of Biological Signal Processing in the Core Studies of Human Movement at Federal University of Paraíba (CSHM/UFPB).

The study was approved by the Research Ethics Committee Lauro Wanderley University Hospital (CEP/HULW/UFPB), under the protocol number 009/2009. Individuals were informed about the study's purpose, and signed a consent form, agreeing to participate in the study, according to the Brazilian National Health Council (NHC), Resolution 196/96.

The sample was selected by convenience, meeting the following inclusion criteria: age between 20 and 80 years old, and based on a physiotherapy evaluation form, no disorders that would compromised static balance were identified, such as: chronic vestibular syndrome, labyrinthitis, vertigo and/or neurological, cognitive and/or orthopedic impairments.

The study included 71 volunteers, male and female, divided into 3 groups (Figure 1) according to age: 1 - the youth group (YG = 25 individuals: 14 men and 11 women, 22.2±2.1), ages between 20 and 40 years; 2 - the middle-aged group (MAG = 23 individuals: 10 men and 13 women; 50.7±5.7 years), ages between 41 and 60, and 3 - the group of older individuals (EG = 23 individuals: 9 men and 14 women, 66.7±5.4 years), ages over 60 years, who regularly participated in an exercise program that includes, for example, water gymnastics, lasting 1 hour twice a week.

The sample size was estimated by means of a pilot study that determined the necessary number of participants for each group (www.lee.dante.br). The criterion was to meet a difference of 1.3 cm of anterior-posterior postural displacement (APD). A total of 21 individuals would be needed for each group, considering a significance level of 5%, power of test of 80%, and a standard deviation of 1.5 cm. To prevent possible dropouts, we added at least two subjects in each group, resulting in a total sample of 71 subjects.

Equipment

Anthropometric data (weight and height) was collected using analog scale, 100g accuracy and coupled with a stadiometer (Filizola, Brazil). Static postural balance was assessed in the anterior-posterior and mediolateral directions using a force platform (EMG System, Brazil), with a sampling frequency of 100 Hz.

Procedures

Initially, individuals' anthropometric data (age, weight and height) were registered barefoot of each group. During data acquisition via stabilometric (postural oscillation), each individual was asked stand on a force platform (EMG System, Brazil) wearing their normal shoes, in a comfortable and aligned position (i.e., with the body mass distributed as best as possible-based on the coordinate lines of the platform-, arms relaxed at their sides), keeping still and silent, gazing an image located one meter away at eye level). After a verbal command (attention, ready, go), individuals were instructed to remain as still as possible during 30 seconds for data collection.

Data collection included: three support conditions (standing on two-feet, DLS); one-foot stance with the dominant leg, DL, and non-dominant leg, NDL, and three visual conditions: full vision, FV (Figure 2A, B and C); partial vision, wearing swimming goggles with 50% visibility, PV; and occluded vision, wearing swimming goggles with 0% visibility, AV (Figure 2D, Eand F). These conditions were randomly presented (Dalal, 2008Dalal, G. E. (2012). Citind randomization.com. [última modificação em 16/07/2008] Access: 15/03/2012. Retrieved from http://www.radomization.com.
Retrieved from http://www.radomization.c... ).

One minute rest time was given between each condition, and if an individual could not maintain position for 30 seconds on the first try, they were given a second trial and even third trial. Throughout the procedure, a quiet environment was req uired, and a researcher stood beside each individual for their safety. In full vision (FV) condition, some individuals kept their corrective glasses. To prevent possible falls during the assessments of one-foot standing and restricted vision, older individuals wore a parachute vest connected to the ceiling by two metal cables (Figure 2C and F).

The static postural balance records were analyzed using the 400 BIOMEC software (version 2009 - EMG System, Brazil). Fata was processed using MatLab (Component Runtime 7.6) to quantify the total (TD), anteroposterior (AP; axis Y) and mediolateral (ML; X axis) displacement of the center of pressure (CoP) (in centimeters), using a second order Butterworth filter.

Statistical analysis

The statistical procedures (descriptive and inferential) were performed in Statistical Package for Social Sciences (SPSS - 15.0). Normal distribution of the data (Shapiro Wilk's) and homogeneity of variances (Levene's) were confirmed. Then, analysis of variance (ANOVA - three way) was computed for each variable (TD, APD and MLD) considering groups, support and visual conditions. When necessary, Tukey post hoc tests were employed, considering a significance level of 5%.

Results

The anthropometric characteristics of the groups were: YG body mass = 64.90±13.93 kg, height = 1.68±0.10 m, and BMI = 22.89±1.18 kg/m2; MAG body mass = 69.75±10.88 kg, height = 1.62±0.09 m, BMI = 26.58±2.31 kg/m2; EG body mass = 69.58±11.30 kg, height = 1.57±0.10 m, BMI = 28.23±2.85 kg/m2.

The ANOVA three way revealed differences between groups (TD: F=17.45; APD: F=33.21; MLD: F=34.70, p<0.01, respectively), support conditions (TD: F=137.82; APD: F=130.80; MLD: F=112.11, p<0.01, respectively), and visual conditions (TD: F=8.71; APD: F=56.08; MLD: F=39.54, p<0.01, respectively). Interactions between groups and support conditions were detected for the variables TD (F=3.38, p<0.01), APD (F=4.38, p<0.01), and MLD (F=8.11, p<0.01) and for groups X visual conditions for the variables TD (F=4.72, p<0.01), APD (F=2.49, p<0.05), and MLD (F=2.97, p<0.05).

According to Table 1, during the one-foot standing task, Tukey post-hoc tests indicated that, regarding the interactions between group and support conditions, the MAG showed higher TD than YG (DL and NDL: p<0.01) and GE (DL and NDL: p<0.01 and p<0.05, respectively). The MAG and EG showed higher APD than YG during the one-foot standing task, in both legs (DL and NDL: p<0.01). MAG and EG showed higher MLD than YG (p<0.01); and EG showed greater MLD than MAG during the one-foot standing task for both legs (DL and NDL: p<0.05, respectively).

Regarding the interaction between group and visual conditions, MAG showed higher TD than EG (p<0.05) during the visual occlusion condition; and higher TD that YG (p<0.01) and EG (p<0.05) during partial vision condition. During the full visual condition, MAG (p<0.01) and EG (p<0.01) exhibited higher TD than YG.

With respect to APD, MAG and EG showed higher values than YG during the visual occlusion and partial visual conditions (p<0.01); and EG showed higher values than YG during the full vision condition (p<0.05).

As for the MLD, MAG and EG presented higher averages than YG during visual occlusion (p<0.01) and partial visual conditions (p<0.05 and p<0.01, respectively). EG showed higher mean values compared to MAG during partial visual condition (p<0.05), and also EG had higher mean values compared to YG, during the full visual condition (p<0.05).

Discussion

The results of the present study showed that age has a strong influence on static postural balance when associated with manipulations of support and visual conditions. In general, larger body oscillations-represented by the anterior-posterior (AP) and mediolateral (ML) directions-were found for the individuals of middle age and the older individuals.

Barbieri, Gissot and Pérennou (2010)Barbieri, G., Gissot, A. S., & Pérennou, D. (2010). Ageing of the postural vertical. Age (Dordr), 32(1), 51-60. DOI: 10.1007/s11357-009-9112-5.
https://doi.org/10.1007/s11357-009-9112-... reported that the changes related to aging interfere with the ability of individuals internally align their bodies with the vertical direction, therefore, playing an important role in postural decline in healthy elderly. However, in the present study, during the one-foot stance, individuals of the MAG group showed higher TD than individuals of the EG group, and the individuals of the YG group. Possibly, for the individuals of the EG, these differences were the result of effects of practice in regular physical exercises (Lojudice, 2008Lojudice, D. C.; Laprega, M. R., & Vidal, P. (2008). Equilíbrio e marcha de idosos residentes em instituições asilares do município de Catanduva, SP. Revista Brasileira de Geriatria e Gerontologia, 11(2), 181-189. Retrieved from http://revista.unati.uerj.br/scielo.php?script=sci_arttext&pid=S1809-98232008000200005&lng=pt&nrm=iso&tlng=pt.
Retrieved from http://revista.unati.uerj... ), therefore, improving postural stability and reducing the risk for falls (Nardone & Schieppati, 2010Nardone, A.& Schieppati, M. (2010). The role of instrumental assessment of balance in clinical decision making. European Journal of Physical and Rehabilitation Medicine, 46(2), 221-237.; Pimentel & Scheicher, 2009Pimentel, R. M., & Scheicher, M. E. (2009). Comparação do risco de queda em idosos sedentários e ativos por meio da escala de equilíbrio de Berg. Fisioterapia e Pesquisa, 16(1), 6-10. Retrived from http://www.revistasusp.sibi.usp.br/pdf/fpusp/v16n1/02.pdf.
Retrived from http://www.revistasusp.sib... ).

In contrast, analysis of the AP and ML directions showed that MAG and EG exhibit higher displacements during one-foot stance than individuals in the YG group, and EG showed greater displacement than MAG in the ML direction. These results corroborate results by Barbieri et al. (2010) and have great clinical relevance. Older individuals often are unable to move from the two-feet to one-foot stance during walking due to difficulties in controlling the lateral movement of their bodies (Rogers & Mille, 2003Rogers, M. W.& Mille, M-L. (2003). Lateral stability and falls in older people. Exercise and Sport Sciences Reviews, 31(4), 182-187. Retrieved from http://www.laps.univ-mrs.fr/IMG/pdf/Rogers_Mille_ESSR_2003.pdf.
Retrieved from http://www.laps.univ-mrs.... ).

Despite the differences in postural control between one-foot stance and two-feet stance, in this study no differences were observed between dominant and non-dominant legs, which corroborates with several other studies conducted with both young and older individuals (Alonso, Brech, Bourquin, & Greve 2011Alonso, A. C., Brech, G. C., Bourquin, A. M., & Greve, J. M. D. (2011). The influence of lower-limb dominance on postural balance. São Paulo Medical Journal, 129(6), 410-413. Retrieved from http://www.scielo.br/pdf/spmj/v129n6/v129n6a07.pdf.
Retrieved from http://www.scielo.br/pdf/... ; Alonso, Bronzatto Filho, Brech, & Moscoli, 2008Alonso, A. C., Bronzatto Filho, E., Brech, G. C., & Moscoli, F. (2008). Estudo comparativo do equilíbrio postural entre atletas de judô e indivíduos sedentários. Brazilian Journal of Biomechanics, 9 (17), 130-137. Retrieved from http://citrus.uspnet.usp.br/biomecan/ojs/index.php/rbb/article/view/84
Retrieved from http://citrus.uspnet.usp.... ; Tookuni et al., 2005Tookuni, K. S., Bollinger Neto, R., Pereira. C. A. M., Souza, D. R., Greve, J. M. A., & Ayala, A. A. (2005). Análise comparativa do controle postural de indivíduos com e sem lesão do ligamento cruzado anterior do joelho. Acta Ortopédica Brasileira, 13(3), 115-119. Retrieved from http://www.scielo.br/pdf/aob/v13n3/en_25670.pdf.
Retrieved from http://www.scielo.br/pdf/... ).

When we investigated the role of vision, MAG and EG showed higher TD than YG during FV condition. However, MAG showed greater TD than EG during the AV condition, and greater TD than YG and EG during the PV condition. The efficiency of the visual system is an essential factor for body balance (Freitas Júnior, 2003; Sihvonen, Sipilä, & Era 2004Sihvonen, S. E., Sipilä, S., & Era, P. A. (2004). Changes in Postural Balance in Frail Elderly Women during a 4-Week Visual Feedback Training: A Randomized Controlled Trial. Gerontology, 50(2), 87-95. doi: 10.1159/000075559.
https://doi.org/10.1159/000075559... ), and consequently, low visual acuity (Macedo, Pereira, Gomes, Silva, & Castro, 2008Macedo, B. G., Pereira, L. S. M., Gomes, P. F., Silva, J. P., & Castro, A. N. V. (2008). Impacto das alterações visuais nas quedas, desempenho funcional, controle postural e no equilíbrio dos idosos: Uma revisão de literatura. Revista Brasileira de Geriatria e Gerontologia, 11(3), 419-432. Retrieved from http://revista.unati.uerj.br/scielo.php?script=sci_arttext&pid=S1809-98232008000300010&lng=pt&nrm=iso&tlng=pt.
Retrieved from http://revista.unati.uerj... ) or absence of vision, even if momentary, generates instability (Costa, Goroso, & Lopes, 2009Costa, R. M. C. L.; Goroso, D. G., & Lopes, J. A. F. (2009). Estabilidade postural de adultos jovens na privação momentânea da visão. Revista Acta Fisiátrica, 16(1), 19-24. Retrevied from: http://www.actafisiatrica.org.br/default.asp?ed=22.
Retrevied from: http://www.actafisiatric... ), which in this study was more evident for the MAG. This can also be related to differences between the levels of physical condition among the groups.

To Bugnariu and Fung (2007)Bugnariu, N.& Fung, J. (2007). Aging and selective sensorimotor strategies in the regulation of upright balance. Journal of NeuroEngineering and Rehabilitation, 4(19): 1-7. doi:10.1186/1743-0003-4-19.
https://doi.org/10.1186/1743-0003-4-19... , who compared sensorimotor strategies during regulation of upright balance of the young and older healthy adults, aging affects the interaction of the somatosensory and visual systems affecting the ability of the central nervous system (CNS) to maintain upright stance equilibrium. Therefore, older adults tend to show greater AP and ML CoP displacements when compared to young adults.

Kitabayashi, Demura, Kawabata, Uchiyama and Demura (2011)Kitabayashi, T., Demura, S-I., Kawabata, H., Uchiyama, M., & Demura, T. (2011). Comparison of the body-sway characteristics of young adults compared to healthy elderly and elderly with equilibrium disorder. Perceptual and Motor Skills, 113(2), 547-556. doi: 10.2466/10.15.26.PMS.113.5.547-556.
https://doi.org/10.2466/10.15.26.PMS.113... also found through stabilometry, greater sway in the AP and ML direction of healthy older individuals (n = 342) compared to young ones (n = 380).

According to Freitas Júnior and Barela (2006), there is a consensus on the decrease of postural control in the elderly, indicating that they sway more than young adults, during both, eyes open and eyes closed conditions.

Our results corroborate others studies (Brooke-Wavell, Perrett, Howarth, & Haslam, 2002Brooke-Wavell, K., Perrett, L. K., Howarth, P. A., & Haslam, R. A. (2002). Influence of the visual environment on the postural stability in healthy older women. Gerontology, 48(5), 293-297. doi:10.1159/000065252.
https://doi.org/10.1159/000065252.... ; Cruz, Oliveira & Melo, 2010) that analyzed the CoP displacement in the AP and ML directions, and that observed that the visual feedback is an important contribution to replace reduced somatosensory and vestibular sensory input in older individuals, especially during one-foot stance tasks (Deyer & Ashton-Miller, 1999Deyer, T. W.& Ashton-Miller, J. A. (1999). Unipedal balance in healthy adults: effect of visual environments yielding decreased lateral velocity feedback. Archives of Physical Medicine Rehabilitation, 80(9), 1072-1077. doi: 10.1016/s0003-9993(99)90063-1.
https://doi.org/10.1016/s0003-9993(99)90... ). In addition, for Soares (2010)Soares, A. V. (2010). A contribuição visual para o controle postural. Revista de Neurociências, 18(3), 370-379. Retrieved from http://www.revistaneurociencias.com.br/edicoes/2010/RN1803/415%20revisao.pdf.
Retrieved from http://www.revistaneuroci... , the importance of vision increases gradually with the advancing of age, becoming a key factor for the stability of older people. He noted that, for adults with ages 20 to 60 years, the stability decreases 30% when eyes are closed and reaches 50% for individuals over 60 years.

The fact that individuals in the EG were practicing regular physical activity may somehow have influenced the results of TD. YG and MAG performed only activities of daily living (ADLs), and most studies with older people in the literature include institutionalized (Medeiros et al., 2012Medeiros, P. A., Heinz, C., Filippin, L. I., Vendrusculo, A. P., Virtuoso, J. F., Streit, I. A..& Mazo, G. Z. (2012). Estudo correlacional entre parâmetros de avaliação da marcha e equilíbrio em idosas institucionalizadas. Revista ConScientiae Saúde, 11(3), 470-476. doi: 10.5585/ConsSaude.v11n3.3436.
https://doi.org/10.5585/ConsSaude.v11n3.... ) or community residents (Freitas Júnior, 2003), but not engaged in regular physical activity. Furthermore, the use of the parachute vest safety system by the EG group could have an effect on results by adding information that helped stabilization of the body.

Conclusion

The results showed that, for all three age groups, static postural balance in healthy individuals decreased over time, and conditions of support and vision can negatively affect groups of older age.

We thank the participants and collaborators in this research, and CNPq for financial support (Edital Universal 2008). This study was presented at the 2nd Brazilian Congress of Electromyography and Kinesiology (II Cobec) at Piracicaba, State of São Paulo in 2012.

References

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