Dinamic balance, lifestyle and emotional states in young adults

Cruz, Ivana Beatrice Manica da; Barreto, Daniele Coronel Mena; Fronza, Andressa Boer; Jung, Ivo Emilio da Cruz; Krewer, Cristina Costa; Rocha, Maria Izabel de Ugalde Marques da; Silveira, Aron Ferreira da

doi:10.1590/S1808-86942010000300020

Abstracts

A one hypothesis to explain some vestibular peripheral disorders is their association with life style. Thus, studies with young adults are relevant. AIM: to analyze the prevalence of dynamic balance alterations in young adults and their possible association with life style variables, health and negative emotional states (since they can impact the outcome). MATERIALS AND METHODS: we carried out a non-probabilistic cross-sectional, clinical-retrospective study with young adults (18-32 years of age) from a university with 751 individuals, with a mean age of 22.45± 3.32 years. Life style, health and negative emotional states (NES) variables - depression, stress and anxiety, were collected by means of an interview. The Unterberger test was used in order to check for indications of dynamic balance alterations. Individuals with altered dynamic balance (ADB) were compared to those without these alterations (controls). RESULTS: From our sample, 642 (83.6%) had less than 45º of deviation, while 109 (14.2%) had greater than 45º deviation and were the considered with ADB. The ADB group had a greater prevalence of smoking, alcohol abuse/dependence, high blood pressure and NES. CONCLUSION: the study highlights the occurrence of ADB which needs to be corroborated in future studies

anxiety; smoking; musculoskeletal equilibrium; life style; depression

Uma hipótese para explicar algumas desordens periféricas vestibulares seria sua correlação com variáveis do estilo de vida. Assim, a realização de estudos populacionais sobre o tema em adultos jovens é relevante. OBJETIVOS: Analisar a prevalência de indicação de alterações no equilíbrio dinâmico em adultos jovens e sua possível associação com variáveis do estilo de vida, saúde e estados emocionais negativos (pois podem intervir nos resultados). MATERIAL E MÉTODO: Foi realizado um estudo epidemiológico transversal, não-probabilístico, retrospectivo-clínico, em adultos jovens (18-32 anos) de uma comunidade universitária com 751 indivíduos, com média de 22.45± 3.32 anos. Variáveis do estilo de vida, saúde e estados emocionais negativos (EEN), que são depressão, ansiedade e estresse, foram coletadas via entrevista. Teste de Unterberger foi aplicado para averiguar indicação de alteração no equilíbrio dinâmico. Indivíduos com equilíbrio dinâmico alterado (EDA) foram então comparados com os sem alteração (controle). RESULTADOS: Da amostra 642 (83.6%) desviaram menos que 45º enquanto que 109 (14.2%) apresentaram um desvio maior que 45º sendo então considerados o grupo EDA. O grupo EDA apresentou maior prevalência de tabagismo, abuso/dependência de álcool, hipertensão arterial sistêmica e de EEN. CONCLUSÃO: O estudo destaca a ocorrência de EDA que precisa ser comprovado em estudos futuros

ansiedade; depressão; equilíbrio músculo-esquelético; estilo de vida; tabagismo

ORIGINAL ARTICLE

Dinamic balance, lifestyle and emotional states in young adults

Ivana Beatrice Manica da Cruz^I; Daniele Coronel Mena Barreto^II; Andressa Boer Fronza^II; Ivo Emilio da Cruz Jung^III; Cristina Costa Krewer^IV; Maria Izabel de Ugalde Marques da Rocha^V; Aron Ferreira da Silveira^VI

^IPhD. Post-Doctorate. Adjunct Professor. Federal University of Santa Maria (UFSM) - Morphology Department - Health Sciences Center

^IISpeech and Hearing Therapist. MSc student - Graduate Program in Human Communication Disorders. Federal University of Santa Maria (UFSM) - Morphology Department - Health Sciences Center

^IIIPsychology Student, Scientific Initiation. Federal University of Santa Maria (UFSM) - Morphology Department - Health Sciences Center

^IVMSc. Assistant Professor. Federal University of Santa Maria (UFSM) - Morphology Department - Health Sciences Center

^VPhD, Adjunct Professor. Federal University of Santa Maria (UFSM) - Morphology Department - Health Sciences Center

^VIPhD, Adjunct Professor - Advisor at the Graduate Program in Human Communication Disorders. Federal University of Santa Maria (UFSM) - Morphology Department - Health Sciences Center

Correspondence to

ABSTRACT

A one hypothesis to explain some vestibular peripheral disorders is their association with life style. Thus, studies with young adults are relevant.

AIM: to analyze the prevalence of dynamic balance alterations in young adults and their possible association with life style variables, health and negative emotional states (since they can impact the outcome).

MATERIALS AND METHODS: we carried out a non-probabilistic cross-sectional, clinical-retrospective study with young adults (18-32 years of age) from a university with 751 individuals, with a mean age of 22.45± 3.32 years. Life style, health and negative emotional states (NES) variables - depression, stress and anxiety, were collected by means of an interview. The Unterberger test was used in order to check for indications of dynamic balance alterations. Individuals with altered dynamic balance (ADB) were compared to those without these alterations (controls).

RESULTS: From our sample, 642 (83.6%) had less than 45º of deviation, while 109 (14.2%) had greater than 45º deviation and were the considered with ADB. The ADB group had a greater prevalence of smoking, alcohol abuse/dependence, high blood pressure and NES.

CONCLUSION: the study highlights the occurrence of ADB which needs to be corroborated in future studies.

Keywords: anxiety, smoking, musculoskeletal equilibrium, life style, depression.

INTRODUCTION

Walking is a common movement performed by human beings and it is controlled by the nervous system which regulates the temporal-space association between the position and the movement maintaining body ballance¹. The signs and symptoms of body balance change can crop up when there is a conflict in the integration of vestibular information, appearing upon rotational dizziness (vertigo) and/or the non-rotational². The physical decline associated with this movement seems to be associated with aging and to non-transmissible chronic diseases^3-5. In this case, changes associated with aging of the psychomotor, sensorimotor and neuromuscular systems cause the appearance of postural balance problems, thus increasing the risk of falls. In Group B, the patients had sensorineural hearing loss in mild to moderate levels, unilaterally in six ^6,7.

The capacity a person has to close the eyes and walk without moving, depends on a normal vestibulo-spinal and proprioceptive functions. With aging, such capacity also suffers changes such as the presence of vestibular dysfunctions as Ménière's disease, central vestibular lesions, multiple sclerosis, etc. Nonetheless, vestibular dysfunctions may also have a vascular lesion associated to the vertebrobasilar system, which is responsible for the cochleovestibular blood irrigation⁸.

Recently, a hypothesis to explain peripheral vestibular disorder of vascular origin would be its correlation with morbidities associated to lifestyle and atherosclerosis. Some authors⁹ consider this hypothesis in their study, using carotid ultrasonography in order to assess the diameter of the intima layer of these vessels and biochemical markers in 85 patients complaining of dizziness. Results describe that there is a positive correlation between peripheral vestibular disorders and vascular changes associated to atherosclerosis. An epidemiological study from the National Health and Nutrition Examination Survey which included 1,685 individuals with age equal to or higher than 50 years, observed a gait problem in women with low levels of HDL-cholesterol and a greater frequency of abdominal obesity¹⁰. Other studies also describe an association between gait disorders and abdominal obesity^11,12.

Nonetheless, epidemiological studies, especially in young adults who have still not accumulated a large number of dysfunctions and morbidities are insipient and would be relevant to analyze how much vascular change - as is the case of cardiovascular risk factors - could influence body balance.

Within the main factors associated to vascular changes which could affect the vestibular system we have: smoking, systemic hypertension, obesity - for its association with atherosclerotic, inflammatory changes and diabetes mellitus^13,14.

Given the relevance of the topic and the low quality of studies associating balance changes and (cardio) vascular risks, we led a cross-sectional populational study in young adults in whom we noticed the prevalence of individuals with dynamic balance disorders using the Unterberger test and the following risk factors: smoking, overweight/obesity, a past of hypertension and diabetes mellitus. Since there may be changes in dynamic balance associated to emotional states, we also investigated if individuals with indication of dynamic balance changes could have a greater prevalence of self-reported negative emotional states (NES) (anxiety, stress and depression).

MATERIALS AND METHODS

Outlining, population and sample

We did a cross-sectional epidemiological study in young adults who were previously selected for studies on environmental-genetic factors associated with smoking and other cardiovascular risks. Our study sample was made up of a university community. The sample selection was non-probabilistic, done from a complementary undergraduate course aimed at epidemiological investigations of aging, which included 122 undergraduate students from courses in the fields of health and biology. These students were trained as research assistants as to methodological, ethical, structured interview deployment and Unterberger balance test aspects. Each student invited, read and collected the patient's signature in the informed consent form (TCLE) and collected information from 10 volunteers (05 men and 05 women) with ages between 18 and 32 years. Once the information was collected, they were plotted by the research assistant. Afterwards, data truthfulness was checked as well as information collection quality and data typing in an Excel spreadsheet by a team of undergraduates and graduate students (masters and doctorates) who participated in the study. The calculation of sample size estimated the inclusion of a minimum number of 600 and a maximum of 1200 individuals. A total of 1,024 individuals with mean ages of 22.45± 3.32 (18 to 32 years) were included in the study. From these, we selected 751 individuals for this study for presenting similar cultural and socio-economic characteristics. The project which this study was part of was previously approved by the Ethics in Research Committee of this Institution, under process # 23081.012293/2007-03. All the volunteers signed the TCLE and the study was led within the standards of resolution 196/1996 from the National Council of Ethics in Research (CONEP).

Variables studied

The general data on socio-economic, cultural, lifestyle and health indicators were collected through a structured interview. The average time of questionnaire application was 20-25 minutes. Anthropometric data on weight (Kg) and height (m) was used to calculate the body mass index (BMI, Kg/m2) which later served to classify the individuals as non-obese (BMI < 25 kg/m2), overweight (>25<30 Kg/m2) and obese (>30 kg/m2). The waist line (WL) was measured by the research assistants, previously trained to collect such information. The WL was measured at the navel height15. Because of the lack of universally accepted cutting points for WL, we chose to employ the one used in an investigation about the association between WL and health risks (normal for women; < 88 cm and high: > 88cm; normal for men <102 cm, and high > 102 cm)¹⁶.

Three main lifestyle variables were investigated: smoking, abuse indication and/or alcohol addiction and regular physical activity. Were considered smokers those who reported having smoked at least 100 cigarettes in the past ninety days. The degree of nicotine addiction was also characterized through the Fagerstrom test, which score determines the following addiction categories in points: 0 - 2: very low; 3 - 4: low; 5: mean; 6 - 7: high and 8 - 10: very high)¹⁷. The abuse/addiction concerning alcohol was tested through the CAGE test which is made up of four questions. The affirmative answer for two questions indicated addiction and/or abuse of alcoholic beverages. This score is broadly used by the World Health Organization (WHO)¹⁸.

Regular physical activity was evaluated through two general questions: whether the volunteer had performed some type of regular physical activity at least twice a week in the past six months. To those individuals who reported some kind of regular physical activity we asked about the type of activity. The other question considered whether the individual, in his daily working activities (studying/working) remained seated for most of the time. The mean time spent on these activities was also asked.

Negative emotional states were evaluated by means of three general questions whether in the past six months: "the individual felt sad or depressed without apparent cause for at least three times per week "; "felt anxious without apparent cause, for at least three times per week " and "felt stressed, without apparent cause, for at least three times per week ". We also asked about history of morbidities, especially blood hypertension, diabetes mellitus and dyslipidemias, which are metabolic disorders considered of cardiovascular risk.

In order to assess dynamic balance we used the Unterberger test. We asked our volunteers to walk raising their knees to approximately 45º without actually moving, doing 50 steps (one per second) with their arms extended and eyes closed. We considered altered those individuals who shifted to the right or to the left in 45º or more. All the researchers were instructed to employ this test using a physical therapist or speech and hearing therapist. The test was run in a dark place, with low noise in order to avoid possible interference to the data collected.

In order to do the statistical analysis, we first plotted the data in an Excel spreadsheet and, later, it was transferred and analyzed by the SPSS version 12.0 statistical package. The results obtained were described as mean+standard deviation (SD) or as absolute and relative (%) frequencies according to the type of variable. After estimating the prevalence of individuals with dynamic balance alteration indicated by the test employed (hereby called group with altered dynamic balance, ADB) and the individuals who executed the test within the expected standards (here we called it Control Group) among lifestyle, health and negative emotional status variables, especially those associated with vascular risk. Categorical variables were statistically compared by the Chi-Square or Fisher's exact tests. Continuous variables were compared by the t-student test since these variables have a normal distribution assessed by the Kolmogorov-Smirnof test. The tests in which the significance value was p<0.05 were deemed significant. The multivariate analysis used logistic regression (Backward Wald method) using all the variables associated with dynamic balance change in which the univaried statistical analysis showed a significance value of p<0.1.

RESULTS

Of the 751 young adults who participated in the study, 642 (83.6%) had less than 45º of sideways shifting in the gait test, while 109 (14.2%) had a shifting greater than 45º, then being considered ADB. In this case, 322 (8.9%) from the control group were women and 320 (85.1%) were men. The number of women with gait deviation was 53 (14.15%) and that of men was 56 (14.9%) and there were no statistically significant differences between the genders (c2=0.087, p=0.773). In the studied sample, 49.1% shifted to the right and 42.5% shifted to the left.

The comparison between the general characteristics of these two groups is summarized on Table 1. As we can see both in men and women, the mean age and the anthropometric variables were statistically similar between the control and the ADB groups.

Thumbnail

Fig. 1 shows the comparison of the cardiovascular risk factors distribution between the control and the ADB groups. In the ADB group we noticed a significantly higher participation of smokers when compared to non-smokers (c2=7.766, p=0.005) with an odds ratio of 1.902 (1.204-3.004) times higher chance of smoking individuals having balance disorders (in other words, being included in the ADB) when compared with non-smokers. The nicotine addiction analyses done by the Fargerstron test showed that, in average, 60.8% (n=73) of smokers had low addiction and 39.2% (n=47) had moderate addiction to nicotine. This ratio was statistically similar in the two groups tested.

The indication of alcohol abuse or addiction evaluated between the two groups showed a higher prevalence of such condition in the ADB group (20.2%, n=22) when compared to the control group (11.9%, n=76). (c2=5.687, p=0.017). The odds ratio of an individual with alcohol abuse/addiction indication to have balance disorders was estimated in OR=1.880 (1.112-3.179).

Another lifestyle variable investigated was associated with physical activity. When the individual was asked whether or not he/she had some physical activity 13.0% (n=50) of those in the ADB group reported having participated in regular physical activity at least twice a week in the past six months, while this frequency in the control group was of 15.8% (n=59) - and these differences were not statistically significant. The most frequent types of physical activities were: aerobic activity (31.0%), weight lifting (24.0%) and some kind of sport (20.7%). Among volunteers, 568 (75.8%) reported doing most of their work/study seating down, and such ratio was similar between the Control Group and the ADB Group with a mean value of 6.48±2.86 daily hours spent in these activities. This activity was also similar in the Control and ADB groups, hereby investigated.

A total of 117 (16.3%) patients in the sample were classified as being obese, and there were no statistically significant differences in this distribution between young adults from the Control Group and those from the ADB Group (c2=0.030, p=0.863).

Although this is a sample of young adults, 2.0 % (n=15) already had high blood pressure. In this case, ADB individuals had a rate of 4.6% (n=5) of hypertension, while those in the control group had only 1.6% (n=10). In this case, these differences were statistically significant (c2=4.369, p=0.037). The odds ratio of hypertensive individuals having dynamic balance disorders was: OR=3.038 (1.018-9.068) times higher when compared to those with normal blood pressure.

Only three individuals were diabetic, thus it was not possible to do a consistent statistical analysis. Nonetheless, it is worth mentioning that all of them had more than 45º of shifting and were classified in the ADB Group. A total of 29 (3.9%) individuals reported having dyslipidemias, and such disorder did not have a differentiated distribution between Groups Control and ADB (c2=0.175 p=0.675).

Of the young adults investigated, 10 (1.3%) reported having very bad hearing, 11 (1.5%) had a constant tinnitus in one of the ears and 131 (17.4%) reported having tinnitus in certain situations. In this case, none of these conditions was statistically significant when we compared the two groups - Control and ADB. The visual acuity self-perception was also not associated with the altered dynamic balance, happening to 8.7% (n=67) of the individuals who reported having bad or very bad vision.

The ADB group had a significantly higher rate of all the NES indicators (anxiety, depression and stress) as it can be seen in Fig. 1. The odds ratio of individuals with depression having altered dynamic balance was OR=1.653 (1.020-2.677), while individuals with anxiety had an odds ratio of OR=1.531 (1.011-2.352), and stressed individuals had an odds ratio of OR= 1.548 (0.995-2.408).

The multivariate analysis showed that smoking and the negative emotional states (NES) (especially stress) were associated to the dynamic balance of the young adults who were investigated, regardless of gender, age and alcohol abuse/addiction.

DISCUSSION

The present study evaluated the prevalence of dynamic balance disorders in young adults and its possible association with lifestyle and morbidity variables which are considered cardiovascular risks, in which there was an independent association of smoking and negative emotional states - especially stress.

The results showed a relatively high prevalence of individuals with altered dynamic balance if we consider that here we had a potentially healthy sample. Unfortunately, we did not find a similar populational study which could be used as a reference to compare this prevalence we observed. Despite the few studies in the literature, it is important to mention that the prevalence of individuals with changes in their stationary gait tends to increase very much with aging. According to some authors,19 about 85% of the elderly above 65 years of age complained of postural balance disorders and have, as a consequence, gait shifting, falls and postural instability. Thus, it is considered that such changes arise from organic alterations associated with biological aging. Such changes can be worsening by the presence of chronic non-transmissible diseases such as diabetes mellitus, neurologic diseases, atherosclerosis, depression, and others. In this study involving young adults one can not rule out the fact that the gait disorders seen in the individuals would not be indicators of biological aging of the vestibular system increased by risk factors. Thus, we suggest the need for further epidemiological studies in order to see how much the results obtained come close to the epidemiological reality of the population investigated.

Moreover, we noticed in the sample studied, an almost equal distribution in terms of gait shifting to the right or to the left. The gait deviation without the aid of vision is considered an example of what is called "directional tendency". These are reported when the person tends to shift to one direction. As far as the static gait is concerned, some studies indicate that two-thirds of the individuals who performed this movement without looking tended to shift to the right^20-23. Others did not report a predominant trend²⁴ while other studies reported a trend of gait shifting to the left²⁵. In the present study there was a mild trend towards shifting to the right. These authors²⁵ investigated this issue more in depth and suggested that this trend could be associated with factors such as the presence of asymmetry in the mental space representation, vestibular disorder associated with sensory-motor asymmetries or asymmetries in the dopaminergic system. Despite not being the main scope of the present paper and the limitations inherent to general screening studies, it is important to mention that the asymmetry found confirms prior studies that the static gait without vision input is a directional tendency and that we need further studies in order to better understand its mechanisms²⁵.

The associations seen between dynamic balance changes and smoking, drinking, hypertension and negative emotional states, even considering that epidemiological studies on this topic are extremely insipient, seems to have a consistent biological support.

Considering the result observed between smoking and stationary gait changes we can comment that smoking addiction is considered one of the best predictors of negative longevity for humans for being associated with an increase in the risk of developing non-transmissible chronic disorders such as cardiovascular, pulmonary and neoplastic diseases. The total number of deaths associated with smoking has reached the figure of 4.9 millions annually, corresponding to more than 10 thousand per day. According to the WHO, should its current expansion trends continue, these figures will increase to 10 million annual deaths around the year of 2030, and half of them will happen to individuals in a productive age (between 35 and 69 years)²⁶.

It seems that the negative pleiotropic have an effect on many organs and systems of the body through the presence of a huge number of bioactive substances on which nicotine has a relevant impact. Nicotine, the main active component of tobacco has a high addictive potential, comparable to cocaine and heroin. This substance is quickly absorbed by the central nervous system (CNS). There, it binds to central and peripheral receptors, crossing the blood-brain barrier (nicotinic cholinergic receptors -nAchR) and, thus, increasing the production of neuromediators such as noradrenalin, acetylcholine, serotonin and dopamine²⁷.

Even if in a small number, some studies suggest that nicotine can induce an unbalance in the vestibulo-ocular and vestibulo-spinal reflexes^28,29. Unfortunately, epidemiological investigations on such associations are very insipient.

Another possible nicotine influence is on modulating the peripheral vasoconstriction of the vestibulo-spinal system. A recent study assessed the effect of vascular risk factors, alone or in combination, on the balance of elderly citizens using a posturography platform. Among the vascular risks tested, glucose intolerance was the only risk factor independently associated with unbalance. Nonetheless, the joint presence of many risk factors, including smoking, seems to cause balance disorders. The authors also comment that such effect seems to be subclinical, associated with nervous system problems impairing body balance30. Therefore, there are indications that smokers could have a higher risk of having dynamic balance disorders even when young. However, such hypothesis needs to be confirmed in future studies which assess other elements associated with body balance.

Negative emotional states were the other set of independent variables associated with dynamic balance changes in the sample of young adults here investigated. Specifically speaking, depression is considered a mood state characterized by feelings of sadness, hopelessness and disheartening. Such state can vary from feelings known as negative emotional states all the way to pathological states such as depression major. In the first case, one can say that there is a state of "reactive depression" associated to the stressful situations of daily life. Prior studies about depression have found an overlapping between the psychiatric and neurological activities. One example of this statement comes from a study³¹ in which 134 depressive patients in whom important neurotological alterations were seen, and also many patients who reported signs of vertigo and nausea, usually found in vestibular disorders. Another investigation which assessed the vestibular system integrity upon depression is the study of the vestibulo-ocular reflex. The ocular reflex movement depends on the vestibular nucleus activity and other authors reported that in depressed patients there was an asymmetry in the reflex stimulus in which the activity detected on the left side was approximately half of the activity observed on the right side. The authors also found a hypoactivity of the vestibular nucleus in individuals with depression when compared to controls, specifically on the right side of the nucleus. These results corroborate through neurophysiology the association between these depressive states (especially in the case of depression major) and balance changes through activity asymmetries in the vestibular nucleus³². Here it is interesting to notice that few studies have been done on the static and dynamic balance in young adults and its possible association with negative emotional states or even with the prevalence of neuro-psychiatric disorders.

And finally, it is important to discuss the main limitations of the study hereby described. Investigations on the health indicators or balance changes in large populational samples meddle in the need to apply instruments, which are, in principle, of low cost and easy applicability. One of these tests is commonly used in the clinical evaluation of dynamic balance disorders, which was concocted by Unterberger and later modified by Fukuda³³ employed here in this investigation. This test has been used as an indicator of vestibular disorder even when there is criticism concerning its real specificity and sensitivity in detecting peripheral vestibular asymmetry in patients affected with this disorder³⁴ and the results must be interpreted with caution when the test is used in the diagnosis of these dysfunctions³⁵.

One study which compared 21 asymptomatic volunteers with 38 patients with peripheral vestibular disorder, in which the Unterberger-Fukuda test was applied, using data digital capture and analysis, showed that the lateral movement, the pace of the steps, the shoulder shifting was equal in both groups investigated, however the time taken in each step and the angular deviation was greater in the group of patients when compared to the controls³⁶. Despite the test limitation concerning its sensitivity and specificity to vestibular disorders, such test has been used in populations without disorders with a relative frequency. Additionally, dynamic balance tests, such as the Unterberger, have been associated with advanced technological equipment which allow for a more accurate monitoring and a greater objective interpretation. This is the case in the study²⁵ which quantified the lateral deviation based on the Unterberger-Fukuda test and determined the possible factors which could be potentially associated to these deviations assessing 25 young adults in experimental conditions. Thus, complementary investigations with this technological support could be led with the aim of confirming the associations between dynamic balance, smoking and negative emotional state.

Another limitation of this study is associated with the fact that it is a cross-sectional study and the use of only one test of dynamic balance indication, while usually in the diagnosis of different vestibular disorders numerous tests are applied to the patients. Since this is a small epidemiological initial screening test, such limitation can be corrected in complementary studies about the health of the vestibular-spinal system, especially concerning body balance.

CONCLUSION

Regardless of methodological limitations, the study hereby reported stresses the occurrence of dynamic balance changes in apparently healthy young adults in the population and that of smoking and negative emotional states as independent risk factors. Such results may be proven through future clinical-epidemiological investigations.

REFERENCES

1. Maki BE, Mellroy WE. The role of limb movements in maintaining upright stance: 'change-in-support' strategy. Phys Ther. 1997;77:488-507.
2. Kós AOA, Tomita S, Torraca TSS, Decoster, DMH, Vidaurre AS. Estudos em Otoneurologia. Rio de Janeiro: RBO; 1986 (Consenso).
3. Nevitt MC, Cummings SR, Kidd S, Black D. Risk of factors for recurrent non-syncopal falls. JAMA. 1989;261:2663-8.
4. Lord SR, Lloyd DG, Li SK. Sensorimotor function, gait patterns and falls in community-dwelling women. Age Ageing. 1996;25:292-9.
5. Salem DB, Walker PM, Aho S, Tavernier B, Giroud M, Tzourio C et al. Brain flexibility and balance and gait performances mark morphological and metabolic abnormalities in the elderly. J Clin Neurosci. 2008;15:1360-5.
6. Rogers MW, Wardman DL, Lord SR, Fitzpatrick RC. Passive tactile sensory imput improves stability during standing; Exp Brain Res. 2001;136:514-22.
7. Rogers MW, Hedman LD, Johnson ME, Martinez KM, Mille ML. Triggering of protective stepping for the control of human balance: age and contextual dependence. Cognitive Brain Res. 2003; 16:192-8.
8. Szirmai A, Küstel M, Pánczél G, Kocher I, Répássy G, Nagy Z. Evidences of vascular irigin of cochleovestibular dysfunction. Acta Neurol Scand. 2001;104:68-71.
9. Wada M, Naganuma H, Tokumasu K, Hashimoto S, Ito A, Okamoto M. Arteriosclerotic changes as background factors in patients with peripheral vestibular disorders. Int Tinnitus J. 2008;14(2):131-4.
10. Okoro CA, Zhong Y, Ford ES, Balluz LS, Strine TW, Mokdad AH. Association between the metabolic syndrome and its components and gait speed among U.S. adults aged 50 years and older: a cross-sectional analysis. BMC Public Health. 2006;6:282.
11. Ostir GV, Volpato S, Fried LP, Chaves P, Guralnik JM. Reliability and sensitivity to change assessed for a summary measure of lower body function: results from the women's Health and aging study. J Clin Epidemiol. 2002;55(9):916-21.
12. Bootsma-van der Wiel A, Gussekloo J, De Craen AJ, Van Exel E, Bloem BR, Westendorp RG. Common chronic diseases and general impairments as determinants of walking disibality in the oldest-old population. J Am Geriatr Soc. 2002;50:1405-10.
13. Stehouwer CD, Clement D, Davidson C, Diehm C, Elte JW, Lambert M et al. Peripheral arterial disease: a growing problem for the internist. Eur J Intern Med. 2009;20(2):132-8.
14. Grover-Páez F, Zavalza-Gómez AB. Endothelial dysfunction and cardiovascular risk factors. Diabetes Res Clin Pract. 2009;84(1):1-10.
15. Lohman TG, Roche AF, Martorell R. Anthropometric standardization reference manual. Champaign: Human Kinetics Book; 1998.
16. Janssen I, Katzmarzyk PT, Ross R. Waist circumference and not body mass index explains obesity-related health risk. Am J Clin Nutr. 2004;79:379-84.
17. Fagerstrom KO, Schneider NG. Measuring nicotine dependence: a review of the Fagerstrom Tolerance Questionnaire. J Behav Med. 1989;12:159-82.
18. Bush B, Shaw S, Clary P, Delbanco TL, Aronso MD. Screening for alcohol abuse using the CAGE Questinnaire. Am J Med .1987;82(2):231-5.
19. Simonceli L, Bittar RMS, Bottino MA. Perfil diagnóstico do idoso portador de desequilíbrio corporal: resultados preliminares. Rev Bras Otorrinolaringol. 2003;69(6):772-7.
20. Peitersen E. Vestibulospinal reflexes. X. Theoretical and clinical aspects of the stepping test. Arch Otolaryngol. 1967;85:192-8.
21. Porac C, Coren S. Lateral Preferences and Human Behavior. New York: Springe Verlag; 1981.
22. Previc FH, Saucedo JC. The relationship between turning behavior and motoric dominance in humans. Percept Mot Skills. 1992;75:935-44.
23. Reiss M, Reiss G. Further aspects of the asymmetry of the stepping test. Percept Mot Skills. 1997;85:1344-6.
24. Fukuda T. The stepping test: to phases of the labyrinthine reflex. Acta Otolaryngol. 1959;50:95-108.
25. Weiler SW, Foeh Kp, van Mark A, Touissant R, Sonntag N, Gaessler A et al. Outpatient rehabilitation of workers with musculoskeletal disorders using structured workplace description. Int Arch Occup Environ Health. 2009;82(4):427-34.
²⁶
World Health Organization [Site na Internet]. Disponível em http:www.whor.org Acessado em 2 de agosto de 2009.
» link
27. Yanbaeva DG, Dentener MA, Creutzberg EC, Wesseling G, Wouters EF. Systemic effects of smoking. Chest. 2007;131(5):1557-66.
28. Pereira CB, Strupp M, Eggert T, Straube A, Brandt T. Nicotine-induced nystagmus: three-dimensional analysis and dependence on head position. Neurology. 2000;55(10):1563-6.
29. Pereira CB, Strupp M, Holzleitner T, Brandt T. Smoking and balance: correlation of nicotine-induced nystagmus and postural body sway. Neuroreport. 2001;12(6):1223-6.
30. Di Iorio A, Abate M, Pini B, Di Nicola I, Marinelli M, Guglielmi M et al. Effects of vascular risk factors on balance assessed by computerized posturography in the elderly. Aging Clin Exp Res. 2009;21(2):136-42.
31. Nagy E, Claussen CF, Bencze G, Heid L, Bencsik B, Kersebaum M. Depressive disorders in relation to neurootological complaints. Int Tinnitus J. 2004;10(1):58-64.
32. Soza Ried AM, Aviles M. Asymmetries of vestibular dysfunction in major depression. Neuroscience. 2007;144(1):128-34.
33. Menon AD, Sakano E, Weckx LL. Consenso sobre vertigem. Rev Bras Otorrinolaringol. 2000; 6(66 Supp 11):9-35.
34. Honaker JA, Boismier TE, Shepard NP, Shepard NT. Fukuda stepping test: sensitivity and specificity. J Am Acad Audiol. 2009;20(5):311-4.
35. Bonanni M, Newton R. Test-retest reliability of the Fukuda Stepping Test. Physiother Res Int. 1998;3(1):58-68.
36. Serafini F, Caovilla HH, Ganança MM. Digital craniocorpography and peripheral vestibular diseases. Int Tinnitus J. 2008;14(1):34-6.

Endereço para correspondência:

Ivana Beatrice Manica da Cruz

Av. Roraima 1000, Prédio 19, Sala 3126 Camobi

Santa Maria RS 97105900.

Publication Dates

Publication in this collection
14 July 2010
Date of issue
June 2010

History

Received
19 Aug 2009
Accepted
15 Dec 2009

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

[1] 1. Maki BE, Mellroy WE. The role of limb movements in maintaining upright stance: 'change-in-support' strategy. Phys Ther. 1997;77:488-507.

[2] 2. Kós AOA, Tomita S, Torraca TSS, Decoster, DMH, Vidaurre AS. Estudos em Otoneurologia. Rio de Janeiro: RBO; 1986 (Consenso).

[3] 3. Nevitt MC, Cummings SR, Kidd S, Black D. Risk of factors for recurrent non-syncopal falls. JAMA. 1989;261:2663-8.

[4] 4. Lord SR, Lloyd DG, Li SK. Sensorimotor function, gait patterns and falls in community-dwelling women. Age Ageing. 1996;25:292-9.

[5] 5. Salem DB, Walker PM, Aho S, Tavernier B, Giroud M, Tzourio C et al. Brain flexibility and balance and gait performances mark morphological and metabolic abnormalities in the elderly. J Clin Neurosci. 2008;15:1360-5.

[6] 6. Rogers MW, Wardman DL, Lord SR, Fitzpatrick RC. Passive tactile sensory imput improves stability during standing; Exp Brain Res. 2001;136:514-22.

[7] 7. Rogers MW, Hedman LD, Johnson ME, Martinez KM, Mille ML. Triggering of protective stepping for the control of human balance: age and contextual dependence. Cognitive Brain Res. 2003; 16:192-8.

[8] 8. Szirmai A, Küstel M, Pánczél G, Kocher I, Répássy G, Nagy Z. Evidences of vascular irigin of cochleovestibular dysfunction. Acta Neurol Scand. 2001;104:68-71.

[9] 9. Wada M, Naganuma H, Tokumasu K, Hashimoto S, Ito A, Okamoto M. Arteriosclerotic changes as background factors in patients with peripheral vestibular disorders. Int Tinnitus J. 2008;14(2):131-4.

[10] 10. Okoro CA, Zhong Y, Ford ES, Balluz LS, Strine TW, Mokdad AH. Association between the metabolic syndrome and its components and gait speed among U.S. adults aged 50 years and older: a cross-sectional analysis. BMC Public Health. 2006;6:282.

[11] 11. Ostir GV, Volpato S, Fried LP, Chaves P, Guralnik JM. Reliability and sensitivity to change assessed for a summary measure of lower body function: results from the women's Health and aging study. J Clin Epidemiol. 2002;55(9):916-21.

[12] 12. Bootsma-van der Wiel A, Gussekloo J, De Craen AJ, Van Exel E, Bloem BR, Westendorp RG. Common chronic diseases and general impairments as determinants of walking disibality in the oldest-old population. J Am Geriatr Soc. 2002;50:1405-10.

[13] 13. Stehouwer CD, Clement D, Davidson C, Diehm C, Elte JW, Lambert M et al. Peripheral arterial disease: a growing problem for the internist. Eur J Intern Med. 2009;20(2):132-8.

[14] 14. Grover-Páez F, Zavalza-Gómez AB. Endothelial dysfunction and cardiovascular risk factors. Diabetes Res Clin Pract. 2009;84(1):1-10.

[15] 15. Lohman TG, Roche AF, Martorell R. Anthropometric standardization reference manual. Champaign: Human Kinetics Book; 1998.

[16] 16. Janssen I, Katzmarzyk PT, Ross R. Waist circumference and not body mass index explains obesity-related health risk. Am J Clin Nutr. 2004;79:379-84.

[17] 17. Fagerstrom KO, Schneider NG. Measuring nicotine dependence: a review of the Fagerstrom Tolerance Questionnaire. J Behav Med. 1989;12:159-82.

[18] 18. Bush B, Shaw S, Clary P, Delbanco TL, Aronso MD. Screening for alcohol abuse using the CAGE Questinnaire. Am J Med .1987;82(2):231-5.

[19] 19. Simonceli L, Bittar RMS, Bottino MA. Perfil diagnóstico do idoso portador de desequilíbrio corporal: resultados preliminares. Rev Bras Otorrinolaringol. 2003;69(6):772-7.

[20] 20. Peitersen E. Vestibulospinal reflexes. X. Theoretical and clinical aspects of the stepping test. Arch Otolaryngol. 1967;85:192-8.

[21] 21. Porac C, Coren S. Lateral Preferences and Human Behavior. New York: Springe Verlag; 1981.

[22] 22. Previc FH, Saucedo JC. The relationship between turning behavior and motoric dominance in humans. Percept Mot Skills. 1992;75:935-44.

[23] 23. Reiss M, Reiss G. Further aspects of the asymmetry of the stepping test. Percept Mot Skills. 1997;85:1344-6.

[24] 24. Fukuda T. The stepping test: to phases of the labyrinthine reflex. Acta Otolaryngol. 1959;50:95-108.

[25] 25. Weiler SW, Foeh Kp, van Mark A, Touissant R, Sonntag N, Gaessler A et al. Outpatient rehabilitation of workers with musculoskeletal disorders using structured workplace description. Int Arch Occup Environ Health. 2009;82(4):427-34.

[26] ²⁶
World Health Organization [Site na Internet]. Disponível em http:www.whor.org Acessado em 2 de agosto de 2009.
» link

[27] 27. Yanbaeva DG, Dentener MA, Creutzberg EC, Wesseling G, Wouters EF. Systemic effects of smoking. Chest. 2007;131(5):1557-66.

[28] 28. Pereira CB, Strupp M, Eggert T, Straube A, Brandt T. Nicotine-induced nystagmus: three-dimensional analysis and dependence on head position. Neurology. 2000;55(10):1563-6.

[29] 29. Pereira CB, Strupp M, Holzleitner T, Brandt T. Smoking and balance: correlation of nicotine-induced nystagmus and postural body sway. Neuroreport. 2001;12(6):1223-6.

[30] 30. Di Iorio A, Abate M, Pini B, Di Nicola I, Marinelli M, Guglielmi M et al. Effects of vascular risk factors on balance assessed by computerized posturography in the elderly. Aging Clin Exp Res. 2009;21(2):136-42.

[31] 31. Nagy E, Claussen CF, Bencze G, Heid L, Bencsik B, Kersebaum M. Depressive disorders in relation to neurootological complaints. Int Tinnitus J. 2004;10(1):58-64.

[32] 32. Soza Ried AM, Aviles M. Asymmetries of vestibular dysfunction in major depression. Neuroscience. 2007;144(1):128-34.

[33] 33. Menon AD, Sakano E, Weckx LL. Consenso sobre vertigem. Rev Bras Otorrinolaringol. 2000; 6(66 Supp 11):9-35.

[34] 34. Honaker JA, Boismier TE, Shepard NP, Shepard NT. Fukuda stepping test: sensitivity and specificity. J Am Acad Audiol. 2009;20(5):311-4.

[35] 35. Bonanni M, Newton R. Test-retest reliability of the Fukuda Stepping Test. Physiother Res Int. 1998;3(1):58-68.

[36] 36. Serafini F, Caovilla HH, Ganança MM. Digital craniocorpography and peripheral vestibular diseases. Int Tinnitus J. 2008;14(1):34-6.

Brasil

Brasil

Dinamic balance, lifestyle and emotional states in young adults

Abstracts

Endereço para correspondência:

Publication Dates

History