ONLINE FIRST Effect of Music-Based Multitask Training on Gait, Balance, and Fall Risk in Elderly People A Randomized Controlled Trial Andrea Trombetti, MD; Me´lany Hars, PhD; Franc¸ois R. Herrmann, MD, MPH;Reto W. Kressig, MD; Serge Ferrari, MD; Rene´ Rizzoli, MDBackground: Falls occur mainly while walking or per-
group. Balance and functional tests improved compared
forming concurrent tasks. We determined whether a mu-
with the control group. There were fewer falls in the in-
sic-based multitask exercise program improves gait and
tervention group (incidence rate ratio, 0.46; 95% confi-
balance and reduces fall risk in elderly individuals.
dence interval, 0.27-0.79) and a lower risk of falling (rela-tive risk, 0.61; 95% confidence interval, 0.39-0.96). Similar
Methods: We conducted a 12-month randomized con-
changes occurred in the delayed intervention control
trolled trial involving 134 community-dwelling individu-
group during the second 6-month period with interven-
als older than 65 years, who are at increased risk of fall-
tion. The benefit of the intervention on gait variability
ing. They were randomly assigned to an intervention
group (n = 66) or a delayed intervention control groupscheduled to start the program 6 months later (n = 68). Conclusion: In community-dwelling older people at in-
The intervention was a 6-month multitask exercise pro-
creased risk of falling, a 6-month music-based multi-
gram performed to the rhythm of piano music. Change
task exercise program improved gait under dual-task con-
in gait variability under dual-task condition from base-
dition, improved balance, and reduced both the rate of
line to 6 months was the primary end point. Secondary
outcomes included changes in balance, functional per-formances, and fall risk. Trial Registration: clinicaltrials.gov Identifier: NCT01107288 Results: At 6 months, there was a reduction in stride length variability (adjusted mean difference, −1.4%; P Ͻ.002) under dual-task condition in the intervention
Published online November 22, 2010.
group, compared with the delayed intervention control
doi:10.1001/archinternmed.2010.446FALLSARECOMMONANDDEV- whenperformingconcurrenttasks,such
or cognitive tasks.11,12 Gait variability (ie,
stride-to-stride fluctuations in walking),
particularly during dual-task walking con-
least 1 fall, and half of those fall repeat-
ditions, can objectively characterize gait
edly.1,3-5 This problem will continue to grow
as the number of older adults increases over
flecting a more unstable gait pattern, that
the coming decades.6 Thus, preventing falls
in turn leads to an increased risk of fall-
in elderly individuals is a major concern.
ing.1,13-17 There is little information regard-
Measures to reduce falls are often of lim-
ing effective measures to improve or even
Author Affiliations: Division
ited benefit.7 Exercise can counteract key
risk factors for falls, such as poor balance,
der dual-task conditions in elderly people.
and consequently reduce risk of falling in
elderly community-dwelling individuals.7,8
See also
land, in the early 20th century. It is now
related article
practiced worldwide in the field of music,
as well as dance, theater, and therapy. Prac-
titioners are introduced to music’s basic ele-
over, older adults are more likely to fall
2010 American Medical Association. All rights reserved.
ous multitask exercises performed to the rhythm of im-
ing to a computer-generated list prepared by an independent
provised piano music.18 Recently, specific classes for older
statistician, without stratification, using a permuted block ran-
adults have been developed. The integrated motor and cog-
domization design. Allocation assignment was concealed from
nitive components are key features of this program, which
involves a greater interest for dual- or multiple-task prac-tice than other multicomponent attention-demanding ex-
INTERVENTION
ercise forms (eg, Tai Chi). In a cross-sectional study of older,long-term practitioners of Jaques-Dalcroze eurhythmics,
The intervention was a structured 1-hour weekly class exerciseprogram led by an experienced instructor. It featured various mul-
age-related increase in stride-to-stride variability in a dual-
titask exercises, sometimes involving the handling of objects (eg,
task context appeared to be attenuated.19
percussion instruments or balls), which became gradually more
We conducted a randomized controlled trial to deter-
difficult over time.22 Basic exercises consisted of walking in time
mine whether a 6-month music-based multitask exercise
to the music and responding to changes in the music’s rhyth-
program (ie, Jaques-Dalcroze eurhythmics) would im-
mic patterns. Exercises involved a wide range of movements and
prove gait and balance and reduce fall risk in community-
challenged the balance control system mainly by requiring mul-
dwelling older adults at high risk of falling. Change in gait
tidirectional weight shifting, walk-and-turn sequences, and ex-
variability under dual-task condition from baseline to 6
aggerated upper body movements when walking and standing.
months was the primary end point. Secondary end points
Subjects in the delayed intervention control group were in-
were to assess changes in other quantitative gait and bal-
structed to maintain their usual physical and social activities, aswas the early intervention group after the program ended, ie, dur-
ance measures, functional test performances, and falls and
ing the second 6-month period. Both groups were asked to avoid
to determine through a 6-month postintervention fol-
any new additional exercise programs during the course of the
low-up whether the benefit due to the intervention could
study. No instructions were provided to perform any specific ex-
ercise outside class time. Adherence to the Jaques-Dalcroze eu-rhythmics program was verified by weekly attendance records. FOLLOW-UP VISITS STUDY DESIGN
Participants were assessed by a trained multidisciplinary teamblind to the participants’ group allocations and to information
In this 12-month monocenter, randomized controlled trial, sub-
from previous evaluations. Functional tests and instrumental
jects were randomly assigned to either a music-based multitask
gait and balance analysis were conducted using a standardized
exercise program or a delayed intervention control group for 6
protocol, as detailed in the following subsection. Interviews col-
months (or 25 weeks). The primary end point was assessed at 6
lected sociodemographic characteristics, fall history, nutri-
months. During the second 6-month period, the delayed inter-
tional status,23 physical activity level,24 and neuropsychologi-
vention control group participated in the intervention program,
cal status.25-29 All participants also underwent a complete physical
while the early intervention group returned to their usual habits
(ie, no more intervention). Both groups were assessed at base-line and months 6 and 12. Enrollment began in February 2008,and the follow-up period ended in December 2009. The study
ASSESSMENT OF GAIT, BALANCE,
was approved by Geneva University Hospitals ethics committee. AND FUNCTIONAL PERFORMANCE
All study participants provided written informed consent.
Gait and balance were assessed using an electronic pressure sen-sitive walkway (GAITRite; CIR Systems Inc, Havertown, Pennsyl-
STUDY PARTICIPANTS
vania) and angular velocity transducers (SwayStar; Balance Inter-national Innovations GmbH, Iseltwald, Switzerland), respectively.
Participants were recruited in the local community through mul-
Gait parameters were collected according to the spatiotemporal
tiple strategies, including advertisements in local newspapers.
gait analysis guidelines.30 The subjects were asked to walk at their
The inclusion criteria were (1) adults 65 years or older, (2) liv-
self-selected usual, slow, and fast speed as a single task. Then, they
ing in the community, (3) without previous experience of Jaques-
were asked to walk at a self-selected speed and to simultaneously
Dalcroze eurhythmics, except during childhood, and (4) at in-
count aloud backward by 1 starting from 50, as a dual task, with-
creased risk of falling. Participants were considered at risk of
out specific instruction to prioritize either task. Coefficient of varia-
falls if they met at least 1 of the following criteria: (1) 1 or more
tion (CV) was used as a measure of variability for stride time and
self-reported falls after the age of 65 years, (2) balance impair-
stride length parameters (CV=[standard deviation/mean]ϫ100).
ment as assessed by a simplified Tinetti test with a score higher
The relative and absolute test-retest reliability of gait outcome mea-
than 2 of 7,3,20 and (3) 1 or 2 criteria of physical frailty.21 Sub-
sures was examined in a random sample of 30 study participants.
jects were excluded if their medical history or physical exami-
Under the dual-task condition, intraclass correlation coefficients
nation revealed (1) a neurological disease associated with mo-
(2,1) for gait variability measures were all above 0.68. The stan-
tor deficit or an orthopedic disease with a significant impact
dard error of measurement values were 1.59% and 0.99% for CV
on gait and/or balance that would compromise outcomes as-
of stride time and stride length, respectively.
sessment (2) or any other medical conditions that would limit
The SwayStar system consists of 2 angular velocity trans-
participation (eg, terminal illness). Participants fully depen-
ducers worn on the lower trunk.31 Each participant was tested
dent on an assistive device were excluded.
for a 2-legged stance task for 20 seconds and a 1-legged stancetask for 10 seconds with eyes open and for 1 dynamic task (ie,
RANDOMIZATION
getting up from a chair, sitting down, standing up again, andremaining standing).32 Four outcome variables were calcu-
Eligible subjects were randomized to either the intervention or
lated for each task, in addition to task duration, ie, 90% range
the delayed intervention control group in a 1:1 ratio accord-
of both trunk angular displacement and angular velocity, in me-
2010 American Medical Association. All rights reserved.
for 12 months and recorded daily using a diary mailed monthlyto the study coordinator.37 Participants who failed to return the
diary or provided incomplete data were contacted by telephone. SAMPLE SIZE CALCULATION
The sample size was determined using data from a previous
study.19 Ninety-six participants (ie, 48 in each group) were needed
for a statistical power of 90% to detect a difference between groups
at a 2-sided significance level of 5% on the primary outcome gait
variability in dual-task condition, assuming that gait variability
in this population was 4%. This allowed us to detect a differ-
ence of 1% in gait variability between the intervention and the
control groups at completion of the first 6-month intervention.
With 10% mortality and 20% dropout rates, a sample size of 130participants was targeted. STATISTICAL ANALYSIS
All analyses were based on intention-to-treat, with the last value
carried forward for missing values. The 2 test, t test, or Wilcoxon
rank sum test were used, as appropriate, to compare baseline char-
acteristics. Changes from baseline to 6 months were summarized
asmeansandstandarddeviations.Estimatesofbetween-groupmeandifferences, adjusted for baseline values, were computed, togetherwith 95% confidence intervals (CIs). Analyses of covariance were
performed to examine differences in changes across groups, with
baseline value as covariate. Because gait velocity may represent a
potential confounder when evaluating gait variability,38 additional
analyses with adjustments for changes in gait velocity were per-
formed for all variability measures. Data were also analyzed at a
normalized velocity of 100 cm/s (ie, within the individual rangeof velocities and close to the mean usual gait velocity) using an in-terpolation procedure, pooling the 3 walking conditions under a
singletask(ie,self-selectedslow,usual,andfastspeeds),asdescribed
elsewhere.39,40 Six-to12-monthchangesweresummarizedasmeansand standard deviations. Crossover analyses were performed using
a specific Stata procedure (command pkcross) that enables analy-
sis of crossover experiments and provides significance values forsequence, period, intervention, and carryover effects. The data werereanalyzed (1) without adjustment for baseline covariates, (2) using
per-protocol analysis of study completers without imputation,
and (3) using linear mixed-effects regression models (with Stata
“xtmixed” command) to predict the primary end point, with
8 Had declining health4 Had inadequate time for
visit, intervention, and visit by intervention interaction as ex-
For fall outcomes, log-binomial regression models were used
to calculate relative risks comparing both the number of sub-jects with 1 or more falls and subjects with multiple falls (Ն2
falls during the study period) in both groups. The incidence
rate ratio for the number of falls was analyzed using a negative
binomial regression model. In addition, survival analyses were
conducted: hazard ratios were estimated from a Cox propor-
tional hazards model for the first fall, and its extension, theAndersen-Gill model,41 for all falls. In these models, subjectswho did not achieve expected follow-up were censored at the
Figure 1. Flowchart for enrollment, randomization, and follow-up of study participants.
All statistical significance tests were 2-sided, and PϽ.05 was
considered statistically significant. Analyses were performed using
diolateral and anteroposterior directions.33 For functional tests,
Stata software version 11.0 (StataCorp, College Station, Texas).
each participant underwent Timed Up & Go34,35 and simpli-fied Tinetti tests.3,20,36
ASSESSMENT OF FALLS
As shown in the flowchart (Figure 1), 241 individuals
Falls were defined as “unintentionally coming to rest on ground,
were screened and 134 (56%) enrolled. Of these, 22 (16%)
floor, or other lower level.”37 Falls were prospectively monitored
and 28 (21%) dropped out of the study at 6 and 12 months,
2010 American Medical Association. All rights reserved.
respectively. There was no difference between groups inthe number of participants with incomplete follow-up. Table 1. Baseline Characteristics of Participants
Mean attendance rate at the exercise program was 78%and did not vary by group. The attendance rate of the
Intervention Intervention
participants completing the intervention was 83%, 77%
Characteristic
of whom attended at least 20 classes (ie, 80% of the classes). The main reasons for not attending classes included health
problems, family constraints, or difficulties related to
travel. No major adverse events occurred during the study,
and there were no adverse effects, such as falls, cardio-
vascular events, or any injury during or following the ex-
The mean (SD) age of the participants was 75.5 (6.9)
years, and 96% were women (Table 1). Baseline char-
acteristics were identical in both groups, except for height
(P=.04), with no differences in study outcomes (Table 2
and Table 3). Participants in both groups displayed simi-
lar baseline fall history profiles in the year before the study.
Completers and dropouts did not differ significantly on
Under the single-task condition, intervention group
subjects increased their usual gait velocity (adjusted mean
difference [AMD], 4.7 cm/s; 95% CI, 0.5 to 8.8; P = .03),
and their stride length (AMD, 3 cm; 95% CI, 0.5 to 5.6;
P = .02) compared with the delayed intervention control
group (Table 2). In the intervention group, the stride time
variability improved (AMD, −0.4%; 95% CI, −0.7 to −0.1;
Physical activity level, mean (SD), kcal/wk
P = .01). When normalized for a gait velocity of 100 cm/s
(see the “Methods” section), the change in gait variabil-
ity was no longer significant. Under the dual-task con-
dition, intervention group subjects increased their stride
length (AMD, 3.1 cm; 95% CI, 0.1 to 6.1; P = .04) and de-
creased their stride length variability (AMD, −1.4%; 95%
CI, −2.3 to −0.6; P Ͻ.002) (Figure 2) compared with
controls. Adjustments for gait velocity changes did not
influence gait variability modifications. Other statistical
approaches (ie, without adjustment, per-protocol analy-
sis as well as mixed-effects regression model) provided
similar results in both magnitude and direction for the
By comparison with the delayed intervention con-
trols, the intervention group improved stance time for
the 1-legged stance task (AMD, 0.9 s; 95% CI, 0.3 to 1.6;
P = .006) (Table 3) and decreased mediolateral angular
velocity (AMD, −4.6 degrees/s; 95% CI, −8.6 to −0.6;
P = .02). In the Tinetti and Timed Up & Go tests, the in-
tervention group did better than the controls (Table 3).
Compared with the control group, the intervention
group experienced fewer falls during the first 6-month pe-
riod: the unadjusted incidence rate ratio for falls was 0.46
(95% CI, 0.27 to 0.79; P=.005) and remained similar when
adjusted for age, falls history over the previous 12 months,
Tinetti test performance, and the number of frailty crite-
ria (according to Fried et al21) met (Table 4). The num-
ber of subjects with 1 or more falls was also statistically
different between both groups (relative risk, 0.61; 95% CI,0.39 to 0.96; P=.03) with a number needed to treat of 5
Abbreviations: BMI, body mass index (calculated as weight in kilograms
divided by height in meters squared); FAB, Frontal Assessment Battery; HADS,
(95% CI, 2.1 to 34.4). The relative risk for multiple falls
Hospital Anxiety and Depression Scale; MMSE, Mini-Mental State Examination;
was 0.19 (95% CI, 0.06 to 0.63; P=.007). Using a Cox pro-
MNA, Mini-Nutritional Assessment; SF-12, 12-item Short-Form Health Survey.
portional hazards model, we found that the unadjusted haz-
Significant difference between groups (PϽ.05).
ard ratio for the time to first fall was 0.53 (95% CI, 0.30
c Five-point Likert scale from 1 (excellent) to 5 (bad).
to 0.94; P=.03) in the intervention group compared with
2010 American Medical Association. All rights reserved. Table 2. Change in Gait Outcome Measures by Groups Mean (SD) Mean (SD) Baseline Changes at 6 moa Adjusted Changes at 12 mob Effect,d Between-Group P Value Intervention Intervention Intervention Intervention Difference P Intervention Intervention Outcomes Sequence vention Single-Task Condition Dual-Task Conditione
Abbreviations: CI, confidence interval; CV, coefficient of variation.
a Changes were calculated as 6-month follow-up minus baseline.
b Changes were calculated as 12-month follow-up minus 6-month follow-up.
c Analyses of covariance on change in measures with the baseline value as covariate.
d Crossover analysis of variance on change in measures using a specific procedure dealing with the analysis of crossover experiments, which provides significance
values for respectively sequence, period, intervention, and carryover effects. Ellipses represent nonsignificant values.
e One subject under the dual-task condition had to be excluded from the analysis due to technical failure of GAITRite; CIR Systems Inc, Havertown, Pennsylvania.
the control group. This remained significant after adjust-
same period, while the intervention was dispensed, 19
ment for baseline covariates. When comparing the 2 groups
subjects (34%) of the former delayed intervention group
using an Andersen-Gill model, the unadjusted hazard ra-
had at least 1 fall, of whom 6 (11%) had fallen repeat-
tio of 0.46 (95% CI, 0.27 to 0.78; P=.004) remained sig-
edly, with 28 reported falls. The incidence of falls was
significantly reduced during this period of intervention
Using a crossover analysis of variance, we found sig-
compared with the first 6 months (P = .02), as was the
nificant carryover effects for some outcomes, indicating
proportion of participants with multiple falls (P = .01).
that several changes in the early intervention group had
The reduction in the proportion of subjects with 1 or more
been maintained at 12-month follow-up (Table 2 and
falls failed to reach significance (P = .06).
Table 3). The improvement in gait variability under dual-task condition was retained 6 months after the interven-tion had ended, as were improvements in 1-legged stance
duration and in Tinetti performance. At the 12-monthfollow-up, when both groups had taken part in the in-
To our knowledge, this is the first evidence of a revers-
tervention program, the crossover analysis revealed im-
ibility in age-dependent increase of gait variability un-
provements in stride length and stride length variability
der cognitive-motor dual-task condition in older adults.
under the single-task condition and stride length vari-
Indeed, dual-task gait performance improved in the music-
ability under the dual-task condition, as well as in 1-legged
based multitask exercise program group, with reduc-
stance duration and Tinetti test performance.
tion in stride length variability, regardless of gait veloc-
Between 6 and 12 months, 56 participants in each
ity modification. All statistical analyses showed similar
group were followed up for falls. Sixteen subjects (29%)
results, which confirm the robustness of our findings. Few
in the early intervention group had at least 1 fall and 4
studies to date have demonstrated an improvement of
(7%) had fallen repeatedly, with 20 reported falls. The
dual-task gait performance with training, including stud-
incidence of falls, proportion of subjects with 1 or more
ies in patients with stroke, Parkinson disease, or demen-
falls and those with multiple falls in this group did not
tia or in older adults, but most of their sample sizes were
differ between the intervention and the follow-up pe-
small.43-47 Our study also indicates that gait variability may
riod (P=.63, P=.64, and P=.71, respectively). During the
be improved under a single-task condition, as was pre-
2010 American Medical Association. All rights reserved. Table 3. Change in Balance and Functional Outcomes Mean (SD) Mean (SD) Baseline Changes at 6 moa Adjusted Changes at 12 mob Effect,d Between-Group P Value Intervention Intervention Intervention Intervention Difference P Intervention Intervention Outcomes Sequence vention
Abbreviations: CI, confidence interval; A-P, body sway in anteroposterior direction; M-L, body sway in mediolateral direction.
a Changes were calculated as 6-month follow-up minus baseline.
b Changes were calculated as 12-month follow-up minus 6-month follow-up.
c Analyses of covariance on change in measures with the baseline value as covariate.
d Crossover analysis of variance on change in measures using a specific procedure dealing with the analysis of crossover experiments, which provides significance
values for respectively sequence, period, intervention, and carryover effects. Ellipses represent nonsignificant values.
viously suggested in older adults, in particular after train-ing or pharmacological interventions.48-52 The same find-
ing was also recently reported in healthy older adults after
We can only speculate on the factors responsible for
the detected improvements in dual-task gait variability:
they could be related to more automated tasks, to task
coordination skills development, or to both.46,54 The in-
tervention effect under other dual-task conditions (eg,motor interference tasks) needs to be further explored.
Also, the intervention may involve increased gait per-formance by improving attention and executive func-
Figure 2. Stride length variability under the dual-task condition for both
tion.55-58 An association between gait variability and ex-
groups. Values represent means using last observation carried forward.
ecutive function, particularly during dual tasking, has been
Error bars represent 95% confidence intervals.
reported in elderly fallers (those with Ն1 fall).59 Fur-ther work is needed to fully assess the impact of this pro-
plication for older adults, since a low gait speed was found
gram on cognitive performances, using a comprehen-
to be a consistent risk factor for disability, institutional-
sive neuropsychological battery for executive functions.
ization, and mortality.61 An increase in self-confidence
The current findings extend the existing knowledge
may explain these findings.62 An improvement of bal-
of the efficacy of physical exercise interventions to im-
ance in 1-legged stance is also consistent with previous
prove gait, balance, and functional capacity in elderly
reports of improved 1-legged stance time following a wide
people.8,60 The improvement observed in gait velocity is
range of exercise programs.63 These changes were also
consistent with a meta-analysis that reported a success
accompanied by small but significant gains in func-
rate of 57% after exercise training to improve usual gait
tional performances. Modifications in the Tinetti score
speed.60 This finding may have an important practical im-
after the intervention were mainly due to an improve-
2010 American Medical Association. All rights reserved. Table 4. Falls at the 6-Month Follow-up Intervention Intervention Outcomes Unadjusted Adjusteda
Participants with multiple (Ն2) falls, No. (%)
Abbreviations: CI, confidence interval; HR, hazard ratio; IRR, incidence rate ratio; RR, relative risk.
a Adjusted for age, history of falls over the previous 12 months, simplified Tinetti test performance, and total number of frailty criteria (accordingtoFried et al21)
ment in the performance of the 1-legged stance task. Un-
may have resulted in reporting bias. Second, the results
expectedly, there were no differences in sway para-
should be interpreted in light of the eligibility criteria and
meters in the 2-legged stance task and the dynamic task
with regard to the gender imbalance in the study popu-
of sitting to standing. The latter task mainly requires
lation. The overwhelming predominance of women re-
greater lower extremity strength, which was only a small
cruited may be partly explained by demographic factors
(ie, in Switzerland, women 65 years and older outnum-
Although the study was not powered to detect between-
ber men by approximately 1.35 to 1) and movement to
group differences in falls, a reduction in the incidence
music activities being more attractive for women. In ad-
of falls, and in the risk of falling was found. While com-
dition, the participants who enrolled in this trial prob-
parisons between trials are difficult when there are dif-
ably had a greater interest in health issues than the gen-
ferences in study design, core components of the inter-
eral population of elderly people. This might have resulted
ventions, population targeted, intervention duration, or
in the inadvertent selection of more motivated individu-
assessments of falls, the 54% reduction in falls observed
als. Third, there was no attention control group. Fourth,
in our study compares favorably with the rates observed
the number of withdrawals could be a limitation, but it
in the most effective exercise-based interventions re-
was taken into account in the power calculation. Fi-
ported so far, with a meta-analysis demonstrating an over-
nally, there was only 1 class instructor and the out-
all fall reduction of 37% for Tai Chi interventions.7,8 Our
comes achieved took place at 1 center. Therefore, fur-
results are in agreement with another meta-analysis, which
ther studies are needed to confirm the generalization
showed that interventions involving a large balance com-
ponent are the most effective for preventing falls among
In conclusion, this randomized controlled trial is the
older people.8 The fall risk reduction in our trial may have
first, to our knowledge, to show that participation in mu-
been related to the multimodal nature of the interven-
sic-based multitask exercise classes once a week over a
tion and to improvements in major risk factors for falls,
6-month period can improve gait performance under
single and cognitive-motor, dual-task conditions, as well
Jaques-Dalcroze eurhythmics seems to be able to change
as improve balance, and reduce both the rate of falls and
patterns of physical activity in elderly people by provid-
the risk of falling in at-risk elderly community-dwelling
ing a strong motivation for the initiation and mainte-
adults. Our findings suggest that this program may be
nance of exercise behavior, especially in women (96% of
useful for fall prevention and rehabilitation in community-
the participants in this trial) who are often less physically
based settings such as senior centers.
active than men.65,66 The adherence to the intervention pro-gram was high (78%), compared with the mean rate of 63%
Accepted for Publication: September 17, 2010.
reported in a review that examined exercise adherence in
Published Online: November 22, 2010. doi:10.1001
elderly people,67 possibly in relation to the music compo-
nent, which has been shown to facilitate exercise adher-
Correspondence: Andrea Trombetti, MD, Division of
ence in older adults.68 Fifty-six percent of participants have
Bone Diseases, Department of Rehabilitation and Geri-
registered in new fee paying sessions after the study.
atrics, University Hospitals and Faculty of Medicine of
Our study had some limitations. First, the nature of
Geneva, 1211 Geneva 14, Switzerland (Andrea.Trombetti
the intervention precluded blinding participants, which
2010 American Medical Association. All rights reserved. Author Contributions: Dr Trombetti had full access to
fective exercise for the prevention of falls: a systematic review and meta-analysis.
the data in the study and takes responsibility for the in-
J Am Geriatr Soc. 2008;56(12):2234-2243.
9. Berg WP, Alessio HM, Mills EM, Tong C. Circumstances and consequences of
tegrity of the data and the accuracy of the data analysis.
falls in independent community-dwelling older adults. Age Ageing. 1997;26
Author Contributions: Dr Trombetti had full access to
the data in the study and takes responsibility for the in-
10. Niino N, Tsuzuku S, Ando F, Shimokata H. Frequencies and circumstances of
tegrity of the data and the accuracy of the data analysis.
falls in the National Institute for Longevity Sciences, Longitudinal Study of Ag-
Study concept and design: Trombetti, Hermann, Kressig,
ing (NILS-LSA). J Epidemiol. 2000;10(1)(suppl):S90-S94.
11. Bloem BR, Valkenburg VV, Slabbekoorn M, Willemsen MD. The Multiple Tasks
Ferrari, and Rizzoli. Acquisition of data: Trombetti and
Test: development and normal strategies. Gait Posture. 2001;14(3):191-202.
Hars. Analysis and interpretation of data: Trombetti, Hars,
12. Bergland A, Pettersen AM, Laake K. Falls reported among elderly Norwegians
Hermann, Kressig, Ferrari, and Rizzoli. Drafting of the
living at home. Physiother Res Int. 1998;3(3):164-174. manuscript: Trombetti and Hars. Critical revision of the
13. Maki BE. Gait changes in older adults: predictors of falls or indicators of fear. manuscript for important intellectual content: Hermann,
J Am Geriatr Soc. 1997;45(3):313-320.
14. Hausdorff JM. Gait variability: methods, modeling and meaning. J Neuroeng Rehabil.
Kressig, Ferrari, and Rizzoli. Statistical analysis: Trom-
2005;2(1):19. doi:10.1186/1743-0003-2-19.
betti, Hars, and Hermann. Administrative, technical, and
15. Priest AW, Salamon KB, Hollman JH. Age-related differences in dual task walk-
material support: Hermann and Kressig. Study supervi-
ing: a cross sectional study [published online November 14, 2008]. J Neuroengsion: Trombetti, Ferrari, and Rizzoli. Rehabil. 2008;5:29. doi:10.1186/1743-0003-5-29.
16. Brach JS, Studenski SA, Perera S, VanSwearingen JM, Newman AB. Gait vari-
Financial Disclosure: None reported.
ability and the risk of incident mobility disability in community-dwelling older
Funding/Support: This study was funded by the follow-
adults. J Gerontol A Biol Sci Med Sci. 2007;62(9):983-988.
ing organizations and foundations: Loterie Romande
17. Verghese J, Holtzer R, Lipton RB, Wang C. Quantitative gait markers and incident
Geneva, Carigest SA, Gertrude Hirzel Foundation, Leena-
fall risk in older adults. J Gerontol A Biol Sci Med Sci. 2009;64(8):896-901.
ards Foundation, Oltramare Foundation, Eagle Founda-
18. Jaques-Dalcroze E´. Rhythm, Music & Education. Rev ed. London, England: Dal-
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Into the pediatrician's practice M.I. Petrovskaya, T.V. Kulichenko Scientific Center of Children's Health, RAMS, Moscow Herbal Treatment of Inflammatory Diseases of the Upper Respiratory Tract This article is devoted to one of the most common manifestations of diseases of respiratory system and upper respiratory tract - coughing. While performing a protective function , the cough in
Grey squirrel, Sciurus carolinensis , populations have been subjected to various degrees of control in thewoodlands of Ireland and Britain since their introduction. The populations readily recover, but therecolonisation rates and other ecological effects of the culls have not been fully examined. Monthlylive trapping programmes were used to monitor the grey squirrel populations in two woodlands. C