Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT03636672 |
| Other study ID # |
BARZI0104 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
March 1, 2019 |
| Est. completion date |
June 30, 2021 |
Study information
| Verified date |
July 2021 |
| Source |
Barzilai Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
A Randomized Control Trial will be conducted with Independent old adults (age 70 years old
and older) who willing to participate in the study. They will be randomly allocated to two
groups: 1) Stationary bicycle riding that includes perturbation balance training during
riding; 2) Stationary bicycle riding that does not includes perturbation balance training
during riding. Balance and Gait assessments will be tested before and after 3 months of
training (2-3 times a week).
Description:
Falls and fall-related injuries are common elder health problems. Falls are the leading cause
of fatal and nonfatal injuries among older adults, reducing mobility and independence, and
increase the risk of death. Between 30 to 40% of the community-dwelling older persons fall at
least once a year, usually by falling sideways that is resulting in 95% of hip fractures. In
the U.S. in 2014, the estimated direct medical costs for fall-related injuries were $31.3
billion and is expected to reach $67.7 billion by 2030 Age-related changes in the balance
control system increase the risk of falls. Execute a rapid step, whether voluntary or
compensatory, is the most important balance strategy to prevent a fall. In voluntary stepping
test, the foot contact times (i.e., stepping time) and reaction time (initiation phase) were
able to predict future fall and injury from fall. Studies of the reactive postural control
have shown that older adults initiate stepping at lower levels of instability, use multiple
steps, experience leg collisions or fail to recover balance compared to younger adults. The
Medio-Lateral center of pressure sway range with Eyes Closed is the best single predictor for
future fall.
Studies showed that older adults were able to adapt in a reactive manner after participation
in a Perturbations based balance training (PBBT) that challenged the mechanisms responsible
for dynamic stability. These studies also showed a reducing in rate of falls and diverse
risks of falls in older adults (voluntary stepping times, balance control in standing and
walking, improved function and reduced fear of falls). however, in these studies the training
devices and programs were designed to participants who able to walk independently the whole
training sessions, lasting 20-45 minutes each and appropriate only for a small portion of the
general elderly population. In fact, in 2014 in U.S., the community-dwelling older persons
that reported a fall were divided equally into three health status: poor-fair, good, very
good-excellent with 33% rate of fall each subgroup. This fact motivates us to provide
accessibility PBBT for a wider range of the elderly population, and not for the "strongest"
older subjects.
Inspired by the well-known health advantages of cycling and the medio-lateral postural
control demand during two-wheel bicycle riding, encourage us to conduct a preliminary study
for feasibility. In this study we found older adults who aged with bicycle riding habits have
benefits in reactive and predictive aspects of postural control mechanisms (particularly in
the medio-lateral postural control) while standing and stepping, both related to risk of
falling in the elderly (see Preliminary result section). Because the special importance of
the medio-lateral balance control for preventing lateral falls and hip fractures in old age,
considering our preliminary findings, we hypothesize that following exposure to training
program that includes unexpected perturbations exercises during cycling will significantly
improve compensatory and voluntary stepping times as well as the medio-lateral balance
control in older adults, factors that are associated with falls and fall- related injuries.
Objectives: firstly, to explore whether training while riding a new bicycle simulator device
providing unexpected perturbations can reduce risks of falls in standing and walking in
independent older adults. Secondly, if so, to examine this bicycle simulator device providing
unexpected perturbations method in a wider range of elderly subjects (i.e., who do not walk
independently or walk for only short distances or with assisted devices or suffering from
fear of falling or in pre-walking rehabilitative phases after stroke or other morbidity).
Methods Study design: A double blinded randomized controlled trial. Participants: Relatively
healthy Community dwelling older adults that are 70 years or older, independent in daily
living activities, walking without assistive devices, without morbidity that influence
balance performance. The study will be approved by the Helsinki committee of Barzilai
University medical center, Ashkelon, Israel. All subjects will sign an informed consent
statement.
Training programs: We will use two identical exercise bicycles, one will remain a stationary
Bicycle device for the control group, and bicycle simulator device providing unexpected
perturbations during a bicycle simulator riding for the experimental group. The intervention
Group will receive 24 bicycle simulator device providing unexpected perturbations sessions,
twice a week for 12 weeks (about 20 min. each). The subjects will be instructed to "ride on
the bicycle in your preferred pace and try to stabilize yourself". To prevent injury if loss
of balance occurred during the cycling, the subject will wear a loose safety harness that can
arrest the fall. The bicycle simulator device providing unexpected perturbations program will
have 24 levels of difficulty with increasing levels of perturbations (i.e., increase
displacement, velocity and accelerations of the translations). The control group will receive
24 sessions, twice a week for 12 weeks, about 20 minutes' bicycle riding on the stationary
device, pedaling in subject own preferred pace without perturbations and wearing a loose
safety harnesses. Since both group will train on two identical exercise bicycles, they will
be blinded to the allocation to intervention or control group.
Assessments: 1) Compensatory Step Execution tests during Standing and Walking: The subjects
will be instructed to react naturally. Ten perturbation levels will be induced through a
device that provides controlled and unexpected anterior-posterior and medio-lateral platform
translations during a single belt treadmill in standing and walking. Four directional
perturbations (right/left/forward/backward) in a random order each level for a total of 40
perturbation trials. Kinematic analysis: Three-dimensional kinematic data will be collected
through the optical motion capture, providing kinematic analysis of a motion sequence.
Sixteen infrared cameras are covered the lab space sample simultaneously, at frequency of 200
Hz, the location of 35 reflective markers placed on anatomical landmarks of the body and
another two on the moving platform. The following Balance compensatory kinematics parameters:
(1) Platform perturbation; (2) First Step initiation time (milliseconds); (3) Foot contact
time (milliseconds); (4) Compensatory Step execution time (milliseconds); (5) Step swing time
(milliseconds); (6) Step length (centimeters); (7) End of Compensatory steps time
(milliseconds); (8) Total distance center of mass made (centimeters); (9) Distance of center
of mass from leg at the step-beginning point (centimeters); 10) Arms lift initiation times
(milliseconds); 11) Maximal arms swing amplitude/length (centimeters); 12) Arms swing times
(milliseconds). Observational analysis: observing each trail video and identifying the
compensatory reactions (see preliminary results). 2) Voluntary Step Execution Test:
Participants are instructed to voluntary step as quickly as possible following a
somatosensory cue, given randomly on one of their feet. A total of 8 trials will be conducted
in singe task and dual task conditions (while performing the modified Stroop task). Specific
temporal events were extracted from the step execution data: (a) Reaction Time; (b) Foot
Contact Time; (c) Preparation Time; (d) Swing Time. 3) Postural Stability: The subjects will
be instructed to stand barefoot as still as possible on the force platform in a standardized
stance. Five 30-s quiet-standing trials with eyes open and five trails with eyes blindfolded.
Evaluation of balance control will be made using both, traditional measure of postural sway
(e.g. medio-lateral-sway, anterior-posterior -sway, sway velocity, and sway area), and
calculating the Stabilogram-Diffusion Analysis parameters from center of pressure data. In
addition, clinical measurements and questionnaires will be conducted as the secondary outcome
measures: Berg Balance Scale (BBS); 6-minute walk test (6MWT); Medical History form; Late
Life Function and Disability Instrument (LLFDI); Falls Efficacy Scale-International (FES);
Mini Mental state examination (MMSE).
