Spinal Cord Injury Clinical Trial
Official title:
Determination of Novel Methods of Exercise Testing During Treadmill Gait in Incomplete Spinal Cord Injury
Treadmill therapy has the potential to improve the physical fitness and voluntary function
of incomplete-lesion spinal cord injured (SCI) patients. However, if it is to be offered as
a rehabilitation strategy, evidence must be gathered to support its effectiveness. Present
methods used to determine the efficacy of treadmill training do not provide accurate means
of monitoring changes in physical fitness during the exercise, or to accurately measure the
changes in voluntary muscle function which may occur during a training intervention.
We are therefore currently recruiting subjects for a study investigating the feasibility of
new methods for monitoring improvements in physical fitness during walking on a treadmill.
We also aim to develop methods for monitoring changes in voluntary muscle strength. The bone
density of both legs will also be measured to determine if any improvement has occurred
following training.
Treadmill therapy has the potential to improve the cardiopulmonary fitness, voluntary
function, and lower limb bone density of incomplete spinal cord injury (SCI) patients.
However, if it is to be offered clinically as a rehabilitation strategy then evidence must
be gathered to support its effectiveness.
The efficacy of FESāassisted walking with incomplete SCI individuals, both overground and on
a treadmill, has previously been assessed by monitoring walking speed, stride length,
endurance, cadence, the physiological and oxygen cost, % body weight support (treadmill),
and by performing observational gait analysis and manual muscle testing (1,2,3,4,5,6).
However, these methods do not provide a means of measuring changes in fitness or for
accurately monitoring improvements in voluntary muscle function.
At present appropriate methods for testing a person's cardiopulmonary fitness on a treadmill
are lacking. Previously, incremental exercise tests have been carried out by maintaining a
constant inclination and increasing the speed linearly.
However, if the speed is increased linearly it is likely that it will increase at too fast a
pace. Therefore the test will become a measure of the subject's ability to move their legs
quickly and/or efficiently enough, rather than metabolic factors. If a steep gradient is
chosen as the constant inclination then a high initial metabolic cost will result, which
will limit the test time. Another common method used is to maintain a constant speed while
increasing the sine of the angle of inclination. The problem with this method of testing is
that if too low a speed is selected then a very steep gradient results before the level of
tolerance is reached, and if too high a speed is selected there is a high initial metabolic
cost. These problems were addressed in a recent paper by Porszasz et al., 2003 (7). They
demonstrated that by increasing walking speed linearly and treadmill gradient curvilinearly,
a linear increase in work rate occurs with the subjects fatiguing at a moderate speed. If
this protocol could be adapted for use with incomplete SCI patients it would provide an
accurate means of testing changes in cardiopulmonary function which may result after
treadmill training.
It has recently been recorded that dynamometry (rather than manual muscle scores) should be
used to assess changes in voluntary function in incomplete SCI patients (8). Therefore we
will employ this approach in this study. Following a spinal injury there is a rapid decline
in bone mineral density which increases the risk of fracture following minor trauma.
Therefore we will also measure the bone density at the epiphyses and shaft of the tibia and
femur to determine if this form of training leads to changes in bone mineral density in this
patient population.
By demonstrating that treadmill training can improve the cardiopulmonary fitness of
individuals with incomplete SCI, their voluntary strength, and bone mineral density, it will
help to provide the evidence that this form of rehabilitation is worthwhile.
By increasing cardiopulmonary fitness it will reduce their risk of developing cardiovascular
disease, a major problem in this population due to their sedentary lifestyle. If it can be
demonstrated to improve their voluntary function it would suggest that their quality of life
and ability to carry out activities of daily living may also improve. Improving their bone
density would consequently reduce their risk of fracture. Therefore the results of this
study will contribute to the quest of trying to improve the overall health and functional
ability of this patient population.
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Allocation: Non-Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Educational/Counseling/Training
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