Journal of Novel Physiotherapies
Open Access

Spinal cord injuries; walking; obstacle crossing training; walking device; rehabilitation; five times sit to stand test; timed up and go; 10 meter walk test; walking index for spinal cord injury

Spinal cord injury (SCI) is one of the most devastating conditions possible [1]. Spinal cord injury (SCI) is possibly the most disruptive and traumatic event that can occur in anyone’s life. SCI poses huge challenges in the form of coping process as well as rehabilitation [2].A multidisciplinary approach is required to restore their life and expe ct the opportunity for an independent and productive future, shown to be beneficial with lower mortality, decreased pressure sores, slightly greater chance of neurologic recovery [3,4]. The annual incidence of spinal cord injury (SCI) worldwide has been reported to be between 11.5 and 57.8 cases per million population [3].

As per report of the International conference (spinal injuries management), the incidence of spinal injury was estimated at 15 new cases per million per year in India. Walking is one of the principal goal after a spinal cord injury and is considered the most important objective by patients and is the principal target of rehabilitation approaches. Depending on the severity of the lesion, most patients have the potential to recover walking.

Independent walking is an ultimate goal that patients with spinal cord injury (SCI) want to achieve. However the patients can improve walking ability after participation in a rehabilitation program, the majority of them do not recover functional walking [5]. Approximately 70% of patients with incomplete spinal cord injury can become ambulatory after participation in a rehabilitation program. However, most of them walk only within the house, walk only at a short distance, require assistance from person or walking device and fail to walk over small obstacle of sizes that are commonly found in homes and communities.

Previous studies indicate that 39% to 75% of independent ambulatory patients with SCI have experienced at least 1 fall during a 6 to 12 month follow up period, with most of the falls occurring as a result of stumbling over an obstacle while walking [6].

To successfully walk over a high obstacle, patients must use a flexor strategy to increase foot clearance, whereas a wide obstacle requires them to lengthen their step length. In addition, to effectively walk over obstacles, patients must be able to balance themselves on double limb support when lifting the walking devices off the ground [7].

It has been seen that obstacle crossing training immediately enhanced functional ability related to walking of ambulatory patients with spinal cord injury. However, randomized controlled trial is needed to support benefits of incorporation of obstacle crossing training into rehabilitation practice [5]. Therefore, purpose of this study is to find out the effectiveness of Obstacle Crossing training and conventional over ground walking training on functional ability among ambulatory patients with spinal cord injury.

A pre and post-test experimental design was used in our study. A sample of 17 spinal cord subjects who met the inclusion criteria and willing to participate in the study voluntarily were recruited in the study. Out of a total of 17 patients, 1 subject was dropped out from study.

Inclusion criteria were as follows: Subjects with sub acute incomplete spinal cord injury (ASIA C, D), having age of 18-65 years, gender: both male and female, subjects should have ability to walk independently with or without walking device or braces, ability to rise from a chair independently with or without the use of hands.

Exclusion Criteria were as follows: Patients with SCI from progressive disease, any neurological or medical disorder that could have negative impacts on ambulatory ability, any sign or symptom that might face participation in study such as pain in musculoskeletal system (>5 on VAS) having any condition in which patient cannot communicate effectively such as head injuries, cognitive issues, active cardiac or pulmonary conditions, Parkinson’s disease, peripheral neuropathy in lower extremities, stroke, psychiatric history or any other active clinical conditions.

All the subjects were given a detailed explanation of the procedure and a written content was obtained. Participants were assessed for their baseline demographics and neurological deficits, that is, motor and sensory scores, level of injury and severity using the American Spinal Injury Association (ASIA). Baseline measurements and post intervention scores are taken after 2 weeks (5 sessions per week). Participants were then randomly divided into two groups by computer generalized randomization and undergo training.

Group 1: (Experimental Group) Obstacle crossing training with conventional over ground walking training.

The test was conducted in a 10 meter walking space. Wooden obstacles (0.5cm wide and 360 cm long) were in 3 heights (1 cm, 4 cm, and 8 cm) to represent obstacles likely found in homes and communities. To provide a high obstacle, each obstacle was placed vertically, to present a wide obstacle, each obstacle was placed flat on the floor. A physiotherapist walked alongside the participant throughout the test [7].

During training, participants were instructed to walk continuously over every obstacle at their self-determined walking speed with or without a walking device, and not to attempt any obstacle that might pose a risk of injury for them. During taking part in the study, participants still received routine treatments from other rehabilitation professionals as needed. They were able to take a period of rest as required [5].

During testing, participants used walking devices, orthosis (e.g., ankle-foot orthosis), and the glasses or corrective lenses that they normally wore during walking [7]. Progression of the task included increasing obstacle frequency, varying rates of obstacle delivery, and increasing obstacle size.

Group 2: (Control Group) conventional over ground walking training.

Different types of walking in parallel bar-forward walking, backward walking, straight line walking, heel to toe walking, sit to stand activity. Rocker board training, unsupported sitting, unsupported walking. Participants were instructed to walk at a self-determined walking speed along a 10-m walkway with or without a walking device continuously as good and as long as they could.

Outcome measures

10 Meters walk test: Participants were instructed to walk a set of distance (10 meters). To minimize acceleration and deceleration effects, the time required over the middle 6m of walkway was recorded. The average time for the three trials was recorded [8]. Five times sit to stand test: Participants sat on an armless chair with their back upright against the backrest of chair, placing their feet flat on the floor, while their arms at the side or on the walking devices. The test measured the time taken to complete five repetitions of the sit to stand maneuver [8, 9].

Timed up and go test: Participants sat against the backrest of the chair and their arms on the arm rest or on the walking device. They were instructed to stand up from the chair, walk at a fast speed for 3m, turn around a cone, walk back and sit down with or without walking device. The average of three trials was recorded [8, 10].

WISCI II- It assess the amount of physical assistance needed, as well as devices required, for walking following paralysis that results following spinal cord injury. They are more precise measure of improvement in walking ability specific to SCI. Rank orders the ability of a person to walk 10m after a spinal cord injury from most to least severe impairment.

Statistical analysis: The Statistical Package of Social Science (SPSS) for windows, version 20.0. The normality of the distribution of the data was tested using the Shapiro-Wilk test. As a result of SW test (p≤0.05), the parametric test analysis used to determine statistical significance between and within the groups. Analysis was done for 16 subjects who completed the study.

Independent t-test was also used to analyze the age, time since injury to check the homogeneity of the subjects in both the groups. Independent t-test was used to analyze the difference between group 1 and group 2. Within group analysis between pre intervention and post intervention was performed using and paired t-test. A significance level of p≤0.05 was fixed the value of confidence interval was set at 95%.

This study was done to compare the effectiveness of obstacle crossing training on gait performance in ambulatory patients with spinal cord injury. The results obtained after 10 treatment sessions over a period of 2 weeks between two groups were compared. The subjects in both the groups were compared with respects to their age, time since injury and ASIA grading from each other pre-intervention. On comparison between both the groups there was no statistically significant different in Walking Index of Spinal Cord Injury (WISCI II), Timed Up and Go Test (TUG) and 10 Meter Walk Test (10MWT) except Five Times Sit to Stand Test (FTSST). Our result are in consensus with the P Wattanapann et al (2013) who quoted that obstacle crossing training may not replicate its results on extrinsic factors like functional ability and fall. Therefore, further studies can be designed to train the patients in community environment where they get hands on exposure to extrinsic factors.

However FTSST has found to be significant between two groups. The potential reason can be attributed to be because of good quadriceps muscle strength of some patients which is the main component to make a patient stand from sitting. As we did not measure strength objectively before intervention so we cannot justify improved FTSST scores was due to our intervention. The potential reasons for not getting the significant difference in majority of the outcome measures might be attributed to various factors. One might be the small sample size, which may have attribute to type-II statistical error and less duration of treatment. As walking and balance are broader domains to be achieved in rehabilitation of spinal cord injury patients. These outcome in depends upon too many factors like age, ASIA grading, time since injury, functional ability and rehabilitation time. Since in our study we only emphasized on obstacle training for 2 weeks due to time constraints which was insufficient to bring significant changes in domains.

On the contrary our results are not in consensus with the W Pramodhyakul et al [5] who found significant difference immediately after obstacle crossing training. To overcome the limitation of immediate effects and better generalization of results we proposed an intervention of 2 weeks and planned for RCT. However at the end we found a longer duration (4weeks or more) of obstacle crossing might yield positive result. Majority of the studies on obstacle crossing training were focused on ASIA D. In our inclusion criteria we added ASIA C as it was as unexplored facet till date.

On comparison within both the groups, the pre and post intervention scores of Walking Index of Spinal Cord Injury, Five Times Sit to Stand Test , Timed Up and Go Test and 10 Meter Walk Test of Obstacle Crossing Training along with conventional over ground walking training (Group 1) have shown statistically significant improvement as compared to their pre intervention scores. The pre and post intervention scores of Walking Index of Spinal Cord Injury, Five Times Sit to Stand Test, Timed Up and Go Test and 10 Meter Walk Test of control group (Group 2) have no statistically significant improvement. This means that there was an improvement in experimental group.

W pramodhyakul et al [5] (2013) studied the immediate effect of obstacle crossing training in independent ambulatory patients with spinal cord injury and conventional over ground walking on functional ability among independent patients with Spinal cord injury and concluded that Obstacle Crossing. Training immediately enhanced functional ability related to walking of ambulatory participants with SCI.

Emily J, et al. [10] (2017) studied the effect of adapt locomotor training including the obstacle training and basic locomotor training and concluded that adapt locomotor training was feasible for chronic spinal cord injury individuals. S Amatacharya et al. [6] (2015) stated that patients failed to walk over an obstacle so incorporation of obstacle crossing in walking training would help patients to successfully manage hazardous environment or make them aware that they are at risk of injury.

However, the statistical analysis between the group showed that the result was significant only for Five Times Sit to Stand Test, but the functional ability gait measures was improved in obstacle crossing training group than the conventional over ground walking training group when examined clinically.

The result shows that there was no significant difference in between the group comparisons, but within group comparisons showed significant improvement in Walking Index of Spinal Cord Injury, Five Times Sit to Stand Test, Timed Up and Go Test and 10 Meter Walk Test, the mean difference in all domains were more in the experimental group as compared to the controlled group. The study concluded that Obstacle Crossing Training shall be incorporated for gait and walking training with other rehabilitation procedures on functional ability and gait performance in individual with incomplete spinal cord injury.

• The sample size was small to establish the effectiveness of Obstacle Crossing Training statically. Future research with a large sample may help to establish the effectiveness of obstacle crossing training on functional ability among patients with spinal cord injury.

• The duration of the obstacle crossing training could have been long to show the significant change. Also, no follow up measures were taken to assess the retention of the gait and functional ability improvement over a longer period of time.

Not applicable.

Author declares no conflict of interest.

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