Introduction
Stroke is one of the main causes of hospitalizations and mortality in Brazil and worldwide. In general, it causes some kind of deficiency, either partial or complete1. The motor deficits resulting from this disease cause muscle weakness, reduced mobility, and limited ability to perform functional tasks and affect about 40% of people who do not walk independently in the community2.
It is understood that the non-paretic lower limb has a higher proportion of body weight that results in the oscillation of the orthostatic posture, characterizing an asymmetrical profile in weight transfer and greater oscillations on the paretic side than the non-paretic side, hindering the ability to walk. These changes in gait cause postural instability, limit gait capacity, increasing the risk of falls, and compromising the functional independence of these patients3.
Recovery from walking is the most desired goal for patients and clinicians. For Fritz and Lusardi4, gait speed (GS) is the "sixth vital sign." As a basic clinical parameter, this function is evaluated by the GS test (GST), which is easy to apply, fast, and reliable. In general, the patients with the best performance in GS (>0.80 m/s) are those who present with the lowest deficits, the best functional performance, and greater independence in the activities of daily living (ADLs), being usually independent ambulators in the community. On the other hand, those with poorer performance in GS (<0.80 m/s) are the most neurologically compromised patients, who present higher functional dependence, higher risk of falls, and hospitalization, and, in general, are home ambulators, especially those with GS < 0.40 m/s5,6.
The aim of this research was to verify the relationship between GS and different variables, such as age, injury time, body composition, muscle strength, spasticity, and functional mobility in hemiparetic stroke patients.
Methodology
The study was descriptive correlational7. It was performed at the Center for Neurorehabilitation at Guilherme Guimbala College, in Joinville, Santa Catarina, Brazil. This study was approved by the Ethics Committee for Research Involving Human Beings (number 1.671.505). The participants were informed about the objectives and procedures of the study and signed the free and informed consent form.
Study participants
Consecutive volunteers of both genders aged 35 years and older, with a clinically stable history of stroke, in the subacute (between 3 and 6 months after the event) or chronic phases (more of 6 months after stroke episode) participated in the study. The patients were informed about the evaluation procedures that would be performed in the application of the study and were then invited to participate in the study.
As requisites for participation in the study, the inclusion and exclusion criteria described below were established.
Inclusion criteria
Hemiparetic stroke patients, clinically stable and in the subacute or chronic phases; age range from 35 years; be in agreement and show interest in participating in the project from start to finish; and then, they signed the free and informed consent form.
Exclusion criteria
Patients with hemiparesis due to other pathologies than stroke as well as hemiplegic patients; severe visual and/or auditory impairment; non-cooperative patients and/or patients with severe cognitive deficit assessed by means of the Mini-Mental State Examination with the cutoff points proposed by Bertolucci et al.8; and patients who could not walk independently, even if using walking aid devices such as crutch, cane, or walker were excluded from the study.
Measuring instruments and procedures
REGISTRATION FORM
This form included patient identification data and other general information (name, date of birth, address, telephone number, laterality, use of orthoses, and/or walking aids), sociodemographic data (gender, marital status, ethnicity, level of education, professional status, and profession), as well as clinical information (if the patient had more than one stroke, stroke type and time, main complaint, medications in use, adjuvant treatments, dysfunctions and/or associated pathologies, smoking, alcohol consumption, and family history of the disease) and anthropometric information (height, body mass, and body mass index [BMI]).
Digital Anthropometric Scale and Stadiometer
To measure body mass, a digital Omron® scale, model HBF-514C, BR, duly calibrated, was used, and the unit of measurement was recorded in kilograms (kg). Height was measured by means of a Sanny® stadiometer, model ES2020, manufactured by American Medical do Brasil Ltda., BR. This instrument has an accuracy of 0.1 mL, and the measurement was recorded in meters (m).
The BMI was obtained by means of the ratio between body mass (kg) and height (m) squared. The classification was performed according to the following cutoff points proposed by the World Health Organization (WHO): low weight (<18.50 kg/m2); normal weight (18.50-24.99 kg/m2); overweight (25.00-29.99 kg/m2); Grade I obesity (30.00-34.99 kg/m2); Grade II obesity (35.00-39.99 kg/m2); and Grade III obesity (≥40.0 kg/m2)9.
FUGL-MEYER SCALE (FMS)
The FMS was used to measure the level of motor impairment. It is noteworthy that in the present study only, the section destined to the motor evaluation of the lower limb was used, which includes the analysis of reflex activity, synergic muscle action in flexion and extension, and the movements with and without synergy. The patients were classified according to the degree of motor impairment in severe (0-7), strong (>7-14), moderate (>14-21), and light (>21-28)10.
MODIFIED ASHWORTH SCALE (MAS)
The MAS was used to evaluate the degree of spasticity. It should be noted that only the spasticity of the quadriceps femoris muscle was evaluated.
This scale grades the spasticity in six levels: 0 - there is no increase in muscle tone; 1 - slight increase in muscle tone, manifested by a slight capture and release, or by minimal resistance at the end of the range of motion, when the affected part is moved in flexion or extension; 2 - slight increase in muscle tone, manifested by a slight capture followed by minimal resistance throughout the rest (less than half) of the range of motion; 3 - more accentuated increase in muscle tone during most of the range of motion, but the affected parts are easily moved; 4 - considerable muscle tone increased, difficult passive movement; and 5 - rigid affected parts, in flexion or extension11.
TIMED UP AND GO TEST (TUGT)
The TUGT was used to evaluate functional mobility12,13. The test requires the individual to stand up from a standardized chair with support, walk 3 m in a straight line on the floor, return to the chair, sitting in the initial position, and the time to perform this task is recorded in seconds. In addition to being a quick and easy to apply test, it has been widely used in individuals with stroke14-17, as it has proven to be a valid and highly reliable instrument in the evaluation of this population.
At present, the TUGT is considered the best predictor of participation of individuals with stroke in the ADLs18. The instrument demonstrates good intraexaminer (ICC 0.95) and interexaminer reliability (ICC 0.98)19.
GST
GS is considered a fast, practical, and reliable measure. It is related to functional mobility, level of independence, risk of falls, and hospitalization4,6.
The patients were divided into two groups. The first group had the best performance in GST (>0.80 m/s). In general, these patients are community ambulators and are less neurologically compromised. The second group, with the worst performance in GST (<0.80 m/s), is patients who present greater neurological impairment, present worse functional performance, risk of falls, and hospitalization, and, in general, are home walkers4,6.
During the GST, the patients were instructed to perform the test as soon as possible on a 10 m path for timing (Fig. 1). To eliminate the effects of acceleration and deceleration in the test, a distance of 3 m was added at the beginning and end of the route. The patient started walking and, after a distance of 3 m, the stopwatch was activated. The time count ended at the 10 m marker, leaving another 3 m left for the patient's deceleration. Therefore, the unit of measurement used for GS was meters per second (m/s).
DYNAMOMETRY
To measure the strength of the extensor (EM) and flexor muscles (FM) knee, a Bonnet chair was prepared and adapted with a load cell, which is attached to the chair, allowing bilateral evaluation of the strength of the muscle groups mentioned above. A load cell of the IWM® brand, model GL-100 China, was used, which acts through the compression mechanism, with a capacity of 60 kg, properly calibrated. This cell has a division of 0.1 kg and sensitivity of 2.0 mV/V. Its excitation voltage is from 6 to 10 V.
The positioning of the patient and the equipment was different for each muscle group. For EM, the following positioning was adopted: patient seated in the chair, with the trunk supported on the backrest, with legs hanging, hip at 110° flexion in relation to the trunk and knees flexed at 90°20-23; for this muscle group, the equipment (sensor with the load cell) was positioned at the level of the distal third of the leg (just above the malleolar region), on the anterior face. For FM, it was used: patient seated in the chair, with the trunk supported on the backrest, hip at 110° flexion in relation to the trunk and knees flexed at 60°24; for this muscle group, the equipment was also positioned at the level of the distal third of the leg, however, on the posterior face. Figure 2 illustrates the positioning of the patient and the sensor with the load cell during the procedures.
Three bilateral measurements of each muscle group were performed in maximum voluntary isometric contraction during a period of 5 s21,25, with an interval of 60 s between each measurement. It is noteworthy that the measurements were taken on alternate days and, as a reference, the arithmetic mean resulting from the three evaluations was recorded. The patient was instructed to perform as much force as possible from a green signal projected on the screen, which indicated the beginning of the test, and this strength should be maintained until the disappearance of the green color, indicating the end of the test.
Data analysis
Data tabulation and analysis were performed using GraphPad Prism 6® software, determining minimum, maximum, mean, and standard deviation values. To verify the relationship between the study variables (GS vs. other variables), we used Pearson's correlation test for parametric variables (BMI, TUGT, and muscle strength measurements through dynamometry) and Spearman's correlation test for non-parametric data (FMS and MAS). The significance level of 95% (p < 0.05) was considered.
Results
Twenty-four patients participated in the study, 12 men and 12 women with post-stroke hemiparesis. All patients suffered an ischemic stroke confirmed by examination of images such as computed tomography and/or magnetic resonance imaging. Two groups of patients were formed, those who walked with GS higher than 0.80 m/s and another with GS lower than 0.80 m/s. Patients are seen at a physical therapy service twice a week regularly.
Next, data from the statistical analysis of the group with the best performance in GST (> 0.80 m/s) are presented. Tables 1 and 2 show descriptive statistics and correlation analysis data. Eight patients participated in this group, five men and three women.
Age | ST | BMI | TUGT | GST | FMS | MAS | ESp | ESnp | FSp | FSnp | |
---|---|---|---|---|---|---|---|---|---|---|---|
M | 59.3 | 23.3 | 27.4 | 12.7 | 1.06 | 25.6 | 0.50 | 17.6 | 24.0 | 7.9 | 12.0 |
DP | 10.3 | 35.7 | 5.68 | 2.71 | 0.27 | 3.0 | 0.76 | 10.2 | 7.9 | 5.9 | 6.4 |
Minimum | 46.0 | 4.00 | 17.6 | 8.62 | 0.80 | 19.0 | 0.0 | 7.30 | 13.3 | 2.8 | 5.4 |
Maximum | 70.0 | 108 | 37.7 | 18.4 | 1.64 | 28.0 | 2.00 | 35.3 | 36.2 | 18.3 | 23.9 |
ST: stroke time (months); BMI: body mass index (kg/m2), TUGT: timed up and go test (time in s); GST: gait speed test in 10 m (m/s); FMS: Fugl-Meyer scale - lower limb section (0-28); MAS: Modified Ashworth Scale (0-5); ESp: extensors muscle strength paretic side (kgf); ESnp: extensors muscle strength non-paretic side (kgf); FSp: flexors muscle strength paretic side (kgf); FSnp: flexors muscle strength non-paretic side (kgf).
Age | ST | BMI | TUGT | FMS | MAS | ESp | ESnp | FSp | FSnp | |
---|---|---|---|---|---|---|---|---|---|---|
r | 0.66 | −0.37 | 0.15 | −0.77 | 0.70 | −0.54 | 0.87 | 0.80 | 0.85 | 0.85 |
p | 0.077 | 0.370 | 0.718 | 0.026 | 0.061 | 0.060 | 0.005 | 0.018 | 0.007 | 0.008 |
ST: Stroke time (months); BMI: body mass index (kg/m2); TUGT: timed up and go test (time in s); FMS: Fugl-Meyer scale - lower limb section (0-28); MAS: Modified Ashworth Scale (0-5); ESp: Extensors muscle strength paretic side (kgf); ESnp: Extensors muscle strength non-paretic side (kgf); FSp: flexors muscle strength paretic side (kgf); FSnp: flexors muscle strength non-paretic side (kgf).
Then, data from the statistical analysis of patients who wander with GST < 0.80 m/s (16 patients, 7 men and 9 women) are presented. Tables 3 and 4 present the descriptive statistics and correlation analysis data.
Age | ST | BMI | TUGT | GST | FMS | MAS | ESp | ESnp | FSp | FSnp | |
---|---|---|---|---|---|---|---|---|---|---|---|
M | 56.8 | 20.1 | 28.9 | 35.1 | 0.38 | 19.5 | 1.9 | 12.6 | 23.3 | 4.9 | 11.7 |
DP | 10.8 | 22.5 | 8.34 | 20.7 | 0.2 | 4.9 | 1.7 | 7.3 | 8.0 | 3.0 | 4.6 |
Minimum | 37.0 | 3.0 | 18.4 | 14.2 | 0.1 | 11.0 | 0.0 | 3.8 | 11.4 | 0.8 | 6.4 |
Maximum | 79.0 | 96.0 | 44.8 | 88.5 | 0.7 | 27.0 | 5.0 | 28.1 | 39.6 | 12.8 | 21.1 |
ST: stroke time (months); BMI: body mass index (kg/m2); TUGT: timed up and go test (time in s); GST: gait speed test in 10 m (m/s); FMS: Fugl-Meyer scale - lower limb section (0-28); MAS: Modified Ashworth Scale (0-5); ESp: extensors muscle strength paretic side (kgf); ESnp: extensors muscle strength non-paretic side (kgf); FSp: flexors muscle strength paretic side (kgf): FSnp: flexors muscle strength non-paretic side (kgf).
Age | ST | BMI | TUGT | FMS | MAS | ESp | ESnp | FSp | FSnp | |
---|---|---|---|---|---|---|---|---|---|---|
r | 0.27 | −0.26 | −0.03 | −0.87 | 0.69 | −0.61 | 0.55 | 0.30 | 0.39 | 0.13 |
p | 0.316 | 0.335 | 0.928 | 0.000 | 0.004 | 0.010 | 0.026 | 0.257 | 0.135 | 0.637 |
ST: stroke time (months); BMI: body mass index (kg/m2); TUGT: timed up and go test (time in s); FMS: Fugl-Meyer scale - lower limb section (0-28); MAS: Modified Ashworth Scale (0-5); ESp: Extensors muscle strength paretic side (kgf); ESnp: Extensors muscle strength non-paretic side (kgf); FSp: Flexors muscle strength paretic side (kgf); FSnp: flexors muscle strength non-paretic side (kgf).
The groups when stratified based on GST were not different in terms of epidemiological and general clinical aspects, such as age, post-stroke injury time, and BMI. However, when compared to the other variables between the groups such as GST, TUGT, FMS, and MAS, it is observed that there is a significant difference between them. As for muscle strength tests, no significant difference was observed, although on the paretic side, the group with the worst performance in GS tests had a deficit of 28.4% in extensors muscles and 38.0% in flexors muscles lower than the group with the best performance. This may have an important clinical repercussion, as indicated in correlation tests involving this variable.
Discussion
Walking in hemiparetic patients after stroke is described as uncoordinated, arrhythmic, and unbalanced5,26,27. The GS is a clinical and biomechanical parameter that quickly, easily, and reliably translates performance in this primary function. In fact, there is a relationship between the performance in GST and the level of functional independence, risk of falls, and hospitalization of these patients5,6.
In individuals affected by stroke, although GS is a determining factor of functional capacity, other variables may be associated with functional deficit, such as anthropometric characteristics28. In our study, the correlation between BMI and GS was weak and not significant for both groups. Similar results were found in a study by Sheffler et al.29, where the influence of body mass on hemiparetic gait was evaluated. Although overweight may negatively affect post-stroke gait, the authors find no association between BMI and specific spatial-temporal parameters, including GS, cadence, double support time, or step length when measured over short distances.
Muscle strength and endurance seem to play a special role for good performance in this function, and this directly affects the functional capacity6. Although the paretic side is the most affected in relation to muscle strength, the non-paretic side may also show reduced strength. In individuals affected by stroke, the strength deficits range from 17% to 40% on the paretic side and from 5% to 40% on the non-paretic side. It is worth noting that this asymmetry of strength can also occur in healthy people, but in a smaller proportion (up to 10%)27.
In a study conducted by Hyun et al.30, the strength of the knee extensors and the dynamic balance was evaluated as predictors of walking in hemiparetic patients due to stroke in the acute phase. Fifty-three patients participated in the study, who were stratified in domestic ambulators (GST < 0.4 m/s) and community ambulators (GST > 0.4 m/s). The function of balance and functional mobility was evaluated using the Berg Balance Scale and the TUGT, respectively. The strength of the extensors and flexors knee was measured with an isokinetic dynamometer. The results found in the study indicate that the balance and strength of the knee extensors are the strongest predictors for the gait function of patients. However, the authors point out that the results may vary according to the severity of the gait. These findings corroborate those obtained in our study, where in the group with the best performance in GST (> 0.8 m/s), there was a strong and significant correlation (r ≥ 0.80) of both muscle groups, flexors and extensors knee on the paretic side. Moreover, for the other group, with poorer performance in GST (< 0.8 m/s), the extensors knee strength also showed significant correlation.
Still regarding the evaluation of muscle strength, it is important to comment on the asymmetry found between the paretic and non-paretic sides. In the group with the best performance in GST, there was less asymmetry, 26.7% in the extensors muscles knee and 34.2% lower in the flexors muscles side than in the non-paretic side. In the group with the worst performance in GST, this asymmetry is remarkable. An asymmetry of 45.9% was found in the extensors muscles and 58.1% in the flexors muscles in relation to the non-paretic side. In some cases, this asymmetry is even higher than that observed in the literature27.
As for spasticity, as noted above, only the extensors muscles knee was evaluated by the MAS. This muscle usually presents an abnormal hyperactivity, which manifests, especially in the balance phase, during acceleration and intermediate balance of gait31. Spasticity is considered a common manifestation that results from abnormal neuroplasticity and intrinsic changes in the affected muscles32. Wissel et al.33 pointed out that the presence of spasticity is associated with complaints of pain, greater impairment of muscle strength, and lower levels of functional independence. Our study corroborates these findings and indicates that this combination of higher degrees of spasticity with higher strength deficit is indicators of worse performance.
Another parameter that is strong and significantly related to the performance in GST is functional mobility, which in this study was evaluated by TUGT. Persson et al.34 indicated that the TUGT is a sensitive test to detect changes in functional mobility in this special population, through time. This test is practical, fast, and low cost and has been widely used, especially in the elderly and hemiparetic patients evaluation. It allows estimating performance in several daily tasks such as getting up from a chair, walking, turning on one's own axis, and sitting down35.
Conclusion
The study shows that there is a strong and significant relationship between GS and the degree of paresis, spasticity, and functional mobility.
The combination of an important motor deficit ex pressed by greater asymmetry of strength muscle between the paretic and non-paretic sides, and a greater degree of spasticity indicates worse gait performance.
We must improve evaluation of strength and tonus muscle to develop programs that emphasize increased strength and management of spasticity. A careful evaluation, followed by an adequate intervention, will certainly bring benefits to the locomotion these patients, and this is crucial to achieve this goal so desired by patients seeking a rehabilitation service.
These results should be viewed with caution, as the small number of patients evaluated is a limitation. New studies should be carried out with a larger number of participants, as well as the analysis of other variables not controlled here.