Journal List > Ann Rehabil Med > v.43(5) > 1150767

Park, Lee, Kim, Lee, and Kim: Effect of Decreased Skeletal Muscle Index and Hand Grip Strength on Functional Recovery in Subacute Ambulatory Stroke Patients

Abstract

Objective

To investigate the effect of decreased Skeletal Muscle Index (SMI) and hand grip strength on functional recovery in subacute ambulatory stroke patients.

Methods

Subacute stroke patients who were referred to the rehabilitation center were recruited. Decreased SMI and hand grip strength were diagnosed according to the Asian Working Group on Sarcopenia. Diagnostic criteria were decreased SMI and decreased unaffected hand grip strength. SMI was measured by bioelectrical impedance analysis. Unaffected hand grip strength was measured with a hand dynamometer. Patients were divided into two groups, decreased group (DG) and not-decreased group (NDG), according to the presence of decreased SMI and hand grip strength. Both groups received conventional stroke rehabilitation for 3 weeks. All patients were evaluated at the baseline and at 3 weeks after treatment. Functional status was evaluated with 4-meter walk test (4MWT), 6-minute walk test (6MWT), Timed Up and Go test (TUG), and Modified Barthel Index (MBI).

Results

Both groups showed improvement in 4MWT, TUG, and MBI. NDG showed improvement in 6MWT. Comparing improvements between the two groups, NDG showed more improvement in 6MWT and TUG than DG.

Conclusion

The presence of decreased SMI and hand grip strength had negative effects on functional recovery in subacute ambulatory stroke patients.

INTRODUCTION

Decreased Skeletal Muscle Index (SMI) and hand grip strength are major diagnostic components of sarcopenia. Characteristics of patients with decreased muscle mass and strength are expected to be similar to those of patients with sarcopenia. Sarcopenia was first introduced by Rosenberg in 1989 [1]. It was described as a general loss of muscle mass that occurred with advancing age. The definition of sarcopenia has evolved to account for body size, body fat, strength, and functions [2-5]. Some studies have reported that the loss of muscle mass and muscle function or the presence of sarcopenia is related to functional decline in the elderly [6,7]. Although the prevalence of sarcopenia has some variations due to different definitions, tools of diagnosis, and patient populations, the European Working Group on Sarcopenia in Older People (EWGSOP) has reported a prevalence of up to 29% in elderly community-dwelling populations and a prevalence of 14%–33% in long-term care populations [8]. Among various factors causing sarcopenia, advanced age has been consistently suggested as a major risk factor for sarcopenia [9–14].
Stroke is substantially prevalent among older patients. The risk of stroke rapidly rises with age, doubling each decade after age 55 [15]. As stroke and sarcopenia share the same risk factor which is age, they might have common comorbid state of diseases. In addition, these two diseases might influence each other’s conditions. Nevertheless, there are few studies about the comorbidity of sarcopenia and stroke. Only several studies have reported the relationship between the two diseases about stroke-related sarcopenia [16,17]. These studies have reported that stroke-related sarcopenia has a number of features distinguishing from age-related sarcopenia, stating that sarcopenia is the chronic consequence of stroke. However, in patients with early stage of stroke, it is not reasonable to regard sarcopenia as a consequence of stroke. In addition, decreased muscle mass and strength might have influence on the recovery of stroke.
Since studies regarding the effect of sarcopenia or decreased muscle mass and strength in the early stage of stroke on recovery were lacking, the objective of this study was to investigate the effect of decreased SMI and hand grip strength on functional recovery in subacute ambulatory stroke patients.

MATERIALS AND METHODS

This study was approved by the Institutional Review Board of Dong-A University Hospital (No. DAUHIRB-19-052). Subacute stroke patients who were referred to rehabilitation center were recruited. Inclusion criterion was the first ever onset of stroke revealed by computed tomography or magnetic resonance images. To evaluate the effect of decreased SMI and hand grip strength on functional recovery in subacute phase of stroke, duration of stroke was limited to be from 1 week to 1 month. To prevent additional loss of muscle mass, patients started bedside rehabilitation with physical therapist in stroke care unit within 72 hours of admission. To accomplish functional evaluations, patient’s status had to be at Functional Ambulation Category (FAC) 3 or 4, indicating that they could walk under supervision or independently on even surface [18]. Patients with severe cognitive impairment having Mini Mental Status Examination (MMSE) score of less than 10, recurrent history of stroke, or other severely ill medical conditions that could have caused decline in muscle mass were excluded.
At admission, patients were evaluated for the presence of decreased SMI and hand grip strength. Diagnosis was made according to the definition agreed by the Asian Working Group for Sarcopenia (AWGS) [19]. For muscle mass measurement, SMI was calculated by Bioelectrical Impedance Analyses (InBody S10; InBody, Cerritos, CA, USA). Cutoff values were less than 7.0 kg/m2 for men and 5.7 kg/m2 for women. For muscle strength measurement, hand grip strength was measured with a hand dynamometer (EH101; Zhongshan Camry Electronic Co. Ltd., Zhongshan, China). Cutoff values were less than 26 kg for men and less than 18 kg for women. Most patients had hemiplegia due to stroke. Grip strength of the dominant hand could not be acquired in some patients. To substitute for dominant hand, unaffected side hand grip strength was measured. Patients were asked to sit in a straight-backed chair with their feet flat on the floor and elbow flexed to 90°. The arm was not supported and the dynamometer was held by the testing hand in a neutral grip. Patients were instructed to squeeze the handle as hard as possible for 3 seconds and the maximum contractile force (kg) was recorded. Tests were performed three times with a 60-second rest period between each trial. Mean value of the three repeated measurements was used for analysis. Although gait speed of less than 0.8 m/s was in AWGS definition, all patients had gait problems due to stroke. Thus, gait speed had to be excluded in evaluation for sarcopenia. According to SMI and grip strength, patients were divided into two groups: decreased group (DG) and not-decreased group (NDG). Both groups received conventional rehabilitation treatments for 3 weeks. Treatments were consisted of stability training, gait training, and resistance training of hip and knee extensors. Stability and gait training were done 30 minutes per session, 2 sessions per day, 10 sessions per week for 3 weeks. Resistance training were done 30 minutes per session, 1 session per day, 5 sessions per week for 3 weeks.
All patients were evaluated at the baseline and at 3 weeks after treatment. Functional status was evaluated with 4-meter walk test (4MWT), 6-minute walk test (6MWT), Timed Up and Go test (TUG), and Modified Barthel Index (MBI). Ten categories of MBI were reorganized to three subcategories: activity of daily living (ADL), incontinence, and mobility. ADL consisted of personal hygiene, bathing, feeding, toileting, and dressing. Incontinence consisted of bowel and bladder control. Mobility consisted of stair-climbing, ambulation, and transfer.
All statistical analyses were conducted using SPSS version 20.0 for Windows (SPSS Inc., Chicago, IL, USA). Chi-squared test was used to compare sex, stroke type, stroke location, FAC, and dominant hand between the two groups. Mann–Whitney U-test was used to compare baseline characteristics and changes of measurements between the two groups. Wilcoxon signed rank test was used to determine changes between measurements in each group. A statistical significance level was set at p<0.05.

RESULTS

During the study period, 146 stroke patients were admitted to our department. A total of 104 patients were excluded from this study. Thus, 42 were recruited (12 in DG and 30 in NDG). Three patients in NDG dropped out due to early discharge. Finally, 39 who completed all treatment sessions were investigated (Fig. 1). Baseline characteristics of these subjects are shown in Table 1. Twelve patients were in DG and 27 patients were in NDG. In DG, 6 were males and 6 were females. In NDG, 15 were males and 12 were females. In DG, 8 patients had infarction and 4 had hemorrhage. In NDG, 17 patients had infarction and 10 had hemorrhage. Mean age was 68.24±12.92 years in DG and 64.85±9.73 years in NDG. Mean stroke duration from the onset of stroke to referral was 14.17±5.42 days in DG and 16.73±5.53 days in NDG. In DG, 5 had stroke in the left side and 7 had it in the right side. In NDG, 11 had stroke in the left side and 16 had it in the right side. In DG, 11 had stroke in supratentorial region and 1 had it in infratentorial region. In NDG, 22 had stroke in supratentorial region and 5 had it in infratentorial region. Mean initial National Institutes of Health Stroke Scale was 4.58±2.53 in DG and 3.85±4.52 in NDG. Mean modified Rankin Scale was 3.25±0.75 in DG and 3.28±0.61 in NDG. Mean duration of stay in stroke care unit was 2.91±0.99 days in DG and 2.78±1.18 days in NDG. Mean penetration-aspiration score following videofluoroscopic swallowing study was 4.25±2.70 in DG and 3.35±2.73 in NDG. No patient in DG was left-handed while one patient in NDG was left-handed. In DG, 8 patients had FAC 3 and four patients had FAC 4. In NDG, 16 patients had FAC 3 and 11 had FAC 4. Mean MMSE was 18.50±4.03 in DG and 18.85±3.92 in NDG. Mean SMI of males was 6.55±0.41 kg/m2 in DG and 7.85±0.76 kg/m2 in NDG. Mean SMI of females was 5.32±0.34 kg/m2 in DG and 6.25±0.40 kg/m2 in NDG. Mean unaffected side grip strength of males was 19.52±6.28 kg in DG and 34.63±5.61 kg in NDG. Mean unaffected side grip strength of females was 12.52±3.67 kg in DG and 20.52±3.53 kg in NDG. In functional evaluation, mean 4MWT was 0.65±0.24 m/s in DG and 0.78±0.32 m/s in NDG. Mean 6MWT was 143.52±15.18 m in DG and 155.64±17.85 m in NDG. Mean TUG was 10.15±3.28 seconds in DG and 9.84±3.67 seconds in NDG. Mean MBI was 73.13±9.66 in DG and 75.25±10.57 in NDG. Except for SMI or grip strength, other baseline characteristics showed no statistically significant difference between the two groups.
Changes of measurements at 3 weeks after treatment are shown in Table 2. In DG, 4MWT, TUG, and MBI were improved by 0.78±0.38 m/s, 7.76±2.78 seconds, 82.63±7.16 and 3.67±0.51, respectively. In NDG, 4MWT, 6MWT, TUG, and MBI were improved by 0.98±0.48 m/s, 202.18±20.71 m, 6.12±3.48 seconds, 86.33±9.86, and 3.67±0.48, respectively. NDG showed additional improvement in 6MWT. Scores for three subcategories of MBI were increased in both groups after rehabilitation. In DG, ADL, incontinence, and mobility were improved by 32.58±1.50, 16.67±3.44, 33.25±3.25, respectively. In NDG, ADL, incontinence, and mobility were improved by 33.67±3.51, 16.81±3.19, 35.19±2.54, respectively.
Comparison results of changes in measurements between the two groups are shown in Table 3. In 6MWT, DG showed 28.87±7.71 m changes and NDG showed 47.52±9.55 m changes. In TUG, DG showed -2.48±1.39 second changes and NDG showed -3.78±1.54 second changes. NDG showed significantly more changes in 6MWT and TUG compared to DG.

DISCUSSION

This study found that decreased SMI and hand grip strength had negative effects on functional recovery in subacute ambulatory stroke patients. Patients without decrease of SMI or hand grip strength had additional improvement in 6MWT. When comparing changes between the two groups, only patients without decreased SMI or hand grip strength showed improved changes in 6MWT and TUG.
Some studies have shown that decreased muscle mass and strength can influence function in several medical conditions. In community dwelling older adults, lower SMI was associated with cardiopulmonary functions [20]. In addition, there was a positive correlation between SMI and peak oxygen uptake [20]. Another study has reported that the elderly with sarcopenia is over three times more likely to fall than non-sarcopenic individuals regardless of age, gender, or other confounding factors [21]. Several studies have reported that the presence of sarcopenia in pre-operative state has negative outcomes. Harimoto et al. [22] have reported that patients with decreased muscle mass and strength in liver transplantation have worse liver function, greater blood loss, greater incidence of postoperative complications, and longer hospital stay. Similar results in colorectal cancer surgery and orthopedic surgery have also been reported [23,24]. In ankylosing spondylitis, SMI has positive correlation with spine mobility and strength [25]. In peripheral arterial disease, patients with decreased skeletal mass demonstrate decreased mobility and function [26]. In the case of stroke, age-related muscle atrophy has increased risk of dysphagia after stroke [27]. Another study has found that unaffected side grip strength is a predictive factor for shortterm functional gain and outcome after stroke [28]. The stronger the grip strength and the greater the difference between admission and discharge MBI, the greater the discharge MBI [28]. In accordance with other studies, our study found that decreased SMI and hand grip strength had negative influence on functional recovery of subacute ambulatory stroke patients. As decreased muscle mass and strength were proven to have negative effect on various medical conditions, they seemed to play the same role in stroke.
The present study evaluated functions mainly associated with gait. Although MBI represented overall function, other measurements including 4MWT, 6MWT, and TUG were also used in this study. For definition of sarcopenia, most studies evaluated gait speed as a representative of physical performance. The international working group on sarcopenia regarded gait speed of less than 1 m/s as poor functional capacity [3]. The special interest group defined sarcopenia by gait speed of less than 0.8 m/s using 4MWT [29]. The AWGS suggested gait speed of 0.8 m/s as the cutoff value for low physical performance by walking 6 m at usual gait speed [19]. The foundation for the national institutes of health provided evidence that usual gait speed of less than 0.8 m/s was associated with reduced survival and increased disability [30]. Because patients in the present study could not walk at usual speed due to hemiplegia, mean gait speed was less than 0.8 m/s in both groups. Although hemiplegia had compromised gait speed, the absolute value of 4MWT after treatment in NDG showed improvement above the cutoff value of sarcopenia, implying that the presence of decreased SMI and hand grip strength had negative effects on stroke recovery. In addition to hemiplegia, decreased muscle mass and strength seemed to have led to decline in gait function. It might be associated with weakened plantar flexion and uncoordinated intersegmental lower limb motion that were observed in age-related sarcopenic elderly [31].
Besides changes of 4MWT, changes of 6MWT and TUG also showed improvement in NDG. 4MWT was used to evaluate gait speed only. 6MWT was used to evaluate gait endurance and TUG was used to evaluate overall functions such as balance and mobility. Although sarcopenia was defined as decreased physical performance by gait speed, there were other functional declines due to sarcopenia. Several studies have shown that sarcopenia has negative effects on balance [21], mobility [25,26], and overall function [28]. Loss of muscle mass and strength could be associated with not only gait speed, but also other functional parameters. Different changes in 6MWT and TUG between the two groups might be associated with decreased endurance and decline in balance and mobility.
There are some reports about association between gait and function. Usual gait speed is highly predictive for the onset of disability, severe mobility limitation, and mortality [32,33]. Poorer TUG is associated with poorer physical/mental function and mood status [34]. In geriatric population, gait speed is significantly slower in acute care settings compared to outpatient settings [35]. It has been shown that gait speed is an important measure in comprehensive geriatric assessment [35]. One study has reported that cutoff value of above 0.85 m/s and 318 m could predict community walking after stroke [36]. According to that study, patients with similar stage as in our study could walk at speed of 0.72 m/s [36]. Stroke patients with decreased SMI and hand grip strength in our study could walk at speed of 0.65 m/s. The reason for slower gait speed might be explained by the effect of decreased muscle mass and strength.
In the present study, patients with decreased SMI and hand grip strength showed lesser extent of recovery. To overcome the effect of these components of sarcopenia, some treatment options are available. Marty et al. [37] have reported that in elderly with sarcopenia, protein, vitamin D, creatine, and amino acid interventions in combination with resistance training can improve muscle mass, strength, and physical performance. Patients in DG of the present study received the same amount of resistance training as those in NDG. Tsekoura et al. [38] have reported that supervised strengthening exercise approach to sarcopenic population is effective for improving SMI, muscle mass, and gait speed. One report on congestive heart failure patients with low muscle mass has shown improvement by resistance training [39]. A recent metaanalysis has shown that low-intensity resistance training can sufficiently enhance the synthesis of muscle proteins, thus recommending it for maintaining skeletal muscle mass in frail older people [40]. It is well accepted that individuals performing resistance training are required to intake adequate protein. In addition, older adults may benefit from increased consumption of branched-chain amino acids [41]. Patients with decreased SMI and hand grip strength might need additional resistance exercise and nutritional support to diminish functional discrepancies.
This study has some limitations. First, this study evaluated the effect of decreased SMI and hand grip strength on stroke recovery only in subacute phase. Additional study in chronic phase may have different results. Second, this study mainly evaluated gait function. However, there could be other functional declines due to decreased muscle mass and hand grip strength such as dysphagia, cognition, spasticity, motor control, and so on. Third, sample size was relatively small. Lastly, even though we tried to minimize the effect of stroke on skeletal muscle and strength by shortening the immobilization period, other factors causing loss of muscle and strength such as denervation, endocrine dysfunction, and inflammatory process after the stroke could not be avoided. Further study might be needed to find out the comprehensive effects of decreased muscle mass and strength on stroke.
In conclusion, the present study found discrepancies in functional recovery between patients with decreases of SMI and hand grip strength and those without such decreases in subacute ambulatory stroke patients. The presence of decreased SMI and hand grip strength had negative effect on functional recovery in subacute ambulatory stroke patients. Thus, appropriate attention and supplementary treatment focusing on muscle mass and strength by strengthening exercise and nutritional support are needed when treating stroke patients with decreased SMI and hand grip strength.

Notes

No potential conflict of interest relevant to this article was reported.

Conceptualization: Park JK, Lee KW. Methodology: Lee KW, Kim SB, Lee JH. Formal analysis: Park JK, Kim YH. Writing – original draft: Park JK. Writing – review and editing: Kim YH. Approval of final manuscript: all authors.

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Fig. 1.
Flowchart showing the enrollment of subjects. MMSE, Mini-Mental State Examination; FAC, Functional Ambulatory Category; SMI, Skeletal Muscle Index.
arm-2019-43-5-535f1.tif
Table 1.
Baseline characteristics of patients enrolled in this study
DG NDG p-value
Sex 0.748
 Male 6 15
 Female 6 12
Stroke type 0.824
 Infarction 8 17
 Hemorrhage 4 10
Age (yr) 68.24±12.92 64.85±9.73 0.628
Stroke location
 Left 5 11 0.952
 Right 7 16
 Supratentorial 11 22 0.820
 Infratentorial 1 5
Initial NIHSS 4.58±2.53 3.85±4.52 0.176
Initial mRS 3.25±0.75 3.28±0.61 0.977
Stroke care unit stay (day) 2.91±0.99 2.78±1.18 0.742
Stroke duration (day) 14.17±5.42 16.73±5.53 0.617
FAC (3/4) 0.661
 3 8 16
 4 4 11
MMSE 18.50±4.03 18.85±3.92 0.822
Penetration-Aspiration score 4.25±2.70 3.35±2.73 0.297
Dominant hand 0.781
 Left 0 1
 Right 12 26
SMI (kg/m2)
 Male 6.55±0.41 7.85±0.76 0.041*
 Female 5.32±0.34 6.25±0.40 0.035*
Grip strength, unaffected (kg)
 Male 19.52±6.28 34.63±5.61 0.029*
 Female 12.52±3.67 20.52±3.53 0.032*
Function
 4MWT (m/s) 0.65±0.24 0.78±0.32 0.198
 6MWT (m) 143.52±15.18 155.64±17.85 0.598
 TUG (s) 10.15±3.28 9.84±3.67 0.354
 MBI 73.13±9.66 75.25±10.57 0.698
  ADL 27.58±4.70 30.44±3.30 0.168
  Incontinence 14.83±6.63 14.33±3.63 0.776
  Mobility 30.92±2.19 31.85±8.08 0.391

Values are presented as mean±standard deviation.

DG, decreased group; NDG, not-decreased group; NIHSS, National Institutes of Health Stroke Scale; FAC, Functional Ambulation Category; MMSE, Mini Mental Status Examination; SMI, Skeletal Muscle Index; 4MWT, 4-meter walk test; 6MWT, 6-minute walk test; TUG, Timed Up and Go test; MBI, Modified Barthel Index; ADL, activity of daily living.

* p<0.05 by Mann-Whitney U-test.

Table 2.
Changes of measurements after treatment
DG
NDG
Baseline After 3 weeks Baseline After 3 weeks
4MWT (m/s) 0.65±0.24 0.78±0.38* 0.78±0.32 0.98±0.48*
6MWT (m) 143.52±15.18 172.52±21.18 155.64±17.85 202.18±20.71*
TUG (s) 10.15±3.28 7.76±2.78* 9.84±3.67 6.12±3.48*
MBI 73.13±9.66 82.63±7.16* 75.25±10.57 86.33±9.86*
 ADL 27.58±4.70 32.58±1.50* 30.44±3.30 33.67±3.51*
 Incontinence 14.83±6.63 16.67±3.44* 14.33±3.63 16.81±3.19*
 Mobility 30.92±2.19 33.25±3.25* 31.85±8.08 35.19±2.54*
FAC 3.42±0.51 3.67±0.49 3.41±0.50 3.67±0.48

Values are presented as mean±standard deviation.

DG, decreased group; NDG, not-decreased group; 4MWT, 4-meter walk test; 6MWT, 6-minute walk test; TUG, Timed Up and Go test; MBI, Modified Barthel Index; ADL, activity of daily living; FAC, Functional Ambulatory Category.

* p<0.05 by Wilcoxon signed-rank test.

Table 3.
Comparison of changes in measurements between the two groups
DG NDG p-value
Δ4MWT (m/s) 0.13±0.08 0.20±0.12 0.137
Δ6MWT (m) 28.87±7.71 47.52±9.55 0.038*
ΔTUG (s) -2.48±1.39 -3.78±1.54 0.045*
ΔMBI 9.62±4.67 11.08±7.96 0.228
 ADL 3.21±4.47 3.26±2.87 0.774
 Incontinence 3.33±3.44 3.48±3.57 0.877
 Mobility 2.33±3.96 3.33±2.36 0.284
ΔFAC 0.25±0.62 0.26±0.44 0.964

Values are presented as mean±standard deviation.

DG, decreased group; NDG, not-decreased group; 4MWT, 4-meter walk test; 6MWT, 6-minute walk test; TUG, Timed Up and Go test ; MBI, Modified Barthel Index; ADL, activity of daily living; FAC, Functional Ambulatory Category.

* p<0.05 by Mann-Whitney U-test.

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