Arms contribution in Sit-To-Stand (SitTS) is determined by the legs’ muscle condition. Several compensating strategies were discovered in efforts to achieve complete SitTS cycles. These findings triangulate the spinal cord injury (SCI) persons’ biomechanical measures with their subjective feeling of load borne by both their limbs throughout the SitTS approaches.
Execution of Sit-to-Stand (SitTS) in incomplete spinal cord injury (SCI) patients involves motor function in both upper and lower extremities. The use of arm support, in particular, is a significant assistive factor while executing SitTS movement in SCI population. In addition, the application of functional electrical stimulation (FES) onto quadriceps and gluteus maximus muscles is one of the prescribed management for incomplete SCI to improve muscle action for simple lower limb movements. However, the relative contribution of upper and lower extremities during SitTS has not been thoroughly investigated. Two motor incomplete SCI paraplegics performed repetitive SitTS to fatigue exercise challenge. Their performance was investigated as a mixed-method case-control study comparing SitTS with and without the assistance of FES. Three sets of SitTS tests were completed with 5-min resting period allocated in between sets, with mechanomyography (MMG) sensors attached over the rectus femoris muscles bilaterally. The exercise was separated into 2 sessions; Day 1 for voluntary SitTS and Day 2 for FES-assisted SitTS. Questionnaires were conducted after every session to gather the participants' input about their repetitive SitTS experience. The analysis confirmed that a SitTS cycle could be divided into three phases; Phase 1 (Preparation to stand), Phase 2 (Seat-off), and Phase 3 (Initiation of hip extension), which contributed to 23% ± 7%, 16% ± 4% and 61% ± 6% of the SitTS cycle, respectively. The contribution of arms and legs during SitTS movement varied in different participants based on their legs' Medical Research Council (MRC) muscle grade. In particular, the applied arm forces start to increase clearly when the leg forces start to decline during standing. This finding is supported by the significantly reduced MMG signal indicating leg muscle fatigue and their reported feeling of tiredness.
Sit-To-Stand (SitTS) is a significant movement in a human's activity of daily living (ADL). It is also a prerequisite for basic functional activities such as standing, transferring, and walking. For patients with incomplete spinal cord injury (SCI), paraplegics in particular, SitTS exercise is a crucial activity for their functional independence1,2. This exercise is essential for independence training, which eventually helps SCI population to improve their quality of life. In order to perform a sufficient and adequate SitTS exercise, the knowledge regarding their biomechanics and muscle activity should be feasibly measurable during the training.
In a clinical rehabilitation program, SCI patients with grade American Spinal Cord Injury Association (ASIA) Impairment Scale, AIS C have a better progression and chance of recovering their motor function than those with grade AIS B, who has complete motor deficits. The SitTS performance plays an important measure in an SCI patient to indicate their motor functionality during the recovery process3. However, SCI AIS C patients require both support from the upper and lower limbs to achieve successful series of repeated SitTS movements. The upper limb support plays an important role in unloading the knees while providing adequate lifting forces and assuring the body balance during the exercise4.
The purpose of this study is to describe the biomechanical contributions of arms and legs throughout repetitive SitTS in incomplete SCI individuals. This study positions the biomechanical analysis in relation to the participants' subjective sense of their arms and legs muscle performance and feelings of 'effort and tiredness' throughout the SitTS exercise.
Many previous SitTS studies only concentrated on investigating the kinematics and kinetics aspects of the activity4,5,6,7. In a wider context of SitTS training, the development of this method which includes the instrumented standing frame (SF) and force plate analysis, could lead researchers to assess both upper and lower limb contribution of other populations such as stroke, elderly, and patients with osteoarthritis8,9,10. A previous study by Zoulias et al., instrumented custom-built hardware and software of SF presented a large frame design11. This method can be challenging to replicate. Hence this SitTS study highlighted a portable instrumented SF that can be adopted by other researchers with an existing motion analysis laboratory setup.
The SitTS exercise and informed consent in this manuscript are described under ethical consideration by University of Malaya Medical Centre Ethics Committee (2017119-4828)12. Study procedures were explained in detail to each participant, and written informed consent was obtained before beginning the SitTS trial. This study was conducted as mixed-mode, where quantitative data were obtained using biomechanical analysis, whereas subjective scores were obtained from feedback sessions (of the participants) and audio recordings (of the researcher-participants interactions during the study). This pilot study compared the participant's contributions of arms and legs in SitTS exercise voluntarily versus their performance with the presence of FES.
1. Participants selection
2. SitTS experimental setup
NOTE: In this SitTS exercise, three parameters will be recorded. The first parameter is arms force and the second parameter is legs force. The third parameter is mechanomyography (MMG) which looks at the rectus femoris muscle activity.
3. SitTS protocol
4. Data acquisition and analysis
5. Feedback session
A total of 399 and 463 SitTS trials were completed without and with FES assisted correspondingly. The trials that contributed to each set are tabulated in Table 2. The participants could perform more SitTS trials with the presence of electrical stimulation on their legs, i.e., FES. Overall, both participants managed to perform more SitTS trials with the aid of FES. This suggests that FES helps in stimulating participants' quadriceps to execute SitTS action in a prolonged period20. There were three phases of SitTS described in this study. Phase 1 began with the start of the movement and lasted when the buttocks left the seat. Phase 2 referred to the time when buttocks leave the seat up to the maximum hip flexion event. Phase 3 denoted from the beginning of hip extension and lasted until the end of the movement. Each phase contributed 23% ± 7% for Phase 1, 16% ± 4% for Phase 2, and 61% ± 6% for Phase 3 of the SitTS cycle, as illustrated in Figure 3. Three phases of SitTS were defined in this study following an earlier study by Kagaya et al. that had a similar protocol of exercise in which SCI participants used the aid of hand-assists21. Phase 1 displayed the highest standard deviation (SD) of its contribution with ±7% proving that participants recruit diverse strategies to initiate buttocks lift-up from the seat throughout the study.
Overall, the mean time of FES-SitTS cycle between the initial trial in each set was identified to be significantly shorter (t = 1.28 s) as compared to the final trials (t = 1.66 s) in each set (p < 0.0005), as shown in Table 3. This indicates slower standing-up movement, most likely due to muscle tiredness or fatigue, and the added effort to stabilize themselves during the standing-up movement. FES-evoked exercise caused participants to be more prone to fatigue towards the end of their SitTS action in each set. Meanwhile, a non-significant difference of mean time was observed during voluntary SitTS activity p = 0.571, which suggests that there are several strategies of SitTS accomplishment initiated by participants throughout the voluntary SitTS session. There were some factors that might contribute to these several strategies, which consumed diverse time allocation. Participants' feet placement22,23 and trunk control22 during the early phase of voluntary SitTS played a major contribution as there were a few times participants tended to lift one of the feet and sway their trunk from front to back24 first before they started leaving the chair. This is also associated with the previous study by Lee & Lee24 that investigated the forward-and-backward swaying in preparation to stand was affected by the height of the chair.
The presence of negative values at the leg% during the early to middle stage of SitTS (Figure 4A, Figure 5A, Figure 6A, and Figure 7A) were due to the calibration procedure of force plate 2 that was taken while participants' feet were in contact with these force plate. This initialized the stationary sitting force as zero, as their legs were lifted slightly when repositioning in preparation to stand, resulting in the force value appearing negative. Since both participants had the pattern of adjusting their feet position by lifting the leg during the early stage of SitTS, force plate 2 showed a negative magnitude of force which indicated the eliminated force that existed by the feet before the calibration process took place. The habit of adjusting their feet position before actually standing might be a common practice of biomechanical preparation among all, which needs to be considered in other standing-related exercises25. Similarly, Camargos et al. reported that patients need to adopt a spontaneous SitTS strategy which results in higher functional levels25. Additionally, normalized root mean square (RMS)-MMG exhibited a similar graph pattern throughout the study. The amplitude of RMS-MMG was correlated to quadriceps muscle contraction and its force production26. The highest peak amplitude of normalized RMS-MMG described that the quadriceps muscles produced the highest force in between Phase 1 and Phase 2 of SitTS cycle (Figure 4C, Figure 5C, Figure 6C, and Figure 7C ). These highest forces were generated by the participants to prepare their legs for early knee joint stabilization before its extension. In addition, quadriceps muscles were observed to produce greater muscle contraction during the late phase of SitTS to help the legs to stabilize the feet and legs for standing posture22,25.
Furthermore, muscle contraction at the right leg was significantly higher as compared to the left leg for both participants during voluntary SitTS action (p < 0.05). These voluntary SitTS allowed them to use all strength from their limbs, especially from their legs, to execute the SitTS action. Hence both participants were assumed to use more effort on the right leg during these actions. In addition, Participant 1 had contracture of the right quadriceps muscle, which resulted in continuous contraction, thereby generating constant muscle force throughout the experiment.
Meanwhile, Table 4 summarises the answers given by the participants regarding their experience in performing the SitTS exercise. The contribution of arms and legs during SitTS movement varied among the participants based on their MRC muscle strength grade. In this study, the lower limbs' muscle strength for each participant is accessible in step 1.1.2. Hence in this step, the SCI participants' arms and legs contributions are presented individually, as shown in Figure 4 to Figure 7.
Biomechanical contributions of arms versus legs
Overall, throughout the SitTS action in both sessions, Participant 1's arm percentage showed a higher contribution in total body weight percentage as compared to his leg percentage (Figure 4A and Figure 5A). This result occurred as Participant 1 completely utilized his strength in both arms and left legs to bring up his upper body for standing. Both arms were used to support the left leg in providing stability for the whole body. Therefore, he endured most of his body weight using the arms and SF during the accomplishment of SitTS. Participant 1 had several joint contractures in the right knee and right ankle of the leg. As a result, Participant 1 did not put his body weight onto the right leg during the exercise. By comparing the two sessions, a higher contribution of Participant 1's arm percentage was presented during FES SitTS. This result proposes that his arms were utilized to control a full right knee extension that was stimulated by FES. Even though the muscles were electrically-stimulated in Participant 1, his right knee could not provide full knee extension during the end phase of SitTS. This statement is validated as the right knee angle did not reach normal knee extension range of motion (0° to 5°) during late phase of SitTS, as shown in Figure 4B and Figure 5B.
For Participant 2, there were huge increases of leg percentage from Phase 2 to Phase 3 of SitTS in both sessions. In general, Participant 2 had a better score of MRC muscle grade for legs as compared to Participant 1. As a result, Participant 2's arms and legs contribution pattern changed drastically throughout the SitTS action. Towards the end of the SitTS cycle, Participant 2's legs contributed 79.5% (without FES) and 78.8% (with FES) of the load-bearing, proving that her legs provided good weight-bearing to support her whole body during standing. The results suggested that the arms play a minor role in assisting Participant 2 during SitTS study.
In contrast, by comparing 2 sessions (Figure 6A and Figure 7A), a higher contribution of leg% during the end phase of voluntary SitTS proposed that Participant 2 exerted more strength onto her legs to bear the full body weight. In addition, during the final set of voluntary SitTS, Participant 2 exhibited a smaller knee angle during the early stage of the movement (Figure 6B). This finding suggests that towards the final set of voluntary SitTS tasks, Participant 2 compensated her fatigued state by positioning a smaller knee angle that provided lesser pressure on the feet27. In addition, FES stimulation helped Participant 2 perform SitTS by giving less strength exertion to the legs at the force plate during the end phase of session 2.
Subjective feedback
Among the 3 phases, which included 5 events of SitTS (Figure 3), both participants reported that their arms were the most tired during Event B while their legs were most tired during Event C. These 2 events were closely related to each other as both events occurred at Phase 2 of the SitTS motion. During Event B, i.e., when the buttocks lift-up was initiated, Participant 1 was observed to increase arm strength to lift his upper body from the chair (Figure 4A and Figure 5A). Meanwhile for Participant 2, the maximum contribution of arms was detected during Event B for FES-assisted SitTS (Figure 7A). These coincided with the accomplishment of SitTS action that was continued with the preparation of legs to stand without falling during Event C as observed by the motion analysis system (Figure 4B, Figure 5B, Figure 6B, and Figure 7B). These assumptions were verified as both participants' knee angles started to decrease (knee started to extend). These ideas are supported by participants' opinions during the interview. Participant 2 selected Event A in both conditions as the most stable position. The answer given by Participant 2 was expected as she felt secure while sitting on the chair.
Conversely, without the help of FES, Participant 1 felt most stable during Event C. This result was due to the presence of arm strength that assisted him to carry his body weight upward. While with the aid of FES, Event E was chosen as the most stable as he agreed that FES had helped him to straighten both his knees and allowed him to stand up confidently. Besides that, Participant 1 experienced the least stable position at Event E during voluntary SitTS due to his weak right leg (Quadriceps MRC muscle grade: Grade 2). These statements were proven by his major arms contribution towards the end of SitTS phase, as illustrated biomechanically in Figure 4A and Figure 5A. Next, with the aid of FES, Participant 1 felt the least stable during Event B, as reflected in Figure 3. Even with the presence of FES, Participant 1 believed that these events were where the initial transition of his body moving from sitting to standing. Meanwhile, Participant 2 felt the least stable during Event C in both sessions. These corresponded with the arrangement of both legs and arms to stand without falling as observed by the motion analysis system and illustrated in Figure 6 and Figure 7. The verbal expression was biomechanically verified as Participant 2's knee started to fully extend (Figure 6B and Figure 7B).
In addition, the normalized RMS-MMG of the quadriceps muscle showed a peak value during Event C. This indicated his effort to straighten his body to increase the hip angle when standing. Additionally, during the final trial of FES assisted SitTS session (Figure 7C), both quadriceps muscles displayed a small constant normalized RMS-MMG value throughout SitTS phase as agreed by Participant 2, who already felt tired, which emphasized the point of using the upper body to straighten herself in the final few standing process. In addition, following the FES-assisted SitTS session, both participants were confident with the use of FES device. Overall, participants experienced positive outcomes during their exercise.
Figure 1: Custom-made chair setup. The custom-made chair was placed inside force plate 1. Both feet were placed on force plate 2. This figure shows the overall setup of the participant's initial position on the custom-made chair and instrumented SF with the force plates. Please click here to view a larger version of this figure.
Figure 2: Placement of the force sensor. (A) An instrumented force sensor was placed at the bottom part of the rubber stopper of SF (side view). (B) The placement of four instrumented force sensors (top view). The figure presents the placement of the force sensor at the bottom part of the rubber stopper of the SF. Please click here to view a larger version of this figure.
Figure 3: A cycle of SitTS activity assisted by SF. The figure describes a complete cycle of SitTS with the presence of a standing frame. Please click here to view a larger version of this figure.
Figure 4: Participant 1's body weight contribution, knee flexion angle, and normalized quadriceps RMS-MMG during voluntary SitTS (Set 1-Initial Trial versus Set 3-Final Trial). The figure illustrates the parameters obtained by Participant 1 during the voluntary SitTS exercise. Please click here to view a larger version of this figure.
Figure 5: Participant 1's body weight contribution, knee flexion angle, and normalized quadriceps RMS-MMG during assisted FES SitTS (Set 1-Initial Trial versus Set 3-Final Trial). The figure explains the parameters obtained by Participant 1 during FES assisted SitTS exercise. Please click here to view a larger version of this figure.
Figure 6: Participant 2's body weight contribution, knee flexion angle, and normalized quadriceps RMS-MMG during voluntary SitTS (Set 1-Initial Trial versus Set 3-Final Trial). The figure illustrates the parameters obtained by Participant 2 during the voluntary SitTS exercise. Please click here to view a larger version of this figure.
Figure 7: Participant 2's body weight contribution, knee flexion angle, and normalized quadriceps RMS-MMG during assisted FES SitTS (Set 1-Initial Trial versus Set 3-Final Trial). The figure explains the parameters obtained by Participant 2 during FES assisted SitTS exercise. Please click here to view a larger version of this figure.
Figure 8: The condition of SCI participants lifting the leg hence producing the negative value of the legs force during the early phase of SitTS. The figure verifies the negative value obtains from the legs' force when participant tries to lift the heel during the initial phase of SitTS. Please click here to view a larger version of this figure.
Figure 9: The combination of the determinants in the SitTS experiment. The figure concludes the combined parameters involved in the SitTS study. Please click here to view a larger version of this figure.
Participant | Leg | FES current (mA) | |
Quadriceps | Gluteal Maximus | ||
1 | R | 58 | 46 |
L | 46 | 46 | |
2 | R | 35 | 28 |
L | 35 | 28 |
Table 1: FES current stimulated during SitTS study. The table shows the amplitude of FES current for each participant on the quadriceps and gluteal maximus muscle.
Participant | Number of SitTS trials | |||||
No FES | FES | |||||
Set 1 | Set 2 | Set 3 | Set 1 | Set 2 | Set 3 | |
1 | 96 | 30 | 31 | 96 | 61 | 36 |
2 | 95 | 92 | 55 | 89 | 91 | 90 |
Table 2: Number of completed trials of SitTS movements by two SCI individuals. The table provides the total number of SitTS trials by the participants.
Trials | N | No FES | FES |
Mean time (s) | Mean time (s) | ||
Initial | 60 | 1.57 ± 0.244 | 1.28 ± 0.123a |
Final | 60 | 1.84 ± 0.210 | 1.66 ± 0.295a |
Table 3: Mean time for a complete cycle of SitTS during initial and final trials in each set. The table presents the mean time taken for participants to complete a cycle of SitTS during initial and final trials in each set. An independent sample t-test was done, values were given as mean ± SD (N = 60). Means with superscripts 'a' were significant (p < 0.0005).
Participant 1 | Participant 2 | ||||||
Without FES | With FES | Without FES | With FES | ||||
Which event(s) do you think is the most tiring for your upper limbs? | B | B | B | B | |||
Which event(s) do you think is the most tiring for your lower limbs? | C | C | C | C | |||
Which event(s) do you think is the most stable during experiment? | C | E | A | A | |||
Which event(s) do you think is the least stable during experiment | E | B | C | C |
Table 4: Reported stability and fatigue experienced by participants during the accomplishment of SitTS activity. The table shows the answer given by participants regarding their stability and fatigue experienced during SitTS exercise.
The current study demonstrated a bodyweight contribution in SCI individuals during SitTS exercise. This study presented SF as an essential assistive device for paraplegics to do a successful SitTS cycle. Moreover, an instrumented SF was developed to ensure the arms force can be assessed too28. The application of MMG was added in the study to observe prime SitTS muscle that helps researchers to understand SitTS performance better. Furthermore, the feedback session enabled researchers to obtain insights regarding their subjective feeling that support the evidence of quantitative data of the SitTS study.
Representative results showed a negative magnitude of legs force which indicated the eliminated force that existed at the feet before the calibration process took place (Figure 8). These SitTS protocol addressed a limitation of producing negative value of legs' force during the early phase of the exercise. Hence researchers shall anticipate a modification technique of these conditions for future similar SitTS exercises. Additionally, we found that MMG device is more suitable to measure muscle activity during the FES-assisted SitTS exercise as compared to the electromyography (EMG).
MMG proposes an alternative to the utilization of EMG, especially in addressing the sensitive response to skin impedance changes. These impedance fluctuations may be initiated by sweating & incorrect measurements caused by the FES-induced electrical artifacts. While EMG detects the electrical activity of prime muscle of these movements, the presence of electrical stimulation through the muscle during the exercise interferes with the electrical-based motor action potential captured. MMG has been reported to be unaffected by the limitations of EMG29, which makes it advantageous for FES assisted SitTS exercise applications. Wessell et al. reported that MMG is more sensitive to muscle's mechanical responses generated by electrical stimulus compared to EMG, which is affected by other common electrical background30.
This study is limited by two main practical factors. Firstly, only 2 SCI participants fulfilled the inclusion criteria of the SitTS study from our accessible SCI volunteers. The low sample size of the population presents as the limitation of the study as they may not represent the highly different incomplete SCI population. This SitTS pilot study revealed the variation in arms and legs contribution based on their legs' MRC muscle grade. Further studies with more participants with different MRC muscle grade scores are recommended to further explain other potentially varying limbs strategies. Another limitation of this study is the learning effect achieved by the participants after completing the SitTS exercise on Day 1 that may have affected their performance on Day 2. The SitTS exercise was expected to display a higher number of trials on Day 2 since the same training had been done before in Day 1, and FES was applied in addition31. Hence, alternating the treatment between Day 1 and Day 2 (with and without FES) and between participants is ideal for performing the SitTS experiment to ascertain any potential benefit over the other. In this study, the order of the SitTS exercise for Participant 2 was switched (i.e., FES-assisted in Day 1 and voluntary SitTS in Day 2), and these orders shall be alternated with new participants' intake in the future.
The significance of this SitTS study highlighted a portable instrumented SF where it can be easily replicated by other researchers with an existing motion analysis laboratory setup. This technique was supported by another study from Chang et al. that also had instrumented walker with two load cells. Their study focused on the implanted neuroprosthesis users who mostly relied on their upper limbs during stand-to-sit activity28.
Although the FES intervention in SitTS exercise did not obviously alter the biomechanical contributions of arms and legs, the participants' perception of arms and leg fatigue was positively influenced by FES. This may not manifest itself in terms of the ground reaction force or joint angles but was felt by the SCI participants while performing the SitTS exercise. FES application gave participants a major impact to execute the better training performance in terms of more trials can be achieved. Both participants acknowledged the therapeutic benefit of the FES, in particular, the increased muscle mass11; hence they felt more motivated to participate in the SitTS study. The findings of this study provide important insight into FES in the clinical rehabilitation program. FES is believed to have more potential benefits for the post-SCI population.
The results obtained are helpful for researchers and clinicians to interpret the fatigue stage of patients throughout SitTS training in a clinical rehabilitation setting, especially for spinal cord injury patients whose legs were reported to be partially involved when stimulated with FES5. As SitTS training has high outcome specificity2, it is crucial for the training sessions to be fully informed of the movement and muscle performance. Clinicians may use these important parameters to evaluate the fatigue experienced by the targeted participants. Hence the current SitTS results promote a more rational approach to designing a proper SitTS training program.
Since SCI patients do not utilize the momentum transfer manouver5 as do healthy able-bodied people, it becomes more important that the training be done using a complete but relatively simple and portable setup as SCI patients relied heavily on their arm support to perform SitTS28. This should include primary outcome measures recommended in the clinical practice guideline14. Hence this study may benefit the clinical society as it is easy to replicate while taking into account the participants' feedback, at the same time looking at the biomechanics and the muscle activity level through MMG. Other potential outcomes that can be gained from SitTS training are bone mineral density improvement11 and better ground reaction force transfer rate7 with different stimulation parameters. The setup can also be used for safe and controlled stand-to-sit movement28 training among people with incomplete SCI.
The authors have nothing to disclose.
The authors acknowledge and appreciate all the SCI volunteers who participated in this study. This research was supported by the Ministry of Higher Education, Malaysia, and the University of Malaya through Fundamental Research Grant Scheme (FRGS) Grant No. FP002-2020; FRGS/1/2020/SKK0/UM/02/1.
Customade chair | A customade chair was built to following to the force plate's dimension. | ||
FES RehaStim 2 | Hasomed | A device that can stimulate electrical current towards the muscle. | |
FlexiForce A201 | Tekscan, Inc., USA | Force ranges: 0-100 lbs. (440 N) | Force sensors is used to capture arms force at standing frame. |
Foldable standing frame | Height: 70.0 cm – 90.0 cm. | A walking frame that was bought from local medical company. | |
Motion Analysis | Vicon Oxford, UK | A system that records kinematic and kinetics of the activity. | |
Serial port terminal application | CoolTerm | version 1.4.6; Roger Meier's | An application to record the force sensor data. |
Vibromyography software | BIOPAC System Inc., USA | AcqKnowledge 4.3.1 | A software to record and strore raw MMG data. It also function for offline analyses. |
VMG transducers and BIOPAC Vibromyography system | BIOPAC System Inc., USA | BP150 and HLT100C | A device to measure muscle activity. |