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Article

Effect of Lower Extremity Muscle Strength on Aerobic Capacity in Adults with Cerebral Palsy

by
Jungwan You
and
Seungwook Choi
*
Health and Wellness College, Sungshin Women’s University 2, 34 da-gil, Bomun-ro, Seongbuk-gu, Seoul 02844, Korea
*
Author to whom correspondence should be addressed.
Appl. Sci. 2022, 12(9), 4141; https://doi.org/10.3390/app12094141
Submission received: 25 March 2022 / Revised: 14 April 2022 / Accepted: 19 April 2022 / Published: 20 April 2022
(This article belongs to the Special Issue Biotechnology and Sports Engineering II)
Review Reports Versions Notes

Abstract

:
The purpose of this study is to analyze the effect of lower extremity muscle strength of HIP joint and KNEE joint on the aerobic capacity to provide the basic data for developing an exercise program that can effectively improve the aerobic capacity of adults with cerebral palsy (CP) by identifying the part of the lower extremity muscle. A total of 18 ambulant adults with CP were recruited for this study. Seven ambulant adults with CP were excluded because they did not achieve the criteria of maximal exercise. The data from 11 subjects (11 men) with CP were used for the analysis. The mean (±SD) age, height, weight, and BMI of the subjects were 37.00 ± 12.72 years, 170.45 ± 6.37 cm, 67.02 ± 8.62 kg, and 23.09 ± 2.78 kg/m2, respectively. To measure the muscle strength of HIP joint and KNEE joint in lower extremities, the variables of the isokinetic muscle strength and the muscular endurance were performed using the isokinetic equipment (Biodex Co., Shirley, NY, USA). For the isokinetic muscle strength measurement of HIP joint, the 45°/sprotocol indicating the muscle power and the 300°/s protocol indicating the muscle endurance were used. Additionally, the measurement of KNEE joint was performed once on the left and right side, using the protocol of 60°/s indicating the muscle power and 300°/s indicating the muscular endurance. Progressive exercise tests were conducted on the treadmill (Quinton model—4500) using previously developed protocols targeting CP. The initial protocol speeds were 5 km/h−1 and 2 km/h−1 for the subjects who have been classified as Gross Motor Function Classification System (GMFCS) level I and II, respectively. Using a portable cardiopulmonary indirect breath-by-breath calorimetry system (MetaMax 3B; Cortex Biophysik, Leipzig, Germany), pulmonary ventilation (VE), respiratory exchange ratio (RER), and oxygen uptake (VO2) have been persistently measured. HR monitor (Polar Electro, Kempele, Finland polar Co. RS-800) was used to measure heart rate (HR). A correlation analysis was conducted to find out how the lower extremity muscle strength and aerobic capacity with cerebral palsy are related. Therefore, as a result, VO2peak among aerobic capacity displayed a significant positive correlation in 45° and 300°/s peak torque/BW of HIP joint, and with 60° and 300°/s peak torque/BW of KNEE joint. It was the same with 60°/s Agon/Antag ratio of KNEE Joint (p < 0.05). VEpeak showed a significant positive correlation with 45° and 300°/s peak torque/BW of HIP joint, as well as correlation with 60° and 300°/s peak torque/BW and 60°/s Agon/Antag ratio of KNEE joint (p < 0.05). However, HRpeak showed a significant positive correlation only in 45°/s peak torque/BW of HIP joint (p < 0.05). The result of step-wise analysis was to find out which muscle strength significantly affects VO2peak and HRpeak among aerobic abilities in the lower extremity muscles of those disabled with cerebral palsy. Among the muscle functions of lower extremity muscle strength, 300°/s peak torque/BW of KNEE Joint was found to have the greatest effect on VO2peak (p < 0.001). As a result, 300°/s peak torque/BW of KNEE Joint was found to be the predictable factor that could explain the VO2peak in the disabled people with cerebral palsy at 67% (R2 = 0.661). In particular, among the muscle functions of lower extremity muscle strength at 45°/s peak, torque/BW of HIP Joint was found to have the greatest effect on HRpeak (p < 0.001). As a result, this factor was found to be the predictable factor that could explain the HRpeak in disabled people with cerebral palsy at 39% (R2 = 0.392). In this study, the muscle strength of the lower extremity of CP was closely related to the aerobic capacity, and the muscle endurance of KNEE Joint and the muscle power of HIP Joint were found to be important factors to predict the aerobic capacity of CP.

1. Background

Cerebral palsy (CP) is a neurodevelopmental disorder that begins in infancy (childhood) and continues throughout life [1]. It represents a ‘motor disorder’ in which abnormal lesions occur in the overall part of the body (global physical) [2], such as the nervous system, the muscular system, and the skeletal system due to the brain damage that occurs before brain development has been completed [3]. Additionally, when there is a brain damage like the case of CP, the kinematic problems occur due to the abnormal muscle tension, abnormal reflexes, and movement patterns [4]. In addition, it is common that the normal posture cannot be maintained because the joint motion range (Range of Motion) is reduced due to the contraction and relaxation of involuntary muscle as well as the decrease in muscle mass due to the abnormal muscle development [5].
Previous studies on the skeletal muscle structure of CP reported, through a comparison between children with cerebral palsy and general children, that the muscle strength of children with cerebral palsy is weak because the length and thickness of muscle fibers are shorter and thinner than those of general children [6,7,8,9,10,11,12,13]. In a study measuring the sarcomeres in the flexor muscle fibers of the carpal muscle, both in the adolescents with spastic cerebral palsy and normal young adults, the length of the sarcomeres in the group with spasticity was found to be abnormally longer than that of the control group without spasticity [14]. The same study has reported that the elasticity of fiber bundles and single fiber is lower in children with cerebral palsy than in general children, even in childhood, because the extracellular matrix is delicate, its quality is poor, and its strength is weak [15]. In other words, although it is difficult to explain anatomically, the abnormal development of the CP muscle is thought to be due to the secondary loss of muscle length because of the lesions in the central nervous system. The problem of such abnormal muscle deformation is not only the important cause of muscle loss and muscle stiffness, but also that of the decreased motor ability of whole body.
For CP, low muscle strength affects the gait pattern [16,17] and decreases motor function [18] compared to normal people, so it can be thought that it will adversely affect aerobic capacity. Basically, the aerobic capacity refers to the ability to deliver oxygen to muscles, generate energy during exercise, and utilize it as one of the exercise abilities [19]. Additionally, it is an important indicator for predicting the adult health, diseases [20,21], the cardiopulmonary function and the mortality rate [22]. Previous studies have reported that the aerobic capacity of CP is significantly lower than that of normal people [23,24,25,26,27]. A study comparing the aerobic capacity of 24 cerebral palsy children (16 males and 8 females) and general children reported that children with cerebral palsy had significantly lower aerobic capacity than that of general children, explaining that the involuntary muscle convulsion was the main reason [28]. In addition, a study comparing the aerobic capacity of adult CPs to that of general adults using arm ergometer reported that adult CPs had a significantly lower aerobic capacity because various muscle abnormalities and movement restrictions of adult CPs lead to the motor abnormality [25]. In conclusion, CP manifests the combination of problems related to the muscle weight loss, muscle cramp, stiffness, and rigidity due to the abnormal muscle fiber development. These abnormal movements and gait patterns cause such phenomenon, adversely affecting the aerobic capacity.
Among the muscle strengths of the whole body, that of the lower extremities is closely related to the aerobic capacity [29]. Although the following is not the result of a study targeting people with cerebral palsy, it was reported that when the selective training was performed only on the lower extremities without full body training in patients with chronic heart failure, as the muscle strength of the lower extremities increased, the breathing difficulties felt at the same intensity of exercise decreased, and at the same time, the muscle strength of the flexor muscle of the KNEE joint increased, as well as the maximum oxygen intake [29]. In other words, it was suggested that both the increase in peak oxygen uptake (VO2peak) and the increase in muscle strength in the lower extremities had a positive effect on reducing dyspnea [30]. Additionally, it was reported that there was a positive correlation between the instantaneous lower extremity muscle strength and the cardiopulmonary function [31]. It was reported that there was a positive correlation between the peak oxygen uptake and the muscle strength of the KNEE extensor, and the afferent contraction was more closely related to the peak oxygen uptake (VO2peak) than the eccentric contraction in the study comparing the relationship between the peak oxygen uptake and the lower extremities muscle strength according to the speed and contraction pattern of muscle contraction in the KNEE extensor [32]. There was only one study on CP, and it concluded that VO2peak increased significantly as a result of 8 weeks of upper and lower limb training using Schwinn Air-Dyne ergometer in 7 CPs [33]. In other words, the high muscle strength of the lower extremities is closely related to obtaining high aerobic capacity, which can be thought to have a more positive effect on the disabled with cerebral palsy as well as normal people.
Looking at the studies on the motor ability of CP so far, most of the studies were conducted on children, not adults [34,35,36,37]. However, contrary to the past claims that muscle tissue will not change continuously in the patients with the brain injury and brain lesion, recent studies have reported that the skeletal muscle in CPs consistently exhibits different denaturation patterns from those of normal muscle depending on the several factors and causes the clinically observed weakness [15]. In addition, they pointed out the problems and seriousness of the secondary motor dysfunction and changes that occur in adult cerebral palsy [38,39,40,41,42,43,44,45]. Additionally, there are many studies comparing the correlation between lower limb muscle strength and aerobic capacity in normal people or in other diseases, but no studies have yet examined the correlation of lower limb muscle strength and the aerobic capacity of adult CPs.
Therefore, in order to investigate the relationship between the lower extremity muscles strength of CP and the aerobic capacity, this study measured the lower extremity muscle strength (Extension and Flexion of the KNEE joint, Extension and Flexion of the HIP joint) and the aerobic capacity in adults with cerebral palsy, but not of children with cerebral palsy. Therefore, the purpose of this study was to analyze the effect of lower extremity muscle strength on the aerobic capacity and to provide the basic data for developing the exercise program that can effectively improve the aerobic capacity of adults with cerebral palsy by identifying the part of the lower extremity muscle that is most closely related to the aerobic capacity.

2. Methods

This study was approved by the ethical committee of the Center for Research Ethics, Sungshin Women’s University. The investigation conforms to the Declaration of Helsinki. All subjects gave written, informed consent before participating in the study.
(1)
Participants: This study was conducted from April 2019 to June 2020 in the Seoul Municipal CP welfare center in Korea. A total of 18 ambulant adults with CP were recruited for this study. 7 ambulant adults with CP were excluded because they did not achieve the criteria of maximal exercise. Thus, the data from 11 subjects (11 men) with CP were used for the analysis. The mean (±SD) age, height, weight, and BMI of the subjects were 37.00 ± 12.72 years, 170.45 ± 6.37 cm, 67.02 ± 8.62 kg, and 23.09 ± 2.78 kg/m2, respectively.
(2)
Lower extremity muscle strength measurement (Isokinetic exercise test): To measure the muscle strength of HIP joint and KNEE joint in lower extremities, the variables of the isokinetic muscle strength and the muscular endurance were performed using the isokinetic equipment (Biodex Co, Shirley, NY, USA). The range of motion (ROM) of all joints was as follows: 0° of maximum extension was set as neutral, the range of flexion was set as 90° bent from the neutral position, and gravity compensation was performed in the state of flexion of about 15°. For accurate measurement during the test, a dynamometer coincided in the motion axis of each test joint, and the subjects were given an accurate understanding of the test and practiced three times before the test. For the isokinetic muscle strength measurement of HIP joint, the 45°/s protocol indicated the muscle power and the 300°/s protocol indicating the muscle endurance were used. Additionally, the measurement of KNEE joint was performed once on the left and right side using the protocol of 60°/s, indicating the muscle power and 300°/s indicating the muscular endurance. Then, the results of peak torque % body weight (%) and Agon/Antag ratio (%) of the agonist and antagonist muscle, both in the left and right side, were analyzed using the average value.
(3)
Aerobic capacity measurement: Progressive exercise tests were conducted on the treadmill (Quinton model- 4500) using previously developed protocols targeting CPs [28,46]. The initial protocol speeds were 5 km/h−1 and 2 km/h−1 for the subjects who has been classified as GMFCS level I and II, respectively. There was a speed increase at a rate of 0.25 km/h−1 every minute until it was terminated voluntarily. The subjects were verbally instructed to continue until they felt the exhaustion. Using a portable cardiopulmonary indirect breath-by-breath calorimetry system (MetaMax 3B; Cortex Biophysik, Leipzig, Germany), pulmonary ventilation (VE), respiratory exchange ratio (RER), and oxygen uptake (VO2) were persistently measured. A HR monitor (Polar Electro, Kempele, Finland polar Co. RS-800) was used to measure heart rate (HR). During the gait on the treadmill, peak VE (VEpeak) and peak RER were defined as values measured when VO2peak was detected. The subjects had the mission to accomplish two of the following three criteria for the results to be accepted with VO2peak: (1) RER value greater than 1.0, (2) The value of heart rate greater than the predicted heart rate ([220-age] × 085), or (3) a plateau (increase of <150 mL ∙ min of oxygen) in O2 with increasing work rates. To avoid the effect on the metabolic response and HR of the subjects, they were told to avoid excessive physical activity for 24 h before testing and to refrain from any stimulating substances (alcohol, coffee, tobacco, and so on) or any drugs which could interfere with the experiment. Subjects had their last meal 3 h prior to the initiation of the test.

3. Results

These are the results of measuring the lower extremity muscle strength and the aerobic capacity of disabled people with cerebral palsy (Table 1). The lower extremity muscle strength measured peak torque/BW to be 105.49 ± 33.35 at 45°/s of HIP Joint and Agon/Antag ratio was 226.15 ± 119.20. Additionally, peak torque/BW was 120.23 ± 47.13 at 300°/s and Agon/Antag ratio was 199.43 ± 91.60. For the KNEE Joint at 60°/s, peak torque/BW was 167.43 ± 39.72 and Agon/Antag ratio was 45.87 ± 12.09. In addition, the KNEE Joint at 300°/s, peak torque/BW was 106.90 ± 18.88 and Agon/Antag ratio was 77.09 ± 9.86. Finally, the aerobic capacity was 37.63 ± 8.12 for VO2peak (mL/kg/min), 78.71 ± 23.00 for VEpeak (l/min), and 186.90 ± 12.05 for HRpeak (beats/min).
This is the result of correlation analysis to find out the relationship between the lower extremity muscle strength and the aerobic capacity of disabled people with cerebral palsy (Table 2). As such, VO2peak, among aerobic capacities, displayed a significant positive correlation in 45° and 300°/s peak torque/BW of HIP joint, and with 60° and 300°/s peak torque/BW of KNEE Joint. In addition, it was the same with 60°/s Agon/Antag ratio of KNEE Joint (p < 0.05). Likewise, VEpeak showed a significant positive correlation with 45° and 300°/s peak torque/BW of HIP joint along with the same correlation with 60° and 300°/s peak torque/BW and 60°/s Agon/Antag ratio of KNEE Joint (p < 0.05). However, HRpeak showed a significant positive correlation only in 45°/s peak torque/BW of HIP joint (p < 0.05).
This is the result of step-wise analysis to find out which muscle strength significantly affects VO2peak among aerobic abilities in the lower extremity muscles of those disabled with cerebral palsy (Table 3). Among the muscle functions of lower extremity muscle strength, 300°/s peak torque/BW of KNEE was found to have the greatest effect on VO2peak (p < 0.001). As a result, 300°/s peak torque/BW of KNEE was found to be the predictable factor that could explain the VO2peak in disabled people with cerebral palsy at 66% (R2 = 0.661).
This is the result of step-wise analysis to find out which muscle strength significantly affects HRpeak among aerobic abilities in the lower extremity muscles of those disabled with cerebral palsy (Table 4). Among the muscle functions of lower extremity muscle strength, 45°/s peak torque/BW of HIP, in particular, was found to have the greatest effect on HRpeak (p < 0.001). As a result, this factor was found to be the predictable factor that could explain the HRpeak in the disabled people with cerebral palsy at 39% (R2 = 0.392).

4. Discussion

So far, there have been more studies that investigated the motor abilities of children with cerebral palsy than those of adults with cerebral palsy [34,35,36,37]. Additionally, most of the studies examining the relationship between muscle strength and aerobic capacity were conducted on the general public or the diseased patients, not on those disabled with cerebral palsy [47,48,49]. Therefore, this study investigated the relationship between the muscle strength and the aerobic capacity in adults with cerebral palsy based on the fact that there is a close relationship between the muscle strength and the aerobic capacity.
As a result of correlation analysis, VO2peak showed a significant positive correlation between 45° and 300°/s peak torque/BW of HIP joint, 60° and 300°/s peak torque/BW of KNEE, and 60°/s Agon/Antag ratio of KNEE (p < 0.05). Additionally, 45°/s peak torque/BW of HIP joint showed a significant positive correlation with HRpeak (p < 0.05). The characteristics of gait that generally appear in CPs are caused by the limited range of motion of HIP Joint and KNEE Joint, the excessive adduction and internal rotation of HIP, the tilt of front pelvis, the pelvic obliquity, and the persistent plantar flexion at the ankle [34,50]. Due to these factors, CP gait has the general characteristics of reduced heel strike, reduced gait speed, and reduced stride length, and these gait parameters (stride, gait speed, gait posture, heel strike, etc.) are closely related to the muscle strength, in which gait speed has an especially high correlation with the muscle strength [18]. In general, the muscle weakness and the decrease in gait ability in CP lower the efficiency of gait and require a lot of energy from the body, which affects the decrease in stride length [51]. In addition, it was reported that the high oxygen cost (poor gait economy) of CP comes from muscle co-activation and total body mechanical power [52,53]. Among all the factors that measured the lower extremity muscle strength in this study, the following factors showed a significant correlation with VO2peak: 45°/s peak torque/BW representing the muscle power of HIP, 300°/s peak torque/BW representing the muscle endurance of HIP, 60°/s peak torque/BW indicating the muscle power, and 300°/s peak torque/BW indicating the muscle endurance of KNEE (p < 0.05). Additionally, 45°/s peak torque/BW of HIP showed a significant correlation with HRpeak (p < 0.05).
This is consistent with the previous studies above which showed that the muscle strength of CP is closely related to gait ability and exercise ability, and it can be considered an important result that can explain the relationship between the lower limb muscle strength of CP and the gait ability and the exercise ability in CP. Eventually, the abnormal muscle development of CP degrades the lower limb muscle strength, which leads to the abnormal gait patterns. Therefore, it can be considered that it adversely affects the aerobic capacity as a result of inefficiently using a large amount of physical energy for gait, resulting in the decrease in aerobic capacity.
Additionally, in this study, 60°/s Agon/Antag ratio of KNEE showed a significant positive correlation with VO2peak (p < 0.05). In a previous study, the EMG pattern was used to observe the muscle movement during CP gait, and as a result, it was reported that the agonist and antagonist muscles around the joint contracted simultaneously [52]. In addition, it was reported to increase in the KNEE extensor and reduce the flexor by introducing CPs into the lower limb muscle strength enhancement program, which eventually resulted in the improved gait ability by increasing the stride, which was due to the improved abnormal balance of KNEE agonist and antagonist muscles [54]. It can be thought that the abnormal ratio of agonistic and antagonistic muscles of the KNEE to CP is a factor that can adversely affect not only gait ability but also exercise ability and is closely related to low aerobic capacity.
Previous studies have reported that the muscles of CP children are smaller [18,55] and weaker [53,56] than normal healthy children. Additionally, the muscle strength is correlated with the gait patterns [55,57] and the motor functions [58], and the muscle strength is more associated with the muscle function than the muscle convulsion [57]. In particular, Eek et al. (2008) reported in CP’s Gross Motor Function Classification System (GMFCS) that the areas of the greatest muscle strength between Level I, in which CP can gait free of an aid apparatus, and GMFCS Level III groups, where CP gaits with aid apparatus, are HIP Extension/Abduction and KNEE Extension muscles [11]. Additionally, in this study, 300°/s peak torque/BW of KNEE was found to have the greatest effect on VO2peak of CP among lower extremities muscle strength (p < 0.01), and it was found to be the predictive factor that could explain VO2peak at the level of 66% in CPs. In addition, 45°/s peak torque/BW of HIP was found to have the greatest effect on HRpeak (p < 0.05), and this factor was found to be the predictive factor that could explain the HRpeak of people with cerebral palsy at the level of 39%. Lack of flexibility and movement control of CP has been recognized as the main cause of the excessive energy use in the inefficient gait of CP. Previous studies investigated the energy requirement for CP adolescent gait, and as a result, 1.5 to 3 times of gait energy of normal adolescents was required depending on the degree and type of gait angle [59]. Additionally, the cost of gait was 3 times than that of normal adolescents [53]. To reduce the inefficient energy consumption during gait, CP adolescents require less convulsions, restoration of stability in posture changes, and removal of foot drag, all of which could be improved by strengthening the muscles of the torso and lower extremities, stressing the need for strengthening the muscle strength of lower extremities [58]. Additionally, the energy consumed during gait in CP children was investigated, and as a result, there was a close relationship between the KNEE extensor and the gait efficiency, suggesting that the KNEE extensor force is an important factor for the efficient use of energy [51]. On the other hand, although it was not a study related to CP, the two preceding studies investigated the kinetics of VO2 by applying a heavy weight training program for normal adults. As a result, it was reported that the running economy improved as the storage of elastic energy increased, and the running economy improved due to the effect of titin on the elastic properties of muscle fibers [59,60]. As such, it can be thought that the lower limb muscle strength has a close relationship with the gait ability and also affects the aerobic capacity.
As a result, it can be concluded that the unstable gait pattern of the lower extremities of CP requires a lot of energy among the aerobic capacity measurements in this study, which resulted in the decrease in aerobic capacity. In particular, for CP, the muscle endurance of lower limb of KNEE Joint and the muscle power of HIP Joint are very important factors that can both enable the efficient gait and predict the aerobic capacity.

5. Conclusions

In this study, the muscle strength of the lower extremity of CP was closely related to the aerobic capacity, and in particular, the muscle endurance of KNEE Joint and the muscle power of HIP Joint were found to be important factors to predict the aerobic capacity of CP. In future studies, it is necessary to investigate how the intervention of muscle exercise programs focused on KNEE Joint and HIP Joint of CP affects the aerobic capacity enhancement. Based on the results of this study, it is considered that a follow-up study is needed to intervene in the exercise program to understand the causal relationship between muscle strength increase and aerobic capacity.

Author Contributions

Writing—original draft, J.Y.; writing—review & editing, S.C. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Ministry of Education of the Republic of Korea and the National Research Foundation of Korea (NRF-2019S1A5B5A01042582).

Institutional Review Board Statement

This study was approved by the ethical committee of the Center for Research Ethics, Sungshin Women’s University (SSWUIRB-2020-007). The investigation conforms to the Declaration of Helsinki.

Informed Consent Statement

All subjects gave written, informed consent before participating in.

Data Availability Statement

Not applicable.

Acknowledgments

The authors would like to thank all the participants involved in the study. The authors would also like to thank the Seoul Municipal CP welfare center in Korea who granted us access to participants.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

CP: cerebral palsy; VO2: oxygen uptake; HR: heart rate; VE: pulmonary ventilation; BW: body weight; Agon/Antag: agonist to antagonist; SD: standard deviation; GMFCS: gross motor function classification system.

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Table
Table 1. Comparison of the Lower Extremity Muscle Strength and Aerobic Capacity (mean ± SD).
Table 1. Comparison of the Lower Extremity Muscle Strength and Aerobic Capacity (mean ± SD).
(n = 11)Lower Extremity Muscle Strength
HIP JointKNEE Joint
45°/s300°/s60°/s300°/s
peak torque/BWAgon/Antag ratiopeak torque/BWAgon/Antag ratiopeak torque/BWAgon/Antag ratiopeak torque/BWAgon/Antag ratio
Mean ± S.D105.49 ± 33.35226.15 ± 119.20120.23 ± 47.13199.43 ± 91.60167.43 ± 39.7245.87 ± 12.09106.90 ± 18.8877.09 ± 9.86
Aerobic Capacity
VO2peak (mL/kg/min)VEpeak (l/min)HRpeak (beats/min)
Mean ± S.D37.63 ± 8.1278.71 ± 23.00186.90 ± 12.05
Table
Table 2. Correlation Coefficients between Lower Extremity Muscle Strength and Aerobic Capacity.
Table 2. Correlation Coefficients between Lower Extremity Muscle Strength and Aerobic Capacity.
A1A2A3A4B1B2B3B4CD
A20.594-
A30.892 **−0.385-
A4−0.5150.690 *−0.445-
B10.570−0.0980.5330.148-
B20.435−0.2130.581−0.0910.609 *-
B30.600−0.1720.656 *−0.1350.874 **0.635 *-
B40.105−0.0920.258−0.1840.3390.5140.505-
C0.745 **−0.3510.767 **−0.4900.658 *0.610 *0.813 **0.361-
D0.667 *−0.3920.638 *−0.2150.736 **0.635 *0.869 **0.2600.745 **-
E0.626 *−0.4320.499−0.4350.3490.3940.474−0.1730.729 *0.739 *
* p < 0.05, ** p < 0.01. Note. A: HIP (A1: 45°/s peak torque/BW, A2: 45°/s Agon/Antag ratio, A3: 300°/s peak torque/BW, A4: 300°/s Agon/Antag ratio), B: Knee (B1: 60°/s peak torque/BW, B2: 60°/s Agon/Antag ratio, B3: 300°/s peak torque/BW, B4: 300°/s Agon/Antag ratio), C: VO2peak, D: VEpeak, E: HRpeak.
Table
Table 3. Stepwise regression analysis for prediction of VO2peak.
Table 3. Stepwise regression analysis for prediction of VO2peak.
BBetapR2 ChangeR2F
KNEE 300°/s peak torque/BW0.3500.8130.0020.6230.66117.517 **
** p < 0.01.
Table
Table 4. Stepwise regression analysis for prediction of HRpeak.
Table 4. Stepwise regression analysis for prediction of HRpeak.
BBetapR2 ChangeR2F
HIP 45°/s peak torque/BW0.2260.6260.0390.3250.3925.812 *
* p < 0.05.
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You, J.; Choi, S. Effect of Lower Extremity Muscle Strength on Aerobic Capacity in Adults with Cerebral Palsy. Appl. Sci. 2022, 12, 4141. https://doi.org/10.3390/app12094141

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You J, Choi S. Effect of Lower Extremity Muscle Strength on Aerobic Capacity in Adults with Cerebral Palsy. Applied Sciences. 2022; 12(9):4141. https://doi.org/10.3390/app12094141

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You, Jungwan, and Seungwook Choi. 2022. "Effect of Lower Extremity Muscle Strength on Aerobic Capacity in Adults with Cerebral Palsy" Applied Sciences 12, no. 9: 4141. https://doi.org/10.3390/app12094141

APA Style

You, J., & Choi, S. (2022). Effect of Lower Extremity Muscle Strength on Aerobic Capacity in Adults with Cerebral Palsy. Applied Sciences, 12(9), 4141. https://doi.org/10.3390/app12094141

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