Physical Performance Correlates with Self-Reported Physical Function and Quality of Life in Patients at 3 Months after Total Knee Arthroplasty

Article information

Ann Geriatr Med Res. 2020;24(2):99-106
Publication date (electronic) : 2020 June 11
doi : https://doi.org/10.4235/agmr.20.0018
1Department of Rehabilitation Medicine, Regional Rheumatoid and Degenerative Arthritis Center, Jeju National University Hospital, Jeju National University College of Medicine, Jeju, Korea
2Department of Physical Medicine and Rehabilitation, Korea University Anam Hospital, Seoul, Korea
3Department of Orthopedic Surgery, Regional Rheumatoid and Degenerative Arthritis Center, Jeju National University Hospital, Jeju National University College of Medicine, Jeju, Korea
Corresponding Author: Bo Ryun Kim, MD, PhD Department of Physical Medicine and Rehabilitation, Korea University Anam Hospital, 73 Goryeodae-ro, Seongbuk-gu, Seoul 02841, Korea E-mail: brkim08@gmail.com
Received 2020 March 31; Revised 2020 May 21; Accepted 2020 May 21.

Abstract

Background

Although total knee arthroplasty (TKA) is an effective treatment for knee osteoarthritis, assessment of postoperative outcomes remains unclear. This study aimed to identify postoperative physical performance factors that are correlated with self-reported physical function and quality of life (QoL) at 3 months after unilateral TKA.

Methods

In total, 158 patients who underwent unilateral primary TKA completed performance-based physical function tests at 3 months after surgery, including Stair Climbing Tests (SCT), 6-Minute Walk Tests (6MWT), Timed Up and Go tests (TUG), and instrumental gait analysis. We also measured the isometric knee flexor and extensor strengths of the operated and non-operated knees. Self-reported physical function and QoL were assessed using the Western Ontario and McMaster Universities Osteoarthritis Index (WOMAC) and the Euro-QoL Five Dimensions (EQ-5D) questionnaire, respectively.

Results

Bivariate analyses showed that WOMAC function and EQ-5D were correlated with age, other self-reported measures, and performance-based measures. The WOMAC pain (r=0.71, p<0.001) showed a high positive correlation. While the EQ-5D (r=-0.7, p<0.001) showed a highly negative correlation with WOMAC function, WOMAC pain (r=-0.67, p<0.001) showed a moderately negative correlation with EQ-5D. In multivariate linear regression analyses, WOMAC pain, peak torque of the flexor of the non-operated knee, and reductions in extensor and stride length were associated with self-reported physical function, whereas WOMAC pain, SCT ascent, and cadence were associated with postoperative QoL.

Conclusions

Physical performance factors were significantly associated with self-reported physical function and QoL in patients at 3 months after unilateral TKA. These findings suggest that performance-based physical function could be used to assess outcomes after TKA.

INTRODUCTION

Knee osteoarthritis (OA) is the single most common joint disease and a major cause of disability in older adults. Pain and swelling of the affected joints can reduce mobility and impair activities of daily living and quality of life (QoL).1,2)

Total knee arthroplasty (TKA) is an effective and cost-efficient treatment for patients with end-stage knee arthritis.3) The most prevalent preoperative expectations of TKA are relief of pain.4,5) However, despite pain relief after successful TKA, patient expectations of physical function and QoL are often unfulfilled.6,7)

Physical function changes over time after TKA. Our previous study showed correlations between preoperative performance-based physical function and self-reported physical function and QoL.8) Dynamic balance and exercise capacity were powerful predictors of self-reported physical function and QoL. During the first month after TKA, physical performance and the results of self-reported questionnaires worsen substantially from preoperative conditions.9,10) Performance-based measures showed greater responsiveness compared to self-reported questionnaires early after surgery and patients tend to overestimate actual short- and long-term changes in physical function after TKA.11) In addition, several studies using both questionnaires and physical performance functions have shown that the self-reported physical function of individuals often differs substantially from their actual functional capability.12,13) Due to the discrepancies between self-reported and performance-based physical function, correlation analysis of both outcomes is necessary in patients who undergo unilateral TKA. By the third postoperative month, self-reported physical function and QoL scores usually surpass preoperative values.14) Moreover, the greatest improvements in gait and lower extremity function occur during the first 3 months after TKA.15) By this time, most patients have resumed their daily activities in the community and at home.

We previously reported improvement in functional outcomes during the first 3 months after the application of a critical pathway for patients who underwent TKA.16) This study included patients who underwent unilateral and bilateral TKA; however, we did not assess the relationship between physical performance and self-reported physical function.

Identifying performance-based measures that affect self-reported measures will likely be meaningful; moreover, it is important to identify factors that prevent patients from fulling their expectations after TKA. Therefore, this study aimed to identify postoperative physical performance factors related with self-reported physical function and QoL at 3 months after unilateral TKA. The results of this study may guide postoperative rehabilitation strategies to improve physical performance and self-reported physical function and QoL.

MATERIALS AND METHODS

Study Design and Participants

This retrospective cross-sectional study enrolled 158 patients who were diagnosed with knee OA and underwent unilateral primary TKA between October 2013 and May 2019. The inclusion criterion for this study was patients who walk independently with or without an ambulatory aid after surgery. Patients with previous neurological, cardiorespiratory, or orthopedic disease that caused ambulatory deficits were excluded.

All patients completed performance-based physical function tests, including Stair Climbing Tests (SCTs), 6-Minute Walk Tests (6MWTs), Timed Up and Go tests (TUGs), and instrumental gait analyses. We also measured the isometric knee flexor and extensor strengths of the operated and non-operated knees. Self-reported physical function and pain were measured using the Western Ontario and McMaster Universities Osteoarthritis Index (WOMAC), and self-reported QoL was measured using the Euro-QoL Five Dimensions (EQ-5D) questionnaire.

We informed the patients about the nature of the study and its risks and benefits and all participants provided written consent. The study protocol was approved by the Institutional Review Board at Jeju National University Hospital (No. JEJUNUH 2019-12-013).

Rehabilitation Protocol

Beginning on the first day after TKA, patients underwent a standard rehabilitation program including passive knee range of motion (ROM) and physical modalities such as cryotherapy and transcutaneous electrical nerve stimulation for relief of knee pain and swelling. The patients started progressive resistance strengthening exercises 7 days after surgery and an intensive rehabilitation program including gait training, aerobic exercises using an ergometer, functional training for transfer, and stair climbing beginning on postoperative day 14. The patients participated in the rehabilitation programs twice daily, five times per week for 2 weeks in the rehabilitation department under the supervision of physical therapists.

Outcome Measures

All patients underwent assessments 3 months after surgery, with physical performance and self-reported physical function and QoL tests performed on the same day.

Assessments of performance-based physical function

6MWT: The 6MWT is a performance-based measure of functional exercise capacity, such as walking capacity and gait endurance, in adults. In this test, the participants walk as far as possible for 6 minutes along a 50-m hallway marked with lines.17)

TUG: The TUG test is used to evaluate a dynamic balance. In this test, the participants sit with their backs against a chair (seat height, 44 cm; width, 49 cm; armrest height, 64 cm) placed at the end of a marked 3-m distance and stand up upon hearing the word “go”, walk at a comfortable speed past the 3-m mark, turn around, walk back, and sit down again in the chair without physical assistance, all while being timed.18)

SCT: The SCT is a measurement of the time required to ascend and descend a flight of 12 steps, each 17 cm high and 25 cm wide. In this test, the participants ascend or descend the stairs as fast as possible upon hearing the word “go”. Each patient completed three trials, with a 5-minute rest interval between each pair of trials. The fastest time was recorded for each patient.19)

Measurement of knee ROM: The ROM of the affected knee was measured using a standard long-arm goniometer. The axis, movement arm, and stationary arm of the goniometer were aligned with the center of the lateral epicondyle of the femur, the lateral malleolus, and the greater trochanter of the femur, respectively. The knee flexion ROM was measured as the maximal active bending of the knee with the patient in the supine position. Knee extension ROM was measured as the angle of maximal active straightening with the patient’s heel propped on a 10-cm wooden block. The degree of extension beyond zero for hyperextension during this assessment was recorded as a negative value.20,21)

Gait analysis: A wireless inertial sensing device (G-WALK; BTS Bioengineering S.p.A., Milan, Italy) was used to measure the spatiotemporal variables of gait. The patients wore a semi-elastic back-belt device on the waist to measure the acceleration of the anteroposterior, mediolateral, and vertical axes and were instructed to walk barefoot along an 8-m pathway at a comfortable speed. Gait data were transmitted via Bluetooth to a personal computer and were processed using the BTS G-WALK system, a dedicated software program that measures length, duration, and single supports to calculate a typical gait curve. The second positive peak on the curve was the instant at which the patient’s foot contacted the ground. Therefore, the step length was defined as the distance between two successive foot contacts with the ground, while stride length was defined as the distance between three successive foot contacts. The first and last steps were removed from all calculations because of abnormal patterns and psychological responses at the start and end of walking, respectively.22)

Measurements of isometric strengths of knee extensors and flexors: A physical therapist used an isokinetic dynamometer (HUMAC NORM; Computer Sports Medicine Inc., Stoughton, MA, USA) to measure the maximal isometric strengths of the bilateral knee extensors and flexors. All patients were instructed to start a structured warm-up with the knee joint fixed at 60º of flexion to generate maximal isometric force, followed by maximal voluntary contractions until the torque did not increase by more than 5% during three successive attempts. The patients then performed knee flexion and extension as discrete movements in a single direction. Each contraction lasted 4–5 seconds, with 2-minute rest intervals between contractions. After a 5-minute rest, the patients repeated the procedure on the other lower limb. The variables measured included the peak torques (PTs) of the extensor and flexor, the ratio of hamstring to quadriceps strength (H/Q ratio), and the difference in the strengths of the extensors and flexors between the operated and non-operated knees, expressed as percentages of the strengths of the non-operated knee.21,23)

Assessment of self-reported physical function and QoL

WOMAC: The multidimensional WOMAC index is a questionnaire used to assess pain, stiffness, and physical functional disability24) and has previously been applied to measure self-reported disability in patients with knee OA. The WOMAC index comprises 24 variables: 5 addressing pain, 2 addressing stiffness, and 17 addressing physical function. Each of these variables is scored using a 5-point Likert scale (0=none, 1=slight, 2=moderate, 3=very, 4=extremely). The WOMAC index measures the degree of pain, stiffness, and difficulty in performing 17 activities during the preceding 48 hours. Higher scores indicate greater levels of pain, stiffness, and difficulty.

EQ-5D questionnaires: The EQ-5D questionnaire is widely used to evaluate self-reported QoL by measuring five dimensions of QoL: mobility, self-care, usual activities, pain/discomfort, and anxiety/depression.25) Each dimension has three levels of severity (no problems, some or moderate problems, and extreme problems). The scores were converted using utility weights derived from the general Korean population and ranged from -1 to 1. Lower scores indicated worse overall health status.

Statistical Analysis

All variables were subjected to descriptive statistics. We used Pearson correlation analysis to assess the relationships between postoperative self-reported physical function and QoL, and physical performance. Multivariate linear regression analysis using a backward selection linear regression model was used to determine the postoperative physical performance factors independently associated with self-reported physical function and QoL 3 months after TKA. We used SPSS for Windows version 20.0 (IBM SPSS, Armonk, NY, USA) to perform all analyses, with p<0.05 considered statistically significant.

RESULTS

This study enrolled 158 patients (134 women and 24 men) with a mean age of 72.6±5.8 years and mean body mass index (BMI) of 25.6±3.0 kg/m2. Their baseline demographic and disease-related characteristics are presented in Table 1. Of these 158 patients, 131 (82.9%) had Kellgren–Lawrence grade IV knee OA.

Demographic and disease-related characteristics of the subjects (n=158)

Postoperative Evaluation of Performance-based Physical function, Self-reported Physical Function, and QoL and Their Correlations

Table 2 presents the average postoperative performance-based physical function, self-reported physical function, and QoL scores of these patients.

Postoperative evaluation of performance-based physical function, self-reported physical function, and quality of life in patients 3 months after unilateral TKA

In bivariate analyses, WOMAC function showed significant positive correlations with age (r=0.29, p<0.001), WOMAC pain score (r=0.71, p<0.001), WOMAC stiffness score (r=0.24, p=0.003), TUG (r=0.22, p=0.005), SCT ascent (r=0.24, p=0.003), SCT descent (r=0.22, p= 0.007), and knee extensor deficit (r=0.16, p=0.047). WOMAC function also showed significant negative correlations with EQ-5D score (r=-0.70, p<0.001), stride length (r=-0.19, r=0.022), and PT of the flexor of the operated (r=-0.38, p<0.001) and non-operated (r=-0.47, p<0.001) knees.

EQ-5D scores showed significant negative correlations with age (r=-0.30, p<0.001), WOMAC pain score (r=-0.67, p<0.001), WOMAC stiffness score (r=-0.16, p=0.043), WOMAC function score (r=-0.70, p<0.001), TUG (r=0.22, p=0.005), SCT ascent (r=0.24, p=0.003), and SCT descent (r=0.22, p=0.007). EQ-5D scores also showed significant positive correlations with 6MWT (r=0.31, p<0.001), cadence (r=0.22, p=0.007), and the PT of the flexors of the operated (r=0.24, p=0.002) and non-operated (r=0.27, p=0.001) knees (Table 3).

Correlations between postoperative self-reported physical function and quality of life and physical performance in patients 3 months after unilateral TKA

Factors related with Self-reported Physical Function and QOL by Multivariate Linear Regression Analysis

Postoperative WOMAC-Function score was significantly and independently associated with age (β=0.15, p=0.011), WOMAC pain score (β=0.59, p<0.001), stride length (β=-0.15, p=0.009), PT of the flexor of the non-operated knee (β=-0.31, p<0.001), and extensor deficit (β=0.16, p=0.006). The postoperative EQ-5D score was significantly and independently associated with the WOMAC pain score (β=-0.62, p<0.001), SCT ascent (β= -0.18, p=0.013), and cadence (β=0.13, p=0.031) (Table 4).

Factors associated with self-reported physical function and quality of life by multivariate linear regression analysis

DISCUSSION

The results of the present study showed that objective performance-based physical function was correlated with self-reported physical function and QoL at 3 months after unilateral TKA. WOMAC function and EQ-5D scores were correlated with age, other self-reported measures, and performance-based measures. Based on the classification of correlations as very high, high, moderate, low, or negligible,26) the WOMAC pain score showed a highly positive correlation with the WOMAC function score (r=0.71, p<0.001), whereas the EQ-5D showed a highly negative correlation with WOMAC function score (r=-0.70, p<0.001). Pain after TKA was inversely correlated with time to recovery27) and preoperative pain is correlated with self-reported physical function.8) Patients experience pain for up to 3 months after surgery; however, even reduced pain can negatively affect physical function. Our results suggested that preoperative and postoperative pain control in patients could improve their physical function.

Among the performance-based physical function parameters tested in the present study, strengthening of non-operated knee flexor and extensor had significant correlations with WOMAC function. Quadriceps strength is frequently reduced after TKA and may affect physical functions.10,29,30) Reduced quadriceps strength after TKA was related to lower gait speed,31) and mobility limitations have been reported to be associated with large deficits of strength in surgical knee.19) Moreover, the ratio of quadriceps to hamstring muscle strength was a strong predictor of weight-bearing asymmetry.32) Hamstring muscles on both the operated and non-operated sides were found to be weaker after unilateral TKA. Many rehabilitation programs, however, target quadriceps strengthening of operated side alone, resulting in less information regarding hamstring muscle strength. These results may explain our finding that PT flexor of the non-operated knee and a deficit of the extensor correlated negatively with WOMAC function, and may be useful predictors of postoperative self-reported physical function.

WOMAC-Function score is inversely correlated with gait speed and stride length.33) Older adults with gait speed <1 m/s are at high risk of poor health‐related outcomes.34) Comfortable gait speeds for healthy women and men aged 70–79 years are 1.13 and 1.26 m/s, respectively.35) The mean gait speed in our patients was >1 m/s, which was comparable to that of healthy adults, suggesting that gait speed had little effect on their physical functions. Normal adults have a mean stride length of 1.39 m,36) about 20% higher than that in our patient population, suggesting that stride length rather than gait speed might have affected their physical function. Together, these results may explain the negative correlation between stride length and WOMAC function. Rehabilitation strategies after TKA should emphasize pain relief, strengthening the knee extensor and flexor, and gait training to increase stride length to improve functional outcome.

We also found that EQ-5D scores at 3 months after unilateral TKA were correlated with age, WOMAC pain, WOMAC stiffness, WOMAC function, 6MWT, TUG, SCT ascent, SCT descent, affected ROM extension, cadence, and PT flexor of the operated and non-operated knees. Among these performance-based physical function parameters. Lower pain scores and higher satisfaction scores have been reported in patients after TKA.27) Our results suggested that postoperative pain control and improved physical performance could increase postoperative QoL.

WOMAC pain was strongly and significantly associated with postoperative EQ-5D. The goals of TKA are to reduce pain, restore knee mobility and function, and improve QoL in cases of severe knee OA. Our previous study also showed a correlation between preoperative pain and self-reported QoL.8) Moreover, the most significant predictor of patient dissatisfaction is persistent pain after surgery.37) The results of these and the current study showed that patients continued to experience pain, albeit reduced, for up to 3 months after TKA, which possibly affected their QoL. The patients in our study had relatively lower WOMAC pain scores than those in other studies.38) These lower scores may have been due to the cross-sectional nature of this study, with all patients receiving adequate rehabilitation for 3 weeks. Nevertheless, our findings suggested that pain relief, even if the surgery was successful, is required to improve patient QoL.

We also found that SCT ascent and cadence were useful factors of postoperative EQ-5D scores. Stair activity is one of three recommended performance-based measures in patients with knee OA.39) Stair activity is frequently limited in these patients and, as well as being a goal of postoperative rehabilitation, necessary for patient safety and independence. The SCT test is the most responsive performance-based measurement of recovery early after TKA.11)

Reduced cadence leads to reduced gait speed after TKA.40,41) Limited gait speed is a significant issue; thus, increasing gait speed is a rehabilitation goal in patients with knee OA.32) However, because the gait speed of our patients was similar to the comfortable gait speed of healthy individuals, gait speed was unlikely to have a major effect on QoL 3 months after surgery. Thus, rehabilitation strategies should emphasize pain relief, stair activity, and gait training with increased cadence to improve QoL.

Although both gait function (including spatiotemporal parameters) and physical function (including lower limb strengthening) improve greatly during the first 3 months after TKA, patients’ subjective expectations of physical function remain unfulfilled until 1 year after TKA.6) These parameters, as well as isometric strengthening of the knee 1 month after TKA, showed greater improvement in our previous study than in the present study.42) Accordingly, the self-reported physical function and QoL 3 months after TKA may have been lower than the actually measured values.

Knee flexion and extension ROM at 3 months after TKA were not significantly correlated with physical function or QoL. Moreover, knee ROM at 1 month after TKA did not significantly affect physical function. These findings indicate that for at least 1 month after TKA, knee ROM is unrelated to physical function and QoL.

This study has some limitations. First, the results may not be generalizable to all TKA surgeries since the participants underwent only unilateral primary TKA. Accordingly, studies of patients who underwent bilateral TKA or revision are warranted. Second, the cross-sectional design of this study prevented analyses of the causal relationships among variables. Finally, we did not compare participants to those who did not receive postoperative rehabilitation after unilateral TKA.

In conclusion, the results of this study identified physical performance factors correlated with self-reported physical function and QoL in patients at 3 months after unilateral TKA. These findings suggest that these performance-based physical function could be used to assess outcomes after TKA.

Notes

CONFLICT OF INTEREST

The researchers claim no conflicts of interest.

AUTHOR CONTRIBUTION

Conceptualization, BRK, JHC; Data curation, BRK, JHC, SYL, WBK, YJK; Investigation, BRK, JHC; Methodology: BRK, JHC; Project administration, BRK, JHC, SRK, KWN, SYL, WBK, YJK; Writing original draft, BRK, JHC; Review & editing: BRK, JHC.

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Table 1.

Demographic and disease-related characteristics of the subjects (n=158)

Characteristic Value
Age (y) 72.6±5.8
Sex
 Male 24 (15.2)
 Female 134 (84.8)
BMI (kg/m2) 25.6±3.0
K–L grade
 3 27 (17.1)
 4 131 (82.9)
Comorbidities
 Osteoporosis 81 (51.3)
 Pre-sarcopenia 7 (4.4)
 Degenerative spine disease 26 (16.5)
 Diabetes mellitus 29 (18.4)
 Hypertension 106 (67.1)

Values are presented as mean±standard deviation or number (%).

BMI, body mass index; K–L grade, Kellgren–Lawrence grade.

Table 2.

Postoperative evaluation of performance-based physical function, self-reported physical function, and quality of life in patients 3 months after unilateral TKA

Variable Value
6MWT (m) 443.41±101.76
TUG (sec) 9.24±1.78
SCT (sec)
 Ascent 10.74±3.94
 Descent 12.01±3.96
ROM (º)
 Affected ROM flexion 124.66±11.59
 Affected ROM extension -7.69±5.43
Gait linear parameters
 Gait speed (m/s) 1.20±0.82
 Cadence (steps/min) 120.09±12.97
 Stride length (cm) 111.75±20.71
 Gait cycle duration (sec) 1.66±8.07
 Stance phase duration (% of gait cycle) 64.67±3.39
 Swing phase duration (% of gait cycle) 35.57±1.81
 Double support duration (% of gait cycle) 27.91±4.82
 Single support duration (% of gait cycle) 35.57±3.21
Isometric strength test
 PT of the extensor of the operated knee (Nm) 80.47±26.00
 PT of the extensor of the non-operated knee (Nm) 102.92±63.65
 PT of the flexor of the operated knee (Nm) 51.95±14.05
 PT of the flexor of the non-operated knee (Nm) 52.56±15.26
 Extensor deficit (%) 21.56±21.02
 Flexor deficit (%) 10.09±14.86
Self-reported physical function
 WOMAC-Pain 4.13±2.17
 WOMAC-Stiffness 1.97±1.04
 WOMAC-Function 17.61±8.79
Self-reported quality of life
 EQ-5D 0.82±0.09

Values are presented as mean±standard deviation or number (%).

TKA, total knee arthroplasty; WOMAC, Western Ontario and McMaster Universities Osteoarthritis Index; 6MWT, 6-Minute Walk Test; TUG, Timed Up and Go test; SCT, Stair Climbing Test; EQ-5D, Euro-QOL Five Dimensions; ROM, range of motion; PT, peak torque.

Table 3.

Correlations between postoperative self-reported physical function and quality of life and physical performance in patients 3 months after unilateral TKA

Variable Correlation coefficients (r)
WOMAC function EQ-5D
Age (y) 0.29* -0.30*
BMI (kg/m2) -0.08 -0.01
Self-reported physical function
 WOMAC-Pain 0.71* -0.67*
 WOMAC-Stiffness 0.24* -0.16*
 WOMAC-Function 1 -0.70*
Self-reported quality of life
 EQ-5D -0.70* 1
6MWT (m) 0.01 0.31*
TUG (sec) 0.22* -0.42*
SCT (sec)
 Ascent 0.24* -0.41*
 Descent 0.22* -0.43*
ROM (º)
 Affected ROM flexion 0.10 -0.07
 Affected ROM extension -0.14 0.14
Gait linear parameters
 Gait speed (m/s) -0.02 -0.03
 Cadence (steps/min) -0.03 0.22*
 Stride length (cm) -0.19* 0.10
 Gait cycle duration (sec) -0.04 0.04
 Stance phase duration (% of gait cycle) 0.00 -0.10
 Swing phase duration (% of gait cycle) 0.12 -0.06
 Double support duration (% of gait cycle) 0.11 -0.02
 Single support duration (% of gait cycle) 0.02 -0.09
Isometric strength test
 PT of the extensor of the operated knee (Nm) -0.15 0.14
 PT of the extensor of the non-operated knee (Nm) -0.13 0.11
 PT of the flexor of the operated knee (Nm) -0.38* 0.24*
 PT of the flexor of the non-operated knee (Nm) -0.47* 0.27*
 Extensor deficit (%) 0.16* -0.08
 Flexor deficit (%) 0.02 0.13

TKA, total knee arthroplasty; BMI, body mass index; WOMAC, Western Ontario and McMaster Universities Osteoarthritis Index; 6MWT, 6-Minute Walk Test; TUG, Timed Up and Go test; SCT, Stair Climbing Test; EQ-5D, Euro-QOL Five Dimensions; ROM, range of motion; PT, peak torque.

*

p<0.05.

Table 4.

Factors associated with self-reported physical function and quality of life by multivariate linear regression analysis

Outcome/independent factors Standardized (β) p-value Adjusted R2
Postoperative WOMAC-Function 0.64
 Age 0.15 0.011
 WOMAC-Pain 0.59 <0.001
 Stride length (cm) -0.15 0.009
 PT of the flexor of the non-operated knee (Nm) -0.31 <0.001
 Extensor deficit (%) 0.16 0.006
Postoperative EQ-5D 0.58
 Age -0.18 0.004
 WOMAC-Pain -0.62 <0.001
 SCT ascent -0.18 0.013
 Cadence (steps/min) 0.13 0.031

The logistic regression analyses were adjusted for age, sex, and body mass index (BMI).

WOMAC, Western Ontario and McMaster Universities Osteoarthritis Index; PT, peak torque; EQ-5D, Euro-QOL Five Dimensions; SCT, Stair Climbing Test.