Archives of Physical Medicine and Rehabilitation
Volume 90, Issue 2 , Pages 285-295, February 2009

Associates of Physical Function and Pain in Patients with Patellofemoral Pain Syndrome

  • Sara R. Piva, PhD, PT

      Affiliations

    • Department of Physical Therapy, University of Pittsburgh, Pittsburgh, PA
    • Corresponding Author InformationCorrespondence to Sara R. Piva, PhD, PT, Dept of Physical Therapy, SHRS, University of Pittsburgh, Room 6035, Forbes Tower, Pittsburgh, PA 15260
    • ,
  • G. Kelley Fitzgerald, PhD, PT

      Affiliations

    • Department of Physical Therapy, University of Pittsburgh, Pittsburgh, PA
    • ,
  • James J. Irrgang, PhD, PT

      Affiliations

    • Department of Orthopaedic Surgery, University of Pittsburgh, Pittsburgh, PA
    • ,
  • Julie M. Fritz, PhD, PT

      Affiliations

    • Department of Physical Therapy, University of Utah, Salt Lake City, UT
    • ,
  • Stephen Wisniewski, PhD

      Affiliations

    • Graduate School of Public Health, University of Pittsburgh, Pittsburgh, PA
    • ,
  • Gerald T. McGinty, MS, PT

      Affiliations

    • Physical Therapy Element of United States Air Force Academy, Colorado Springs, CO
    • ,
  • John D. Childs, PT, PhD

      Affiliations

    • Doctor Program of Physical Therapy, US Army–Baylor University, Fort Sam Houston, TX
    • ,
  • Manuel A. Domenech, PT, EdD

      Affiliations

    • Department of Rehabilitation Sciences, Texas Tech University Health Science Center, Odessa, TX
    • ,
  • Scott Jones, DPT

      Affiliations

    • Ramstein Outpatient Physical Medicine Clinic, Ramstein Air Base, Kaiserslautern, Germany
    • ,
  • Anthony Delitto, PhD, PT

      Affiliations

    • Department of Physical Therapy, University of Pittsburgh, Pittsburgh, PA

Article Outline

Abstract 

Piva SR, Fitzgerald GK, Irrgang JJ, Fritz JM, Wisniewski S, McGinty GT, Childs JD, Domenech MA, Jones S, Delitto A. Associates of physical function and pain in patients with patellofemoral pain syndrome.

Objectives

To explore whether impairment of muscle strength, soft tissue length, movement control, postural and biomechanic alterations, and psychologic factors are associated with physical function and pain in patients with patellofemoral pain syndrome (PFPS).

Design

Cross-sectional study.

Setting

Rehabilitation outpatient.

Participants

Seventy-four patients diagnosed with PFPS.

Interventions

Not applicable.

Main Outcome Measures

Measurements were self-reported function and pain; strength of quadriceps, hip abduction, and hip external rotation; length of hamstrings, quadriceps, plantar flexors, iliotibial band/tensor fasciae latae complex, and lateral retinaculum; foot pronation; Q-angle; tibial torsion; visual observation of quality of movement during a lateral step-down task; anxiety; and fear-avoidance beliefs.

Results

After controlling for age and sex, anxiety and fear-avoidance beliefs about work and physical activity were associated with function, while only fear-avoidance beliefs about work and physical activity were associated with pain.

Conclusions

Psychologic factors were the only associates of function and pain in patients with PFPS. Factors related to physical impairments did not associate to function or pain. Our results should be validated in other samples of patients with PFPS. Further studies should determine the role of other psychologic factors, and how they relate to anxiety and fear-avoidance beliefs in these patients.

Key words: Anxiety, Fear, Pain, Patella, Quality of life, Rehabilitation

List of Abbreviations: FABQ, Fear-Avoidance Beliefs Questionnaire, FABQ-PA, Fear-Avoidance Beliefs—physical activity, FABQ-W, Fear-Avoidance beliefs—work, ITB/TFL, iliotibial band/tensor fasciae latae, KOOS, knee injury and osteoarthritis outcome score, KOS-ADLS, Knee Outcome Survey–Activity of Daily Living Scale, NPRS, numerical pain rating scale, PFPS, patellofemoral pain syndrome

 

PATELLOFEMORAL PAIN SYNDROME accounts for 10% to 25% of all visits seen in physical therapy clinics.1, 2, 3 PFPS is characterized by anterior knee pain and crepitation in the patellofemoral joint during and after weight-bearing activities such as walking up or down stairs, squatting, and running. Pain while sitting with the knees flexed, occasional weakness, giving way, and catching sensations are also characteristics of PFPS.4 Based on either underlying theoretic constructs or on previous research, several factors or impairments such as muscle weakness, soft tissue tightness, structural and postural alterations of the lower extremities, quality of movement, and psychologic factors have been suggested to contribute to the occurrence of PFPS.5, 6 Table 1 summarizes the findings of studies with positive and negative results as well as the theoretic rationale about the contribution of several impairments in PFPS.

Table 1. Theoretical Rationale for the Contribution of Different Physical Impairments to PFPS Etiology and Summary of Previous Research Findings
FactorTheoretical Rationale for the Contribution of Physical Impairments to PFPSStudies That Support/Refute Theoretical Rationale and Their Findings
Muscle weakness
QuadricepsQuadriceps is responsible for the dynamic stabilization of the patella inside the trochlear groove.65SupportPatients with PFPS have weaker quadriceps than controls.50, 51 Quadriceps strengthening decreases pain and increases function in short-term follow-up in patients with PFPS.22, 66, 67
RefuteNo differences in quadriceps weakness between PFPS and controls.22, 59
Hip abductors and ERThese muscles help maintain pelvic stability by controlling femoral IR. Weakness may increase femoral IR, valgus knee moments, and compressive forces on the PF joint.67, 68, 69SupportPatients with PFPS have weaker hip muscles compared with matched controls.52
RefuteNo differences in hip strength between subjects with PFPS and an age-matched and sex-matched control group.70
Soft tissue tightness
QuadricepsTightness may pull the patella superiorly, increasing compression of the PF joint during physical activities.68SupportSubjects with PFPS have shorter quadriceps muscles than subjects without PFPS.22, 70, 71
HamstringsTightness may require higher quadriceps force production or cause slight knee flexion, resulting in increased PF joint reaction forces.SupportAssociation between limited hamstrings tightness and PFPS.70, 71
RefuteNo association between hamstrings tightness and PFPS.22
Plantar flexorsTightness may result in limited ankle dorsiflexion, which can be compensated for by excessive rotation of lower leg, altered Q-angle, and increased PF stresses.SupportAssociation between plantar flexor tightness and PFPS.22, 70
RefuteNo differences in ankle dorsiflexion between runners with and without PFPS.59
ITB/TFLTightness may pull the patella laterally and increase the stress over the lateral surface of the trochlear groove.1No studies.
Lateral retinaculumAdaptive shortening of the lateral retinaculum may be a consequence of the lateral displacement of the patella and may relate to PFPS.72, 73SupportManual stretch of the lateral retinaculum decreases PFPS.74
Structural and postural alterations of lower extremities
Increased foot pronationMay cause compensatory internal rotation of lower extremity, increase Q-angle, and pull patella laterally.SupportFemale overpronators who received foot orthotics to correct pronation reported less pain.75
RefuteFoot pronation was a predictor of anterior knee pain in runners. Pronation was higher in asymptomatic runners than in symptomatic runners.50
Altered Q-angleBoth increases and decreases in Q-angle may be associated with increased PF pressures.76SupportRunners with PFPS had significantly higher values of Q-angle than a control group without PFPS.59
RefuteNo association between Q-angle and etiology of PFPS.50, 77, 78
Increased lateral tibial torsionMay increase the tension in the infrapatellar tendon attachment and pull the patella laterally.SupportIncreased tibial torsion in patients with PFPS compared with subjects with no PFPS.79
Increased femoral anteversionMay result in lateral displacement of the patella and increases in the PF pressure.SupportPatients who failed to respond to a conservative treatment for PFPS had higher femoral anteversion than the group who improved with treatment.80
RefuteNo differences between an asymptomatic control group and patients with PFPS.79
Poor quality of movement
Patients with PFPS may exhibit altered movement patterns because of muscle imbalance or different timing between synergic muscles of LE, which may result in abnormal load distribution across the PF joint.5, 81, 82No studies.
Psychologic factors
AnxietyIn patients with other musculoskeletal conditions, the associations among pain, disability, and psychologic factors have been widely studied 29, 37, 83 and seem to support the biopsychosocial models that explain the development of chronic musculoskeletal conditions.16, 26SupportAnxious patients may not respond to PFPS treatments.20
Patients with PFPS had more anxiety and stress symptoms and higher levels of hostility than a control group.21
Fear avoidance beliefs No studies.

Abbreviations: ER, external rotators; IR, internal rotation; PF, patellofemoral; LE, lower extremity.

Although some of these impairments have theoretically or experimentally been associated with the presence of PFPS, it has not been determined whether these same impairments relate to the intensity of the patient's pain or the level of physical function in patients with PFPS. Identification of the key impairments related to pain and function may assist in delineating physical therapy treatment approaches for patients with PFPS. If it can be shown that particular impairments are associated with function and pain, targeting such impairments may improve the effectiveness of physical therapy for patients with PFPS. The aim of this study was to explore whether muscle strength, soft tissue length, postural and biomechanical alterations (foot pronation, quadriceps angle, lateral tibial torsion, femoral anteversion), quality of movement, and psychologic factors are associated with physical function and pain in patients with PFPS. We hypothesized that lower levels of function and higher pain intensity would be related to decreased muscle strength, decreased soft tissue flexibility, excessive foot pronation, excessive quadriceps angle, lateral tibial torsion and femoral anteversion, poor quality of movement, and higher levels of anxiety and fear-avoidance beliefs.

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Methods 

Subjects 

Subjects were recruited from rehabilitation clinics. Patients diagnosed by a physician with PFPS were invited to participate in this study. Patients were eligible to participate if they were between 12 and 50 years of age, had pain in 1 or both knees, had duration of signs and symptoms greater than 4 weeks, had a history of insidious onset not related to trauma, and had pain in the patellar region with at least 3 of the following: manual compression of the patella against the femur at rest or during an isometric knee extensor contraction, palpation of the postero-medial and postero-lateral borders of the patella, resisted isometric quadriceps femoris muscle contraction, squatting, stair climbing, kneeling, or prolonged sitting.

Exclusion criteria included patient report of previous patellar dislocation, knee surgery over the past 2 years, malignancy, systemic arthritis, musculoskeletal or neurologic lower extremity involvement that interfered with physical activity, and pregnancy. Additional exclusion criteria required special testing by the treating clinician and included peripatellar bursitis or tendonitis (focal tenderness at the lower pole of the patella or patella tendon), internal knee derangement (positive McMurray or Apley compression test), ligamentous knee injury or laxity (positive sag, Lachman, varus, or valgus tests), plica syndrome (local tenderness and synovial snap between 30° and 60° of knee flexion), Sinding-Larsen or Osgood-Schlatter disease (tenderness and swelling over the lower pole of the patella or at the tibial tubercle, respectively), and infection (redness, swelling, warmth around the knee).

Procedures 

All subjects signed an informed consent form approved by the University of Pittsburgh Institutional Review Board prior to participation in the study. Data for this study were collected in 1 session. After signing a consent form, subjects completed demographic questionnaires including activity level, and self-reported measures. After that, a physical therapist performed a physical examination and collected data on physical impairments. Subjects had 1 lower extremity tested. Subjects with bilateral symptoms had the most affected knee selected for testing based on self-reported pain.

Measures 

Demographics and biomedical 

Patients completed a questionnaire about their demographics, work activity, medication used for PFPS, and chronicity of the PFPS condition. Level of physical activity was measured using the rating of activity developed by the International Knee Documentation Committee.7 This rating describes 4 predefined levels of activity in subjects with knee pathologies: (1) jumping, pivoting, hard cutting, football, and soccer; (2) heavy manual work, skiing, and tennis; (3) light manual work, jogging, and running; and (4) activities of daily living and sedentary work.

Dependent variables 

Physical function was measured by the KOS-ADLS.8, 9 The KOS-ADLS is a knee-specific measure of physical function that assesses the effects of knee impairment on activities of daily living. Each item is scored on a 6-point Likert scale (0–5 points). The KOS-ADLS score is transformed to a 0 to 100–point scale with 100 indicating the absence of symptoms and functional limitations. The KOS-ADLS has been shown to be reliable, valid, and responsive in subjects with patellofemoral pain.8, 10

Pain intensity was measured using an 11-point NPRS anchored on the left with the phrase “no pain” and on the right with the phrase “worst imaginable pain.” NPRSs were shown to be reliable and valid.10, 11, 12 Subjects rated their current pain, the worst pain, and the least amount of pain in the last 24 hours, and the ratings were averaged.

Independent variables 

The independent variables included measures of physical impairment and responses to psychologic questionnaires. Measures of physical impairment included muscle strength (quadriceps femoris, hip abduction, hip external rotation), soft tissue length (hamstrings, quadriceps, gastrocnemius, soleus, ITB/TFL complex, lateral retinacular structures), foot pronation, Q-angle, tibial torsion, femoral anteversion, and quality of movement. The theoretical rationale for the contribution of these physical impairments to PFPS can be seen in table 1. Table 2 provides a description of how the physical impairments were measured and information about their reliability. Intertester reliability of the physical impairment measures was determined in a subsample of patients from this study. Additional details about the methods used to assess reliability have been reported elsewhere.13 Physical impairments with reliability coefficients below 0.6 were excluded (measure of femoral anteversion was excluded).

Table 2. Description of the Impairment Measures Used in the Study, the Technique Used, and the Intertester Reliability for the Measures
MeasureTechniqueIntertester Reliability
Quadriceps femoris strengthMeasured using an Isokinetic dynamometera. The subject was seated with the tested knee flexed to 75°. The subject was instructed to exert as much force as possible using an isometric contraction while extending the knee against the force-sensing arm of the dynamometer. The contraction was repeated for 4 trials, and the trial with the maximum torque was recorded.ICC above 0.80 in 2 studies.84, 85
Hip abduction strengthMeasured with a hand-held dynamometerb with the subject side-lying with the tested hip positioned superior in relationship to the nontested hip.63 The subject exerted an isometric contraction of the hip abductors against the resistance of the dynamometer positioned proximal to the lateral malleolus. The average force of 2 trials with 1 minute of rest between trials was recorded.ICC=0.85.13
Hip external rotation strengthMeasured with the hand-held dynamometer. Subject was lying prone with the tested knee flexed to 90° and the hip in neutral rotation. Subject exerted an isometric contraction of the hip external rotators against the resistance of the dynamometer positioned just proximal to the medial malleolus. The average force of 2 trials with 1 minute of rest between trials was recorded.ICC=0.79.13
Hamstrings lengthDetermined using the straight leg raise test with the subject lying supine.64 The lower extremity was passively lifted to the firm end feel. Angle of the straight leg raise test was measured with a gravity goniometerc placed over the distal tibia. The average measurement of 2 trials with 5-second pause between trials was recorded.ICC=0.92.13
Quadriceps femoris lengthDetermined by measuring passive knee flexion using the gravity goniometer placed over the distal tibia with the subject in the prone position. The average measurement of 2 trials with 5-second pause between trials was recorded.ICC=0.91.13
Plantar flexors lengthMeasured with a standard goniometer with the subject in prone. We measured the amount of ankle joint dorsiflexion with the knee extended and again with the knee flexed at 90°. Ankle dorsiflexion measured with the knee extended was used to account for the influence of gastrocnemius tightness. Measurement of ankle dorsiflexion with the knee bent was used to detect tightness of joint capsule or soleus muscle. The average measurement of 2 trials with 5-second pause between trials was recorded.
With knee extended ICC=0.92.13

With knee bent ICC=0.86.13

ITB/TFL complex lengthDetermined by using the Ober test.63 A gravity goniometer was placed over the distal portion of the ITB/TFL complex to record the result of the test as a continuous variable. The gravity goniometer was zeroed on a horizontal surface prior to the measurement. Negative values represented more tightness, whereas positive values (below horizontal) represented less tightness. The average measurement of 2 trials with 5-second pause between trials was recorded.ICC=0.97.13
Lateral retinacular structures lengthAssessed with the patellar tilt test.72 The examiner attempted to lift the lateral edge of the patella from the lateral femoral condyle with the subject in supine and the knee in full extension. The inability to lift the lateral boarder of the patella above the horizontal plane indicates a positive test for tightness. Lateral retinacular length was recorded as tight or normal.κ=0.71.13
Foot pronationMeasured by the navicular drop test as the difference in millimeters between height of the navicular at subtalar joint neutral position and that of the relaxed stance position.86, 87ICC=0.93.13
Q-angleMeasured with a standard goniometer as the angle formed by the intersection of a line from the anterior superior iliac spine to the center of patella with a line from the center of the patella to the tibial tubercle76 with the knee in full extension.ICC=0.70.13
Tibial torsionMeasured with the subject prone on a low table, and with the tested knee bent at 90°. The examiner measured the angle formed by the axis of the knee (imaginary line from the medial to lateral femoral epicondyle) and an imaginary line through the malleoli.88, 89ICC=0.70.13
Femoral anteversionMeasured with the Craig test with the participant in prone with the knee flexed to 90°.64 The degree of anteversion was estimated based on the angle of the lower leg with the vertical when the most prominent portion of the greater trochanter reaches the most lateral position or the horizontal plane.ICC=0.45.13
Quality of movementMeasured by visual observation during the lateral step-down test. The subject stood on a 20-cm-high step. The tester kneeled 1m in front of the subject and observed the task. The subject bent the tested knee until the contralateral leg gently contacted the floor and then re-extended the knee to the start position for 5 repetitions. The tester scored the movement according with the use of arm strategy (if subject used an arm strategy in an attempt to recover balance, 1 point was added), trunk movement (if the trunk leaned to any side, 1 point was added), plane of pelvis (if pelvis rotated or elevated one side compared with the other, 1 point was added), medial deviation of the knee (if the knee deviated medially and the tibial tuberosity crossed an imaginary vertical line over the second toe, 1 point was added, or, if the knee deviated medially and the tibial tuberosity crossed an imaginary vertical line over the medial border of the foot, 2 points were added), and steadiness of unilateral stance (if the subject stepped down on the nontested side, or if the subject wavered from side to side on the tested side, 1 point was added). Total score of 0 or 1 was classified as good quality of movement, score of 2 or 3 as medium quality, and score of 4 or above as poor quality of movement.κ=0.67.13

Abbreviations: ICC, intraclass correlation coefficient; κ, Kappa.

The psychologic questionnaires included self-reported measures of anxiety and fear-avoidance beliefs. Anxiety was measured using the Beck Anxiety Index.14 The Beck Anxiety Index has been shown to be reliable and valid to assess the presence and magnitude of anxiety symptoms.14, 15 It consists of 21 items, each scored 0 to 3. Possible score ranges from 0 to 63 with higher scores indicating higher levels of anxiety.

Fear-avoidance beliefs were measured using the FABQ. The FABQ quantifies the level of fear about work and physical activity and has primarily been studied in patients with low back pain.16 The instrument consists of 16 items subdivided into 2 subscales, one that measures FABQ-PA and another that measures FABQ-W. Each item is scored from 0 to 6. Possible scores range from 0 to 42 and 0 to 24 for the FABQ-W and FABQ-PA subscales, respectively. Higher scores represent increased fear-avoidance beliefs. Previous studies reported good reliability of the FABQ for patients with low back pain.17 To apply the FABQ in patients with PFPS, we adapted the form to use in patients with knee pathology as described by van Baar et al.18 We changed the descriptors of physical activities from physical activities such as bending, lifting, walking, or driving to physical activities such as walking, running, kneeling, or driving, and changed the word back to knee throughout the form. Cronbach α values of the FABQ-PA and FABQ-W subscales in our sample of patients with PFPS were 0.72 and 0.89, respectively.

Data Analysis 

Descriptive statistics were calculated and variables inspected for outliers. Correlations between predictors and criteria were determined by calculating Pearson or Spearman ρ coefficients, depending on the distribution of data. During the bivariate correlations, the effects of height and weight on variables of muscle strength or muscle length were partialed out to account for the effect of body size. Variables significantly associated with the criterion variables (α≤0.10) were included in the stepwise regression models. We built 2 forward regression models, the first using the KOS-ADLS scores as the criterion variable, and the second using pain scores as the criterion. We have chosen the forward selection procedure because we wanted to enter the independent variables sequentially (1 by 1) into the model according to their relationship with the dependent variable. Age and sex were controlled in the regression models. The decision to control age and sex was made a priori to decrease unexplained variability. Statistical significance was determined using an α level of 0.05. Significance of the linear association of each variable at each step was tested. Standardized β coefficients for each variable in the final model were calculated, and the significance of each was tested under the null hypothesis that the coefficient was not different from 0. Regression diagnostics (outliers, collinearity, residuals analysis) were performed to make sure the data were appropriate for the analysis.

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Results 

Seventy-four patients were recruited from 4 clinical sites. Twenty-five were from Minot Air Force Base, Minot, ND; 23 from Lackland Air Force Base, San Antonio, TX; 17 from Travis Air Force Base, Fairfield, CA; and 9 from University of Pittsburgh's Centers for Rehabilitation Services, Pittsburgh, PA. Participants across the 4 clinical sites were not significantly different on age, sex, height, weight, activity at work, use of pain medication, chronicity of pain, activity level, KOS-ADLS score, and NPRS score (tested with χ2 or Kruskal-Wallis). The population was comprised of civilians and military personnel. History and demographic characteristics are reported in table 3. Descriptive statistics and bivariate correlations between the predictor variables and KOS-ADLS and pain are shown in table 4. The variables lateral retinaculum tightness, anxiety, FABQ-PA, and FABQ-W demonstrated significant binary relationships with the KOS-ADLS score. The variables tibial torsion, anxiety, and FABQ-PA and FABQ-W were associated with pain.

Table 3. Descriptive Statistics of Patients' Characteristics
VariableN = 74
Age (y)29±9
Women (%)39(52)
Height (cm)170±12
Weight (Kg)76±16
Race(%)
White50(68)
Black8(11)
Hispanic8(11)
Asian3(4)
Native American1(1)
Other4(5)
Work(%)
Mostly sedentary18(24)
Sedentary, walking13(18)
Moderately active34(46)
Demanding9(12)
Use medication for pain(%)43(58)
Chronicity of pain(%)
1–3 mo27(36)
4–6 mo17(23)
7–12 mo7(10)
13–24 mo13(17)
>25 mo10(14)
Activity level(%)
Jumping, pivoting, cutting9(12)
Heavy manual work6(8)
Light manual work22(30)
Activities of daily living37(50)
KOS-ADLS66±17
NPRS average3.8±1.9
Current pain last 24h3.6±2.1
Worst pain last 24h5.6±2.4
Least pain last 24h2.3±1.9

NOTE. Values represent mean±SD or frequency (%).

Table 4. Descriptive Statistics of Potential Predictors and Their Correlations With KOS-ADLS and Pain
N = 74 Mean±SDCorrelation With Function (KOS-ADLS)Correlation With Pain (NPRS)
Quadriceps strength (Nm) 192±730.07−0.03
Hip abductors strength (Kg) 12±4.40.07−0.02
Hip external rotators strength (Kg) 15±5.50.13−0.14
Hamstrings length (deg) 78±12.2−0.12−0.15
Quadriceps length (deg) 132±11.40.140.05
Gastrocnemius length (deg) 7.4±5.60.15−0.13
Soleus length (deg) 14.8±5.4−0.140.03
Iliotibial band/tensor fascia lata length (deg) 13.7±9.6−0.120.14
Lateral retinaculum length—positive test (%) 54(73)0.220.14
Foot pronation (mm) 6.3±3.6−0.03−0.05
Q-angle (deg) 14.4±5.40.06−0.13
Tibial torsion (deg) 17.7±4.90.11−0.18
Quality of movement (%) Coded for analysis as:

Good

Medium

Poor


16(22)

47(64)

11(14)


Patients with good quality vs the others

Patients with medium quality vs the others


0.11


−0.11


−0.01


0.05

Beck Anxiety Index 4.9±6.7−0.450.34
FABQ-PA 16.85±4.8−0.320.31
FABQ-W 8.8±9.1−0.340.37

NOTE. For variables related to muscle strength (quadriceps and hip abductors, external rotators) and muscle length (quadriceps, hamstrings, gastrocnemius, soleus, ITB/TFL), we partialed out the effect of height and weight. Values represent mean±SD or frequency (%).

Abbreviation: deg, degrees.

Significant at P≤.10.

Significant at P≤.01.

The results of the forward regression on KOS-ADLS indicated that after controlling for age and sex, the addition of anxiety and the 2 scales of the FABQ did improve the model fit (table 5). Patients with more limitations in physical function had higher levels of anxiety and fear-avoidance beliefs about physical activity and work. The overall model accounted for 32% of variability in function. With age and sex controlled, anxiety contributed for an additional 18% explanation of variability in function, while FABQ-W and FABQ-PA added 6% and 5%, respectively. The variables sex, anxiety, and FABQ-W and FABQ-PA had β coefficients different from 0.

Table 5. Forward Regression Model on the Association With Physical Function in Patients With PFPS
Variables Total R2Δ R2dfP
Model 1
Age, sex.04.042,71.287
Model 2
Age, sex, anxiety.22.181,70<.001
Model 3
Age, sex, anxiety, FABQ-W.28.061,69.019
Model 4
Age, sex, anxiety, FABQ-W, FABQ-PA.32.051,68.032
Coefficients for model 4BβP
Age−0.09−0.05.640
Sex−7.29−0.22.041
Anxiety−0.71−0.28.013
FABQ-W−0.49−0.27.021
FABQ-PA−0.80−0.23.032

NOTE. Criterion variable equals KOS-ADLS score.

The results of the forward regression on pain (NPRS) indicated that when age and sex were controlled, the only variables associated with pain were FABQ-W and FABQ-PA (table 6). Patients who reported higher levels of pain also scored higher in the FABQ subscales. The overall model accounted for 22% of pain variability. The addition of FABQ-W and FABQ-PA accounted for increments in the explanation of the variation of pain in the order of 11% and 5%, respectively. The regression models had variance inflation factors less than 10, indicating no multicollinearity.19 Visual observation of jackknife residuals plots and box-plots of the standardized residuals revealed that the data fit the linear model assumptions.19

Table 6. Forward Regression Model on the Association With Pain in Patients With PFPS
Variables Total R2Δ R2dfP
Model 1
Age, sex.06.062, 71.105
Model 2
Age, sex, FABQ-W.17.111, 70.004
Model 3
Age, sex, FABQ-W, FABQ-PA.22.051, 69.037
Coefficients for model 3BβP
Age−0.03−0.14.224
Sex−0.06−0.02.892
FABQ-W0.070.31.007
FABQ-PA0.090.23.037

NOTE. Criterion variable equals NPRS.

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Discussion 

Although most physical impairment factors explored during this study have been theoretically or experimentally related to the presence of PFPS, the associates of function and pain in this cohort of patients with PFPS were all psychologic factors. Anxiety was the stronger associate of function, followed by FABQ-W and FABQ-PA. FABQ-W and FABQ-PA were the only associates of pain intensity in this sample. These findings may indicate that psychologic factors are overlooked in patients with PFPS.

Prior studies have shown that patients with PFPS have a different psychologic profile than controls. Carlsson et al20 compared personality characteristics in patients with PFPS and matched controls. They reported that patients with PFPS had significantly greater depression, hostility, and passive attitude than the matched controls. Witonski21 investigated the psychologic profile of patients with anterior knee pain compared with a control group matched by age and reported that patients with anterior knee pain manifested more anxiety, depression, aggression/hostility, and stress symptoms. One study suggested that psychologic factors may contribute to PFPS. Witvrouw et al22 followed 282 athletes during 2 years to determine the risk factors associated with the development of PFPS. They reported that the subjects who developed PFPS looked less for social support and diverted their attention less from a problem than the subjects who did not develop PFPS.22

To our knowledge, this is the first study that reported an association between anxiety and physical function in patients with PFPS. Cross-sectional studies in patients with other musculoskeletal conditions have reported similar results. Montin et al23 investigated the association between anxiety and physical function in patients prior to total hip arthroplasty. They reported that anxiety impaired physical function in these patients. Soderlin et al24 investigated a group of patients with rheumatoid arthritis and reported that anxiety was associated with physical function. In a longitudinal study, Mehta et al25 examined the relationship between anxiety and functional decline in 2940 well functioning adults. They reported that, while anxiety did not associate with decline in performance-based measures of function, it was associated with declines in self-reported functioning (adults with more anxiety were more likely to report incident mobility difficulty). At this time, the clinical implication of the relationship anxiety and function in patients with PFPS is unknown. Before recommending the inclusion of anxiety measures in clinical practice and referral of anxious patients to psychologic expertise, we believe further longitudinal research should determine the role of anxiety on functional outcomes (using both performance-based and self-reported measures of function).

We have included fear-avoidance beliefs in this study because we had observed in clinical practice that patients with PFPS who engaged in physical activities regardless of their knee pain appeared to function and progress through rehabilitation better than those who avoided activities because of pain. We speculated that perhaps the behavior of these patients could fit the fear-avoidance model.26, 27 The model offers a framework to the development of chronic pain. The model proposes that an individual's response to pain may fall somewhere along a continuum between 2 extremes: the adaptive response or confrontation, and the nonadaptive response or avoidance.27, 28 The confronter is likely to view pain as an annoyance and temporary, and is therefore prepared to confront the pain. The confronter is motivated to return to work and normal activities, and thus achieves complete recovery. The avoider responds to painful stimuli by avoiding activities anticipated to cause pain. Avoidance may result in poor behavioral performance, reduced activity levels, overstated pain perception, increased disability, and a subsequent reinforcement of catastrophic thoughts, completing the fear-avoidance circle.16, 26, 27, 28, 29, 30

We have found only 1 study investigating the relationship of physical function and fear of movement/reinjury in patients with lower extremity musculoskeletal condition of similar age. Kvist et al31 surveyed 62 patients who had anterior cruciate ligament reconstruction 3 to 4 years before. While they reported no association between fear of reinjury and the functional subscales of the KOOS, they found that high fear of reinjury was correlated with a low score on the knee-related quality of life subscale of the KOOS. Furthermore, the patients who did not return to their preinjury activity level had more fear of reinjury because of movement.

The association between fear-avoidance beliefs and physical function in this sample of patients with PFPS agrees with findings from cross-sectional studies in patients with chronic and acute low back pain, work-related neck-shoulder pain, cervical spine pain, and a variety of chronic musculoskeletal pain conditions.29, 32, 33, 34, 35, 36, 37, 38 While patients with PFPS had generally similar scores in the FABQ-PA to patients with chronic low back and neck pain, the scores in the FABQ-W were lower, only comparable to scores of patients with work-related neck-shoulder pain. While the magnitude of the association between the 2 subscales of the FABQ and physical function in our sample (r=0.32 and 0.34) was within the ranges reported for patients with chronic lumbar pain and neck pain (r=0.22–0.48), the associations between fear-avoidance beliefs and pain in our sample (r=0.31 and 0.37) were slightly higher than the reports in patients with lumbar and neck pain (r=0.03–0.41).16, 26, 29, 32, 36 With regard to the association between fear-avoidance and pain, although Vlaeyen and Linton39 suggested that pain intensity is not a primary factor in avoidance behavior or disability, several studies suggested that high pain intensity is a threatening experience that drives avoidance,40 and that pain intensity has considerable contribution in explaining disability.41 In patients with knee and hip osteoarthritis, both pain intensity and pain-related fear were associated with function.42 We believe the association of fear-avoidance behavior with function and pain in this exploratory study is not sufficient to confirm the fear-avoidance model in this population.

The main focus of this study was the physical impairments rather than the psychologic variables. Therefore, we did not plan to study how pain intensity, fear-avoidance behaviors, anxiety, and function relate to or interact with each other, nor have we explored how other potential contributors to the fear-avoidance model affect pain or function. Pain was chosen as a dependent variable in conjunction with function because pain is the main complaint of patients with PFPS. At this juncture, our findings suggest that additional studies of the psychologic factors related to function and pain in patients with PFPS deserve higher priority, and the role of psychologic factors in the treatment of patients with PFPS should also be investigated. In other musculoskeletal conditions, psychologic variables such as anxiety, fear-avoidance beliefs, depressive symptoms, catastrophizing behavior, feelings of appraisal of control, and self-efficacy have been more extensively investigated, and their interactions, temporal relationships, and role on disability are better understood.26, 43, 44, 45, 46, 47, 48

A surprising and perhaps most confronting aspect of our results was the lack of association of measures of muscle function (muscle strength and muscle length), structural and postural characteristics, and quality of movement with physical function and pain in this sample of patients with PFPS. The studies that offered the theoretical rationale for the contribution of these physical impairments to PFPS have tested only the difference in magnitude of these impairments between patients with PFPS and controls (see table 1). These studies have not tested whether these same physical impairments were also related to the intensity of the patient's pain or the level of physical function in these patients.

With regard to measures of muscle strength, we hypothesized that stronger muscles would relate to better function and less pain. This hypothesis was based on findings that quadriceps strength related to function in patients with knee osteoarthritis,48, 49 and on evidence that patients with PFPS are weaker than patients without PFPS.22, 50, 51, 52 We are aware of only 1 study that investigated the correlation between function and muscle weakness in patients with PFPS.51 Powers et al51 used the functional assessment questionnaire to assess functional limitations and reported no correlation between function and quadriceps strength, which is in agreement with our findings. Quadriceps strength values for patients in our study and the Powers51 study were similar, with a mean of 2.4±0.78 Nm/kg in the Powers51 study and 2.5±0.76 Nm/kg in our study. The relationship between quadriceps strength and function has been investigated in patients with deficient or reconstructed anterior cruciate ligament. Comparison between populations with deficient or reconstructed anterior cruciate ligament and PFPS seem appropriate because the age and activity profiles of these patients are similar. Results of studies in patients with deficient or reconstructed anterior cruciate ligament are controversial. Some studies reported no association,53, 54 whereas others have reported a significant association between quadriceps strength and function.55, 56

The lack of association between muscle tightness impairments and pain and function in our sample cannot be explained by particular characteristics of our sample with regard to muscle tightness. Values of muscle tightness in our study were not different from those of other studies that used similar measurement techniques. For quadriceps tightness in PFPS, studies reported means of 124°±12°22 and 136°±16°,57 while we had a mean of 132°±11°. For hamstrings tightness in PFPS, 1 study reported a mean of 91°±20°,22 while ours was 78°±12°. Because there is a negative correlation between age and muscle length,58 our lower values may be explained by the age differences (the mean age in our study was 29 years and in the other study was 19 years). Reported ankle dorsiflexion in PFPS was 6.4°,59 while our mean value was 7.4°. We are not aware of studies performed with patients with PFPS that reported measures of ITB/TFL complex tightness.

The lack of relationship with postural or structural alterations may be explained in part by the fact that our sample seemed within normal limits in these measures. Studies that investigated the navicular drop test in healthy adults reported values from 3.6±3.3 mm60 to 9.0±4.2 mm.61, 62 In our study, the mean navicular drop test value was 6.3±3.6 mm. Our values of Q-angle (12° for men and 16° for women) are consistent with the normative values for healthy individuals of 10° for men and 15° for women.63 In a sample of men and women runners with PFPS, the Q-angle had a mean of 17° and SE 0.6°.59 Our mean value of tibial torsion was 18°, which is within the proposed normal values of 13° to 18°.64

In our study, we tried to investigate several of the impairments that have been somehow related to PFPS and that could be tested in a physical therapy clinic. We were surprised to find that our hypothesis about the association between physical impairments and function and pain was refuted. Although the physical impairments were not associated with pain and function in this cross-sectional study, longitudinal studies have yet to be conducted to investigate whether changes in these impairments relate to functional and pain outcome in these patients. Longitudinal studies are needed to understand best the relationship between physical impairments and functional outcome in patients with PFPS.

Study Limitations 

This study has some limitations. Because this was a cross-sectional study with no time sequence, it is not possible to establish any causal relationship between the psychologic factors and pain and physical function. Longitudinal studies are needed to investigate whether patients with prior anxiety and fear-avoidance behavior can predict higher pain and more dysfunction at a later time. Consideration should also be given to the fact that all measures of psychologic factors and pain and physical function were self-reported. The associations between them may have been influenced by method invariance bias. Further research should investigate whether the same associations would be present if physical function was measured by performance-based methods. Furthermore, in our regression models, only around one third of the variability in function and pain were explained. There may exist other impairments or factors that contribute to function and pain in this population that have not been investigated in this study.

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Conclusions 

Our study indicates that psychologic factors were the only associates of function and pain in this sample of patients with PFPS. Patients with more limitations in physical function reported higher levels of anxiety and fear-avoidance beliefs about work and physical activity. Patients with more pain reported higher levels of fear-avoidance beliefs about work and physical activity. Factors related to physical impairments did not associate with function or pain in this sample. Our preliminary results should be validated in other samples of patients with PFPS. Further studies should also determine the role of other psychologic factors and how they relate to anxiety and fear-avoidance beliefs in these patients. Exploration of other psychologic factors may provide insight into developing a biopsychosocial model of functional limitations in patients with PFPS.

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References 

  1. Brody LT, Thein JM. Nonoperative treatment for patellofemoral pain. J Orthop Sports Phys Ther. 1998;28:336–344
  2. Insall J. Current concepts review: patella pain. J Bone Joint Surg Am. 1982;64:147–152
  3. Thomee R. A comprehensive treatment approach for patellofemoral pain syndrome in young women. Phys Ther. 1997;77:1690–1703
  4. Thomee R, Augustsson J, Karlsson J. Patellofemoral pain syndrome: a review of current issues. Sports Med. 1999;28:245–262
  5. Grabiner MD, Koh TJ, Draganich LF. Neuromechanics of the patellofemoral joint. Med Sci Sports Exerc. 1994;26:10–21
  6. Sikorski JM. Importance of femoral rotation in chondromalacia patellae as shown by serial radiography. J Bone Joint Surg Br. 1979;61:435–442
  7. Hefti R, Muller W, Jakob RP, Stäubli HU. Evaluation of knee ligament injuries with the IKDC form. Knee Surg Sports Traumatol Arthrosc. 1993;1:226–234
  8. Irrgang JJ, Snyder-Mackler L, Wainner RS, Fu FH, Harner CD. Development of a patient-reported measure of function of the knee. J Bone Joint Surg Am. 1998;80:1132–1145
  9. Borsa PA, Lephart SM, Irrgang JJ. Comparison of performance-based and patient-reported measures of function in anterior-cruciate-ligament-deficient individuals. J Orthop Sports Phys Ther. 1998;28:392–399
  10. Marx RG, Jones EC, Allen AA, et al. Reliability, validity, and responsiveness of four knee outcome scales for athletic patients. J Bone Joint Surg Am. 2001;83:1459–1469
  11. Jensen MP, Turner JA, Romano JM. What is the maximum number of levels needed in pain intensity measurement?. Pain. 1994;58:387–392
  12. Katz J, Melzack R. Measurement of pain. Surg Clin North Am. 1999;79:231–252
  13. Piva SR, Fitzgerald K, Irrgang JJ, et al. Reliability of measures of impairments associated with patellofemoral pain syndrome. BMC Musculoskelet Disord. 2006;7:33
  14. Beck AT, Epstein N, Brown G, Steer RA. An inventory for measuring clinical anxiety: psychometric properties. J Consult Clin Psychol. 1988;56:893–897
  15. Steer RA, Ranieri WF. Further evidence for the validity of the Beck Anxiety Inventory with psychiatric outpatients. J Anxiety Dis. 1993;7:195–205
  16. Waddell G, Newton M, Henderson D, Somerville I, Main CJ. Fear-Avoidance Beliefs Questionnaire (FABQ) and the role of fear-avoidance beliefs in chronic low back pain and disability. Pain. 1993;52:157–168
  17. Jacob T, Baras M, Epstein L. Low back pain: Reliability of a set of pain measurement tools. Arch Phys Med Rehabil. 2001;82:735–742
  18. van Baar ME, Dekker J, Oostendorp RA, et al. The effectiveness of exercise therapy in patients with osteoarthritis of the hip or knee: a randomized clinical trial. J Rheumatol. 1998;25:2432–2439
  19. Kleinbaum DG, Kupper LL, Muller KE, et al. Applied regression analysis and other multivariable methods. 3rd ed.. Pacific Grove: Duxbury Press; 1998;
  20. Carlsson AM, Werner S, Mattlar CE, Edman G, Puukka P, Eriksson E. Personality in patients with long-term patellofemoral pain syndrome. Knee Surg Sports Traumatol Arthrosc. 1993;1:178–183
  21. Witonski D. Anterior knee pain syndrome. Int Orthop. 1999;23:341–344
  22. Witvrouw E, Lysens R, Bellemans J, Cambier D, Vanderstraeten G. Intrinsic risk factors for the development of anterior knee pain in an athletic population: a two-year prospective study. Am J Sports Med. 2000;28:480–489
  23. Montin L, Leino-Kilpi H, Katajisto J, Lepistö J, Kettunen J, Suominen T. Anxiety and health-related quality of life of patients undergoing total hip arthroplasty for osteoarthritis. Chronic Illn. 2007;3:219–227
  24. Soderlin MK, Hakala M, Nieminen P. Anxiety and depression in a community-based rheumatoid arthritis population. Scand J Rheumatol. 2000;29:177–183
  25. Mehta KM, Yaffe K, Brenes GA, et al. Anxiety symptoms and decline in physical function over 5 years in the Health, Aging and Body Composition Study. J Am Geriatr. 2007;55:265–270
  26. Vlaeyen JW, Seelen HA, Peters M, et al. Fear of movement/(re)injury and muscular reactivity in chronic low back pain patients: an experimental investigation. Pain. 1999;82:297–304
  27. Lethem J, Slade PD, Troup JD, Bentley G. Outline of a fear avoidance model of exaggerated pain perception—I. J Behav Res Ther. 1983;21:401–408
  28. Slade PD, Troup JD, Lethem J, Bentley G. The fear-avoidance model of exaggerated pain perception—II. J Behav Res Ther. 1983;21:409–416
  29. Crombez G, Vlaeyen JW, Heuts PH, Lysens R. Pain-related fear is more disabling than pain itself: evidence on the role of pain-related fear in chronic back pain disability. Pain. 1999;80:329–339
  30. Klenerman L, Slade PD, Stanley IM, et al. The prediction of chronicity in patients with an acute attack of low-back-pain in a general-practice setting. Spine. 1995;20:478–484
  31. Kvist J, Ek A, Sporrstedt K, Good L. Fear of re-injury: a hindrance for returning to sports after anterior cruciate ligament reconstruction. Knee Surg Sports Traumatol Arthrosc. 2005;13:393–397
  32. George SZ, Fritz JM, Erhard RE. A comparison of fear-avoidance beliefs in patients with lumbar spine pain and cervical spine pain. Spine. 2001;26:2139–2145
  33. Badcock LJ, Lewis M, Hay EM, McCarney R, Croft PR. Chronic shoulder pain in the community: a syndrome of disability or distress?. Ann Rheum Dis. 2002;61:128–131
  34. Denison E, Asenlof P, Lindberg P. Self-efficacy, fear avoidance, and pain intensity as predictors of disability in subacute and chronic musculoskeletal pain patients in primary health care. Pain. 2004;111:245–252
  35. Woby SR, Watson PJ, Roach NK, Urmston M. Are changes in fear-avoidance beliefs, catastrophizing, and appraisals of control, predictive of changes in chronic low back pain and disability?. Eur J Pain. 2004;8:201–210
  36. Huis't Veld RM, Vollenbroek-Hutten MM, Groothuis-Oudshoorn KC, Hermens HJ. The role of the fear-avoidance model in female workers with neck-shoulder pain related to computer work. Clin J Pain. 2007;23:28–34
  37. Turk DC, Okifuji A. Psychological factors in chronic pain: evolution and revolution. J Consult Clin Psychol. 2002;70:678–690
  38. Verbunt JA, Seelen HA, Vlaeyen JW, van der Heijden GJ, Knottnerus JA. Fear of injury and physical deconditioning in patients with chronic low back pain. Arch Phys Med Rehabil. 2003;84:1227–1232
  39. Vlaeyen JW, Linton SJ. Fear-avoidance and its consequences in chronic musculoskeletal pain: a state of the art. Pain. 2000;85:317–332
  40. Eccleston C, Crombez G. Pain demands attention: a cognitive-affective model of the interruptive function of pain. Psychol Bull. 1999;125:356–366
  41. Leeuw M, Goossens ME, Linton SJ, Crombez G, Boersma K, Vlaeyen JW. The fear-avoidance model of musculoskeletal pain: current state of scientific evidence. J Behav Med. 2007;30:77–94
  42. Heuts PH, Vlaeyen JW, Roelofs J, et al. Pain-related fear and daily functioning in patients with osteoarthritis. Pain. 2004;110:228–235
  43. Boone DC, Azen SP. Normal range of motion of joints in male subjects. J Bone Joint Surg Am. 1979;61:756–759
  44. Fritz JM, George SZ, Delitto A. The role of fear-avoidance beliefs in acute low back pain: relationships with current and future disability and work status. Pain. 2001;94:7–15
  45. Turner JA, Clancy S. Strategies for coping with chronic low back pain: relationship to pain and disability. Pain. 1986;24:355–364
  46. Lacker JM, Carosella AM, Feuerstein M. Pain expectancies, pain, and functional self-efficacy expectancies as determinants of disability in patients with chronic low back disorders. J Consult Clin Psychol. 1996;64:212–220
  47. Weiner DK, Haggerty CL, Kritchevsky SB, et al. How does low back pain impact physical function in independent, well-functioning older adults? (Evidence from the Health ABC Cohort and implications for the future). Pain Med. 2003;4:311–320
  48. Hurley MV, Scott DL, Rees DJ, Newham J. Sensorimotor changes and functional performance in patients with knee osteoarthritis. Ann Rheum Dis. 1997;56:641–648
  49. Fitzgerald GK, Piva SR, Irrgang JJ, Bouzubar F, Starz TW. Quadriceps activation failure as a moderator of the relationship between quadriceps strength and physical function in individuals with knee osteoarthritis. Arthritis Rheum. 2004;51:40–48
  50. Duffey MJ, Martin DF, Cannon DW, Craven T, Messier SP. Etiologic factors associated with anterior knee pain in distance runners. Med Sci Sports Exerc. 2000;32:182512
  51. Powers CM, Perry J, Hsu A, Hislop JH. Are patellofemoral pain and quadriceps femoris muscle torque associated with locomotor function?. Phys Ther. 1997;77:1063–1075
  52. Ireland ML, Willson JD, Ballantyne BT, Davis IM. Hip strength in females with and without patellofemoral pain. J Orthop Sports Phys Ther. 2003;33:671–676
  53. Chmielewski TL, Wilk KE, Snyder-Mackler L. Changes in weight-bearing following injury or surgical reconstruction of the ACL: relationship to quadriceps strength and function. Gait Posture. 2002;16:87–95
  54. Keays SL, Bullock-Saxton J, Keays AC, Newcombe P. Muscle strength and function before and after anterior cruciate ligament reconstruction using semitendonosus and gracilis. Knee. 2001;8:229–234
  55. Keays SL, Bullock-Saxton JE, Newcombe P, Keays AC. The relationship between knee strength and functional stability before and after anterior cruciate ligament reconstruction. J Orthop Res. 2003;21:231–237
  56. Wilk KE, Romaniello WT, Soscia SM, Arrigo CA, Andrews JR. The relationship between subjective knee scores, isokinetic testing, and functional testing in the ACL-reconstructed knee. J Orthop Sports Phys Ther. 1994;20:60–73
  57. Witvrouw E, Lysens R, Bellemans J, Peers K, Vanderstraeten G. Open versus closed kinetic chain exercises for patellofemoral pain: a prospective, randomized study. Am J Sports Med. 2000;28:687–694
  58. Gajdosik RL, Vander Linden DW, Williams AK. Influence of age on concentric isokinetic torque and passive extensibility variables of the calf muscles of women. Eur J Appl Physiol Occup Physiol. 1996;74:279–286
  59. Messier SP, Davis SE, Curl WW, Lowery RB, Pack RJ. Etiologic factors associated with patellofemoral pain in runners. Med Sci Sports Exerc. 1991;23:1008–1015
  60. Bennett JE, Reinking MF, Pluemer B, et al. Factors contributing to the development of medical tibial stress syndrome in high school runners. J Orthop Sports Phys Ther. 2001;31:504–510
  61. Picciano AM, Rowlands MS, Worrell T. Reliability of open and closed kinetic chain subtalar joint neutral positions and navicular drop test. J Orthop Sports Phys Ther. 1993;18:553–558
  62. Loudon JK, Jenkins W, Loudon KL. The relationship between static posture and ACL injury in female athletes. J Orthop Sports Phys Ther. 1996;24:91–97
  63. Kendall FP, McCreary EK, Provance PG. Muscles testing and function. 4th ed.. Baltimore: Williams & Wilkins; 1993;
  64. Magee D. Orthopaedic physical assessment. 2nd ed.. Philadelphia: W. B. Saunders; 1992;
  65. Fulkerson JP. Disorders of the patellofemoral joint. 3rd ed.. Baltimore: Williams & Wilkins; 1997;
  66. McMullen W, Roncarati A, Koval P. Static and isokinetic treatments of chondromalacia patella: a comparative investigation. J Orthop Sports Phys Ther. 1990;12:256–266
  67. Stiene HA, Brosky T, Reinking MF, Nyland J, Mason MB. A comparison of closed kinetic chain and isokinetic joint isolation exercise in patients with patellofemoral dysfunction. J Orthop Sports Phys Ther. 1996;24:136–141
  68. Hertling D, Kessler RM. Management of common musculoskeletal disorders. In: 3rd ed.. Philadelphia: Lippincott; 1996;p. 315–378
  69. McConnell J, Fulkerson JP. The Knee: Patellofemoral and soft tissue injuries. In:  Zachazewski JE,  Magee DJ,  Quillen WS editor. Athletic injuries and rehabilitation. Philadelphia: W. B. Saunders; 1996;p. 693–728
  70. Piva SR, Goodnite EA, Childs JD. Strength around the hip and flexibility of soft tissues in individuals with and without patellofemoral pain syndrome. J Orthop Sports Phys Ther. 2005;35:793–801
  71. Smith AD, Stroud L, McQueen C. Flexibility and anterior knee pain in adolescent elite figure skaters. J Pediatr Orthop. 1991;11:77–82
  72. Kolowich PA, Paulos LE, Rosenberg TD, Farnsworth S. Lateral release of the patella: indications and contraindications. Am J Sports Med. 1990;18:359–365
  73. Sanchis-Alfonso V, Rosello-Sastre E, Martinez-Sanjuan V. Pathogenesis of anterior knee pain syndrome and functional patellofemoral instability in the active young. Am J Knee Surg. 1999;12:29–40
  74. Rowlands BW, Brantingham JW. The efficacy of patella mobilization in patients suffering from patellofemoral pain syndrome. J Neuromusculoskelet Syst. 1999;7:142–149
  75. Eng JJ, Pierrynowski MR. Evaluation of soft foot orthotics in the treatment of patellofemoral pain syndrome. Phys Ther. 1993;73:62–68
  76. Huberti HH, Hayes WC. Patellofemoral contact pressures: the influence of q-angle and tendofemoral contact. J Bone Joint Surg Am. 1984;66:715–724
  77. Karlsson J, Thomee R, Sward L. Eleven year follow-up of patello-femoral pain syndrome. Clin J Sport Med. 1996;6:222
  78. Kannus P, Natri A, Paakkala T, Järvinen M. An outcome study of chronic patellofemoral pain syndrome: seven-year follow-up of patients in a randomized, controlled trial. J Bone Joint Surg Am. 1999;81:355–363
  79. Eckhoff DG, Brown AW, Kilcoyne RF, Stamm ER. Knee version associated with anterior knee pain. Clin Orthop Relat Res. 1997;152–155Jun
  80. Eckhoff DG, Montgomery WK, Kilcoyne RF, Stamm ER. Femoral morphometry and anterior knee pain. Clin Orthop Relat Res. 1994;64–68May
  81. Vaatainen U, Airaksinen O, Jaroma H, Kiviranta I. Decreased torque and electromyographic activity in the extensor thigh muscles in chondromalacia patellae. Int J Sports Med. 1995;16:45–50
  82. Cesarelli M, Bifulco P, Bracale M. Study of the control strategy of the quadriceps muscles in anterior knee pain. IEEE Trans Rehabil Eng. 2000;8:330–341
  83. van der Windt DA, Kuijpers T, Jellema P, van der Heijden GJ, Bouter LM. Do psychological factors predict outcome in both low-back pain and shoulder pain?. Ann Rheum Dis. 2007;66:313–319
  84. Lin YC, Davey RC, Cochrane T. Tests for physical function of the elderly with knee and hip osteoarthritis. Scand J Med Sci Sports. 2001;11:280–286
  85. Merlini L, Dell'Accio D, Granata C. Reliability of dynamic strength knee muscle testing in children. J Orthop Sports Phys Ther. 1995;22:73–76
  86. McPoil TG, Knecht HG, Schuit D. A survey of foot types in normal females between the ages of 18 and 30 years. J Orthop Sports Phys Ther. 1988;9:406–409
  87. Sell KE, Verity TM, Worrell TW, Pease BJ, Wigglesworth J. Two measurement techniques for assessing subtalar joint position: a reliability study. J Orthop Sports Phys Ther. 1994;19:162–167
  88. Giallonardo LM. Clinical evaluation of foot and ankle dysfunction. Phys Ther. 1988;68:1850–1856
  89. Gross MT. Lower quarter screening for skeletal malalignment—suggestions for orthotics and shoewear. J Orthop Sports Phys Ther. 1995;21:389–405
  • a Biodex System 3 Pro; Biodex Medical Systems, 20 Ramsay Rd, Shirley, NY 11967-4704.
  • b Lafayette Manual Muscle Test System; Lafayette Instrument Company, 3700 Sagamore Pkwy N, Lafayette, IN 47903.
  • c Gravity goniometer; MIE Medical Research Ltd, 6 Wortley Moor Rd, Leeds LS12 4JF, UK.

 Supported by the Clinical Research Grant Program of the Orthopaedic Section of the American Physical Therapy Association, and the Pennsylvania Physical Therapy Association Research Fund.

 No commercial party having a direct financial interest in the results of the research supporting this article has or will confer a benefit on the authors or on any organization with which the authors are associated.

 Reprints are not available from the author.

PII: S0003-9993(08)01632-8

doi:10.1016/j.apmr.2008.08.214

Archives of Physical Medicine and Rehabilitation
Volume 90, Issue 2 , Pages 285-295, February 2009

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