What Can the First 2 Months Tell Us About Outcomes After Anterior Cruciate Ligament Reconstruction?

Jesse C Christensen; Laura R Goldfine; Tyler Barker; Dave S Collingridge

doi:10.4085/1062-6050-49.3.95

. 2015 May;50(5):508–515. doi: 10.4085/1062-6050-49.3.95

What Can the First 2 Months Tell Us About Outcomes After Anterior Cruciate Ligament Reconstruction?

Jesse C Christensen ^*, Laura R Goldfine, Tyler Barker ^*, Dave S Collingridge ^†

PMCID: PMC4560015 PMID: 25594914

Abstract

Context:

Substantial research has been conducted on anterior cruciate ligament reconstruction (ACLR) to evaluate patient outcomes. However, little attention has been given to outcomes during the early phase of recovery and how early deficits affect both short- and long-term outcomes.

Objective:

To identify relationships between demographic (age, sex, and body mass index [BMI]) and intraoperative (isolated ACLR versus primary ACLR + secondary procedures), and postoperative (range-of-motion [ROM] and peak isometric knee-extension force [PIF]) variables during the first 2 months after ACLR using self-reported outcomes.

Design:

Cohort study.

Setting:

Outpatient orthopaedic hospital.

Patients or Other Participants:

A total of 63 patients (38 men, 25 women; age = 33.0 ± 12.1 years; BMI = 26.3 ± 6.5 kg/m²) who underwent ACLR.

Main Outcome Measure(s):

Demographic, intraoperative, and postoperative variables were collected at 1 and 2 months after ACLR and were compared with International Knee Documentation Committee (IKDC) Subjective Knee Evaluation Form scores at 1, 2, and ≥12 months.

Results:

Significant relationships were identified between ≥12-month IKDC scores and the 1-month (Pearson correlation, r = 0.283, r² = 0.08; P = .025) and 2-month (r = 0.301, r² = 0.09; P = .017) IKDC scores. After controlling for other variables, we found that the PIF ratio measures at 1 and 2 months were positively associated with 1- and 2-month IKDC scores (P < .001) and BMI was negatively associated with both 1- and 2-month IKDC scores (P < .05). One-month IKDC scores were related to the 1-month difference in knee-flexion ROM (P = .04).

Conclusions:

The IKDC scores during the first 2 months were positively correlated with patients' perceptions of function on long-term IKDC scores. It also appears that improvements in lower extremity strength and flexion ROM deficits were positively associated with short-term IKDC scores. Higher BMI was negatively associated with patients' perceptions of function on short-term IKDC scores.

Key Words: force output, knee, motion, rehabilitation, International Knee Documentation Committee

Key Points

After anterior cruciate ligament reconstruction, patients' subjective International Knee Documentation Committee (IKDC) scores at both 1- and 2-month follow-ups had fair but significantly positive associations with the ≥12-month IKDC score.
The ratio of surgical- to nonsurgical-limb measures of peak isometric knee-extension force at 1 and 2 months was positively associated with 1- and 2-month IKDC scores.
The difference in flexion range of motion between the surgical and nonsurgical limbs had a significant positive relationship with 1-month IKDC score.
Body mass index had a significant negative association with both 1- and 2-month IKDC scores.
No significant relationships were noted between demographic, intraoperative, or postoperative variables during the first 2 months and IKDC scores at ≥12 months after anterior cruciate ligament reconstruction.

Anterior cruciate ligament reconstruction (ACLR) is a commonly performed surgical procedure in active individuals; injury to this ligament is more frequent in sports requiring multidirectional activities, with an estimated incidence of 81 per 100 000 persons.¹^–³ Discrepancies in the literature exist when evaluating the effects of surgical intervention and rehabilitation on postoperative outcomes. Reconstruction of this ligament and postoperative rehabilitation have been shown to be effective in restoring functional stability of the knee,⁴ minimizing the development of osteoarthritis (OA),⁵^,⁶ and returning patients to their previous level of function.⁵^,⁷ However, persistent lower extremity muscle weakness,⁸^,⁹ insufficient dynamic knee stability,¹⁰ and increased risk of posttraumatic arthrosis³ have also been reported. A considerable number of individuals are unable to return to competitive sports despite successful rehabilitation or ACLR with rehabilitation.¹¹ Though controversy lingers, substantial research has been conducted on specific surgical procedures, various graft options, and rehabilitation protocols in an attempt to identify prognostic risk factors and modifiable predictors to improve self-reported outcomes after ACLR.¹²^,¹³

Although multiple authors have evaluated various factors related to returning individuals to their prior level of function, research identifying the effectiveness of early postoperative measures on self-reported outcomes after ACLR is lacking. Several self-efficacy studies have provided compelling evidence that a large number of patients are unable to return to their prior level of function in spite of an apparently successful surgery and rehabilitation.¹¹ Therefore, it is important to understand the psychosocial ramifications of the injury and monitor self-reported outcomes throughout the rehabilitation process to improve both short- and long-term function.

Accumulating evidence suggests that both demographic and intraoperative findings have a significant influence on patient outcomes after ACLR.⁵^,¹⁴^–²⁰ In particular, medial meniscectomy, residual ligamentous laxity, and femoral chondral defects have all been associated with subsequent degenerative arthrosis as seen on radiography.⁵^,¹⁵^,²⁰ Studies also suggest that demographic risk factors such as age, sex, and body mass index (BMI) might have a profound influence on self-reported outcomes after ACLR. Higher BMI scores might predict lower self-reported outcomes scores.¹²^,¹³ Also, the odds of successful outcomes are 0.35 times lower for persons over the traditional threshold for obesity (BMI ≥ 30 kg/m²).²¹ Conflicting evidence exists on whether age and sex are associated with self-reported outcomes.¹⁴^,¹⁶^–¹⁹ Whereas some studies¹⁴^,¹⁷^,¹⁸ point to lower self-reported outcomes in women and older patients, others¹⁶^,¹⁹ indicate no difference in overall outcomes.

Postoperative rehabilitation is an integral component to a successful recovery after ACLR. The inability to restore symmetric range of motion (ROM)⁶^,⁷ and muscular strength⁷^,²² affects patient satisfaction. Postoperative ROM deficits have been associated with a higher incidence of OA changes and lower self-reported outcomes scores.⁵^,⁶^,¹⁹ Additional research has shown that muscular weakness, specifically of the quadriceps femoris, is related to poorer functional outcomes.²³^–²⁵ Furthermore, establishing preoperative lower extremity strength⁷^,²²^,²⁶ and restoring symmetric ROM⁶^,⁷ are important in increasing overall functional ability and improving self-reported outcomes after ACLR.

Although a significant body of literature has addressed the effects of demographic, intraoperative, and postoperative factors on long-term self-reported outcomes, little attention has been given to the association between these variables and outcomes during the early phase of recovery and how deficits affect long-term outcomes. Studies are needed to investigate correlations between clinical measures and self-reported outcomes during the early stages of recovery. Such studies will reveal the potentially important influences of these factors on both short- and long-term outcomes and will guide clinicians in making appropriate decisions regarding early-stage postoperative rehabilitation.

The purpose of our study was to identify relationships between demographic (age, sex, BMI), intraoperative (isolated ACLR versus primary ACLR + secondary procedures), and postoperative (ROM and peak isometric knee-extension force [PIF]) variables during the first 2 months after ACLR and self-reported outcomes as measured by the International Knee Documentation Committee (IKDC) Subjective Knee Evaluation Form at 1, 2, and ≥12 months. First, we hypothesized that deficits in ROM and PIF during the first 2 months after surgery would be positively associated with IKDC scores at the equivalent time points and at ≥12 months postoperatively. Second, we proposed that IKDC scores during the first 2 months after surgery would be positively associated with IKDC scores at ≥12 months. Third, we suggested that participant characteristics such as secondary surgical procedures, age, sex, and BMI would have significant influences on IKDC scores at 1, 2, and ≥12 months after ACLR.

METHODS

Demographics

We retrospectively identified participants who underwent primary arthroscopic ACLR between 2007 and 2011. Inclusion criteria for this study were age 15 to 65 years; autograft or allograft single- or double-bundle ACLR procedure; partial meniscectomy or chondroplasty procedures (chondral lesions with an Outerbridge grade²⁷ of ≤2) or both; and complete datasets, including comprehensive ROM and PIF testing at 1 and 2 months, as well as complete IKDC Subjective Knee Evaluation Forms at 1, 2, and ≥12 months postoperatively. Exclusion criteria were incomplete objective or subjective measurements, concurrent injury to the posterior cruciate ligament, grade III tear of either medial or lateral collateral ligament, meniscal repair, chondral lesion with an Outerbridge grade²⁷ of >2, involvement in a workers' compensation case, or a neurologic disorder (eg, multiple sclerosis, traumatic brain injury) that might impair postoperative rehabilitation. The institutional review board at Intermountain Healthcare Urban Central Region (Murray, UT) approved this study. All ACLRs were performed by 1 of 2 senior surgeons at The Orthopedic Specialty Hospital (Murray, UT).

Surgical details were obtained from physician-dictated operative notes and included the type of primary procedure (single versus double bundle) and secondary procedures (partial meniscectomy or chondroplasty or both). Postoperative variables collected were the IKDC Subjective Knee Evaluation Form score, unilateral PIF, and knee flexion-extension ROM. All patients participated in a standard 4-phase rehabilitation protocol²⁸ at the same facility. Phase 1 (0 to 4 weeks) of the rehabilitation protocol consisted of passive, active-assist, and active ROM exercises; weight bearing as tolerated (axillary crutches as needed); stationary bicycling; muscle-activation exercises; and inflammation reduction. Phase 2 (4 to 8 weeks) emphasized progressive ROM exercises, muscle strengthening, neuromuscular-control training, and functional activities. Phase 3 (8 to 12 weeks) focused on restoring full, symmetric, passive ROM; muscle strengthening; higher-level neuromuscular-control tasks; and running. Phase 4 (12–24 weeks) involved progressive muscle strengthening, sport-specific neuromuscular-control training, plyometrics, sprinting, and cutting drills as appropriate.

Outcomes Measures

The IKDC Subjective Knee Evaluation Form is an 18-item, site-specific instrument designed to measure symptoms related to function and sports activity in patients who have 1 or more knee conditions including ligament, meniscal, articular cartilage, OA, and patellofemoral injuries.²⁹^,³⁰ The IKDC is a reliable and valid instrument for measuring patient-oriented clinical outcomes pertaining to daily and sports function.³¹^,³² Test-retest reliability is adequate for groups of patients with knee injuries and mixed knee conditions.³³ The minimal clinically important difference has been reported to be between 11.5 and 20.5; the minimal detectable change, between 8.8 and 15.6; and the standard error of the measure, between 3.2 and 5.6.³³ We obtained all subjective IKDC scores at 1- and 2-month visits to outpatient physical therapy. Subjective IKDC scores at ≥12 months (20.7 ± 5.1 months) after surgery were completed via telephone interviews.

A dual-arm goniometer (Chattanooga Medical Supply, Inc, Chattanooga, TN) was used to measure knee ROM similarity, as described by Shelbourne et al.⁶ For knee extension, the heel of the seated patient was positioned on a bolster to allow the examiner to measure the amount of extension or hyperextension, if present. For knee flexion, the patient was instructed to bend the affected knee as far as possible toward the buttocks while seated. The differences in ROM (°) between the ACLR and nonsurgical knee were expressed as separate difference scores for flexion and extension. Unilateral knee ROM was recorded once at the beginning of the 1- and 2-month physical therapy visits, before any stretching or warm-up. The same examiner measured each patient to maintain consistency between limbs. Intratester reliability is high for knee flexion (intraclass correlation coefficient [ICC] = 0.997) and extension (ICCs = 0.972 to 0.985).³⁴ Intertester reliability is also high for knee flexion (ICCs = 0.977 to 0.982) and extension (ICCs = 0.893 to 0.926).³⁴

Lower extremity strength was quantified by unilateral closed chain PIF production (feet-pounds) and was measured using a horizontal Plyo Press 625 III (Athletic Republic, Park City, UT). The reliability (ICC = 0.98) for the PIF measurement on the Plyo Press has been reported previously,³⁵ along with the testing procedures.³⁶ We measured Plyo Press output data from output signals obtained from a mounted force plate (model PPFP; Advanced Mechanical Technology, Inc, Watertown, MA). All data were sampled at 200 Hz with a low-pass filter at 10 Hz using DartPower software (version 2.0; Athletic Republic). Before every testing session, we zeroed and load calibrated the force plate. The nonsurgical leg was tested first, followed by the surgical leg, in all patients. The order of the testing protocol was performed this way to ensure consistency among patients (Figure).

Figure. — Single-legged strength testing of unilateral, closed chain, peak isometric knee-extension force production that was measured using a horizontal Plyo Press (Athletic Republic, Park City, UT).

All patients warmed up on a recumbent bicycle for 10 minutes before strength testing. Patients were then placed in supine position with 60° to 70° of knee flexion. During the testing, patients were instructed and orally encouraged to exert pain-free maximal force against the mounted force plate for 5 seconds. We defined PIF as the highest resultant force produced during the 5-second test for each leg separately during a single trial. Peak isometric force measurements were recorded at 1 and 2 months, postoperatively. All scores were calculated as ratio scores by dividing the nonsurgical limb PIF output by the surgical limb PIF output.

STATISTICAL ANALYSIS

Data Analysis

We investigated relationships between patient-subjective IKDC scores at 1, 2, and ≥12 months with 2-tail Pearson correlation analyses. These correlational analyses gave an indication of whether the IKDC scores were related over time. Correlations from r = 0.25 to 0.5 were considered fair, whereas correlations ranging from r = 0.5 to 0.75 were regarded as moderate to good.³⁷ We then carried out our primary analysis by evaluating relationships between subjective IKDC scores at 1, 2, and ≥12 months and postoperative variables at 1 and 2 months. Hierarchical regression was used to evaluate the influence of the postoperative variables on subjective IKDC scores after secondary procedure, age, sex, and BMI had already been considered. Thus, secondary procedure, age, sex, and BMI were entered into the regression analyses first, followed by the postoperative variables (difference in flexion-extension ROM and PIF ratio). Results from the regressions informed subsequent secondary analyses exploring relationships between dichotomized demographic variables and continuous outcomes. Secondary analyses were carried out with repeated-measures analyses-of-variance (ANOVAs) and independent-samples t tests.

RESULTS

We screened a total of 76 patients. Sixty-three patients who satisfied our inclusion criteria were included in our study (Tables 1 and 2). According to the preliminary Pearson correlation analysis, the ≥12-month IKDC scores had a fairly positive correlation with both the 1-month (r = 0.283, r² = 0.08; P = .025) and 2-month (r = 0.301, r² = 0.09; P = .017) subjective IKDC scores. Furthermore, there was also a good positive correlation between 1- and 2-month IKDC scores (r = 0.671, r² = 0.45; P < .001). The r² values of 0.08 for 1- and ≥12-month IKDC scores and 0.09 for 2- and ≥12-month IKDC scores suggest that 1- and 2-month IKDC scores accounted for less than 10% of the variability in ≥12-month IKDC scores. Repeated-measures ANOVA revealed significant differences in IKDC scores across time. Scores on the IKDC for each follow-up period are outlined in Table 3.

Table 1.

Baseline Demographics of Study Participants

Characteristic	No.
Participants	63
Sex	38 men, 25 women
	Mean ± SD
Age, y	33.0 ± 12.1
Height, cm	172.1 ± 10.3
Weight, kg	80.8 ± 22.5
Body mass index, kg/m²	26.3 ± 6.5

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Table 2.

Surgical Procedures Performed on Participants

Surgical Procedure(s)	n (%)
Isolated ACLR	23 (36.5)
Primary ACLR + secondary procedure(s)	40 (63.5)
Partial medial meniscectomy	17 (27.0)
Partial lateral meniscectomy	13 (20.6)
Partial medial and lateral meniscectomies	1 (1.6)
Chondroplasty	7 (11.1)
Partial meniscectomy and chondroplasty	2 (3.2)
Total	63 (100)

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Abbreviation: ACLR, anterior cruciate ligament reconstruction.

Table 3.

International Knee Documentation Committee (IKDC) Score Data Over Time

Time	IKDC Score, Mean ± SD	Mean Difference Between Time Points (95% Confidence Interval)^a	P Value^b
1 mo	51.9 ± 15.3
versus 2 mo		−11.5 (−15.1, −8.0)	<.001
versus ≥12 mo		−37.2 (−42.1, −32.2)	<.001
2 mo	63.0 ± 12.7
versus 1 mo		11.5 (8.0, 15.1)	<.001
versus ≥12 mo		−25.6 (−29.9, −21.3)	<.001
≥12 mo	89.0 ± 10.5
versus 1 mo		37.2 (32.2, 42.1)	<.001
versus 2 mo		25.6 (21.3, 29.9)	<.001

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^{^a}

Overall repeated-measures analysis of variance (F_1.78,110.05 = 236.31, P < .001).

^{^b}

All pairwise comparisons using Bonferroni correction were significant at <.001.

Follow-up hierarchical multiple regressions to evaluate the relationship between postoperative variables (difference in knee ROM and PIF ratio) and subjective IKDC scores, after accounting for other variables (secondary procedure, age, sex, and BMI), can be seen in Table 4. Incremental F tests of R² changes were significant for both 1- and 2-month IKDC score hierarchical regressions, suggesting that postoperative variables were significantly associated with IKDC scores after taking demographic variables into consideration. One-month IKDC scores were significantly related to the 1-month postoperative variables' difference in flexion ROM (P = .04) and PIF ratio (P < .001). Specifically, with every 1° reduction in the 1-month difference in knee flexion, 1-month IKDC scores increased an average of 0.28 points, and with every 1-unit reduction in the 1-month PIF ratio, 1-month IKDC scores increased an average of 0.29 points. The amount of variability in 1-month IKDC scores (R² value) explained by predictor variability was 0.46 (adjusted R² = 0.39). Two-month IKDC scores were significantly related to the 2-month PIF ratio (P < .001). With every 1-unit reduction in the 2-month PIF ratio, 2-month IKDC scores increased an average of 0.32 points. However, 2-month IKDC scores were not significantly related to 2-month differences in flexion or extension ROM (P = .45 and .78, respectively). The amount of variability in 2-month IKDC scores (R²) explained by predictor variability was 0.36 (adjusted R² = 0.28). Twelve-month IKDC scores were not significantly related to any of the 1- and 2-month postoperative variables (R² = 0.17; adjusted R² = 0.01).

Table 4.

Hierarchical Regression Results

Outcome: International Knee Documentation Committee Score	Predictors	B Coefficient	t Statistic	P Value
1 mo	Secondary procedure	9.44	2.82	.01^a
	Age	−0.25	−1.89	.07
	BMI	−1.00	−2.86	.01^a
	Sex	6.35	1.83	.07
	1-mo FE difference	0.28	2.08	.04^b
	1-mo EXT difference	0.01	0.03	.98
	1-mo PIF difference	0.29	3.31	<.001^a
2 mo	Secondary procedure	2.87	0.96	.34
	Age	−0.17	−1.44	.16
	BMI	−0.71	−2.19	.03^b
	Sex	4.70	1.46	.15
	2-mo FE difference	0.13	0.77	.45
	2-mo EXT difference	0.11	0.29	.78
	2-mo PIF Difference	0.32	3.88	<.001^a
≥12 mo	Secondary procedure	3.52	1.20	.24
	Age	−0.13	−1.05	.30
	BMI	−0.24	−0.74	.46
	Sex	−4.78	1.54	.13
	1-mo FE difference	−0.48	−0.26	.80
	1-mo EXT difference	−0.24	−0.67	.51
	1-mo PIF difference	−0.01	−0.04	.97
	2-mo FE difference	0.25	0.95	.35
	2-mo EXT difference	−0.31	−0.71	.48
	2-mo PIF difference	0.12	0.89	.38

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Abbreviations: BMI, body mass index; EXT difference, difference in extension range of motion, ratio of surgical to nonsurgical limb; FE difference, difference in flexion range of motion, ratio of surgical to nonsurgical limb; PIF difference, difference in peak isometric knee- extension force, ratio of surgical to nonsurgical limb.

^{^a}

Significant at .05.

^{^b}

Significant at .01.

A few demographic variables were significantly related to 1- and 2-month IKDC scores. Body mass index had a significant negative relationship with 1- and 2-month IKDC scores (P = .01 and .03, respectively). Secondary procedure coded as a binary variable (yes versus no) was significantly related to the 1-month IKDC score (P = .01) but not to the 2-month IKDC score (P = .34). We found that patients after ACLR with a secondary procedure demonstrated, on average, an increase of 9.44 in 1-month IKDC score compared with the isolated ACLR group. The influences of age (P = .07 [1 month] and .16 [2 month]) and sex (P = .07 [1 month] and .15 [2 month]) were not significant. Twelve-month IKDC scores were not significantly related to any of the patient demographic variables.

Finally, we explored the influence of age and BMI on IKDC scores with t tests. Differences in IKDC scores were evaluated against age by dividing the cohort into 2 categories: age ≤34 years and >34 years. Patients ≤34 years of age had a statistically higher mean IKDC score at 1 month (P = .01; 95% confidence interval [CI] of difference, 3.46 to 18.12) and a trend toward a higher mean IKDC score at 2 months (P = .07; 95% CI of difference, −0.39 to 11.77) compared with patients >34 years. We also explored differences in IKDC outcomes against BMI scores with traditional obesity demarcation thresholds. This was conducted by dividing the cohort into 2 categories: BMI <30 and BMI ≥30. Although BMI was a significant predictor in the regression analyses, none of the t tests were significant, suggesting that the traditional obesity threshold does not influence 1- and 2-month IKDC scores.

DISCUSSION

In this retrospective study, we identified demographic, intraoperative, and postoperative variables associated with self-reported outcomes after ACLR. The principal findings were (1) patients' subjective IKDC scores at both 1- and 2-month follow-ups had a fairly significant positive association with the ≥12-month IKDC score; (2) the ratio of surgical- to nonsurgical-limb PIF measures at 1 and 2 months had a significant positive association with 1- and 2-month IKDC scores; (3) BMI had a significant negative association with both 1- and 2-month IKDC scores; (4) the difference in flexion ROM had a significant positive relationship with 1-month IKDC score; and (5) demographic, intraoperative, and postoperative variables during the first 2 months were not associated with IKDC scores at ≥12 months after ACLR.

Outcomes after ACLR are typically evaluated through objective means, as measured by clinical examination, ligamentous laxity, and radiography; however, patients are typically more concerned with symptom reduction and functional ability.³⁸ Therefore, self-reported outcomes should be paramount in determining the response to recovery after ACLR. Traditionally, patients have been studied preoperatively and several months after surgery to determine the effects of ACLR.²^,⁴^,⁶^,¹²^,²¹^,²⁴^,²⁵^,³⁹^,⁴⁰ This leads one to question the influence that early postoperative stages of recovery have on self-reported outcomes. Our results showed significant associations between patients' subjective IKDC scores during the first 2 months postoperatively and the ≥12-month IKDC score. This finding suggests that patients' self-reported outcomes during the first 2 months might influence their long-term perceptions of function. Limited research has been conducted to evaluate patients' self-reported outcomes during the earlier stages of recovery and their association with long-term outcomes. Thomee et al⁴¹ concluded that patients' perceived self-efficacy appears to be an important factor associated with subjective physical function and quality of life. Although several factors contribute to patients' self-reported outcomes scores at various times within the recovery process, more attention should likely be placed on the determination, ambition, and effort put into the rehabilitation by the patient, both when designing the treatment program and during the course of the rehabilitation.⁴¹

In a recent systematic review, Te Wierike et al¹¹ reported that athletes with lower levels of fear of reinjury demonstrated better self-reported knee outcomes after ACLR. Furthermore, the investigators found a positive association between goal setting and rehabilitation adherence. Patients with higher adherence scores experienced fewer knee symptoms, indicating that adherence to a rehabilitation program had a positive effect on recovery after ACLR.¹¹ This information is relevant in setting realistic expectations and educating patients on the importance of early-stage recovery in overall recovery.

After controlling for demographic variables (secondary procedures, age, sex, and BMI), we found that ratio differences in the 1- and 2-month PIFs were significantly related to corresponding IKDC scores, suggesting that muscular-strength recovery was related to the perception of function. It appears that as the difference in lower extremity strength resolves during the first 2 months postoperatively, patients tend to report improved function. The literature is limited when evaluating the relationship of early postoperative muscular strength to patients' perceptions of lower extremity function after ACLR. Gerber et al⁴² noted that the quadriceps femoris muscle of the surgical limb could atrophy up to 30% just 3 weeks after ACLR, indicating the importance of resistive training immediately after surgery in an effort to mitigate atrophy and weakness. Other investigators⁸^,⁹ showed that at 6 months postoperatively, individuals can experience a loss of up to 50% of quadriceps strength relative to the contralateral limb and persistent limb weakness after returning to the previous activity level. Other evidence suggests that mitigating muscular atrophy may reduce the risk of rerupture, minimize patellofemoral pain, lessen mobility deficits, and return athletes to sport more quickly after ACLR.⁸^,¹⁰^,⁴³^–⁴⁵ Several researchers²^,³⁹ concluded that aberrant weakness preoperatively is associated with poorer functional outcomes at 6 months after surgery. Although factors including swelling, pain, muscular inhibition, and mobility deficits directly affect postoperative muscle function,⁴⁶ previous work⁴²^,⁴⁷^,⁴⁸ has indicated that early resistive muscle overloading promotes more optimal strength and volume, which in turn is associated with improved self-reported outcomes. Our findings show an association between lower extremity strength and patient-reported function, further promoting the idea that early muscular strength training prevents atrophy and improves self-reported outcomes after ACLR.

Furthermore, our analysis indicates that BMI had a significant influence on patients' 1- and 2-month IKDC scores. This finding is in accordance with previous studies¹²^,¹³^,¹⁷ in which similar functional outcomes were seen in patients with higher BMI scores after ACLR. Overall, we observed that a higher BMI was associated with lower subjective IKDC scores at 1 and 2 months, but this effect did not necessarily occur when the traditional obesity threshold was used as a cutoff point (nonobese = BMI <30, obese = BMI ≥30). The association between obesity and lower self-reported outcomes has been well documented in long-term studies,²¹^,⁴⁹ but little is known about the effect of BMI on patient function during the early phases of recovery. Our results indicate that BMI had a direct association with patient-reported function as early as the first 2 months after surgery. We also noted that patients ≤34 years of age demonstrated significantly higher IKDC scores at 1 month (P = .01) and somewhat higher IKDC scores at 2 months (P = .07) compared with patients >34 years. We evaluated differences in IKDC outcomes against age through means previously described⁵⁰ but we altered them so that we could assess the differences between younger and older subgroups. No difference was seen between the subgroups at ≥12 months, a finding that is consistent with the literature.⁵¹ Based on the current evidence, age alone should not be used to determine whether a patient is an appropriate candidate for ACLR,⁵¹ but it may be a factor in relative self-reported outcomes during the early stages of recovery. Additional studies with larger sample sizes are needed to determine whether age and BMI definitively influence IKDC scores at these time points.

Previous authors have concluded that the inability to restore symmetric knee motion may adversely affect patients' perceptions of function and increase the risk of developing OA.⁵^,⁶ Our findings indicate that knee-flexion deficits at 1 month were positively associated with lower IKDC scores at the same time point. However, this association did not carry through to the 2- and ≥12-month follow-up measures. Hence, although mobility deficits during the first month of recovery may influence patient-reported function during the early phase of recovery, they do not appear to influence long-term subjective outcomes. These mobility findings contradict our original hypothesis. Because others⁵^–⁷ have shown that restoring full mobility relative to the contralateral limb improves long-term subjective outcomes scores and lower extremity strength, while minimizing the risk of developing OA, we recommend continued emphasis on initiating early mobility in postoperative rehabilitation. Studies are needed to confirm the influence of early mobility deficits on subjective self-reported outcomes scores in patients after ACLR.

In the current study, ligament reconstruction with secondary procedures such as partial meniscectomy or chondroplasty or both resulted in significantly higher 1-month IKDC scores. Yet previous studies²⁰^,⁵²^,⁵³ have shown lower 12-month, self-reported outcomes scores in patients with ACLR in conjunction with meniscal or articular cartilage damage. It is possible that our patients with concomitant injuries to the knee may have benefitted psychologically from having the damaged tissue managed surgically. These patients might have also demonstrated lower overall function due to pain, limited mobility, or weight-bearing status, as well as poorer preoperative IKDC scores due to the degree of injury, resulting in the perception of vast improvements at 1 month, comparatively speaking.

Our results suggest that in a cohort of patients recovering from ACLR, subjective IKDC scores during the first 2 months had a fairly positive association with IKDC responses at ≥12 months. However, because 1- and 2-month scores accounted for less than 10% of the variability in ≥12-month scores, they are not ideal indicators of long-term subjective outcomes. Thus, patients who struggle in the early phase of recovery after ACLR may have the potential to improve their long-term self-reported outcomes scores with additional time and continual rehabilitation. Our findings also demonstrate that lower extremity strength deficits and higher BMI may negatively influence patients' insights on physical function during the early phase of recovery. Whereas further research is necessary to explicitly identify factors that directly influence patient-perceived function after ACLR, we believe that understanding how specific variables influence outcomes during early recovery is important in developing both a foundation for future clinical trials and a structured, criteria-based rehabilitation protocol for improving functional outcomes. This line of research has not been thoroughly explored and could hold value in improving our understanding of the importance of early-stage recovery to both short- and long-term self-reported outcomes scores.

The present study has noteworthy limitations. First, our sample was small and comprised a heterogeneous group of surgical procedures. Although our sample represents a realistic population of patients, the multitude of secondary procedures may have affected the results. Second, the IKDC scores were obtained by 2 different means throughout this project. Scores were acquired in person during the first 2 months of rehabilitation and by phone interviews for the ≥12-month follow-up. The variations in data-collection modes may have introduced bias. Third, the strength-testing protocol required only 1 trial for each lower extremity to determine PIF production. Multiple trials would potentially provide a more accurate interpretation of force output. Fourth, preoperative assessments of muscular strength on the nonsurgical limb and ≥12-month postoperative ROM and PIF measurements were not obtained.

CONCLUSIONS

Patients' IKDC scores during the first 2 months had a fairly positive correlation with long-term IKDC scores. Lower extremity strength and knee-flexion ROM deficits were positively associated with short-term IKDC scores. Higher BMI had a negative association with patients' perception of function on short-term IKDC scores. No demographic, intraoperative, or postoperative variables had an influence on long-term IKDC scores after ACLR.

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[i1062-6050-50-5-508-b01] 1.Frobell RB, Lohmander LS, Roos HP. Acute rotational trauma to the knee: poor agreement between clinical assessment and magnetic resonance imaging findings. Scand J Med Sci Sports. 2007;17(2):109–114. doi: 10.1111/j.1600-0838.2006.00559.x. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b02] 2.Logerstedt D, Lynch A, Axe MJ, Snyder-Mackler L. Pre-operative quadriceps strength predicts IKDC2000 scores 6 months after anterior cruciate ligament reconstruction. Knee. 2013;20(3):208–212. doi: 10.1016/j.knee.2012.07.011. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b03] 3.Friel NA, Chu CR. The role of ACL injury in the development of posttraumatic knee osteoarthritis. Clin Sports Med. 2013;32(1):1–12. doi: 10.1016/j.csm.2012.08.017. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b04] 4.Heijne A, Werner S. A. 2-year follow-up of rehabilitation after ACL reconstruction using patellar tendon or hamstring tendon grafts: a prospective randomised outcome study. Knee Surg Sports Traumatol Arthrosc. 2010;18(6):805–813. doi: 10.1007/s00167-009-0961-3. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b05] 5.Shelbourne KD, Gray T. Minimum 10-year results after anterior cruciate ligament reconstruction: how the loss of normal knee motion compounds other factors related to the development of osteoarthritis after surgery. Am J Sports Med. 2009;37(3):471–480. doi: 10.1177/0363546508326709. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b06] 6.Shelbourne KD, Urch SE, Gray T, Freeman H. Loss of normal knee motion after anterior cruciate ligament reconstruction is associated with radiographic arthritic changes after surgery. Am J Sports Med. 2012;40(1):108–113. doi: 10.1177/0363546511423639. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b07] 7.Shelbourne KD, Klotz C. What I have learned about the ACL: utilizing a progressive rehabilitation scheme to achieve total knee symmetry after anterior cruciate ligament reconstruction. J Orthop Sci. 2006;11(3):318–325. doi: 10.1007/s00776-006-1007-z. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b08] 8.Hsiao SF, Chou PH, Hsu HC, Lue YJ. Changes of muscle mechanics associated with anterior cruciate ligament deficiency and reconstruction. J Strength Cond Res. 2014;28(2):390–400. doi: 10.1519/JSC.0b013e3182986cc1. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b09] 9.Thomas AC, Villwock M, Wojtys EM, Palmieri-Smith RM. Lower extremity muscle strength after anterior cruciate ligament injury and reconstruction. J Athl Train. 2013;48(5):610–620. doi: 10.4085/1062-6050-48.3.23. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b10] 10.Ardern CL, Webster KE, Taylor NF, Feller JA. Return to the preinjury level of competitive sport after anterior cruciate ligament reconstruction surgery: two-thirds of patients have not returned by 12 months after surgery. Am J Sports Med. 2011;39(3):538–543. doi: 10.1177/0363546510384798. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b11] 11.Te Wierike SC, van der Sluis A, van den Akker-Scheek I, Elferink-Gemser MT, Visscher C. Psychosocial factors influencing the recovery of athletes with anterior cruciate ligament injury: a systematic review. Scand J Med Sci Sports. 2013;23(5):527–540. doi: 10.1111/sms.12010. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b12] 12.Dunn WR, Spindler KP. Predictors of activity level 2 years after anterior cruciate ligament reconstruction (ACLR): a Multicenter Orthopaedic Outcomes Network (MOON) ACLR cohort study. Am J Sports Med. 2010;38(10):2040–2050. doi: 10.1177/0363546510370280. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b13] 13.Spindler KP, Huston LJ, Wright RW, et al. The prognosis and predictors of sports function and activity at minimum 6 years after anterior cruciate ligament reconstruction: a population cohort study. Am J Sports Med. 2011;39(2):348–359. doi: 10.1177/0363546510383481. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b14] 14.Ageberg E, Forssblad M, Herbertsson P, Roos EM. Sex differences in patient-reported outcomes after anterior cruciate ligament reconstruction: data from the Swedish Knee Ligament Register. Am J Sports Med. 2010;38(7):1334–1342. doi: 10.1177/0363546510361218. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b15] 15.Ait Si Selmi T, Fithian D, Neyret P. The evolution of osteoarthritis in 103 patients with ACL reconstruction at 17 years follow-up. Knee. 2006;13(5):353–358. doi: 10.1016/j.knee.2006.02.014. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b16] 16.Barber FA, Elrod BF, McGuire DA, Paulos LE. Is an anterior cruciate ligament reconstruction outcome age dependent? Arthroscopy. 1996;12(6):720–725. doi: 10.1016/s0749-8063(96)90177-2. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b17] 17.Frobell RB, Svensson E, Gothrick M, Roos EM. Self-reported activity level and knee function in amateur football players: the influence of age, gender, history of knee injury and level of competition. Knee Surg Sports Traumatol Arthrosc. 2008;16(7):713–719. doi: 10.1007/s00167-008-0509-y. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b18] 18.Noojin FK, Barrett GR, Hartzog CW, Nash CR. Clinical comparison of intraarticular anterior cruciate ligament reconstruction using autogenous semitendinosus and gracilis tendons in men versus women. Am J Sports Med. 2000;28(6):783–789. doi: 10.1177/03635465000280060301. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b19] 19.Roe J, Pinczewski LA, Russell VJ, Salmon LJ, Kawamata T, Chew M. A. 7-year follow-up of patellar tendon and hamstring tendon grafts for arthroscopic anterior cruciate ligament reconstruction: differences and similarities. Am J Sports Med. 2005;33(9):1337–1345. doi: 10.1177/0363546504274145. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b20] 20.Shelbourne KD, Gray T. Results of anterior cruciate ligament reconstruction based on meniscus and articular cartilage status at the time of surgery. Five- to fifteen-year evaluations. Am J Sports Med. 2000;28(4):446–452. doi: 10.1177/03635465000280040201. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b21] 21.Kowalchuk DA, Harner CD, Fu FH, Irrgang JJ. Prediction of patient-reported outcome after single-bundle anterior cruciate ligament reconstruction. Arthroscopy. 2009;25(5):457–463. doi: 10.1016/j.arthro.2009.02.014. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b22] 22.Eitzen I, Moksnes H, Snyder-Mackler L, Risberg MA. A progressive 5-week exercise therapy program leads to significant improvement in knee function early after anterior cruciate ligament injury. J Orthop Sports Phys Ther. 2010;40(11):705–721. doi: 10.2519/jospt.2010.3345. [DOI] [PMC free article] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b23] 23.Decker MJ, Torry MR, Noonan TJ, Riviere A, Sterett WI. Landing adaptations after ACL reconstruction. Med Sci Sports Exerc. 2002;34(9):1408–1413. doi: 10.1097/00005768-200209000-00002. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b24] 24.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(2):231–237. doi: 10.1016/S0736-0266(02)00160-2. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b25] 25.Petschnig R, Baron R, Albrecht M. The relationship between isokinetic quadriceps strength test and hop tests for distance and one-legged vertical jump test following anterior cruciate ligament reconstruction. J Orthop Sports Phys Ther. 1998;28(1):23–31. doi: 10.2519/jospt.1998.28.1.23. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b26] 26.Liu-Ambrose T, Taunton JE, MacIntyre D, McConkey P, Khan KM. The effects of proprioceptive or strength training on the neuromuscular function of the ACL reconstructed knee: a randomized clinical trial. Scand J Med Sci Sports. 2003;13(2):115–123. doi: 10.1034/j.1600-0838.2003.02113.x. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b27] 27.Outerbridge RE. The etiology of chondromalacia patellae. J Bone Joint Surg Br. 1961;43-B:752–757. doi: 10.1302/0301-620X.43B4.752. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b28] 28.Christensen JC, Goldfine LR, West HS. The effects of early aggressive rehabilitation on outcomes after anterior cruciate ligament reconstruction using autologous hamstring tendon: a randomized clinical trial. J Sport Rehabil. 2013;22(3):191–201. doi: 10.1123/jsr.22.3.191. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b29] 29.Irrgang JJ, Anderson AF, Boland AL, et al. Development and validation of the International Knee Documentation Committee subjective knee form. Am J Sports Med. 2001;29(5):600–613. doi: 10.1177/03635465010290051301. [DOI] [PubMed] [Google Scholar]

[i1062-6050-50-5-508-b30] 30.Kocher MS, Steadman JR, Briggs K, Zurakowski D, Sterett WI, Hawkins RJ. Determinants of patient satisfaction with outcome after anterior cruciate ligament reconstruction. J Bone Joint Surg Am. 2002;84(9):1560–1572. doi: 10.2106/00004623-200209000-00008. [DOI] [PubMed] [Google Scholar]

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PERMALINK

What Can the First 2 Months Tell Us About Outcomes After Anterior Cruciate Ligament Reconstruction?

Jesse C Christensen, DPT, SCS

Laura R Goldfine, MS, PTA

Tyler Barker, PhD

Dave S Collingridge, PhD

Abstract

Context:

Objective:

Design:

Setting:

Patients or Other Participants:

Main Outcome Measure(s):

Results:

Conclusions:

Key Points

METHODS

Demographics

Outcomes Measures

Figure.

STATISTICAL ANALYSIS

Data Analysis

RESULTS

Table 1.

Table 2.

Table 3.

Table 4.

DISCUSSION

CONCLUSIONS

REFERENCES

ACTIONS

PERMALINK

RESOURCES

Cite

Add to Collections

PERMALINK

What Can the First 2 Months Tell Us About Outcomes After Anterior Cruciate Ligament Reconstruction?

Jesse C Christensen, DPT, SCS

Laura R Goldfine, MS, PTA

Tyler Barker, PhD

Dave S Collingridge, PhD

Abstract

Context:

Objective:

Design:

Setting:

Patients or Other Participants:

Main Outcome Measure(s):

Results:

Conclusions:

Key Points

METHODS

Demographics

Outcomes Measures

Figure.

STATISTICAL ANALYSIS

Data Analysis

RESULTS

Table 1.

Table 2.

Table 3.

Table 4.

DISCUSSION

CONCLUSIONS

REFERENCES

ACTIONS

PERMALINK

RESOURCES

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