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Abstract

Background:

Studies on the clinical outcomes of derotational femoral osteotomy to treat recurrent patellar dislocation in the presence of increased femoral anteversion are limited.

Purpose:

To investigate the role of derotational femoral osteotomy in the treatment of recurrent patellar dislocation in the presence of increased femoral anteversion.

Study Design:

Systematic review; Level of evidence, 4.

Methods:

A systematic review was performed according to the PRISMA guidelines (Preferred Reporting Items for Systematic Reviews and Meta-analyses) by searching the Medline, Embase, Web of Science, and Cochrane Library databases through February 10, 2021. Included were studies of skeletally mature patients presenting with recurrent patellar dislocation and exhibiting increased femoral anteversion who subsequently underwent derotational femoral osteotomy. Methodological quality was assessed using the MINORS (Methodological Index for Nonrandomized Studies) score. The basic characteristics of each study were recorded and analyzed: characteristic information, radiological parameters, surgical techniques, patient-reported outcomes, and complications.

Results:

A total of 6 studies with 163 patients (170 knees) were included. Sample sizes ranged from 7 to 66 patients, and the patients were predominantly women (range, 79%-100%). The mean age and follow-up ranges were 18 to 28 years and 16 to 44 months, respectively. The mean femoral anteversion decreased significantly from 34° preoperatively to 12° postoperatively. In studies reporting pre- and postoperative outcomes, significant improvements were found in the Lysholm score (from 24.8 to 44.1), Kujala score (from 15.8 to 41.9), International Knee Documentation Committee score (from 11.0 to 28.0), and visual analog scale for pain (from 2.0 to 3.7). All studies reported postoperative complications, giving an overall reported complication rate of 4.7%, but no redislocations occurred during the follow-up period.

Conclusion:

For recurrent patellar dislocation in the presence of increased femoral anteversion, combination treatment with derotational femoral osteotomy led to favorable clinical outcomes with a low redislocation rate. However, there was no consensus among researchers on the indications for derotational femoral osteotomy in the treatment of recurrent patellar dislocation.

Keywords

derotational femoral osteotomy femoral anteversion recurrent patellar dislocation clinical outcome

Medial patellofemoral ligament reconstruction (MPFL-R) has been considered the mainstay of treatment of recurrent patellar dislocation (RPD) over the past decade.^1,5,13,25,29 However, unfavorable clinical outcomes after MPFL-R have also been reported, and several risk factors have been recognized to cause these outcomes.²⁸

An increased femoral anteversion angle (FAA) has been recognized as a possible risk factor for RPD.^7,8,11,23,32 Recent biomechanical studies have revealed that an increased FAA can significantly increase the lateralizing force that acts on the patella and may be a cause of MPFL-R failure.^20,21 To date, the treatment of RPD in the presence of increased FAA is still debated. Some studies have found that increased femoral anteversion is correlated with inferior clinical outcomes and MPFL-R failure.^14,44 Given these reasons, derotational femoral osteotomy has been proposed as a treatment of RPD in the presence of increased femoral anteversion, and subsequent clinical studies have confirmed the clinical benefit of this procedure.^{15,19,27,38,42} However, these studies are limited to small case series, and no study has attempted to analyze them in totality.

The purpose of this study was to investigate the role of derotational femoral osteotomy in treating RPD in the presence of increased femoral anteversion. It was hypothesized that favorable functional outcomes and low redislocation rates would be found after isolated and combined derotational femoral osteotomy.

Methods

Literature Research

A systematic review was performed following the PRISMA guidelines (Preferred Reporting Items for Systematic Reviews and Meta-analyses).²⁶ The Medline, Embase, Web of Science, and Cochrane Library databases were searched by all of the authors independently on February 10, 2021. The search terms were as follows: (patellar dislocation OR patellar instability OR patellar subluxation OR patellofemoral dislocation OR patellofemoral dysfunction) AND (rotational osteotomy OR derotational osteotomy OR torsional osteotomy).

Study Selection

All articles identified by these search terms were generally reviewed and then discussed among authors according to the inclusion or exclusion criteria. If there were any disagreements among the authors about a study’s inclusion, the final decision was made by the senior author (H.Z.). Full-text articles were then critically reviewed. Additionally, all references from the studies were reviewed and reconciled to verify that no relevant articles were missing from the systematic review. All studies were included that reported the clinical outcomes of derotational femoral osteotomy for RPD in the presence of increased femoral anteversion. The main purpose of this systematic review was to investigate the role of derotational femoral osteotomy for treating RPD in the presence of increased femoral anteversion; therefore, patients with a history of undergoing ipsilateral derotational tibial osteotomy were excluded. The detailed inclusion and exclusion criteria are described in Table 1.

Table 1

Inclusion and Exclusion Criteria of the Systematic Review

Inclusion Criteria	Exclusion Criteria
Patients with recurrent patellar dislocation History of derotational femoral osteotomy A minimum follow-up of 12 mo Evidence levels 1-4	History of ipsilateral tibial osteotomy Cadaveric, biomechanical, or animal study Surgical technique article Systematic review or meta-analysis Patient duplication Non–English language publication

Data Abstraction

Data extraction was performed independently by 2 reviewers (Z.Z. and H.Z.). Each full-text article was abstracted regarding study characteristics, patient characteristics, surgical techniques, and outcome measures. Data on pre- and postoperative outcome measurements were extracted as means and standard deviations. The decision tree of von Elm et al³⁶ was used to identify and exclude duplicate studies. Any discrepancies were resolved through discussion with a third author (T.Z.).

Study characteristics included publication date, study design, level of evidence, number of patients/knees, and length of follow-up. Characteristic data consisted of patient sex and age. Surgical techniques for derotational femoral osteotomy and combined procedures were summarized according to the descriptions in the studies.

Outcome measures consisted of pre- and postoperative clinical and radiographic evaluations. Clinical assessments included patient-reported function scores and objective patellar stability (eg, MPFL residual laxity). Radiographic measurements included the pre- and postoperative FAA and patellar tilt angle.

Risk-of-Bias Assessment

The methodological quality of each study was assessed independently by 2 review authors (Z.Z. and H.Z.) according to the MINORS (Methodological Index for Nonrandomized Studies) score.³¹ The items on the questionnaire were scored as follows: 0 if not reported, 1 when reported but inadequate, and 2 when reported and adequate; there was a maximum possible score of 16 for noncomparative studies and 24 for comparative studies. MINORS scores of 13 to 16 for noncomparative studies and 21 to 23 for comparative studies were considered low risk of bias, and scores ≤12 and ≤20 were deemed high risk for noncomparative and comparative studies, respectively. Any discrepancies in scores were settled by consensus between the review authors.

Data Analysis

Individual study heterogeneity regarding patient populations and treatment prevented meta-analysis calculations. Therefore, descriptive statistics were used for numerical characteristic data (age and follow-up) and clinical and radiological outcomes. Reliability statistics were calculated using the Cohen κ coefficient to quantify the degree of agreement between the raters for the MINORS scores. When the standard deviation was not available, the authors were contacted to provide the missing data, or it was calculated according to the Cochrane handbook.¹⁷

Results

Study Identification

Of the 193 studies identified, 34 proceeded to full-text review. Ultimately, 6 studies were represented in the systematic review (Figure 1). Five studies were retrospective case series (level 4),^{2,15,19,27,38} and 1 study was a retrospective cohort study (level 3).⁴⁰ The mean MINORS score was 12.0 ± 0.7 (range, 11-13) for the 5 noncomparative studies,^{2,15,19,27,38} and the score was 20 for the 1 comparative study (Table 2).⁴⁰ Of the 6 studies, 5 were assessed as having a high risk of bias (MINORS score <13 for a noncomparative study or <21 for a comparative study).^{2,15,19,27,38} The Cohen κ coefficient for interrater reliability was 0.94, indicating almost-perfect agreement.

Figure 1.

Flowchart of the search strategy following the PRISMA guidelines. RPD, recurrent patellar dislocation.

Table 2

Study Characteristics ^a

Lead Author	Year	Study Design	LOE	MINORS Score	Patients (Knees), No.	Mean Age, y	Female/Male, No.	Mean Follow-up, mo
Zhang⁴⁰	2021	Cohort study ^b	3	20/24	66 (66)	21	59/7	37
Biedert²	2020	Case series	4	12/16	7 (9)	22	7/0	25
Yang³⁸	2019	Case series	4	12/16	20 (20)	21	18/2	18
Frings¹⁵	2019	Case series ^c	4	11/16	16 (19)	21	15/4	26
Imhoff¹⁹	2019	Case series	4	13/16	42 (44)	28	NR	44
Nelitz²⁷	2015	Case series	4	12/16	12 (12)	18	12/0	16

^a LOE, level of evidence; MINORS, Methodological Index for Nonrandomized Studies; NR, not reported.

^b This study compared the results of patients undergoing derotational femoral osteotomy vs a nonderotational osteotomy procedure.

^c This study reported clinical results after combined distal femoral osteotomy, which included 19 derotational femoral osteotomies and 12 varus osteotomies. Only patients who underwent derotational femoral osteotomy were included in the systematic review.

Patient Characteristics

The 6 studies comprised 163 patients (170 knees). Table 2 summarizes each study. Age was cited in all 6 studies, with the mean ranging from 18 to 28 years. Sex distribution was 111 women (90%, range 79%-100%) and 13 men (10%) in 5 studies.^{2,15,27,38,40} All studies noted the follow-up intervals, resulting in a mean follow-up from 16 to 44 months.

Surgical Techniques

Table 3 depicts the surgical details across the studies. All studies reported the cutoff value of femoral anteversion for derotational femoral osteotomy (range, 20°-30°). The preoperative mean FAA ranged from 31° to 39° (mean, 34°) in all studies, and the postoperative mean FAA mean ranged from 10° to 16° (mean, 12°) in 4 studies.^15,19,38,40 Supracondylar derotational osteotomy was performed in all studies. A total of 62.4% of the patients underwent combined MPFL-R,^19,27,40 and 28.2% of the patients underwent medial reefing to stabilize the patella.^2,15,38 Of the 6 studies, 4 reported that additional bony procedures were performed to correct concurrent bony deformities^2,15,19,40 such as tibial tubercle transfer (29.4%),^15,19,40 valgus/varus correction (15.9%),^15,19 and trochleoplasty (8.8%).^2,19

Table 3

Operative Procedure Data ^a

Lead Author	Cutoff Value for Osteotomy	Mean Pre/Post FAA (Modality)	Surgical Approach	Patellar Stabilization Procedure, No. ^b	Combined Bony Procedures
Zhang⁴⁰	30°	34°/10° (3D CT)	Lateral	66/0/0	TT transfer (n = 30)
Biedert²	27°	38°/NR (axial CT)	Lateral	0/9/0	Trochleoplasty (n = 9)
Yang³⁸	25°	31°/16° (axial CT)	Lateral	0/20/0	None
Frings¹⁵	>20° ^c	39°/11° (axial CT or MRI)	Lateral, medial	0/19/0	TT transfer (n = 14) Valgus correction (n = 5)
Imhoff¹⁹	>25° ^d	31°/12° (axial MRI)	Lateral	28/0/16	TT transfer (n = 6) Valgus correction (n = 22) Trochleoplasty (n = 6)
Nelitz²⁷	25°	34°/NR (axial MRI)	Lateral	12/0/0	None

^a Osteotomy level for each study: distal femur. 3D, 3-dimensional; CT, computed tomography; FAA, femoral anteversion angle; MPFL-R, medial patellofemoral ligament reconstruction; MRI, magnetic resonance imaging; NR, not reported; Pre/Post, pre- and postoperative; TT, tibial tubercle.

^b MPFL-R/reefing/none.

^c In this article, derotational femoral osteotomy was indicated when the FAA exceeded the normal value by 10°. According to Dejour et al⁸ (normal value, 10.8°), the cutoff value of femoral anteversion should have been ≥20° in this article.

^d The original article did not report the indication of derotational femoral anteversion. We tried to contact the corresponding author by email but failed to obtain a response. In this article, the author declared that femoral anteversion >25° was a severe risk factor for patellofemoral instability; therefore, it seems reasonable to assume that the cutoff value of femoral anteversion for derotational femoral osteotomy was at least 25°.

Subjective Clinical Outcomes

Six patient-reported outcomes were described in the articles. The visual analog scale for pain, International Knee Documentation Committee score, Tegner score, Kujala score, and Lysholm score were used as outcome measures in ≥3 studies and are summarized in Table 4. Significant pre- to postoperative improvement was seen in all except for the Tegner score.

Table 4

Functional Scores ^a

	Tegner Score		VAS Score		IKDC Score		Kujala Score		Lysholm Score
Lead Author	Preop	Postop	Preop	Postop	Preop	Postop	Preop	Postop	Preop	Postop
Zhang^40,b	3.2 ± 0.6	4.4 ± 0.8			56.7 ± 11.2	83.1 ± 10.4	53.8 ± 11.2	82.3 ± 8.4	58.2 ± 10.2	83.7 ± 9.0
Biedert²	2.7	6.0					41.2	83.1
Yang³⁸	5.5 ± 2.5	5.8 ± 1.4	4.2 ± 2.1	1.3 ± 1.1	70.6 ± 21.4	90.8 ± 14.3	72.4 ± 19.9	88.2 ± 12.3
Frings¹⁵	2.2 ± 1.3	3.7 ± 1.2	4.9 ± 2.6	1.2 ± 1.5			47.7 ± 27	84.4 ± 16	40.5 ± 20.4	84.6 ± 15.2
Imhoff¹⁹	4	4	4 ± 3	2 ± 2	54 ± 13	65 ± 17			46 ± 21	71 ± 24
Nelitz²⁷	4	4.5	4	1.5	60	85	69	92.5

^a Blank cells indicate not reported. Values are presented as mean ± SD. IKDC, International Knee Documentation Committee; Postop, postoperative; Preop, preoperative; VAS, visual analog scale.

^b The postoperative functional scores were significantly higher in the derotational group than in the control group.

Patient satisfaction was reported in 5 studies,^{2,15,19,27,38} with a postoperative satisfaction rate ranging from 72% to 100% (Table 5). One study compared the clinical outcomes of MPFL-R with and without derotational femoral osteotomy for treating RPD with an FAA >30°,⁴⁰ which demonstrated that the former yielded more favorable subjective outcomes than MPFL-R alone, and this circumstance was more remarkable when the patients had a preoperative high-grade J-sign.

Table 5

Complication, Satisfaction Rate, and Radiological Assessments ^a

Lead Author	Complications	Satisfaction, % ^b	Other Assessments
Zhang⁴⁰	None	Not reported	Residual J-sign, patellar medial laxity index
Biedert²	Persisting pain (n = 1)	89/0/11	Cartilage injury grade
Yang³⁸	Limited knee flexion (n = 1)	100/0/0	Congruence angle and patellar tilt
Frings¹⁵	Wound infection (n = 1) Screw dislocation (n = 1)	100/0/0	None
Imhoff¹⁹	Loss of correction (n = 1) Graft slippage (n = 1)	72/15/13	None
Nelitz²⁷	Limited knee flexion (n = 2)	92/8/0	None

^a No patients experienced patellar redislocation; however, 6% of patients after derotational femoral osteotomy showed medial patellofemoral ligament residual graft laxity.

^b Satisfied/partially satisfied/dissatisfied.

Radiological and Objective Clinical Outcomes

Pre- and postoperative patellar tilt was reported in 1 study.³⁸ The mean preoperative patellar tilt was 30.4°, while the mean postoperative patellar tilt was 15.8°. One study used patellofemoral stress radiography to measure the postoperative MPFL graft residual laxity (if the patellar medial laxity index exceeded 50%, MPFL residual graft laxity was considered for the reconstructed ligament),⁴⁰ showing a 6% rate of MPFL residual graft laxity (Table 5).

Complications

All but the comparative study reported postoperative complications (Table 5). A total of 8 complications were noted for a rate of 4.7%. Major and minor complications were reported. The most common complication was limited knee flexion (1.8%), which was resolved by enhanced rehabilitation or manipulation under anesthesia. No patients experienced patellar subluxation or redislocation postoperatively.

Discussion

The most important finding of this systematic review was that derotational femoral osteotomy in the treatment of RPD in the presence of increased FAA results in favorable subjective and objective outcomes with low rates of redislocation. However, there is no consensus among researchers on the indications for derotational femoral osteotomy in the treatment of RPD.

Isolated MPFL-R has gained much popularity over the last few years in the treatment of RPD, given its lower surgical trauma and favorable clinical outcomes.^3,22,30 Erickson et al¹² performed 90 isolated MPFL-R procedures regardless of increased femoral anteversion and other bony pathologies and noted a significant improvement in outcome scores, with a low redislocation rate (1.1%). Similarly, in the study by Blanke et al,³ isolated MPFL-R resulted in superior clinical outcomes and patellar stability irrespective of the value of femoral anteversion and subgroup analysis demonstrated that increased femoral anteversion (>20°) did not lead to worse outcomes than in patients with an FAA <20°. Therefore, the question is whether derotational femoral osteotomy should be performed in the treatment of patients with increased FAA.

The indications for derotational femoral osteotomy in the treatment of RPD is a question worth researching. Many studies performed derotational femoral osteotomy when preoperative femoral anteversion reached a specific threshold, which usually varied from 20° to 30° based on the experience and preference of the surgeon.^{2,15,19,27,38,40} The current biomechanical and clinical evidence regarding the threshold of derotational femoral anteversion for RPD is limited. A recent biomechanical study found a persistent increased lateralizing force vector acting on the patella after MPFL-R when the FAA was 20°, which might increase the stress on the reconstructed MPFL and lead to MPFL failure and patellar redislocation.²¹ Therefore, the authors proposed an additional derotational femoral osteotomy in such cases to neutralize the abnormal force vector produced by the increased FAA. Franciozi et al¹⁴ investigated the influence of an increased FAA on clinical outcomes in patients with RPD treated by MPFL-R with tibial tubercle transfer and found that an FAA >30° was associated with worse functional outcomes. Similarly, Teitge³⁵ indicated that derotational femoral osteotomy is beneficial if the FAA is >30°. In the study by Zhang et al,⁴⁴ patients were divided into 3 FAA groups: low (<20°), medium (20°-30°), and high (>30°). The authors noted that patient-reported outcomes and patellar stability in the medium FAA group were comparable to those in the low FAA group but significantly better than those in the high FAA group; therefore, they speculated that patients with a high FAA (>30°) were possible candidates for derotational femoral osteotomy.

Another view holds that the severity of patellar maltracking should be taken into consideration when determining whether to perform derotational femoral osteotomy in patients with RPD and increased FAAs. In the treatment algorithm for RPD proposed by Frosch and Schmeling,¹⁶ isolated MPFL-R was advocated when patellar tracking was normal, regardless of the increased FAA, and derotational femoral osteotomy was to be performed only in the presence of patellar maltracking. Zhang et al⁴³ analyzed the risk factors for severe patellar maltracking of RPD and found that an increased FAA was strongly associated with a high-grade J-sign; therefore, given the adverse impact of severe patellar maltracking on the outcomes after MPFL-R, the authors suggested that derotational femoral osteotomy should be performed when an increased FAA is coupled with a high-grade J-sign. Zhang et al⁴⁰ recently conducted another study to investigate whether patients with an increased FAA could benefit from combined derotational femoral osteotomy. This study compared the clinical outcomes of MPFL-R alone versus MPFL-R with derotational femoral osteotomy for treating RPD with an increased FAA (>30°), and it determined that the derotational osteotomy group had significantly better patient-reported outcomes and a lower rate of MPFL residual graft laxity than the control group. A subgroup analysis was then performed by stratifying the results regarding severity of preoperative patellar maltracking (low- vs high-grade J-sign) and revealed that patients with a high-grade J-sign could benefit more from the combined derotational osteotomy than patients with a low-grade J-sign. Therefore, the authors concluded that derotational femoral osteotomy should be considered for patients with an increased FAA (>30°) and concurrent high-grade J-sign.

Another potential indication for derotational femoral osteotomy is revisional surgery for RPD. Some authors have speculated that a neglected increased FAA is a common reason for MPFL-R failure.^16,28,37 Therefore, Weber et al³⁷ stated that derotational osteotomy for excessive femoral anteversion should be performed in patients with failed soft tissue procedures. For patients with failed primary MPFL-R and neglected increased FAA, Nelitz et al²⁸ performed derotational femoral osteotomy and MPFL-R, and a favorable clinical outcome was achieved in these revision cases. Similarly, Zhang et al⁴¹ analyzed the risk factors for MPFL residual laxity and declared that the restoration of normal femoral anteversion by derotational femoral osteotomy was a critical step in the management of revision cases.

Other bony deformities may coexist in patients with an increased FAA. How to treat these concurrent bony deformities is still debated in the literature. Frings et al¹⁵ declared that all predisposing risk factors—including rotational deformities, increased tibial tubercle–trochlear groove distance, patella alta, and genu valgum—should be addressed simultaneously to restore normal patellar tracking, similar to the “à la carte” approach introduced by the Lyon group.⁶ In contrast, in the studies of Nelitz et al²⁷ and Yang et al,³⁸ derotational femoral osteotomy was performed as the isolated bony procedure. In fact, the concurrent mild to moderate valgus deformity could be corrected simultaneously by derotational femoral osteotomy without increasing treatment-related morbidity.¹⁸ For patients with severe trochlear dysplasia, a recent meta-analysis found that combined trochleoplasty decreased the redislocation rate at the cost of a higher risk of postoperative range-of-motion limitation.³⁹ In the present systematic review, no redislocations occurred among the patients who did not undergo trochleoplasty. Therefore, based on the results of this systematic review, when derotational femoral osteotomy was performed to correct the increased FAA in patients with RPD, the combined trochleoplasty was usually not recommended owing to its potential morbidity.

Derotational femoral osteotomy was initially applied to address patients with idiopathic torsional deformities of the lower extremities or miserable malalignment syndrome associated with significant patellofemoral pain.^{4,9,10,24,33,34} Teitge³⁵ was the first to systematically describe the clinical use of derotational femoral osteotomy in patellofemoral instability in 2006. Subsequently, several investigations reporting the successful outcomes of derotational femoral osteotomy have been published.^{9,10,24,33,34} However, these publications were excluded from this systematic review because of the heterogeneity of the patients in these studies, such as those mixing patellar instability and anterior knee pain or mixing femoral and tibial derotational osteotomy.

There are several limitations to this study. The major limitations of this systematic review are the low levels of evidence, heterogeneity bias, and retrospective nature of most studies, such as several combined procedures (eg, tibial tubercle transfer and trochleoplasty). These limitations are not uncommon in systematic reviews of novel orthopaedic surgical procedures and are mostly unavoidable until higher-level studies of the current topic are conducted and published.

Conclusion

For RPD in the presence of increased femoral anteversion, combination treatment with derotational femoral osteotomy leads to favorable clinical outcomes with a low redislocation rate. However, there is no consensus among researchers on the indications for derotational femoral osteotomy in the treatment of RPD.

Footnotes

Final revision submitted August 17, 2021; accepted August 25, 2021.

One or more of the authors has declared the following potential conflict of interest or source of funding: Funding for this study was received from the Capital’s Funds for Health Improvement and Research (grants 2020-1-2071 and 2020-2-2075) and the National Key R&D Program of China (grant 2019YFF0301700). AOSSM checks author disclosures against the Open Payments Database (OPD). AOSSM has not conducted an independent investigation on the OPD and disclaims any liability or responsibility relating thereto.

References

Allen

Krych

Johnson

Mohan

Stuart

Dahm

. Combined tibial tubercle osteotomy and medial patellofemoral ligament reconstruction for recurrent lateral patellar instability in patients with multiple anatomic risk factors. Arthroscopy. 2018;34(8):2420–2426.

Biedert

. Combined deepening trochleoplasty and supracondylar external rotation osteotomy for recurrent patellar instability in patients with trochlear dysplasia and increased femoral antetorsion. Knee. 2020;27(4):1158–1166.

Blanke

Watermann

Haenle

Feitenhansl

Camathias

Vogt

. Isolated medial patellofemoral ligament reconstruction can be an effective procedure in patellofemoral instability with risk factors. J Knee Surg. 2020;33(10):992–997.

Bruce

Stevens

. Surgical correction of miserable malalignment syndrome. J Pediatr Orthop. 2004;24(4):392–396.

Burnham

Howard

Hayes

Lattermann

. Medial patellofemoral ligament reconstruction with concomitant tibial tubercle transfer: a systematic review of outcomes and complications. Arthroscopy. 2016;32(6):1185–1195.

Dejour

. The patellofemoral joint and its historical roots: the Lyon School of Knee Surgery. Knee Surg Sports Traumatol Arthrosc. 2013;21(7):1482–1494.

Dejour

Le Coultre

. Osteotomies in patello-femoral instabilities. Sports Med Arthrosc Rev. 2007;15(1):39–46.

Dejour

Walch

Nove-Josserand

Guier

. Factors of patellar instability: an anatomic radiographic study. Knee Surg Sports Traumatol Arthrosc. 1994;2(1):19–26.

Dickschas

Harrer

Pfefferkorn

Strecker

. Operative treatment of patellofemoral maltracking with torsional osteotomy. Arch Orthop Trauma Surg. 2012;132(3):289–298.

10.

Dickschas

Harrer

Reuter

Schwitulla

Strecker

. Torsional osteotomies of the femur. J Orthop Res. 2015;33(3):318–324.

11.

Diederichs

Köhlitz

Kornaropoulos

Heller

Vollnberg

Scheffler

. Magnetic resonance imaging analysis of rotational alignment in patients with patellar dislocations. Am J Sports Med. 2013;41(1):51–57.

12.

Erickson

Nguyen

Gasik

Gruber

Brady

Shubin Stein

. Isolated medial patellofemoral ligament reconstruction for patellar instability regardless of tibial tubercle-trochlear groove distance and patellar height: outcomes at 1 and 2 years. Am J Sports Med. 2019;47(6):1331–1337.

13.

Franciozi

Ambra

Albertoni

, et al. Anteromedial tibial tubercle osteotomy improves results of medial patellofemoral ligament reconstruction for recurrent patellar instability in patients with tibial tuberosity–trochlear groove distance of 17 to 20 mm. Arthroscopy. 2019;35(2):566–574.

14.

Franciozi

Ambra

Albertoni

, et al. Increased femoral anteversion influence over surgically treated recurrent patellar instability patients. Arthroscopy. 2017;33(3):633–640.

15.

Frings

Krause

Akoto

Frosch

. Clinical results after combined distal femoral osteotomy in patients with patellar maltracking and recurrent dislocations. J Knee Surg. 2019;32(9):924–933.

16.

Frosch

Schmeling

. A new classification system of patellar instability and patellar maltracking. Arch Orthop Trauma Surg. 2016;136(4):485–497.

17.

Higgins

JPT

Thomas

Chandler

, et al. Cochrane Handbook for Systematic Reviews of Interventions. John Wiley & Sons; 2019.

18.

Imhoff

Beitzel

Zakko

, et al. Derotational osteotomy of the distal femur for the treatment of patellofemoral instability simultaneously leads to the correction of frontal alignment: a laboratory cadaveric study. Orthop J Sports Med. 2018;6(6):2325967118775664.

19.

Imhoff

Cotic

Liska

, et al. Derotational osteotomy at the distal femur is effective to treat patients with patellar instability. Knee Surg Sports Traumatol Arthrosc. 2019;27(2):652–658.

20.

Kaiser

Schmoelz

Schoettle

Zwierzina

Heinrichs

Attal

. Increased internal femoral torsion can be regarded as a risk factor for patellar instability-A biomechanical study. Clin Biomech (Bristol, Avon). 2017;47(4):103–109.

21.

Kaiser

Schmoelz

Schöttle

Heinrichs

Zwierzina

Attal

. Isolated medial patellofemoral ligament reconstruction for patella instability is insufficient for higher degrees of internal femoral torsion. Knee Surg Sports Traumatol Arthrosc. 2019;27(3):758–765.

22.

Kita

Tanaka

Toritsuka

, et al. Factors affecting the outcomes of double-bundle medial patellofemoral ligament reconstruction for recurrent patellar dislocations evaluated by multivariate analysis. Am J Sports Med. 2015;43(12):2988–2996.

23.

Lee

Anzel

Bennett

Pang

Kim

. The influence of fixed rotational deformities of the femur on the patellofemoral contact pressures in human cadaver knees. Clin Orthop Relat Res. 1994;(302):69–74.

24.

Leonardi

Rivera

Zorzan

Ali

. Bilateral double osteotomy in severe torsional malalignment syndrome: 16 years follow-up. J Orthop Traumatol. 2014;15(2):131–136.

25.

Longo

Berton

Salvatore

, et al. Medial patellofemoral ligament reconstruction combined with bony procedures for patellar instability: current indications, outcomes, and complications. Arthroscopy. 2016;32(7):1421–1427.

26.

Moher

Liberati

Tetzlaff

Altman

; PRISMA Group. Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. J Clin Epidemiol. 2009;62(10):1006–1012.

27.

Nelitz

Dreyhaupt

Williams

Dornacher

. Combined supracondylar femoral derotation osteotomy and patellofemoral ligament reconstruction for recurrent patellar dislocation and severe femoral anteversion syndrome: surgical technique and clinical outcome. Int Orthop. 2015;39(12):2355–2362.

28.

Nelitz

Williams

Lippacher

Reichel

Dornacher

. Analysis of failure and clinical outcome after unsuccessful medial patellofemoral ligament reconstruction in young patients. Int Orthop. 2014;38(11):2265–2272.

29.

Neri

Parker

Beach

, et al. Medial patellofemoral ligament reconstruction with or without tibial tubercle transfer is an effective treatment for patellofemoral instability. Knee Surg Sports Traumatol Arthrosc. 2019;27(3):805–813.

30.

Sappey-Marinier

Sonnery-Cottet

O’Loughlin

, et al. Clinical outcomes and predictive factors for failure with isolated MPFL reconstruction for recurrent patellar instability: a series of 211 reconstructions with a minimum follow-up of 3 years. Am J Sports Med. 2019;47(6):1323–1330.

31.

Slim

Nini

Forestier

Kwiatkowski

Panis

Chipponi

. Methodological Index for Non-randomized Studies (MINORS): development and validation of a new instrument. ANZ J Surg. 2003;73(9):712–716.

32.

Souza

Draper

Fredericson

Powers

. Femur rotation and patellofemoral joint kinematics: a weight-bearing magnetic resonance imaging analysis. J Orthop Sports Phys Ther. 2010;40(5):277–285.

33.

Stambough

Davis

Szymanski

Smith

Schoenecker

Gordon

. Knee pain and activity outcomes after femoral derotation osteotomy for excessive femoral anteversion. J Pediatr Orthop. 2018;38(10):503–509.

34.

Strecker

Dickschas

. Torsional osteotomy: operative treatment of patellofemoral maltracking. Oper Orthop Traumatol. 2015;27(6):505–524.

35.

Teitge

. Osteotomy in the treatment of patellofemoral instability. Tech Knee Surg. 2006;5(1):2–18.

36.

von Elm

Poglia

Walder

Tramèr

. Different patterns of duplicate publication: an analysis of articles used in systematic reviews. JAMA. 2004;291(8):974–980.

37.

Weber

Nathani

Dines

, et al. An algorithmic approach to the management of recurrent lateral patellar dislocation. J Bone Joint Surg Am. 2016;98(5):417–427.

38.

Yang

Wang

Zuo

Dai

Wang

. Good outcomes of combined femoral derotation osteotomy and medial retinaculum plasty in patients with recurrent patellar dislocation. Orthop Surg. 2019;11(4):578–585.

39.

Zaffagnini

Previtali

Tamborini

Pagliazzi

Filardo

Candrian

. Recurrent patellar dislocations: trochleoplasty improves the results of medial patellofemoral ligament surgery only in severe trochlear dysplasia. Knee Surg Sports Traumatol Arthrosc. 2019;27(11):3599–3613.

40.

Zhang

Song

, et al. Medial patellofemoral ligament reconstruction with or without derotational distal femoral osteotomy in treating recurrent patellar dislocation with increased femoral anteversion: a retrospective comparative study. Am J Sports Med. 2021;49(1):200–206.

41.

Zhang

Song

Zheng

Feng

Zhang

. The presence of a preoperative high-grade J-sign and femoral tunnel malposition are associated with residual graft laxity after MPFL reconstruction. Knee Surg Sports Traumatol Arthrosc. 2021;29(4):1183–1190.

42.

Zhang

Song

, et al. A high-grade j sign is more likely to yield higher postoperative patellar laxity and residual maltracking in patients with recurrent patellar dislocation treated with derotational distal femoral osteotomy. Am J Sports Med. 2020;48(1):117–127.

43.

Zhang

Song

Zheng

Feng

. A pre-operative grade 3 J-sign adversely affects short-term clinical outcome and is more likely to yield MPFL residual graft laxity in recurrent patellar dislocation. Knee Surg Sports Traumatol Arthrosc. 2020;28(7):2147–2156.

44.

Zhang

Song

Zheng

Feng

. Increased femoral anteversion is associated with inferior clinical outcomes after MPFL reconstruction and combined tibial tubercle osteotomy for the treatment of recurrent patellar instability. Knee Surg Sports Traumatol Arthrosc. 2020;28(7):2261–2269.

Derotational Femoral Osteotomy for Treating Recurrent Patellar Dislocation in the Presence of Increased Femoral Anteversion: A Systematic Review

Abstract

Background:

Purpose:

Study Design:

Methods:

Results:

Conclusion:

Keywords

Methods

Literature Research

Study Selection

Data Abstraction

Risk-of-Bias Assessment

Data Analysis

Results

Study Identification

Patient Characteristics

Surgical Techniques

Subjective Clinical Outcomes

Radiological and Objective Clinical Outcomes

Complications

Discussion

Conclusion

Footnotes

References