Abstract
Purpose
The purpose of this study was to compare patients with osteochondral lesions of the talus (OCLT) with and without concomitant chronic ankle instability (CAI).
Methods
Data from the German Cartilage Registry (KnorpelRegister DGOU) for 63 patients with a solitary OCLT were used. All patients received autologous matrix-induced chondrogenesis (AMIC) for OCLT treatment. Patients in group A received an additional ankle stabilisation, while patients in group B received AMIC alone. Both groups were compared according to demographic, lesion-related, and therapy-related factors as well as baseline clinical outcome scores at the time of surgery. The Foot and Ankle Ability Measure (FAAM), the Foot and Ankle Outcome Score (FAOS), and the Numeric Rating Scale for Pain (NRS) were used.
Results
Patients in group A were older compared to group B [median 34 years (range 20–65 years) vs. 28.5 years (range 18–72 years)]; the rate of trauma-associated OCLTs was higher (89.7% vs. 38.3%); more patients in group A had a previous non-surgical treatment (74.1% vs. 41.4%); and their OCLT lesion size was smaller [median 100 mm2 (range 15–600 mm2) vs. 150 mm2 (range 25–448 mm2)]. Most OCLTs were located medially in the coronary plane and centrally in the sagittal plane in both groups. Patients in group A had worse scores on the FAOS quality-of-life subscale compared to patients in group B.
Conclusion
Patients with OCLT with concomitant CAI differ from those without concomitant CAI according to demographic and lesion-related factors. The additional presence of CAI worsens the quality of life of patients with OCLT. Patients with OCLT should be examined for concomitant CAI, so that if CAI is present, it can be integrated into the treatment concept.
Level of evidence
IV.
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Introduction
Osteochondral lesions of the ankle (OCLA) and chronic ankle instability (CAI) are often coincident. Several authors have described OCLA as an associated pathology in acute and chronically unstable ankles [2, 7, 10, 11, 18, 21]. In CAI, reported rates of chondral and osteochondral lesions of the tibia or talus have ranged from approximately 16% [10] to 95% [21].
Ankle sprains may be associated with ligamentous injuries of the ankle joint, especially the lateral ligaments, and inadequate healing after non-surgical treatment may lead to CAI in 10–30% of cases [11, 19]. It remains unclear whether subsequent OCLA is a result of the initial trauma from the sprain or from repeated microtraumas due to CAI.
Van Dijk et al. conducted a study involving a group of 30 patients who underwent operative repair of acute lateral ankle ligament ruptures and found cartilage lesions of the ankle in 20 patients [27]. Nineteen lesions were located at the tip and/or anterior distal part of the medial malleolus as well as on the opposite medial facet of the talus. The authors concluded that, during an inversion ankle sprain, an impingement occurs between the medial malleolus and the medial facet of the talus, which results in cartilage damage.
Only a few case series have analysed the combined operative treatment of OCLA and CAI, and the study designs differ among these publications. Lee et al. compared the outcomes of patients with osteochondral lesions of the talus (OCLT) alone with the outcomes of patients with both OCLT and CAI after surgical treatment [12]. The treatment of OCLT consisted of bone marrow stimulation. Patients with CAI also received lateral ligament reconstruction. The authors reported an increased proportion of larger cartilage lesions and additional lesions at the tip of the medial malleolus and the tibial plafond for the patients who underwent combined OCLT and CAI treatment. Furthermore, the authors detected an increased clinical failure rate after surgery according to American Orthopedic Foot and Ankle Society (AOFAS) scores as well as inferior outcomes according to the Foot and Ankle Outcome Score (FAOS) sports/recreational activities subscale for the patients with OCLT and CAI compared to the patients with only OCLT [12].
Both Li et al. and Jiang et al. compared the results of combined operative OCLA + CAI treatment to those of CAI treatment alone and reported comparable outcomes in both groups, respectively [8, 13]. Gregush et al. also analysed the results of concomitant operative OCLA + CAI treatment in 31 patients [5]. The authors concluded that the presence of an OCLA had a negative effect on the overall result when compared to the results of patients who underwent lateral ankle stabilisation as an isolated procedure. Yasui et al. evaluated the clinical outcome of 16 patients after simultaneous surgery involving stabilisation of CAI combined with retrograde drilling for subchondral bone lesions of the talus [29]. The authors reported a significant postoperative improvement in AOFAS scores as well as pain measured via Visual Analog Scale scores [29]. Furthermore, Yasui et al. observed a reduction of the lesion size on magnetic resonance imaging when comparing pre- and postoperative scans.
To the best of our knowledge, no study has yet focused on the combined treatment of OCLA and CAI with autologous matrix-induced chondrogenesis (AMIC) plus ankle stabilisation. AMIC is a collagen type I/III scaffold that is inserted into the cartilage defect. A collagen matrix is applied after microfracture, nanofracture or drilling of the subchondral bone, or after autologous bone grafting [3, 22,23,24, 28]. The role of AMIC in the treatment of OCLA is the subject of current research [1, 4, 20].
The purpose of this study was to compare patients with one OCLT with and without concomitant CAI according to demographic, lesion-related, and therapy-related factors as well as baseline clinical outcome scores at the time of surgery. All OCLTs were treated with AMIC. The aim was to investigate whether the presence of CAI has an influence on the demographic and lesion characteristics as well as the baseline clinical outcome scores. Knowledge of such an influence could change patient counselling and therapy decisions. If CAI has an influence, all OCLA patients would have to be examined for CAI and CAI would have to be integrated into the treatment concept.
It was hypothesised that there is a difference according to demographic and lesion-related factors as well as baseline clinical outcome scores between patients with OCLT and CAI compared to patients with OCLT without CAI.
Materials and methods
The data used in this study were obtained from the German Cartilage Registry (KnorpelRegister DGOU). Approval was given by every institutional review board (IRB) at every participating clinical centre. The identification number of the IRB of the study coordination centre at the University Hospital of Freiburg, Germany is 520/14. The study was performed according to the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki declaration and its later amendments. All individual participants gave their informed consent prior to inclusion. The German Cartilage Registry is financially supported by the Deutsche Arthrose-Hilfe e.V. and the Stiftung Oskar-Helene-Heim.
This registry included data of 633 patients with OCLA who underwent operations between 2014 and 2018 in 49 clinical centres. The data were prospectively collected using a web-based remote data entry system. All patients whose data were in the registry by December 2018 were included in the analysis. The following exclusion criteria were used: missing basic data set (patient age and gender), more than one treated OCLA, osteochondral lesion of the distal tibia, any OCLA treatment other than AMIC, any previous surgery on the ankle, and distal tibial osteotomy as concomitant surgery. As a result, a total of 63 patients with a solitary OCLT (38 men and 25 women, median age 31 years [range 18–72 years]) who were treated in 13 different centres were included in the study.
Demographic variables including age, gender (male vs. female) and body mass index were assessed. Information on the aetiology of the OCLT (traumatic, posttraumatic, degenerative, or other), the duration of symptoms, and the location of the OCLT at the talus in the frontal plane (medial vs. lateral) as well as the sagittal plane (anterior vs. central vs. posterior) were also included. The OCLTs were classified according to the Berndt-Harty-Loomer classification [14] and International Cartilage Repair Society (ICRS) classification. The approximate lesion size was calculated by multiplying the lesion length by the width. The cartilage condition at the corresponding joint surface (intact vs. ICRS 1–2 vs. ICRS 3–4) was also assessed. Whether the patients had any previous non-surgical treatment and the reason for the non-surgical treatment if it had occurred was also recorded.
OCLTs were categorised as traumatic when there was evidence of trauma to the ankle within 12 months prior to the current operation, and as post-traumatic when there was evidence of trauma more than 12 months before the operation. OCLTs were categorised as degenerative if there was no evidence of trauma to the ankle in the patient’s history.
The following variables related to the operation were captured: the type of approach to the ankle, whether AMIC was combined with autologous bone grafting, whether an additional debridement of impingement was performed, whether a concomitant ankle stabilisation was performed and, if so, which kind of stabilisation was used.
The study population was divided into two groups. Patients in group A (n = 29) had both OCLT and CAI. They received AMIC for OCLT treatment and an additional ankle stabilisation. Patients in group B (n = 34) had only OCLA. They received AMIC alone. Both groups were compared according to demographic, lesion-related, and therapy-related factors.
The surgical stabilisation techniques that were performed in group A are presented in Table 1.
The clinical condition of the patients was measured at the time of the operation according to the German versions of the Foot and Ankle Ability Measure (FAAM) [16], the FAOS [25], and the Numeric Rating Scale for Pain (NRS) [6]. The NRS score consists of values ranging from 0 (no pain) to 10 (pain as bad as you can imagine). Group A and B were also compared according to FAAM, FAOS, and NRS scores at the time of the operation.
Statistical analysis
The Shapiro–Wilk W test was applied to screen the data for normality of distribution. Mean and standard deviation for normally distributed data, and median and range for non-normally distributed data were reported.
To compare groups A and B according to demographic, lesion-related and therapy-related factors, the Wilcoxon test was used for continuous data and the Chi-square test for categorical data. The Wilcoxon test was also used to compare the FAAM and FAOS subscale scores for groups A and B at the time of the operation, respectively.
The level of significance was set at p = 0.05 for all statistical tests.
Results
Table 2 shows the demographic, lesion-related and therapy-related factors within groups A and B. The patients within group A were older, with a median age of 34 years (range 20–65 years) compared to 28.5 years (range 18–72 years) for group B. However, the difference was not statistically significant.
The aetiology of the OCLT was significantly different between group A and B. In Group A, traumatic and post-traumatic OCLTs were more frequent than degenerative OCLTs (89.7% versus 10.3%), whereas in Group B, the distribution of the aetiology was reversed (61.7% degenerative versus 38.3% traumatic/post-traumatic, p = 0.001).
In both groups, OCLTs were more frequently located at the medial than at the lateral talus in the coronary plane, and at the central talus than the anterior or posterior talus in the sagittal plane. There were no statistically significant differences between groups A and B regarding the localisation of the OCLTs. The OCLTs in group A were smaller, with a median lesion size of 100 mm2 (range 15–600 mm2) compared to 150 mm2 (range 25–448 mm2) in group B; however, the difference was not statistically significant.
The majority of patients in both groups presented with OCLTs in advanced stages according to the Berndt-Harty-Loomer classification (stage 3–5: group A, 79.3%; group B, 82.4%), as well as the ICRS classification (ICRS stage 3–4: Group A, 93.1%; group B, 94.1%). The corresponding joint surface at the distal tibia was intact in the majority of patients in both groups (group A, 82.8%; group B, 94.1%).
A previous non-surgical treatment of the ankle was significantly more frequent in patients in group A (p = 0.013). The reason for the non-surgical treatment was a ligamentous injury in 90.0% of patients in group A and in all patients in group B.
The frequencies of combined autologous bone grafting or debridement of a bony or soft tissue impingement were not different between group A and B.
FAAM baseline scores at the time of surgery were not significantly different between Groups A and B (Tables 3 and 4). Patients in group A had worse scores on the quality of life subscale of the FAOS compared to patients in group B (p = 0.017). The remaining FAOS subscales were not significantly different between groups A and B (Table 5). The median NRS scores at the time of surgery were not significantly different between groups A and B (median 3 [range 0–8] versus median 3.5 [range 1–9]; missing data, n = 14).
Discussion
The most important finding of this study was that patients with OCLT and concomitant CAI have a decreased quality of life compared to patients with only OCLT. Further, patients with OCLT differ according to demographic and lesion-related factors depending on whether a concomitant CAI is present. Patients with concomitant CAI were older, although the difference in age between Groups A and B was not statistically significant. Furthermore, the rate of trauma-associated OCLTs was significantly higher when concomitant CAI was present, and patients in Group A had also more frequently undergone previous non-surgical treatment of the ankle than patients in Group B.
The aetiology and pathophysiology of OCLA are still unknown [17]. Ankle instability is the result of trauma. Therefore, OCLA can occur as either the result of initial trauma or repeated microtrauma in the context of instability. The rate of arthroscopic detection of OCLAs in operations performed for CAI reported in the literature ranges from 25 to 95% [10, 11, 18, 21].
Lee et al. compared patients with OCLT with and without concomitant CAI and evaluated baseline characteristics before and after propensity score matching [12]. Before matching, the mean age in the OCLT + CAI Group was higher, although this was not statistically significant. Similar results were observed in this study. After matching, the mean age was approximately the same in both groups. An explanation for the somewhat higher age in the OCLT + CAI population could be that the OCLT only developed after a prolonged presence of CAI, for example by repeated microtraumas. Furthermore, Lee et al. found more men than women in both groups, both before and after propensity score matching [12]. In this study, no significant difference was observed according to the gender distribution between Groups A and B.
Lee et al. found a higher rate of trauma-associated OCLTs in the group with concomitant CAI before propensity score matching [12]. However, there was no difference after matching. Also in this study, more patients with a history of trauma were observed in group A. In this study, OCLT was evaluated as degenerative in only three patients in group A. These patients had no trauma in their medical history. However, it is possible that, in these cases, an unremarkable trauma occurred to the ankle, which subsequently led to the development of CAI.
Furthermore, Lee et al. found a higher rate of laterally located lesions and larger lesions in unstable ankles compared to patients with OCLT without CAI [12]. However, the majority of OCLTs in their study were located medially within both groups (OCLT + CAI, 64% vs. OCLT without CAI, 79%). Similar findings regarding the higher rate of lateral lesions were observed in this study, whereby the majority of lesions were located medially in group A (57.1%) as well as in group B (71.9%). In addition, in this study population, the lesions were larger within group B.
In this study, it is not surprising that the rate of previous non-surgical therapies for ligament injuries in Group A was higher than in Group B. It is suspected that inadequate therapy of ligament injury led to CAI, which in turn led to the development of OCLT through repeated microtrauma.
Jiang et al. performed ankle arthroscopy and anatomic lateral ankle ligament repair with suture anchors for CAI in 70 patients [8]. Thirty-four of the patients had additional OCLAs, which were treated with arthroscopic abrasion, curettage, drilling, or microfracture. The authors did not observe a difference in patients’ demographic characteristics between the CAI + OCLA and the CAI groups. Li et al. performed a repair of the lateral ligament complex for chronic ankle instability in 104 patients and found concomitant OCLA in 33 of these patients. The authors addressed this by debridement, microfracture, or osteochondral implantation [13] and did not find any difference in age and gender distribution between the two groups.
Reduced clinical status according to the FAOS and FAAM baseline scores was evaluated in all patients in this study, especially with regard to sports and recreational activities. The joint function of the majority of patients in both groups was classified as abnormal or severely abnormal according to FAAM scores. Quality of life based on the FAOS score was also poor in both groups, with patients in group A having a worse quality of life than patients in group B.
In a recent study, Kim et al. showed that patients with CAI with accompanied osteoarthritis of the medial compartment and long symptom duration benefit from ankle stabilisation according to joint function and symptoms [9]. This underlines the relevance of ankle instability in patients with ankle chondropathy.
This study has several limitations. It is a cross-sectional cohort study with data collection from a national multicentre registry. Patients from 13 different centres were included in the study, which leads to a certain heterogeneity of the data. However, this is a feature of registry studies. Patient data such as lesion size or ICRS scores were provided by the surgeon, which may lead to variability regarding the evaluation of the participating surgeons [15]. However, previous literature reported good inter-observer reliability for ICRS [26], excellent inter-observer reliability for the FAAM [16], and excellent test–retest reliability for the FAOS [25]. In this study, a relatively large number of AMIC patients were included. The homogeneity of the data was improved by including only patients with a solitary talus lesion and without prior surgery on the affected ankle joint. One limitation of this study is that CAI was not uniformly diagnosed in all centres. The respective surgeon was responsible for the diagnosis. In addition, since different stabilisation techniques were used, a comparative statement about different techniques can’t be made.
The performance of combined debridement of a bony or soft tissue impingement as well as autologous bone grafting in combination with AMIC each represents a possible confounder. However, both interventions occurred with similar frequencies in both groups.
This study does not yet assess any clinical follow-up data. Future evaluations of the German Cartilage Registry will show whether the long-term clinical outcome of OCLT patients with and without concomitant CAI differ. Patients with OCLT should be examined for concomitant CAI so that if CAI is present it can be integrated into the treatment concept.
Conclusions
OCLT patients with concomitant CAI differ from OCLT patients without CAI according to demographic and lesion-related factors. The presence of CAI also worsens the quality of life of OCLT patients.
Abbreviations
- AMIC:
-
Autologous matrix-induced chondrogenesis
- AOFAS:
-
American Orthopedic Foot and Ankle Society
- BHL:
-
Berndt–Harty–Loomer
- CAI:
-
Chronic ankle instability
- FAAM:
-
Foot and Ankle Ability Measure
- FAOS:
-
Foot and Ankle Outcome Score
- ICRS:
-
International Cartilage Repair Society
- IRB:
-
Institutional Review Board
- NRS:
-
Numeric Rating Scale for Pain
- OCLA:
-
Osteochondral lesion of the ankle
- OCLT:
-
Osteochondral lesion of the talus
References
Becher C, Malahias MA, Ali MM, Maffulli N, Thermann H (2019) Arthroscopic microfracture vs arthroscopic autologous matrix-induced chondrogenesis for the treatment of articular cartilage defects of the talus. Knee Surg Sports Traumatol Arthrosc 27(9):2731–2736
Choi WJ, Lee JW, Han SH, Kim BS, Lee SK (2008) Chronic lateral ankle instability: the effect of intra-articular lesions on clinical outcome. Am J Sports Med 36(11):2167–2172
D’Ambrosi R, Maccario C, Ursino C, Serra N, Usuelli FG (2017) Combining microfractures, autologous bone graft, and autologous matrix-induced chondrogenesis for the treatment of juvenile osteochondral talar lesions. Foot ankle Int 38(5):485–495
Gottschalk O, Altenberger S, Baumbach S, Kriegelstein S, Dreyer F, Mehlhorn A, Horterer H, Topfer A, Roser A, Walther M (2017) Functional medium-term results after autologous matrix-induced chondrogenesis for osteochondral lesions of the talus: a 5-year prospective cohort study. J Foot Ankle Surg 56(5):930–936
Gregush RV, Ferkel RD (2010) Treatment of the unstable ankle with an osteochondral lesion: results and long-term follow-up. Am J Sports Med 38(4):782–790
Hawker GA, Mian S, Kendzerska T, French M (2011) Measures of adult pain: Visual Analog Scale for Pain (VAS Pain), Numeric Rating Scale for Pain (NRS Pain), McGill Pain Questionnaire (MPQ), Short-Form McGill Pain Questionnaire (SF-MPQ), Chronic Pain Grade Scale (CPGS), Short Form-36 Bodily Pain Scale (SF-36 BPS), and Measure of Intermittent and Constant Osteoarthritis Pain (ICOAP). Arthritis Care Res (Hoboken) 63(Suppl 1):240–252
Hintermann B, Boss A, Schäfer D (2002) Arthroscopic findings in patients with chronic ankle instability. Am J Sports Med 30(3):402–409
Jiang D, Ao Y-F, Jiao C, Xie X, Chen L-X, Guo Q-W, Hu Y-L (2018) Concurrent arthroscopic osteochondral lesion treatment and lateral ankle ligament repair has no substantial effect on the outcome of chronic lateral ankle instability. Knee Surg Sports Traumatol Arthrosc 26(10):3129–3134
Kim S-W, Jung H-G, Lee J-S (2020) Ligament stabilization improved clinical and radiographic outcomes for individuals with chronic ankle instability and medial ankle osteoarthritis. Knee Surg Sports Traumatol Arthrosc. https://doi.org/10.1007/s00167-020-05845-5
Komenda GA, Ferkel RD (1999) Arthroscopic findings associated with the unstable ankle. Foot Ankle Int 20(11):708–713
Lee J, Hamilton G, Ford L (2011) Associated intra-articular ankle pathologies in patients with chronic lateral ankle instability: arthroscopic findings at the time of lateral ankle reconstruction. Foot Ankle Spec 4(5):284–289
Lee M, Kwon JW, Choi WJ, Lee JW (2015) Comparison of outcomes for osteochondral lesions of the talus with and without chronic lateral ankle instability. Foot Ankle Int 36(9):1050–1057
Li H, Hua Y, Li H, Li S, Ma K, Chen S (2018) Treatment of talus osteochondral defects in chronic lateral unstable ankles: small-sized lateral chondral lesions had good clinical outcomes. Knee Surg Sports Traumatol Arthrosc 26(7):2116–2122
Loomer R, Fisher C, Lloyd-Smith R, Sisler J, Cooney T (1993) Osteochondral lesions of the talus. Am J Sports Med 21(1):13–19
Mehl J, Otto A, Willinger L, Hapfelmeier A, Imhoff AB, Niemeyer P, Angele P, Zinser W, Spahn G, Schmitt A (2019) Degenerative isolated cartilage defects of the patellofemoral joint are associated with more severe symptoms compared to trauma-related defects: results of the German Cartilage Registry (KnorpelRegister DGOU). Knee Surg Sports Traumatol Arthrosc 27(2):580–589
Nauck T, Lohrer H (2011) Translation, cross-cultural adaption and validation of the German version of the Foot and Ankle Ability Measure for patients with chronic ankle instability. Br J Sports Med 45(10):785–790
O’Loughlin PF, Heyworth BE, Kennedy JG (2010) Current concepts in the diagnosis and treatment of osteochondral lesions of the ankle. Am J Sports Med 38(2):392–404
Okuda R, Kinoshita M, Morikawa J, Yasuda T, Abe M (2005) Arthroscopic findings in chronic lateral ankle instability: do focal chondral lesions influence the results of ligament reconstruction? Am J Sports Med 33(1):35–42
van Rijn RM, van Os AG, Bernsen RMD, Luijsterburg PA, Koes BW, Bierma-Zeinstra SMA (2008) What is the clinical course of acute ankle sprains? A systematic literature review. Am J Med 121(4):324–331.e6
Shimozono Y, Yasui Y, Ross AW, Miyamoto W, Kennedy JG (2017) Scaffolds based therapy for osteochondral lesions of the talus: a systematic review. World J Orthop 8(10):798–808
Taga I, Shino K, Inoue M, Nakata K, Maeda A, Henry JH (1993) Articular cartilage lesions in ankles with lateral ligament injury. An arthroscopic study. Am J Sports Med 21(1):120–127
Usuelli FG, D’Ambrosi R, Maccario C, Boga M, de Girolamo L (2018) All-arthroscopic AMIC (AT-AMIC) technique with autologous bone graft for talar osteochondral defects: clinical and radiological results. Knee Surg Sports Traumatol Arthrosc 26(3):875–881
Usuelli FG, de Girolamo L, Grassi M, D’Ambrosi R, Montrasio UA, Boga M (2015) All-arthroscopic autologous matrix-induced chondrogenesis for the treatment of osteochondral lesions of the talus. Arthrosc Tech 4(3):e255–259
Valderrabano V, Miska M, Leumann A, Wiewiorski M (2013) Reconstruction of osteochondral lesions of the talus with autologous spongiosa grafts and autologous matrix-induced chondrogenesis. Am J Sports Med 41(3):519–527
Van Bergen CJA, Sierevelt IN, Hoogervorst P, Waizy H, van Dijk CN, Becher C (2014) Translation and validation of the German version of the foot and ankle outcome score. Arch Orthop Trauma Surg 134(7):897–901
Van den Borne MPJ, Raijmakers NJH, Vanlauwe J, Victor J, de Jong SN, Bellemans J, Saris DBF (2007) International Cartilage Repair Society (ICRS) and Oswestry macroscopic cartilage evaluation scores validated for use in Autologous Chondrocyte Implantation (ACI) and microfracture. Osteoarthr Cartil 15(12):1397–1402
Van Dijk CN, Bossuyt PM, Marti RK (1996) Medial ankle pain after lateral ligament rupture. J Bone Joint Surg Br 78(4):562–567
Wiewiorski M, Barg A, Valderrabano V (2013) Autologous matrix-induced chondrogenesis in osteochondral lesions of the talus. Foot Ankle Clin 18(1):151–158
Yasui Y, Takao M, Miyamoto W, Matsushita T (2014) Simultaneous surgery for chronic lateral ankle instability accompanied by only subchondral bone lesion of talus. Arch Orthop Trauma Surg 134(6):821–827
Acknowledgments
We want to thank the Deutsche Arthrose-Hilfe e.V. and the Stiftung Oskar-Helene-Heim.
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The German Cartilage Registry is financially supported by the Deutsche Arthrose-Hilfe e.V. and the Stiftung Oskar-Helene-Heim.
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DK: study design, data acquisition, statistical data analysis and interpretation, drafting and writing the manuscript. AA, MA, SS and CB: study design, revision of the manuscript. MW, OG, YB, SE and CP data acquisition, revision of the manuscript. MDA: study design, statistical data analysis and interpretation, drafting and writing the manuscript. All authors read and approved the final manuscript.
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CP is a consultant of Medartis AG. CP has received or will receive research grants not related to this paper from Plasmaconcept, Medartis, Stryker, DePuysSynthes, NewDeal, and OPED. The other authors declare that they have no potential conflict of interest.
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The study was performed according to the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki declaration and its later amendments.
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Körner, D., Ateschrang, A., Schröter, S. et al. Concomitant ankle instability has a negative impact on the quality of life in patients with osteochondral lesions of the talus: data from the German Cartilage Registry (KnorpelRegister DGOU). Knee Surg Sports Traumatol Arthrosc 28, 3339–3346 (2020). https://doi.org/10.1007/s00167-020-05954-1
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DOI: https://doi.org/10.1007/s00167-020-05954-1