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Knee Surgery, Sports Traumatology, Arthroscopy
Published in: Knee Surgery, Sports Traumatology, Arthroscopy 2/2020

Open Access 01-02-2020 | KNEE

Strength in numbers? The fragility index of studies from the Scandinavian knee ligament registries

Authors: Eleonor Svantesson, Eric Hamrin Senorski, Adam Danielsson, David Sundemo, Olof Westin, Olufemi R. Ayeni, Kristian Samuelsson

Published in: Knee Surgery, Sports Traumatology, Arthroscopy | Issue 2/2020

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Abstract

Purpose

The fragility index (FI) is a metric to evaluate the robustness of statistically significant results. It describes the number of patients who would need to change from a non-event to an event to change a result from significant to non-significant. This systematic survey aimed to evaluate the feasibility of applying the FI to findings related to anterior cruciate ligament (ACL) reconstruction in the Scandinavian knee ligament registries.

Methods

The PubMed, EMBASE, Cochrane Library and AMED databases were searched. Studies from the Scandinavian knee ligament registers were eligible if they reported a statistically significant result (p < 0.05) for any of the following dichotomous outcomes; ACL revision, contralateral ACL reconstruction or the presence of postoperative knee laxity. Only studies with a two-arm comparative analysis were included. Eligibility assessment, data extraction and quality assessment were performed by two independent reviewers. The dichotomous analyses were stratified according to the grouping variable for the two comparative arms as follows; age, patient sex, activity at injury, graft choice, drilling technique, graft fixation, single- versus double-bundle, concomitant cartilage injury and country. The two-sided Fisher’s exact test was used to calculate the FI of all statistically significant analyses.

Results

From 158 identified studies, 13 studies were included. They reported statistical significance for a total of 56 dichotomous analyses, of which all but two had been determined by a time-to-event analysis. The median sample size for the arms was 5540 (range 92–38,666). The mean FI for all 56 dichotomous analyses was 80.6 (median 34.5), which means that a mean of 80.6 patients were needed to change outcome status to generate a non-significant result instead of a significant one. Seventeen analyses (30.4%) immediately became non-significant when performing the two-sided Fisher’s exact test and, therefore, had an FI of 0. The analyses related to age were the most robust, with a mean FI of 178.5 (median 116, range 1–1089). The mean FI of the other grouping variables ranged from 0.5 to 48.0.

Conclusion

There was large variability in the FI in analyses from the Scandinavian knee ligament registries and almost one third of the analyses had an FI of zero. The FI is a rough measurement of robustness when applied to registry studies, however, future studies are needed to determine the most appropriate metric for robustness in registry studies. The use of the FI can provide clinicians with a deeper understanding of significant study results and promotes an evidence-based approach in the clinical care of patients.

Level of evidence

Systematic review of prospective cohort studies, Level II.
Appendix
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Literature
1.
Hamrin Senorski E, Svantesson E, Baldari A, Ayeni OR, Engebretsen L et al (2019) Factors that affect patient reported outcome after anterior cruciate ligament reconstruction—a systematic review of the Scandinavian knee ligament registers. Br J Sports Med 53(7):410–417PubMed
2.
Svantesson E, Hamrin Senorski E, Baldari A, Ayeni OR, Engebretsen L et al (2019) Factors associated with additional anterior cruciate ligament reconstruction and register comparison: a systematic review on the Scandinavian knee ligament registers. Br J Sports Med 53(7):418–425PubMed
3.
Fisher R (1973) Statistical methods and scientific inference, 3rd edn. Hafner Publishing Company, New York
4.
Cohen HW (2011) P values: use and misuse in medical literature. Am J Hypertens 24(1):18–23PubMed
5.
Kyriacou DN (2016) The enduring evolution of the p value. JAMA 315(11):1113–1115PubMed
6.
Mark DB, Lee KL, Harrell FE Jr (2016) Understanding the role of p values and hypothesis tests in clinical research. JAMA Cardiol 1(9):1048–1054PubMed
7.
Walsh M, Srinathan SK, McAuley DF, Mrkobrada M, Levine O et al (2014) The statistical significance of randomized controlled trial results is frequently fragile: a case for a fragility index. J Clin Epidemiol 67(6):622–628PubMed
8.
Gifstad T, Foss OA, Engebretsen L, Lind M, Forssblad M et al (2014) Lower risk of revision with patellar tendon autografts compared with hamstring autografts: a registry study based on 45,998 primary ACL reconstructions in Scandinavia. Am J Sports Med 42(10):2319–2328PubMed
9.
Persson A, Fjeldsgaard K, Gjertsen JE, Kjellsen AB, Engebretsen L et al (2014) Increased risk of revision with hamstring tendon grafts compared with patellar tendon grafts after anterior cruciate ligament reconstruction: a study of 12,643 patients from the Norwegian cruciate ligament registry, 2004–2012. Am J Sports Med 42(2):285–291PubMed
10.
Rahr-Wagner L, Thillemann TM, Pedersen AB, Lind M (2014) Comparison of hamstring tendon and patellar tendon grafts in anterior cruciate ligament reconstruction in a nationwide population-based cohort study: results from the Danish registry of knee ligament reconstruction. Am J Sports Med 42(2):278–284PubMed
11.
Khan M, Evaniew N, Gichuru M, Habib A, Ayeni OR et al (2017) The fragility of statistically significant findings from randomized trials in sports surgery: a systematic survey. Am J Sports Med 45(9):2164–2170PubMed
12.
Prentice HA, Lind M, Mouton C, Persson A, Magnusson H et al (2018) Patient demographic and surgical characteristics in anterior cruciate ligament reconstruction: a description of registries from six countries. Br J Sports Med 52(11):716–722PubMed
13.
Downs SH, Black N (1998) The feasibility of creating a checklist for the assessment of the methodological quality both of randomised and non-randomised studies of health care interventions. J Epidemiol Commun Health 52(6):377–384
14.
Lind M, Menhert F, Pedersen AB (2009) The first results from the Danish ACL reconstruction registry: epidemiologic and 2 year follow-up results from 5818 knee ligament reconstructions. Knee Surg Sports Traumatol Arthrosc 17(2):117–124PubMed
15.
Rahr-Wagner L, Thillemann TM, Lind MC, Pedersen AB (2013) Validation of 14,500 operated knees registered in the Danish knee ligament reconstruction register: registration completeness and validity of key variables. Clin Epidemiol 5:219–228PubMedPubMedCentral
16.
Bjornsson H, Andernord D, Desai N, Norrby O, Forssblad M et al (2015) No difference in revision rates between single- and double-bundle anterior cruciate ligament reconstruction: a comparative study of 16,791 patients from the Swedish national knee ligament register. Arthroscopy 31(4):659–664PubMed
17.
Andernord D, Desai N, Bjornsson H, Ylander M, Karlsson J et al (2015) Patient predictors of early revision surgery after anterior cruciate ligament reconstruction: a cohort study of 16,930 patients with 2-year follow-up. Am J Sports Med 43(1):121–127PubMed
18.
Eysturoy NH, Nissen KA, Nielsen T, Lind M (2018) The influence of graft fixation methods on revision rates after primary anterior cruciate ligament reconstruction. Am J Sports Med 46(3):524–530PubMed
19.
Snaebjornsson T, Hamrin Senorski E, Ayeni OR, Alentorn-Geli E, Krupic F et al (2017) Graft diameter as a predictor for revision anterior cruciate ligament reconstruction and KOOS and EQ-5D values: a cohort study from the Swedish national knee ligament register based on 2240 patients. Am J Sports Med 45(9):2092–2097PubMed
20.
Andernord D, Bjornsson H, Petzold M, Eriksson BI, Forssblad M et al (2014) Surgical predictors of early revision surgery after anterior cruciate ligament reconstruction: results from the Swedish national knee ligament register on 13,102 patients. Am J Sports Med 42(7):1574–1582PubMed
21.
Andernord D, Desai N, Bjornsson H, Gillen S, Karlsson J et al (2015) Predictors of contralateral anterior cruciate ligament reconstruction: a cohort study of 9061 patients with 5-year follow-up. Am J Sports Med 43(2):295–302PubMed
22.
Faltstrom A, Hagglund M, Magnusson H, Forssblad M, Kvist J (2016) Predictors for additional anterior cruciate ligament reconstruction: data from the Swedish national ACL register. Knee Surg Sports Traumatol Arthrosc 24(3):885–894PubMed
23.
Granan LP, Baste V, Engebretsen L, Inacio MC (2015) Associations between inadequate knee function detected by KOOS and prospective graft failure in an anterior cruciate ligament-reconstructed knee. Knee Surg Sports Traumatol Arthrosc 23(4):1135–1140PubMed
24.
Kvist J, Kartus J, Karlsson J, Forssblad M (2014) Results from the Swedish national anterior cruciate ligament register. Arthroscopy 30(7):803–810PubMed
25.
Lind M, Menhert F, Pedersen AB (2012) Incidence and outcome after revision anterior cruciate ligament reconstruction: results from the Danish registry for knee ligament reconstructions. Am J Sports Med 40(7):1551–1557PubMed
26.
Rahr-Wagner L, Thillemann TM, Lind M, Pedersen AB (2015) Comorbidities in patients with anterior cruciate ligament reconstruction compared with matched controls without anterior cruciate ligament injury from danish registries. Arthroscopy 31(9):1741–1747 (e1744) PubMed
27.
Aga C, Kartus JT, Lind M, Lygre SHL, Granan LP et al (2017) Risk of revision was not reduced by a double-bundle ACL reconstruction technique: results from the Scandinavian registers. Clin Orthop Relat Res 475(10):2503–2512PubMedPubMedCentral
28.
Desai N, Andernord D, Sundemo D, Alentorn-Geli E, Musahl V et al (2017) Revision surgery in anterior cruciate ligament reconstruction: a cohort study of 17,682 patients from the Swedish national knee ligament register. Knee Surg Sports Traumatol Arthrosc 25(5):1542–1554PubMed
29.
Fauno P, Rahr-Wagner L, Lind M (2014) Risk for revision after anterior cruciate ligament reconstruction is higher among adolescents: results from the danish registry of knee ligament reconstruction. Orthop J Sports Med 2(10):2325967114552405PubMedPubMedCentral
30.
Snaebjornsson T, Hamrin Senorski E, Sundemo D, Svantesson E, Westin O et al (2017) Adolescents and female patients are at increased risk for contralateral anterior cruciate ligament reconstruction: a cohort study from the Swedish national knee ligament register based on 17,682 patients. Knee Surg Sports Traumatol Arthrosc 25(12):3938–3944PubMedPubMedCentral
31.
Soreide E, Granan LP, Hjorthaug GA, Espehaug B, Dimmen S et al (2016) The effect of limited perioperative nonsteroidal anti-inflammatory drugs on patients undergoing anterior cruciate ligament reconstruction. Am J Sports Med 44(12):3111–3118PubMed
32.
Ahlden M, Samuelsson K, Sernert N, Forssblad M, Karlsson J et al (2012) The Swedish national anterior cruciate ligament register: a report on baseline variables and outcomes of surgery for almost 18,000 patients. Am J Sports Med 40(10):2230–2235PubMed
33.
Rahr-Wagner L, Thillemann TM, Pedersen AB, Lind MC (2013) Increased risk of revision after anteromedial compared with transtibial drilling of the femoral tunnel during primary anterior cruciate ligament reconstruction: results from the Danish knee ligament reconstruction register. Arthroscopy 29(1):98–105PubMed
34.
Persson A, Gifstad T, Lind M, Engebretsen L, Fjeldsgaard K et al (2018) Graft fixation influences revision risk after ACL reconstruction with hamstring tendon autografts. Acta Orthop 89(2):204–210PubMed
35.
Persson A, Kjellsen AB, Fjeldsgaard K, Engebretsen L, Espehaug B et al (2015) Registry data highlight increased revision rates for endobutton/biosure HA in ACL reconstruction with hamstring tendon autograft: a nationwide cohort study from the Norwegian knee ligament registry, 2004–2013. Am J Sports Med 43(9):2182–2188PubMed
36.
Svantesson E, Sundemo D, Hamrin Senorski E, Alentorn-Geli E, Musahl V et al (2017) Double-bundle anterior cruciate ligament reconstruction is superior to single-bundle reconstruction in terms of revision frequency: a study of 22,460 patients from the Swedish national knee ligament register. Knee Surg Sports Traumatol Arthrosc 25(12):3884–3891PubMed
37.
Evaniew N, Files C, Smith C, Bhandari M, Ghert M et al (2015) The fragility of statistically significant findings from randomized trials in spine surgery: a systematic survey. Spine J 15(10):2188–2197PubMed
38.
Kaeding CC, Pedroza AD, Reinke EK, Huston LJ, Spindler KP (2015) Risk factors and predictors of subsequent ACL injury in either knee after ACL reconstruction: prospective analysis of 2488 primary ACL reconstructions from the MOON Cohort. Am J Sports Med 43(7):1583–1590PubMedPubMedCentral
39.
Paterno MV, Rauh MJ, Schmitt LC, Ford KR, Hewett TE (2014) Incidence of second ACL injuries 2 years after primary ACL reconstruction and return to sport. Am J Sports Med 42(7):1567–1573PubMedPubMedCentral
40.
Webster KE, Feller JA (2016) Exploring the high reinjury rate in younger patients undergoing anterior cruciate ligament reconstruction. Am J Sports Med 44(11):2827–2832PubMed
41.
Webster KE, Feller JA, Leigh WB, Richmond AK (2014) Younger patients are at increased risk for graft rupture and contralateral injury after anterior cruciate ligament reconstruction. Am J Sports Med 42(3):641–647PubMed
42.
Wiggins AJ, Grandhi RK, Schneider DK, Stanfield D, Webster KE et al (2016) Risk of secondary injury in younger athletes after anterior cruciate ligament reconstruction: a systematic review and meta-analysis. Am J Sports Med 44(7):1861–1876PubMedPubMedCentral
43.
Browning WM 3rd, Kluczynski MA, Curatolo C, Marzo JM (2017) Suspensory versus aperture fixation of a quadrupled hamstring tendon autograft in anterior cruciate ligament reconstruction: a meta-analysis. Am J Sports Med 45(10):2418–2427PubMed
44.
Hurley ET, Gianakos AL, Anil U, Strauss EJ, Gonzalez-Lomas G (2019) No difference in outcomes between femoral fixation methods with hamstring autograft in anterior cruciate ligament reconstruction—a network meta-analysis. Knee 26(2):292–301PubMed
45.
Jiang H, Ma G, Li Q, Hu Y, Li J et al (2018) Cortical button versus cross-pin femoral fixation for hamstring anterior cruciate ligament reconstruction: a meta-analysis of randomized controlled trials. Am J Sports Med 46(9):2277–2284PubMed
Metadata
Title
Strength in numbers? The fragility index of studies from the Scandinavian knee ligament registries
Authors
Eleonor Svantesson
Eric Hamrin Senorski
Adam Danielsson
David Sundemo
Olof Westin
Olufemi R. Ayeni
Kristian Samuelsson
Publication date
01-02-2020
Publisher
Springer Berlin Heidelberg
Published in
Knee Surgery, Sports Traumatology, Arthroscopy / Issue 2/2020
Print ISSN: 0942-2056
Electronic ISSN: 1433-7347
DOI
https://doi.org/10.1007/s00167-019-05551-x

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