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Article

A Bibliometric Analysis of Fragility Fractures: Top 50

by
Nicolas Vuillemin
1,
Hans-Christoph Pape
2,
Pol Maria Rommens
3,
Kurt Lippuner
4,
Klaus-Arno Siebenrock
1,
Marius Johann Keel
1 and
Johannes Dominik Bastian
1,*
1
Department of Orthopaedic Surgery and Traumatology, Inselspital, Bern University Hospital, University of Bern, 3012 Bern, Switzerland
2
Department of Trauma, University Hospital of Zurich, 8091 Zurich, Switzerland
3
Department of Orthopaedics and Traumatology, University Medical Center of Johannes Gutenberg-University Mainz, D 55131 Mainz, Germany
4
Department of Osteoporosis, Inselspital, Bern University Hospital, University of Bern, 3012 Bern, Switzerland
*
Author to whom correspondence should be addressed.
Medicina 2021, 57(6), 639; https://doi.org/10.3390/medicina57060639
Submission received: 17 May 2021 / Revised: 12 June 2021 / Accepted: 16 June 2021 / Published: 21 June 2021
(This article belongs to the Special Issue Hip and Fragility Fracture Management)
Browse Figures
Versions Notes

Abstract

:
Background and Objectives: The population is aging and fragility fractures are a research topic of steadily growing importance. Therefore, a systematic bibliometric review was performed to identify the 50 most cited articles in the field of fragility fractures analyzing their qualities and characteristics. Materials and Methods: From the Core Collection database in the Thomson Reuters Web of Knowledge, the most influential original articles with reference to fragility fractures were identified in February 2021 using a multistep approach. Year of publication, total number of citations, average number of citations per year since year of publication, affiliation of first and senior author, geographic origin of study population, keywords, and level of evidence were of interest. Results: Articles were published in 26 different journals between 1997 and 2020. The number of total citations per article ranged from 12 to 129 citations. In the majority of publications, orthopedic surgeons and traumatologists (66%) accounted for the first authorship, articles mostly originated from Europe (58%) and the keyword mostly used was “hip fracture”. In total, 38% of the articles were therapeutic studies level III followed by prognostic studies level I. Only two therapeutic studies with level I could be identified. Conclusions: This bibliometric review shows the growing interest in fragility fractures and raises awareness that more high quality and interdisciplinary studies are needed.

1. Introduction

Patients with fragility fractures represent a particularly vulnerable patient group with specific demands and characteristics. Patient-centered care of this patient population requires specific medical expertise to prevent complications and to avoid loss of independence and the need for institutional care. Therefore, a multidisciplinary approach is mandatory, involving orthopedic surgeons, geriatricians, specialists in bone metabolism and pain therapy as well as physiotherapists [1].
Due to the rising numbers of fragility fractures over the last decades, they have increasingly become a key topic in clinical research with a growing number of publications reporting results of studies exploring fragility fractures. In consideration of that, the aim of the present study was to report in a bibliometric review the current research literature on fragility fractures.
We were interested to know what disciplines were active in clinical research in the field of fragility factures, in what geographical regions this research has been conducted, and what key topics were addressed in the most highly cited research articles elaborating fragility fractures.

2. Materials and Methods

From the Core Collection database in the Thomson Reuters Web of Knowledge, we searched for the most influential original articles with reference to fragility fractures. Fragility fractures have been defined as “a fracture that is caused by an injury that would be insufficient to fracture normal bone; the result of reduced compressive and/or torsional strength of bone.” [2]. The search was conducted on 9th of February 2021 and included all available documents. The most cited 50 articles were identified and then analyzed for their qualities and characteristics using this bibliometric review. For further interpretation, parts of the obtained data were presented in relation to estimated data for the world population provided by the United Nations (United Nations, Department of Economic and Social Affairs, Population Division (2019). World Population Prospects 2019, Online Edition. Rev. 1.) [3] and in relation to the gross domestic product (GDP) per capita (in USD) as provided by the National Accounts Sections of the United Nations Statistics Division (Basic Data Selection—amaWebClient. Available online: https://unstats.un.org/unsd/snaama/Basic (accessed on 6 April 2021)).

2.1. Selection Process and Eligibility Criteria

The inclusion and exclusion of articles, as well as data extraction were conducted by an orthopedic resident (N.V.) and a senior consultant orthopedic surgeon (J.D.B.), according to predefined criteria. Disagreements between investigators were solved by consensus.
The selection process was started using a title, abstract and author keywords search of the Thomson Reuters Web of Knowledge. The following search terms were used: (fragility fracture AND elderl * AND orthop *) OR (fragility fracture AND geriatr * AND orthop *) OR (fragility fracture AND older adult AND orthop *)) OR (fragility fracture AND elderl* AND surg *) OR (fragility fracture AND geriatr * AND surg *) OR (fragility fracture AND older adult AND surg *).
The document type was limited to original articles. Timespan was defined from 1900 to 2020. The operator “AND” was used to narrow the search. The operator “OR” was used to widen the search. The asterisk “*” was used to extend the search criteria, for example geriatr* will search for geriatrics and geriatrician. The process of inclusion and exclusion of articles is illustrated in Figure 1. The first exclusion step was performed in titles and abstracts based on either type of article (namely documents others than original articles, e.g., reviews, editorials, letter to the editor, case report, technical notes) or articles without focus on clinical management or diagnostics of fragility fractures (e.g., epidemiological studies and experimental studies, such as biomechanical studies or studies with animals). This exclusion step was redone in a second exclusion step by using full-text article search in remaining cases. For the final inclusion of identified articles, we ranked all articles according to their total citation rate; number one having the highest number of total citations. In case of an equal number of total citations, the articles were further ranked according to the average citation per year and then according to citations in 2020. For the bibliometric analysis, the 50 most cited articles were included.

2.2. Data Extraction and Assessment

For data analysis, information available at the Thomson Reuters Web of Knowledge on 9 February 2021 was used. For each included article, we extracted the following parameters: year of publication, total number of citations, average number of citations per year since year of publication, affiliation of first and senior author (orthopedic surgeon/traumatologist, geriatrician/internal medicine, others), geographic origin of study population, and keywords. For comparison within European countries with versus without identified articles the GDP per capita was used. Articles were classified as being either (1) therapeutic, (2) prognostic, (3) diagnostic studies, or (4) economic and decision analyses using the Journal of Bone and Joint Surgery American classification scheme [4]. The level of evidence was established according to the Journal of Bone and Joint Surgery American criteria with level I being the strongest and level V being the weakest level of evidence. Therapeutic studies were matched to an anatomic region when possible.

2.3. Statistical Analysis

Descriptive methods were used. All obtained data are defined as number, percentage, bar and line diagram. For analyses and plotting of diagrams Microsoft Excel, 2016 and the online tool Infogram Version 2.0.2 Available online: https://infogram.com (accessed on 2 April 2021) were used. For comparison of the GDP per capita within European countries a Mann–Whitney test was performed using GraphPad Prism (Version 9.0, GraphPad Software, San Diego, CA, USA); level of significance p < 0.05. For the visualization of the “fragility fracture homunculus” AutoCAD by AutoDesk, 2021, was used.

3. Results

The 50 most cited articles [5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54] were published between 1997 and 2020. All 50 articles were in English language. The year with the highest number of articles was 2015 (n = 10). In several years, 2009 and before (2008, 2007, 2004, 2003, 2001 to 1998) no article among the most 50 cited ones was published (Figure 2).
The number of total citations per article ranged from 12 to 129 citations, with a mean of 30 citations per article. The oldest study was reported in 1997 by Berlemann et al. [7]. The youngest study was published by Catellani et al. in 2020 [11]. The average citation per year was four with a deviation from 1 to 14 average citations per year. The citations in 2020 ranged from 0 to 37 citations, with an average of six citations. The 10 most cited articles are listed in Table 1.
According to the amount of total citations in descending order with authorship, title, journal, and year of publication and average citations per year. Scientists who were first author of more than one among the 50 most cited articles are listed in Table 2.
Overall, three authors published 2 of the 50 most cited articles as a fist author, and five authors published two articles as senior author. The distribution of first authors’ specialties in relation to their contribution is illustrated in Table 3.
In the majority of publications, orthopedic surgeons and traumatologists (66%) accounted for the first authorship, followed by geriatricians/internal medicine (18%) and others (16%). Orthopedic surgeons and traumatologists, being first author, published together with senior authors being almost always orthopedic surgeons and traumatologists (94%) followed by geriatricians/internal medicine and others. Geriatricians/internal medicine published with senior authors being geriatricians/internal medicine (78%) and with orthopedic surgeons and traumatologists (22%). In the case that “others” were first authors, they mainly published with others (63%) followed by orthopedic surgeons and traumatologists (38%) and none with geriatricians/internal medicine.
Articles were published in 26 different journals. Journals with more than one article are listed in Table 4.
Injury—International Journal of the Care of the Injured published the most articles (n = 6), equal with Osteoporosis International (n = 6). In total, nine journals were identified with more than one article. Those nine journals published 66% (n = 33) of the reviewed articles.
Identified articles mostly originated from Europe (58%), followed by Northern America (26%), Asia and Pacific (16%). The analysis of the distribution of publications in relation to their geographic origin is opposed to the estimated amount of the older population (at least 65 years of age) within those different continents in Figure 3. The highest proportion of the older population is noted in Europe (19%), followed by Northern America (17%), Asia–Pacific (9%), Latin America and Caribbean (9%), and Africa (4%).
Within Europe, most publications were from Italy (n = 7), followed by Germany (n = 6), United Kingdom (n = 3) and Switzerland (n = 3), Austria (n = 2), Ireland (n = 2); Spain, France, Greece, the Netherlands, and Sweden reported one article each (Figure 4).
In Europe, the economic power represented by the GDP was statistically significantly higher (p < 0.0033) in countries with a scientific output identified in this bibliometric review (n = 11; median GDP: USD 46232; range: 19,604–85,135) compared to remaining countries without any (n = 36; median GDP: USD 16.303; range: 3496–190,532) (Figure 5).
The analysis of keywords showed that in total 120 different keywords were used to describe the studies within the most cited 50 articles. The most frequently used keyword was “hip fracture” (used in 14 of the 50 most cited articles), followed by “osteoporosis” (13), “fragility fracture” (11), “fracture” (3), “pelvic fracture” (3); all keywords used more than once are depicted in Figure 6.
The further analysis of study types showed the majority of articles reporting about therapeutic studies (52%), followed by prognostic studies (38%). In total, 10% of the articles reported about economic and decision analyses; no articles with diagnostic studies were identified. The levels of evidence within these study categories are presented in Figure 7. In detail, the distribution of levels of evidence were as follows for:
  • Therapeutic studies n = 2 (4%) with level I, n = 2 (4%) with level II, n = 3 (6%) with level III, n = 19 (38%) with level IV.
  • Prognostic n = 10 (20%) with level I, n = 6 (12%) with level II, n = 3 (6%) with level IV.
  • Economic and decision analyses studies n = 5 (10%) with level III.
Out of 26 therapeutic studies, 24 focused on a specific anatomic region. For two therapeutic studies, a match to an anatomic region was not possible, due to the focus on clinical outcome of new implemented clinical pathways for all kinds of fragility fractures [12,17].
Out of the 24 studies the anatomical region focused on the most was hip joint including acetabulum, femoral head, femoral neck, pertrochanteric region (n = 13), followed by pelvis (n = 4), spine (n = 2), ankle (n = 2), distal femur (n = 1), elbow (n = 1), shoulder (n = 1) (Figure 8).

4. Discussion

The aging population leads to a rapid growth of fragility fractures. Patients with fragility fractures have special needs and their physical condition differs strongly from that of younger patients, leading to new challenges for healthcare professionals [55,56]. Accordingly, the presented bibliometric review was performed to report about the existing literature on the topic of fragility fractures. This bibliometric study demonstrates that research on fragility fractures is a growing field in current clinical research. With a closer look to the development of the citations from 2010 to 2020, the number of citations raised by a factor of 26. The increase of the citations follows the trend of the growing incidence of fragility fractures, e.g., as described by Kannus et al. [55].
The stringent analysis of authorship, origin and main subject of these articles show interesting results. Therapeutic studies find key interest; however, with a low level of evidence, as in the majority a type 4 level of evidence was identified. Only a small minority among the top cited articles are randomized controlled trials. Investigating the outcome of fragility fractures, prospective studies are highly cited. The analysis concerning the field of the authors shows that orthopedic surgeons and traumatologists are the group with the most articles as first authors. With a closer look to distribution on first author and senior author, a collaboration of orthopedic surgeons/traumatologist with geriatricians/internal medicine or “others” was an infrequent finding. As a result, a well-balanced interdisciplinary team of specialists is a rare constellation, indicating the need and potential for interdisciplinary research in the future [42]. The predominance of orthopedic surgeons and traumatologists is probably related to the topic that was addressed in this bibliometric review. Many studies focus on therapeutic options of fragility fractures and prognostic factors.
The analysis of keywords revealed that “hip fracture” was the most used term in highly cited articles. Apparently, current research interest is focused on hip fractures correlating with the circumstance that hip fracture is among the most frequent operating room procedures [57]. This indicates the potential for further research areas; studies should not be limited to the hip joint. Alternatively, other regions (e.g., spinal column, pelvis, shoulder) or the prevention of fragility fractures might be in the front in future. Further, none of the articles discuss the challenges of periprosthetic fractures as it seems to have a rising incidence [58] and they are associated to fragility fractures [59]. The search strategy with the focus on fragility fractures might have neglected the periprosthetic fractures. More than the half of the cited articles were conducted in Europe, and only a minority in other geographical regions. Europe also accounts for the highest proportion of older population leading to a rising incidence for fragility fractures [60]. Those circumstances might raise the awareness of the investigators. Within Europe all articles are from Western European countries. A limited economic strength might account for that finding, as the gross domestic product per capita was significantly higher in those countries with a high amount of publications.
A limitation might be that publications not indexed within Web of Science Core Collection were not included or the search strategy or the language might have limited the number of retrieved articles. The citation count might be a measure of delay such as the study per se. A further limitation might be that in the analysis of research original articles only, but review articles were not included. An article-based, self-citation analysis was not performed, only the total number of citations was presented in this study. Criticizing an article comes with the need to cite it. This brings up the hypothesis that citations are not a sole indicator for quality [61]. The older an article is the longer it can gather citations, which could question the significance of older articles in the current literature [62]. The status on basic research and risk factors in the field of fragility fractures is not represented in this study due to the focus on clinical management in the selection process. With the focus on clinical management and by the selection of “search terms” rheumatologist, endocrinologist, and other specialized bone metabolism units as well as studies on pharmacological treatments might be under-represented.
A strength of the study is the accessibility of the data without advanced statistical methods to provide understanding of current research topics of eminent literature in a relevant global challenge for healthcare professionals. Scientists find their most important published work, amongst their most cited [63] showing that citation rates are a good tool to evaluate the impact of an article in a certain field.

5. Conclusions

Fragility fractures are a research topic of growing interest. Europe and the key topic (hip fracture) were key drivers in the research concerning fragility fractures. The results should encourage all disciplines to undertake more interprofessional research, leading to teams that are more balanced with a wider spectrum of interest and know how. Further, more high-quality research must be promoted especially in the form of randomized controlled studies. With the rising numbers of older people and the rising incidence of fragility fractures worldwide, the numbers of articles in the field of fragility fractures will rise simultaneously. Our bibliometric review acknowledges recent research but raises awareness that timely continuation and optimization for research in fragility fractures is needed.

Author Contributions

Conceptualization, N.V., H.-C.P., P.M.R., K.-A.S., M.J.K. and J.D.B.; data curation, N.V. and J.D.B.; formal analysis, N.V., P.M.R. and J.D.B.; investigation, N.V. and J.D.B.; methodology, N.V.; project administration, J.D.B.; resources, N.V. and J.D.B.; supervision, J.D.B.; validation, H.-C.P., P.M.R., K.L., K.-A.S. and M.J.K.; visualization, N.V.; writing—original draft, N.V.; writing—review and editing, N.V., H.-C.P., P.M.R., K.L., K.-A.S., M.J.K. and J.D.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Medicina 57 00639 g001 550
Figure 1. Flowchart of the selection process.
Figure 1. Flowchart of the selection process.
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Figure 2. Publication and citation of identified articles with time.
Figure 2. Publication and citation of identified articles with time.
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Figure 3. Geographic origin of publications in relation to proportion of older population.
Figure 3. Geographic origin of publications in relation to proportion of older population.
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Figure 4. Geographic origin of articles within Europe. With minimum of zero and maximum of seven articles.
Figure 4. Geographic origin of articles within Europe. With minimum of zero and maximum of seven articles.
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Figure 5. GDP versus scientific output in European countries.
Figure 5. GDP versus scientific output in European countries.
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Medicina 57 00639 g006 550
Figure 6. Keywords used more than once.
Figure 6. Keywords used more than once.
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Medicina 57 00639 g007 550
Figure 7. Level of evidence in the categories of therapeutic, prognostic, and economic studies.
Figure 7. Level of evidence in the categories of therapeutic, prognostic, and economic studies.
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Medicina 57 00639 g008 550
Figure 8. Schematic drawing illustrating the “fragility fracture homunculus” indicating different focusses of therapeutic studies represented with disproportionate sizes of the anatomical sites being reported. The anatomical sites were enlarged by the following equalization: Focus (n) + 1. Hip joint (n = 14), pelvis (n = 5), spine (n = 3), ankle (n = 3), distal femur (n = 2), elbow (n = 2), shoulder (n = 2).
Figure 8. Schematic drawing illustrating the “fragility fracture homunculus” indicating different focusses of therapeutic studies represented with disproportionate sizes of the anatomical sites being reported. The anatomical sites were enlarged by the following equalization: Focus (n) + 1. Hip joint (n = 14), pelvis (n = 5), spine (n = 3), ankle (n = 3), distal femur (n = 2), elbow (n = 2), shoulder (n = 2).
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Table
Table 1. List of the identified 10 most cited articles in the field of fragility fractures according to the amount of total citations with average citations per year.
Table 1. List of the identified 10 most cited articles in the field of fragility fractures according to the amount of total citations with average citations per year.
NTitleTotal (n)Average/Year
1Rommens, P. M., Hofmann, A.
Comprehensive classification of fragility fractures of the pelvic ring: Recommendations for surgical treatment.
Injury-International Journal of the Care of the Injured
2013; 44(12): 1733–1744		12914.3
2Chevalley T, Hoffmeyer P, Bonjour JP, Rizzoli R.
An osteoporosis clinical pathway for the medical management of patients with low-trauma fracture.
Osteoporosis International.
2002; 13(6) 		1135.7
3Kates SL, Mendelson DA, Friedman SM.
The Value of an Organized Fracture Program for the Elderly: Early Results. Journal of Orthopaedic Trauma.
2011; 25(4)		766.9
4Kammerlander C, Gosch M, Kammerlander-Knauer U, Luger TJ, Blauth M, Roth T.
Long-term functional outcome in geriatric hip fracture patients. Archives of Orthopaedic and Trauma Surgery.
2011; 131(10)		625.6
5Berlemann U, Schwarzenbach O.
Dens fractures in the elderly—Results of anterior screw fixation in 19 elderly patients.
Acta Orthopaedica Scandinavica.
1997; 68(4)		602.4
6Samelson EJ, Demissie S, Cupples LA, Zhang XC, Xu HF, Liu CT, et al.
Diabetes and Deficits in Cortical Bone Density, Microarchitecture, and Bone Size: Framingham HR-pQCT Study.
Journal of Bone and Mineral Research.
2018; 33(1)		5313.3
7Zywiel MG, Hurley RT, Perruccio AV, Hancock-Howard RL, Coyte PC, Rampersaud YR. Health Economic Implications of Perioperative Delirium in Older Patients After Surgery for a Fragility Hip Fracture. Journal of Bone and Joint Surgery-American Volume. 2015; 97A(10) 486.9
8Eekman DA, van Helden SH, Huisman AM, Verhaar HJJ, Bultink IEM, Geusens PP, et al. Optimizing fracture prevention: the fracture liaison service, an observational study. Osteoporosis International. 2014; 25(2) 455.6
9Jeffcoat DM, Carroll EA, Huber FG, Goldman AT, Miller AN, Lorich DG, et al. Operative Treatment of Acetabular Fractures in an Older Population Through a Limited Ilioinguinal Approach. Journal of Orthopaedic Trauma. 2012; 26(5) 444.4
10Lemon M, Somayaji HS, Khaleel A, Elliott DS. Fragility fractures of the ankle—Stabilisation with an expandable calcaneotalotibial nail. Journal of Bone and Joint Surgery-British Volume. 2005; 87B(6) 422.5
Table
Table 2. List of authors with more than one article as first author.
Table 2. List of authors with more than one article as first author.
AuthorAffiliationYearsArticles (n)
Christian KammerlanderDepartment of General-, Trauma- and Reconstructive Surgery
University Hospital, LMU Munich
Germany		2011, 20122
CarlaYvonne HendersonGraduate Entry Medical School
University of Limerick
Ireland		2015, 20172
Andreas HöchDepartment of Orthopaedic, Trauma and Plastic Surgery
University of Leipzig
Germany		2017, 20172
Table
Table 3. Distribution of first and senior authors’ specialties (in %).
Table 3. Distribution of first and senior authors’ specialties (in %).
Senior Author1st Author
Orthopedic Surgeons and Traumatologist (66%)Geriatricians/Internal Medicine (18%)Others (16%)
Orthopedic surgeons and traumatologist94%22%38%
Geriatricians/Internal medicine3%78%
Others3% 63%
Table
Table 4. List of journals with more than one article within the identified articles.
Table 4. List of journals with more than one article within the identified articles.
JournalArticles (n)
Osteoporosis International6
Injury—International Journal of the Care of the Injured6
Journal of Orthopaedic Trauma4
Archives of Orthopaedic and Trauma Surgery4
Geriatric Orthopaedic Surgery and Rehabilitation4
Bone3
Journal of Bone and Joint Surgery—American Volume2
Irish Journal of Medical Science2
Aging Clinical and Experimental Research2
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Vuillemin, N.; Pape, H.-C.; Rommens, P.M.; Lippuner, K.; Siebenrock, K.-A.; Keel, M.J.; Bastian, J.D. A Bibliometric Analysis of Fragility Fractures: Top 50. Medicina 2021, 57, 639. https://doi.org/10.3390/medicina57060639

AMA Style

Vuillemin N, Pape H-C, Rommens PM, Lippuner K, Siebenrock K-A, Keel MJ, Bastian JD. A Bibliometric Analysis of Fragility Fractures: Top 50. Medicina. 2021; 57(6):639. https://doi.org/10.3390/medicina57060639

Chicago/Turabian Style

Vuillemin, Nicolas, Hans-Christoph Pape, Pol Maria Rommens, Kurt Lippuner, Klaus-Arno Siebenrock, Marius Johann Keel, and Johannes Dominik Bastian. 2021. "A Bibliometric Analysis of Fragility Fractures: Top 50" Medicina 57, no. 6: 639. https://doi.org/10.3390/medicina57060639

APA Style

Vuillemin, N., Pape, H. -C., Rommens, P. M., Lippuner, K., Siebenrock, K. -A., Keel, M. J., & Bastian, J. D. (2021). A Bibliometric Analysis of Fragility Fractures: Top 50. Medicina, 57(6), 639. https://doi.org/10.3390/medicina57060639

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