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Annals of Translational Medicine logoLink to Annals of Translational Medicine
. 2020 Mar;8(6):365. doi: 10.21037/atm.2020.02.67

The publication trends and hot spots of scoliosis research from 2009 to 2018: a 10-year bibliometric analysis

Lin Tao 1,#, Siming Zhou 1,#, Zhengbo Tao 1,#, Kaicheng Wen 1, Wacili Da 1, Yan Meng 1, Yue Zhu 1,
PMCID: PMC7186647  PMID: 32355809

Abstract

Background

This study aims to quantitatively and qualitatively investigate the trends in scoliosis research and evaluate research hotspots using bibliometric analysis.

Methods

All relevant publications on scoliosis from the period from 2009 to 2018 were extracted from the Web of Science and PubMed databases. Publication trends were analyzed using an Online analysis platform of literature metrology, Bibliographic Item Co-occurrence Matrix Builder (BICOMB), and CiteSpace software. Hotspots were analyzed and visualized using the gCLUTO software package.

Results

A total of 7,445 scoliosis research publications dated between 2009 and 2018 were found. The spine was the most popular journal in this field during this period. The United States maintained a top position in global scoliosis research throughout the 10 years and has had a pivotal influence, followed by China and Canada. Among all institutions, the University of California, San Francisco, was a leader in research collaboration. At the same time, Professors Yong Qiu and Lawrence G. Lenke made great achievements in scoliosis research. We analyzed the major Medical Subject Headings (MeSH) terms/MeSH subheadings and identified eight hotspots in scoliosis research.

Conclusions

We summarized the publication information of scoliosis-related literature in the 10 years from 2009 to 2018, including country and institution of origin, authors, and publication journal. We analyzed former research hotspots in the field of scoliosis and predicted future areas of interest. The development of various new orthopedic plants, artificial intelligence diagnosis, and genetic research will be future hotspots in scoliosis research.

Keywords: Scoliosis, bibliometric analysis, hotspots, co-word biclustering analysis

Introduction

Scoliosis is a three-dimensional (3D) structural spinal deformity and usually manifests as raised ribs, unlevel shoulders, and an asymmetrical waist. It can be diagnosed through a posteroanterior spinal radiograph taken in a standing position which shows a lateral bending of the spine over 10°. In addition to a curved spine, scoliosis is often related to the asymmetry of the trunk and limbs (1). Congenital, neurogenic, and some other classifications of scoliosis have better understood underlying mechanisms compared to idiopathic scoliosis, which denotes a curve of unknown etiology. Idiopathic scoliosis accounts for about 80% of structural coronal deformities (2), and the diagnosis rules out a pre-existing cause. With the continuous improvements in medicine and quality of life, scoliosis has attracted more and more attention. However, many problems relating to clinical treatment and scientific research still need to be solved. According to recent research hotspots combined with practical clinical problems, surgeons and researchers also need to improve the quality of scoliosis diagnosis and treatment, so as to alleviate the pain patients experience during treatment.

In recent years, bibliometric analysis has become increasingly popular. It applies literature metrology characteristics to measure the contribution of an area of research, including disparate countries, institutions, journals, or authors and predicts in detail research trends or hot spots within a certain field. However, there have been few bibliometric studies on scoliosis, and these mainly focus on published information rather than analysis and prediction of research hotspots (3,4). Our previous study showed that biclustering analysis could facilitate the discovery of key research focus areas and related representative literature (5). In particular, co-word biclustering analysis can be used to verify hot spots in research. In this article, we apply an integrated analysis of the content and external features of research literature to identify hot spots in scoliosis pathology, surgical method innovation and implants, quality of life after brace treatment, adverse effects, and diagnostic imaging, as well as genetics. We conduct a brief discussion on scoliosis research and clinical issues and make a prediction on possible progress in the field over the next decade.

Methods

Data sources and search strategies

We considered the Science Citation Index-Expanded and the Social Science Citation Index of Thomson Reuters’ Web of Science to be the most appropriate databases on which to perform our bibliometric analysis. We comprehensively searched Web of Science database to find relevant data from 2009 to 2018 and only included original articles and reviews. The search strategy was presented as follows: TI = (scoliosis) AND Language = English. At the same time, to obtain the Medical Subject Headings (MeSH) terms information which can map the contents of literature and be used to carry out co-word clustering analysis (6), we performed a similar online search on PubMed, which was developed by the National Center for Biotechnology Information (NCBI) of National Library of Medicine (NLM), without language restrictions. The search term used was "scoliosis"[Mesh] from 2009 to 2018. To avoid bias incurred by frequent database renewal, all literature retrieval and data downloads were completed in a single day, September 26, 2019.

Data collection

Two reviewers (Z Tao and S Zhou) independently performed the primary search, and their agreement rate reached 0.90, showing significant accordance (7). Web of Science Core Collection (WoSCC) data including titles, countries of origin, institutions, journals, and authors, were extracted and imported into the Online Analysis Platform of Bibliometrics (http://bibliometric.com/) and CiteSpace V5.5.R1 SE, 64bit (Drexel University, Philadelphia, PA, USA) for bibliometric analysis. PubMed data were imported into the BICOMB (Bibliographic Item Co-Occurrence Matrix Builder) (8) for further hot spot analysis.

Bibliometric analysis

We attempted to describe all publication characteristics, including countries, institutions, journals, authors, and H index. We accessed the 2018 version of Journal Citation Reports (JCR) to obtain the impact factor (IF), which is regarded as an important indicator to measure the scientific value of research (9). In our study, we analyzed the annual publication numbers and growth tendencies of different countries/regions through the Literature Metrology online analysis platform. CiteSpace is an optimal means for collaboration network analysis to connect all kinds of publication characteristics. It can also obtain keywords with high citations to predict the research frontiers and emerging trends in this area. Through CiteSpace, a “time slicing” function can also be applied (e.g., if you set the “years per slice” to 1 while the “top N per slice” is set to 50, the top 50 papers in a year are exported into a single file). According to our objective, nodes of different sizes represented citation counts or publication counts (10,11).

Co-word biclustering analysis of research hotspots

Biclustering was used to display the connection between extremely frequent terms and source literature, and the connection among extremely frequent terms. To survey the hotspots of scoliosis study, we performed a biclustering analysis of the incorporated publications and major MeSH terms/MeSH subheadings. BICOMB is a binary matrix that has source literature as columns and major MeSH terms/MeSH subheadings as rows, and structured through software “gCLUTO” version 1.0 (12). The detailed principle is explained in our previous research (5). We found semantic relationships between major MeSH terms/MeSH subheadings and source literature in clusters of scoliosis research focus and mapped them by matrix and mountain visualization.

Results

The output of related literature

A total of 7,445 publications (6,866 articles and 579 reviews) from 2009 to 2018 met our inclusion criteria (Figure 1). Figure 2A shows the increasing trend in the numbers of scoliosis-related publications (from 481 in 2009 to 966 in 2018).

Figure 1.

Figure 1

Flow chart of literature filtering included in this study. WoSCC, Web of Science Core Collection.

Figure 2.

Figure 2

Output of related literature. The number of annual publications (A) and growth trends of the top 10 countries/regions (B) in scoliosis research from 2009 to 2018.

The contributions of countries and institutions to global publications

The incorporated literature on scoliosis was contributed by at least 84 different countries or regions (Figure 2B). The United States [2,818] was the largest contributor to scoliosis research, followed by China [1,281], Canada [561], Japan [529], and France [444]. Centrality is a major indicators to determine the importance of nodes in the network and a higher centrality means that the node is more important in this network, so the results showed that the United States had more impact than any other country (centrality =0.22), and then England (0.16), and Germany (0.14) (Table 1). In terms of research institutions, the top 10 included the University of California, San Francisco [347], Nanjing University [301], Washington University [297], Chinese University of Hong Kong [263], and New York University [234] (Table 1). A low-density map of the scoliosis research network (density =0.0642) (Figure 3A) means that the research teams were relatively scattered across various institutions, and more mutual cooperation is needed. Most of the central indexes are below 0.15, indicating that most institutions had a low level of impact and that there was insufficient cooperation during the 10-year period. International cooperation analysis showed that cooperation happened most frequently between the United States and Canada, followed by the United States and China (Figure 3B).

Table 1. The top 10 countries/regions and institutions contributing to publications in scoliosis research.

Rank Country/region Article counts Centrality Institutions Article counts Centrality Total number of
citations
Average number of citations Total number of first authors Total number of first author citations Average number of first author citations
1 US 2,818 0.22 Univ Calif San Francisco 347 0.12 3,977 11.46 70 446 6.37
2 China 1,281 0.02 Nanjing Univ 301 0.02 1,650 5.48 186 713 3.83
3 Canada 561 0.08 Washington Univ 297 0.16 3,643 12.27 90 1,324 14.71
4 Japan 529 0.02 Chinese Univ Hong Kong 263 0.13 1,819 6.92 41 344 8.39
5 France 444 0.04 NYU 234 0.05 2,795 11.94 96 1,467 15.28
6 England 376 0.16 Hosp Special Surg 222 0.08 2,169 9.77 55 369 6.71
7 South Korea 338 0 Univ Virginia 203 0.11 3,183 15.68 56 1,234 22.04
8 Italy 296 0.05 Johns Hopkins Univ 197 0.04 897 4.55 73 352 4.82
9 Turkey 294 0.04 Shriners Hosp Children 183 0.14 1,748 9.55 71 652 9.18
10 Germany 288 0.14 Univ Montreal 173 0.01 1,107 6.40 24 118 4.92

Figure 3.

Figure 3

The distribution of countries/regions and institutions. The network map of institutions involved in scoliosis research (A) and cooperation between countries/regions (B).

Journals publishing researches on scoliosis

Recently, 1,056 journals have appeared in the field of scoliosis research. The top 10 most popular journals published 3,308 of all 7,445 pieces of literature on scoliosis in our study (44.43%) (Table 2). Of these, the top 3 journals are Spine, European Spine Journal, and Spine Journal, which accounted for more than 30.50% of all the indexed publications. The highest IF belonged to The Journal of Bone and Joint Surgery-American Volume (4.716), followed by Spine Journal (3.196), Journal of Neurosurgery-Spine (2.998), Spine (2.903), and European Spine Journal (2.513). According to the JCR 2018 standards, the five journals mentioned above are classified as Q1, the Journal of Pediatric Orthopaedics, World Neurosurgery, and Clinical Spine Surgery are classified as Q2, and the American Journal of Medical Genetics Part A is classified as Q3.

Table 2. The top 10 most active journals that published articles in scoliosis research (sorted by count).

Rank Journal title Percentage (N/7,445) IF (2018) Quartile in category (2018) H-index Article counts Total number of citations Average number of citations
1 Spine 15.92% 2.903 Q1 228 1,185 11,968 10.1
2 European Spine Journal 10.44% 2.513 Q1 117 777 4,623 5.95
3 Spine Journal 4.15% 3.196 Q1 94 309 1,123 3.63
4 Journal of Pediatric Orthopaedics 3.79% 2.046 Q2 84 282 1,404 4.98
5 Journal of Neurosurgery-Spine 2.81% 2.998 Q1 84 209 1,305 6.24
6 Journal of Spinal Disorders & Techniques 1.84% 0 0 85 137 805 5.88
7 Journal of Bone and Joint Surgery-American Volume 1.48% 4.716 Q1 235 110 872 7.93
8 World Neurosurgery 1.38% 1.723 Q2 85 103 39 0.38
9 Clinical Spine Surgery 1.37% 1.726 Q2 12 102 105 1.03
10 American Journal of Medical Genetics Part A 1.26% 2.197 Q3 79 94 120 1.28

The contributions of authors to scoliosis research

The ten authors who published the most papers out of all 22,511 authors in this study are listed in Table 3. Of these, Yong Qiu, from the Department of Spine Surgery, Nanjing Drum Tower Hospital in China, ranked first [221], and second was Virginie Lafage from the Department of Orthopaedic Surgery, Hospital for Special Surgery in the USA [178]. These two scholars made great achievements and have become authorities in scoliosis research. We analyzed the citation information for authors (Figure 4A) and co-cited authors (Figure 4B), visualizing them in a network by CiteSpace. Lawrence G. Lenke (899 co-citations) ranked first in the top 10 co-cited authors, followed by Young-Jo Kim [786], Keith H. Bridwell [661], and Si Suk [647] (Table 3). The centrality of the top 4 is more than 0.1, demonstrating that they have become an influential core group in the scoliosis field, having carried out a lot of research to lay a better foundation for future development. And the analysis of high-cited papers showed Virginie Lafage group have an amazing scientific impact for other scholars, 4 of top 10 high-cited papers were published by this group (Table 4).

Table 3. The top 10 most productive authors and co-cited authors contributed to publications in scoliosis research.

Rank Author Article counts Centrality Total number
of citations
Average number of citations First author counts First author citation counts Average first author citation counts Corresponding author Corresponding author citation counts Co-cited author Citation counts Centrality
1 Qiu Y 221 0.04 1,086 4.91 5 63 12.60 101 582 Lenke LG 899 0.22
2 Lafage V 178 0.04 2,424 13.62 5 329 65.80 33 1,108 Kim YJ 786 0.24
3 Zhu ZZ 172 0.09 644 3.74 8 48 6.00 49 99 Bridwell KH 661 0.23
4 Smith JS 150 0.08 2,169 14.46 22 802 36.45 32 529 Suk Si 647 0.10
5 Shaffrey CI 144 0.10 2,255 15.66 0 0 0 15 670 Weinstein SL 636 0.07
6 Lenke LG 129 0.39 1,927 14.94 5 215 43.00 36 681 Glassman SD 623 0.06
7 Bess S 128 0.02 1,437 11.23 7 255 36.43 8 265 Schwab F 545 0.07
8 Ames CP 118 0.04 1,386 11.75 2 42 21.00 12 106 Lonstein JE 489 0.08
9 Schwab F 118 0.09 2,236 18.95 4 489 122.25 2 161 Kuklo TR 429 0.05
10 Liu Z 109 0.14 435 3.99 7 54 7.71 2 0 Smith JS 422 0.04

Figure 4.

Figure 4

The distribution of authors engaged in scoliosis research. The network map of productive authors (A) and the network map of co-cited authors (B).

Table 4. The top 10 high-cited papers in scoliosis research during 2009 to 2018.

Rank Title Journal Corresponding authors Publication year Total citations
1 Prader-Willi syndrome Genetics in Medicine Cassidy SB 2012 465
2 Pelvic tilt and truncal inclination: two key radiographic parameters in the setting of adults with spinal deformity Spine Lafage V 2009 458
3 Adult spinal deformity-postoperative standing imbalance: how much can you tolerate? An overview of key parameters in assessing alignment and planning corrective surgery Spine Lafage V 2010 373
4 Scoliosis Research Society-Schwab Adult Spinal Deformity Classification: a validation study Spine Lafage V 2012 334
5 Effects of bracing in adolescents with idiopathic scoliosis New England Journal of Medicine Weinstein SL 2013 310
6 Friedreich ataxia: the clinical picture Journal of Neurology Pandolfo M 2009 275
7 Radiographical spinopelvic parameters and disability in the setting of adult spinal deformity: a prospective multicenter analysis Spine Lafage V 2013 269
8 Accuracy of pedicle screw placement: a systematic review of prospective in vivo studies comparing free hand, fluoroscopy guidance and navigation techniques European Spine Journal Gelalis ID 2012 226
9 Complications of growing-rod treatment for early-onset scoliosis: analysis of one hundred and forty patients Journal of Bone and Joint Surgery-American Volume Akbarnia B 2010 210
10 Postural deformities in Parkinson’s disease Lancet Neurology Bloem BR 2011 208

Analysis of the scoliosis hotspots

Based on the search results, there were 4,857 major MeSH terms/MeSH subheadings with a cumulative frequency of 24,055 times. They can be defined as extremely frequent terms that appeared more than 52 times after a standard evaluation of H-index, and their frequency accounted for 46.78% (11,252/24,055) of all (Table 5). We analyzed the temporal trend of hotspot shift according to the top 25 terms with the strongest citation bursts during 2009 to 2018 (Figure 5). And we sorted eight different clusters by biclustering, mapping the connection between source literature and MeSH terms/MeSH subheadings by mountain and matrix visualization (Figure 6). The biclustering result can visually show the substance of high-dimensional datasets through mountain visualization. There are 8 perks representing 8 clusters in the 3D landform numbered from 0 to 7 (Figure 6). The information of these clusters is reflected by the perks’ volume, altitude, color and location on the flat. The flat location can distinguish different perks and their interval represents their relative similarity of each cluster. The altitude and color of the perks are usually proportional to the internal similarity and standard deviation of the cluster (blue: high deviation; red: low deviation). The volume of peaks directly reflects the number of extremely frequent major MeSH terms/MeSH subheadings in each cluster. In addition, every cluster should contain at least 30 publications and no triplet perks are allowed to emerge in mountain visualization. In matrix visualization, the column tags and row tags represent PMIDs of source literature and MeSH terms/MeSH subheadings, respectively. The matrix values are represented graphically and their colors paint the emergence frequency of the major MeSH terms/MeSH subheadings in a piece of literature. The color turns from white to red to show a gradual increase in significance (Figure 7). To make analogous rows in a single converged cluster, we reset the rows of the initial matrix and used black horizontal lines to partition each cluster through gCLUTO (Table 6). In matrix visualization, the upper cluster tree represented the literature association and the left cluster tree represented extremely frequent MeSH terms/subheadings association (Figure 7). The above-mentioned 52 extremely frequent terms were divided into 8 clusters and all representative source literature involved in each cluster was studied to summarize the hotspot information further. We finally generalized them into the following 8 hotspots:

Table 5. Highly frequent major MeSH terms from the included publications on scoliosis (n=24,055).

Rank   Major MeSH terms/MeSH subheadings Frequency Proportion of frequency (%) Cumulative percentage (%)
1   Scoliosis/surgery 2,550 10.6007 10.6007
2   Spinal fusion/methods 742 3.0846 13.6853
3   Scoliosis/diagnostic imaging 733 3.0472 16.7325
4   Thoracic vertebrae/surgery 464 1.9289 18.6614
5   Lumbar vertebrae/surgery 372 1.5465 20.2079
6   Scoliosis/therapy 358 1.4883 21.6961
7   Scoliosis/physiopathology 356 1.4799 23.1761
8   Scoliosis/diagnosis 352 1.4633 24.6394
9   Spinal fusion/adverse effects 321 1.3344 25.9738
10   Spinal fusion/instrumentation 296 1.2305 27.2043
11   Kyphosis/surgery 273 1.1349 28.3392
12   Spine/surgery 270 1.1224 29.4617
13   Scoliosis/complications 253 1.0518 30.5134
14   Scoliosis/genetics 243 1.0102 31.5236
15   Scoliosis/pathology 240 0.9977 32.5213
16   Scoliosis/epidemiology 210 0.8730 33.3943
17   Spine/diagnostic imaging 200 0.8314 34.2257
18   Spinal fusion 190 0.7899 35.0156
19   Braces 185 0.7691 35.7847
20   Scoliosis/etiology 179 0.7441 36.5288
21   Thoracic vertebrae/diagnostic imaging 141 0.5862 37.1149
22   Bone screws 139 0.5778 37.6928
23   Orthopedic procedures/methods 139 0.5778 38.2706
24   Lumbar vertebrae/diagnostic imaging 119 0.4947 38.7653
25   Quality of Life 119 0.4947 39.2600
26   Scoliosis/rehabilitation 116 0.4822 39.7423
27   Scoliosis/psychology 115 0.4781 40.2203
28   Osteotomy/methods 110 0.4573 40.6776
29   Scoliosis 109 0.4531 41.1307
30   Orthopedic procedures/instrumentation 105 0.4365 41.5672
31   Pedicle Screws 99 0.4116 41.9788
32   Postoperative complications/epidemiology 97 0.4032 42.3820
33   Postoperative complications/etiology 93 0.3866 42.7687
34   Imaging, three-dimensional/methods 80 0.3326 43.1012
35   Internal fixators 80 0.3326 43.4338
36   Spine/abnormalities 80 0.3326 43.7664
37   Spine/pathology 74 0.3076 44.0740
38   Tomography, X-ray computed/methods 66 0.2744 44.3484
39   Orthopedic procedures/adverse effects 64 0.2661 44.6144
40   Ribs/surgery 64 0.2661 44.8805
41   Prostheses and Implants 62 0.2577 45.1382
42   Kyphosis/diagnostic imaging 60 0.2494 45.3877
43   Postural balance/physiology 59 0.2453 45.6329
44   Posture 59 0.2453 45.8782
45   Scoliosis/congenital 56 0.2328 46.1110
46   Cerebral palsy/complications 54 0.2245 46.3355
47   Scoliosis/classification 54 0.2245 46.5600
48   Genetic predisposition to disease 52 0.2162 46.7761

MeSH, Medical Subject Headings.

Figure 5.

Figure 5

The top 25 terms with the strongest citation bursts during 2009 to 2018.

Figure 6.

Figure 6

Mountain visualization of biclustering of highly frequent major MeSH terms and literatures on scoliosis. MeSH, Medical Subject Headings.

Figure 7.

Figure 7

Visualized matrix of biclustering of highly frequent major MeSH terms and PubMed Unique Identifiers (PMIDs) of literatures on scoliosis. MeSH, Medical Subject Headings.

Table 6. Highly frequent major MeSH a terms-source literatures matrix (localized).

No. Major MeSH terms/MeSH subheadings PubMed Unique Identifiers of source articles
18188567 18357448 18389266 ... 30691740
1 Scoliosis/surgery 1 1 1 ... 0
2 Spinal fusion/methods 1 0 0 ... 0
3 Scoliosis/diagnostic imaging 0 0 0 ... 1
4 Thoracic vertebrae/surgery 1 1 0 ... 0
... ... ... ... ... ... ...
47 Scoliosis/classification 0 0 0 ... 0
48 Genetic predisposition to disease 0 0 0 ... 0

MeSH, Medical Subject Headings.

  1. Quality of life and levels of psychological stress in patients with adolescent idiopathic scoliosis (AIS) treated with braces (Cluster 0);

  2. Pathology of scoliosis (Cluster 1);

  3. Innovative instrumentation and methods used in the surgery of scoliosis (Cluster 2);

  4. Adverse effects of scoliosis (Cluster 3);

  5. Diagnostic imaging of scoliosis (Cluster 4);

  6. Prostheses and implants of scoliosis (Cluster 5);

  7. Genetics researches of scoliosis (Cluster 6);

  8. Asymmetrical postures in cerebral palsy (CP) resulting in scoliosis (Cluster 7).

Discussion

Our statistical and quantitative analysis found that the research output on scoliosis gradually increased in the 10 years from 2009 to 2018, and more and more scholars are focusing their research in the field. Although the research has been extensive, it is relatively messy, and there is a lack of analysis of research hotspots. In this work, we focused on the discussion and interpretation of the eight clusters obtained by co-word biclustering analysis to predict and direct future research trends.

Cluster 0 relates to the quality of life and levels of psychological stress in patients with AIS treated with braces. AIS has been the most common form of spinal deformity in adolescents. Patients with curves between 20° and 40° cobb degrees do not need to undergo surgery, and conservative treatment may be a better choice. Although there are several conservative treatment options, only bracing has been proved to be effective in increasing the spine balance rate and in reducing hump amplitude to prevent the progression of AIS and subsequent surgical needs further. The brace treatment has become the first choice for clinical use of such patients, and the modified “P” Cheneau brace has become a remarkable success as a conservative treatment for AIS on the basis of the SRS/SOSORT criteria (13,14). In addition, related quality of life assessments has drawn great attention from orthopedists all over the world. Recent research found that all teenagers may have some psychological stress in the early stages of wearing a brace, but as they adapt to their new image, this pressure may not impact their long-term quality of life (15,16). Considering early psychological stress, we believe research in this field will provide an important reference for the improvement of the brace as a treatment in the future, and that it may maintain its popularity as an area for future study.

Cluster 1 relates to the pathology of scoliosis, which includes the pathological changes caused by spine deformity and vertebral body rotation, as well as updates on the rapid diagnostic method of imaging. Morphological characteristics and pathological changes to the spine have a great impact on idiopathic scoliosis clinical treatment. Doctors tried their best to detect and reconstruct the actual situation of the patient based on the imaging examination, which can accurately assess pathologies such as spine alignment and dyskinesia. Novel computational methods to evaluate vertebral segmental movement and multiple detection methods have been established, such as a multichannel transmit/receive phased array RF coil which can be used for in vivo spine imaging, thereby rendering high-resolution spine imaging a promising new application in IS clinical research (17-19). More and more valuable literature will appear in the near future focused on this topic.

Cluster 2 relates to the innovative instrumentation and methods used in scoliosis surgery. In recent years, with the rapid development of medical technology, doctors and patients are increasingly pursuing surgical treatments. At the same time, the focus of medical research in the new era has gradually shifted from basic research to translational research. For patients to achieve the best recovery with minimal harm, doctors and scientists have improved a variety of surgical methods and invented more convenient types of surgical equipment based on their years of experience and research (19-22). In this era of innovation and cooperation, medical-industrial integration and clinical translation medicine will surely become the most popular area for development in the future and maybe the most popular research topic in the next decade.

Cluster 3 relates to the adverse effects of scoliosis. Orthopedic surgery for spinal deformity is a difficult and high-risk surgical method in the orthopedic field. Postoperative complications often occur, especially nerve damage. With the application of new surgical methods for spinal deformity; however, more attention has been paid to the related complications of different surgical procedures (23-26). Although, with the continuous development of surgeons’ abilities and modern medical technology, the incidence of complications of surgery for spinal deformity is declining. Therefore, the number of studies in this area may gradually decrease in the future, and more attention will perhaps be paid to some rare complications in the form of case reports.

Cluster 4 relates to the diagnostic imaging of scoliosis. Scoliosis is usually detected during a standard physical examination performed by a general practitioner or school nurse. Cobb Angle plays an important role in idiopathic scoliosis as a main diagnostic index. However, although measurements have been established, Cobb Angle measures a two-dimensional (2D) projection that is actually a 3D distortion, so using Cobb Angle alone is not a reliable way of assessing the deformity. Based on the fact that the etiology of 3D malformations and idiopathic scoliosis is unknown, recent studies have shown interest in obtaining additional measures to describe and quantify scoliosis (27-30). The establishment of these methods can help improve the accuracy of scoliosis diagnosis, help surgeons to understand the patient’s deformity better and guide further treatment. With the continuous development of augmented reality (AR), virtual reality (VR), and mixed reality (MR) technology, more detailed imaging methods will appear, and there will be a definite and significant increase in this type of research.

Cluster 5 relates to prostheses and implants for scoliosis. Surgical treatment of scoliosis in older children is more straightforward and includes correction of spinal curvature, internal fixation, and spinal fusion. However, spinal fusion may not be the best option for young children with significant growth potential because it limits further longitudinal growth of the spine, thereby limiting the growth of the thoracic cavity and potentially inhibiting lung development, leading to respiratory dysfunction and, in some cases, premature death. To address these issues, “non-fusion” technologies have recently been implemented with varying degrees of success, and are attracting increasing levels of attention. Various techniques have been used, such as dual growing rods, Shilla procedure, VEPTR (Vertical Prosthetic Titanium Prosthetic Rib), vertebral stapling, and vertebral tethering, each with advantages and disadvantages (31-34). The emergence of new implants and surgical techniques has seen improved treatments for patients with different conditions that meet the requirements of modern precision medicine. There is reason to believe that research in this area has bright prospects.

Cluster 6 relates to the genetics researches of scoliosis. In recent years, some studies have suggested that genetic factors play an important role in the pathogenesis of scoliosis. They also show a high degree of genetic heterogeneity in autosomal dominant or multifactorial inheritance patterns with major genes. Many studies identified idiopathic scoliosis-susceptible genes (such as SH3GL1, GADD45B, and FGF22) and linked them to idiopathic scoliosis, but these genes are not relevant to all idiopathic scoliosis cases (35-38). There is no doubt that idiopathic scoliosis is a hereditary disease, so finding its related pathogenic genes is of great significance for the prevention or treatment of idiopathic scoliosis, and it must be a hot spot for future research.

Cluster 7 relates to asymmetrical postures in cerebral palsy resulting in scoliosis. Cerebral palsy is an immature, non-progressive lesion that causes movement and postural disorders in the brain. Although cerebral palsy is a static encephalopathy, the related musculoskeletal pathology is usually progressive. Many patients with cerebral palsy, especially those with spastic hemiplegia, have asymmetrical frontal spine (39). Many studies have shown that postural asymmetry is associated with scoliosis, dislocation of the hip, contracture of the hip and knee joint, and the inability to change position (40,41). Therefore, postural problems play an important role in preventing cerebral palsy in children with motor dysfunction. The discussion surrounding this topic has been very lively in the past decade, but because of its limited perspective, it is difficult to predict whether its popularity will continue in future research.

Nonetheless, there may have been some limitations to our study. The databases update continuously, and we only selected the literature published from 2009 to 2018, excluding those published in 2019. Therefore, a discrepancy may exist between our bibliometric analysis and real publication conditions. In addition, the amount of scoliosis-related literature may increase rapidly with the breakthrough of future research.

Conclusions

We summarized the publication information of scoliosis-related literature in the 10 years from 2009 to 2018, including country and institution of origin, authors, and publication journal. We then analyzed the research hotspots based on these publications and predicted future popular trends. Effective treatment of idiopathic scoliosis patients and improvements in quality of life will become the focus of scoliosis research, containing many aspects. Many previous studies have focused on the classification of scoliosis and the choice of corresponding treatment methods. Bracing and surgical treatment will help patients at different stages. In addition, the emergence of new surgical methods, new equipment and new implants using cutting-edge technology, the invention of more accurate image examination and diagnostic technology, and evaluation of postoperative complications management and quality of life all contribute to improving patient outcomes. Finally, research on the etiology of scoliosis, especially genetic research, has great potential to guide the prevention and treatment of scoliosis in the future. We believe our research can reflect novel directions for scoliosis research, and the hotspots mentioned will achieve major scientific breakthroughs someday.

Acknowledgments

Funding: None.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Footnotes

Conflicts of Interest: The authors have no conflicts of interest to declare.

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