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骨科3D打印领域的出版趋势与知识图谱

Publication trends and knowledge mapping in 3D printing in orthopaedics.

作者信息

Vaishya Raju, Patralekh Mohit Kumar, Vaish Abhishek, Agarwal Amit Kumar, Vijay Vipul

机构信息

Department of Orthopaedics and Joint Replacement, Indraprastha Apollo Hospital, Sarita Vihar, New Delhi, India.

Central Institute of Orthopaedics, Safdarjung Hospital and VMMC, New Delhi, 110029, India.

出版信息

J Clin Orthop Trauma. 2018 Jul-Sep;9(3):194-201. doi: 10.1016/j.jcot.2018.07.006. Epub 2018 Jul 30.

Abstract

PURPOSE

Three dimensional (3D) printing, also called 'rapid prototyping' and 'additive manufacturing' is considered as a "second industrial revolution." With this rapidly emerging technology, CT or MR images are used for the creation of graspable objects from 3D reconstituted images. Patient-specific anatomical models can be, therefore, manufactured efficiently. These can enhance surgeon's understanding of their patients' patho-anatomy and also help in precise preoperative planning. The 3D printed patient-specific guides can also help in achieving accurate bony cuts, precise implant placement, and nice surgical results. Customized implants, casts, orthoses and prosthetics can be created to match an individual patient's anatomy. The 3D printing of individualized artificial cartilage scaffolds and 3D bioprinting are some other areas of growing interest. We aim to study the publication trends in 3D printing as applied to the field of orthopaedics.

MATERIALS AND METHODS

A literature search was performed to extract all papers related to 3D printing applications in orthopaedics and allied sciences on the Pubmed, Web of Science and SCOPUS databases. Suitable keywords and boolean operators ("3D Printing" OR "3-dimensional printing" OR "3D printed" OR "additive manufacturing" OR "rapid prototyping") AND (''Orthopaedics" OR "Orthopaedics'') were used, in May 2018. Search was attempted in Cochrane Database of Systematic Reviews, Cochrane Central Register of Controlled Trials, and Database of Abstracts of Review of Effectiveness (DARE) databases, using keywords 3d printing orthopaedics. A similar search was repeated in pubmed and SCOPUS to get more specific papers.No limits were set on the period or evidence level, as 3D printing in orthopaedics is relatively new and evidence available is usually limited to low-level studies. Trends in a publication on these topics were analyzed, focussing on publications, type of research (basic science or clinical), type of publication, authors, institution, and country. Some citations received by these papers were also analyzed in SCOPUS and Web of Science. MS Excel (2008 - Mac version) and VOS Viewer1.6.8 (2018- Mac version) software were used to analyze the search results and for citation mapping respectively. We also identified top 10 most cited articles in the field.

RESULTS

An increasing trend in publications in 3D printing-related work in orthopedic surgery and related fields was observed in the recent past. A search on Pubmed using the above strategy revealed 389 documents. A similar search revealed 653 documents on SCOPUS, many (314) of which were from an engineering background and only 271 were related to medicine. No papers were found in the Cochrane database. Search on TRIP database revealed 195 papers. A similar search revealed 237 papers on orthopedic applications on Pubmed and 269 documents on SCOPUS, whereas a search on Web of Science revealed only 23 papers. Publication trends were then analyzed on data derived from SCOPUS database. Overall, most papers were published from China, followed by United States, United Kingdom, and India.

CONCLUSION

There has been an upsurge of interest in 3D printing in orthopedic surgery, as is evident by an increasing trend in research and publications in this area in the recent years. Presently, 3D printing is in a primitive stage in the field of orthopedic surgery as our knowledge is still insufficient, and costs and learning curve are somewhat high. However, looking at latest publication trends, we are enthusiastic that it holds the key to future in orthopaedics and trauma cases.

摘要

目的

三维(3D)打印,也被称为“快速成型”和“增材制造”,被视为一场“第二次工业革命”。借助这项迅速兴起的技术,CT或MR图像被用于从三维重建图像创建可触摸的物体。因此,可以高效制造针对患者的解剖模型。这些模型能够增强外科医生对患者病理解剖结构的理解,也有助于进行精确的术前规划。3D打印的针对患者的导板还能帮助实现精确的骨切割、准确的植入物放置以及良好的手术效果。可以定制植入物、石膏、矫形器和假肢以匹配个体患者的解剖结构。个性化人工软骨支架的3D打印和3D生物打印是其他一些越来越受关注的领域。我们旨在研究3D打印在骨科领域的应用的发表趋势。

材料与方法

进行文献检索,以从PubMed、科学网和Scopus数据库中提取所有与3D打印在骨科及相关科学领域的应用相关的论文。在2018年5月,使用了合适的关键词和布尔运算符(“3D打印”或“三维打印”或“3D打印的”或“增材制造”或“快速成型”)以及(“骨科”或“矫形外科学”)。尝试在Cochrane系统评价数据库、Cochrane对照试验中心注册库和有效性评价文摘数据库(DARE)中进行检索,使用关键词“3D打印骨科”。在PubMed和Scopus中重复进行类似检索以获取更具体的论文。由于3D打印在骨科领域相对较新且现有证据通常限于低水平研究,因此对时间段或证据水平未设限制。分析了这些主题的发表趋势,重点关注出版物情况、研究类型(基础科学或临床)、出版物类型、作者、机构和国家。还在Scopus和科学网中分析了这些论文的一些被引用情况。分别使用MS Excel(2008 - Mac版)和VOS Viewer1.6.8(2018 - Mac版)软件来分析检索结果和进行引文映射。我们还确定了该领域被引用次数最多的前10篇文章。

结果

最近观察到骨科手术及相关领域中与3D打印相关工作的出版物呈增加趋势。使用上述策略在PubMed上进行检索显示有389篇文献。类似检索在Scopus上显示有653篇文献,其中许多(314篇)来自工程背景,只有271篇与医学相关。在Cochrane数据库中未发现论文。在TRIP数据库中检索显示有195篇论文。类似检索在PubMed上显示有237篇关于骨科应用的论文,在Scopus上显示有269篇文献,而在科学网上检索仅显示有23篇论文。然后根据从Scopus数据库获得的数据对发表趋势进行了分析。总体而言,大多数论文来自中国,其次是美国、英国和印度。

结论

近年来,骨科手术中对3D打印的兴趣激增,这从该领域研究和出版物的增加趋势中可见一斑。目前,3D打印在骨科手术领域尚处于初级阶段,因为我们的知识仍然不足,成本和学习曲线也有些高。然而,从最新的发表趋势来看,我们满怀热情地认为它是骨科和创伤病例未来的关键所在。

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