Bibliometric analysis of application of three-dimensional imaging in liver_CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Authors：

ZHANG Xiao ¹ , HUANG Wei ¹ ,  SONG Bin ²

1. Radiology and Imaging Department of Leshan People’s Hospital, Leshan, Sichuan 614000, P. R. China;
2. Department of Radiology, West China Hospital, Sichuan University, Chengdu 610041, P. R. China;

Corresponding author：

SONG Bin, Email: cjr.songbin@vip.163.com

Keywords：

three-dimensional; radiology; precise liver surgery; bibliometric analysis

DOI：

10.7507/1007-9424.201712040

Video：

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Objective To analyze relevant literatures of three-dimensional (3D ) imaging in liver using bibiometric analysis, and to provide a current status and hotspot in this filed in future for liver surgeon. Methods The bibliographies of liver 3D imaging from November 2007 to November 2017 in the PubMed database were downloaded. The publication years, journals, the first authors, and the frequency of subject headings+subheadings were extracted by Bicomb 2.0 software. The subject headings+subheadings appeared more than 10 times were intercepted as high frequency ones, then created the high frequency subject headings+subheadings co-occurrence matrix. SPSS 22.0 software was applied for clustering analysis with this matrix to get the topic hotspot. Results A total of 269 literatures were screened out. The research in this field reached its peak in 2016. The core area of journals contained 12 journals. There were 6 authors published at least 3 relevant literatures. The number of high frequency subject headings+subheadings was 16. The research hotspot of liver 3D imaging was precise liver surgery. Conclusion Research hotspot of application of 3D imaging in liver is precise liver surgery in recent 10 years.

Citation： ZHANG Xiao, HUANG Wei, SONG Bin. Bibliometric analysis of application of three-dimensional imaging in liver. CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY, 2018, 25(1): 94-98. doi: 10.7507/1007-9424.201712040 Copy

1.	He J, Li D, Lu B, et al. Custom fabrication of composite tibial hemi-knee joint combining CAD/CAE/CAM techniques. Proc Inst Mech Eng H, 2006, 220(8): 823-830.
2.	Waran V, Narayanan V, Karuppiah R, et al. Injecting realism in surgical training-initial simulation experience with custom 3D models. J Surg Educ, 2014, 71(2): 193-197.
3.	廖雯俊, 邬林泉. 3D虚拟肝脏技术在精准肝脏切除中的应用价值. 中国肿瘤临床, 2010, 37(18): 1077-1080.
4.	陈康, 熊力, 郑砚文, 等. 3D打印技术在肝脏外科应用现状及展望. 中国普通外科杂志, 2017, 26(1): 90-95.
5.	谢于, 胡文炜, 胡兆深, 等. 3D影像辅助下的肝脏切除手术规划. 肿瘤学杂志, 2012, 18(7): 500-504.
6.	黄从云, 朱剑华, 刘欣, 等. 3D打印技术在肝脏切除术中的应用. 中国普外基础与临床杂志, 2015, 22(11): 1351-1353.
7.	Numminen K, Sipilä O, Mäkisalo H. Preoperative hepatic 3D models: virtual liver resection using three-dimensional imaging technique. Eur J Radiol, 2005, 56(2): 179-184.
8.	Zhang G, Zhou XJ, Zhu CZ, et al. Usefulness of three-dimensional (3D) simulation software in hepatectomy for pediatric hepatoblastoma. Surg Oncol, 2016, 25(3): 236-243.
9.	张晗, 崔雷. 运用共词聚类分析法研究生物信息学的学科热点医学情报工作, 2004, 25(5): 327-330.
10.	张达. 精准肝脏外科在HCC治疗中的应用. 中国现代普通外科进展, 2017, 20(5): 362-364, 370.
11.	唐敏, 毛谅, 朱斌. 虚拟肝切除: 利用3D肝脏模型进行计算机辅助手术规划. 肝胆胰外科杂志, 2013, 25(3): 258-261.
12.	He YB, Bai L, Aji T, et al. Application of 3D reconstruction for surgical treatment of hepatic alveolar echinococcosis. World J Gastroenterol, 2015, 21(35): 10200-10207.
13.	Hansen C, Wieferich J, Ritter F, et al. Illustrative visualization of 3D planning models for augmented reality in liver surgery. Int J Comput Assist Radiol Surg, 2010, 5(2): 133-141.
14.	Bégin A, Martel G, Lapointe R, et al. Accuracy of preoperative automatic measurement of the liver volume by CT-scan combined to a 3D virtual surgical planning software (3DVSP). Surg Endosc, 2014, 28(12): 3408-3412.
15.	Wang Y, Zhang Y, Peitgen HO, et al. Precise local resection for hepatocellular carcinoma based on tumor-surrounding vascular anatomy revealed by 3D analysis. Dig Surg, 2012, 29(2): 99-106.
16.	Lang H, Radtke A, Hindennach M, et al. Impact of virtual tumor resection and computer-assisted risk analysis on operation planning and intraoperative strategy in major hepatic resection. Arch Surg, 2005, 140(7): 629-638.
17.	Wigmore SJ, Redhead DN, Yan XJ, et al. Virtual hepatic resection using three-dimensional reconstruction of helical computed tomography angioportograms. Ann Surg, 2001, 233(2): 221-226.
18.	Sano K, Makuuchi M, Miki K, et al. Evaluation of hepatic venous congestion: proposed indication criteria for hepatic vein reconstruction. Ann Surg, 2002, 236(2): 241-247.
19.	Cucchetti A, Cescon M, Ercolani G, et al. A comprehensive meta-regression analysis on outcome of anatomic resection versus nonanatomic resection for hepatocellular carcinoma. Ann Surg Oncol, 2012, 19(12): 3697-3705.
20.	Eguchi S, Kanematsu T, Arii S, et al. Comparison of the outcomes between an anatomical subsegmentectomy and a non-anatomical minor hepatectomy for single hepatocellular carcinomas based on a Japanese nationwide survey. Surgery, 200, 143(4): 469-475.
21.	Kuroda S, Kobayashi T, Ohdan H. 3D printing model of the intrahepatic vessels for navigation during anatomical resection of hepatocellular carcinoma. Int J Surg Case Rep, 2017, 41: 219-222.
22.	Zein NN, Hanouneh IA, Bishop PD, et al. Three-dimensional print of a liver for preoperative planning in living donor liver transplantation. Liver Transpl, 2013, 19(12): 1304-1310.
23.	Igami T, Nakamura Y, Hirose T, et al. Application of a three-dimensional print of a liver in hepatectomy for small tumors invisible by intraoperative ultrasonography: preliminary experience. World J Surg, 2014, 38(12): 3163-3166.
24.	Beller S, Eulenstein S, Lange T, et al. Upgrade of an optical navigation system with a permanent electromagnetic position control: a first step towards "navigated control" for liver surgery. J Hepatobiliary Pancreat Surg, 2009, 16(2): 165-170.
25.	Beller S, Hünerbein M, Eulenstein S, et al. Feasibility of navigated resection of liver tumors using multiplanar visualization of intraoperative 3-dimensional ultrasound data. Ann Surg, 2007, 246(2): 288-294.

1. He J, Li D, Lu B, et al. Custom fabrication of composite tibial hemi-knee joint combining CAD/CAE/CAM techniques. Proc Inst Mech Eng H, 2006, 220(8): 823-830.
2. Waran V, Narayanan V, Karuppiah R, et al. Injecting realism in surgical training-initial simulation experience with custom 3D models. J Surg Educ, 2014, 71(2): 193-197.
3. 廖雯俊, 邬林泉. 3D虚拟肝脏技术在精准肝脏切除中的应用价值. 中国肿瘤临床, 2010, 37(18): 1077-1080.
4. 陈康, 熊力, 郑砚文, 等. 3D打印技术在肝脏外科应用现状及展望. 中国普通外科杂志, 2017, 26(1): 90-95.
5. 谢于, 胡文炜, 胡兆深, 等. 3D影像辅助下的肝脏切除手术规划. 肿瘤学杂志, 2012, 18(7): 500-504.
6. 黄从云, 朱剑华, 刘欣, 等. 3D打印技术在肝脏切除术中的应用. 中国普外基础与临床杂志, 2015, 22(11): 1351-1353.
7. Numminen K, Sipilä O, Mäkisalo H. Preoperative hepatic 3D models: virtual liver resection using three-dimensional imaging technique. Eur J Radiol, 2005, 56(2): 179-184.
8. Zhang G, Zhou XJ, Zhu CZ, et al. Usefulness of three-dimensional (3D) simulation software in hepatectomy for pediatric hepatoblastoma. Surg Oncol, 2016, 25(3): 236-243.
9. 张晗, 崔雷. 运用共词聚类分析法研究生物信息学的学科热点医学情报工作, 2004, 25(5): 327-330.
10. 张达. 精准肝脏外科在HCC治疗中的应用. 中国现代普通外科进展, 2017, 20(5): 362-364, 370.
11. 唐敏, 毛谅, 朱斌. 虚拟肝切除: 利用3D肝脏模型进行计算机辅助手术规划. 肝胆胰外科杂志, 2013, 25(3): 258-261.
12. He YB, Bai L, Aji T, et al. Application of 3D reconstruction for surgical treatment of hepatic alveolar echinococcosis. World J Gastroenterol, 2015, 21(35): 10200-10207.
13. Hansen C, Wieferich J, Ritter F, et al. Illustrative visualization of 3D planning models for augmented reality in liver surgery. Int J Comput Assist Radiol Surg, 2010, 5(2): 133-141.
14. Bégin A, Martel G, Lapointe R, et al. Accuracy of preoperative automatic measurement of the liver volume by CT-scan combined to a 3D virtual surgical planning software (3DVSP). Surg Endosc, 2014, 28(12): 3408-3412.
15. Wang Y, Zhang Y, Peitgen HO, et al. Precise local resection for hepatocellular carcinoma based on tumor-surrounding vascular anatomy revealed by 3D analysis. Dig Surg, 2012, 29(2): 99-106.
16. Lang H, Radtke A, Hindennach M, et al. Impact of virtual tumor resection and computer-assisted risk analysis on operation planning and intraoperative strategy in major hepatic resection. Arch Surg, 2005, 140(7): 629-638.
17. Wigmore SJ, Redhead DN, Yan XJ, et al. Virtual hepatic resection using three-dimensional reconstruction of helical computed tomography angioportograms. Ann Surg, 2001, 233(2): 221-226.
18. Sano K, Makuuchi M, Miki K, et al. Evaluation of hepatic venous congestion: proposed indication criteria for hepatic vein reconstruction. Ann Surg, 2002, 236(2): 241-247.
19. Cucchetti A, Cescon M, Ercolani G, et al. A comprehensive meta-regression analysis on outcome of anatomic resection versus nonanatomic resection for hepatocellular carcinoma. Ann Surg Oncol, 2012, 19(12): 3697-3705.
20. Eguchi S, Kanematsu T, Arii S, et al. Comparison of the outcomes between an anatomical subsegmentectomy and a non-anatomical minor hepatectomy for single hepatocellular carcinomas based on a Japanese nationwide survey. Surgery, 200, 143(4): 469-475.
21. Kuroda S, Kobayashi T, Ohdan H. 3D printing model of the intrahepatic vessels for navigation during anatomical resection of hepatocellular carcinoma. Int J Surg Case Rep, 2017, 41: 219-222.
22. Zein NN, Hanouneh IA, Bishop PD, et al. Three-dimensional print of a liver for preoperative planning in living donor liver transplantation. Liver Transpl, 2013, 19(12): 1304-1310.
23. Igami T, Nakamura Y, Hirose T, et al. Application of a three-dimensional print of a liver in hepatectomy for small tumors invisible by intraoperative ultrasonography: preliminary experience. World J Surg, 2014, 38(12): 3163-3166.
24. Beller S, Eulenstein S, Lange T, et al. Upgrade of an optical navigation system with a permanent electromagnetic position control: a first step towards "navigated control" for liver surgery. J Hepatobiliary Pancreat Surg, 2009, 16(2): 165-170.
25. Beller S, Hünerbein M, Eulenstein S, et al. Feasibility of navigated resection of liver tumors using multiplanar visualization of intraoperative 3-dimensional ultrasound data. Ann Surg, 2007, 246(2): 288-294.

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Bibliometric analysis of application of three-dimensional imaging in liver

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