切换至 "中华医学电子期刊资源库"
高级检索
中华胸部外科电子杂志

中华胸部外科电子杂志 ›› 2020, Vol. 07 ›› Issue (03) : 191 -196. doi: 10.3877/cma.j.issn.2095-8773.2020.03.10

所属专题: 文献

综述

3D打印气管支架在长段气管缺损修复中的应用
郑开福1, 刘宇健1, 唐希阳1, 姜涛1, 李小飞1, 赵晋波1,()   
  1. 1. 710032 西安,空军军医大学第二附属医院胸腔外科
  • 收稿日期:2020-08-06 修回日期:2020-08-23 接受日期:2020-08-24 出版日期:2020-08-28
  • 通信作者: 赵晋波
  • 基金资助:
    陕西省创新能力支撑计划(S2018-ZC-XXXM-0054); 空军军医大学尖子人才资助基金(2019); 空军军医大学第二附属医院科技创新发展基金(2019QYTS004)

Application of 3D printed tracheal stents in the repair of long tracheal defects

Kaifu Zheng1, Yujian Liu1, Xiyang Tang1, Tao Jiang1, Xiaofei Li1, Jinbo Zhao1,()   

  1. 1. Department of Thoracic Surgery, Second Affiliated Hospital of Air Force Military Medical University, Xi’an 710032, China
  • Received:2020-08-06 Revised:2020-08-23 Accepted:2020-08-24 Published:2020-08-28
  • Corresponding author: Jinbo Zhao
  • About author:
    Corresponding author: Zhao Jinbo, Email:
全文 ( ) 下载PDF ( ) 导出引用
引用本文:

郑开福, 刘宇健, 唐希阳, 姜涛, 李小飞, 赵晋波. 3D打印气管支架在长段气管缺损修复中的应用[J]. 中华胸部外科电子杂志, 2020, 07(03): 191-196.

Kaifu Zheng, Yujian Liu, Xiyang Tang, Tao Jiang, Xiaofei Li, Jinbo Zhao. Application of 3D printed tracheal stents in the repair of long tracheal defects[J]. Chinese Journal of Thoracic Surgery(Electronic Edition), 2020, 07(03): 191-196.

长段气管缺损的修复重建是临床中一个具有挑战性的难题,目前用于修复重建的气管替代物包括同种异体气管、自体组织、人工气管以及组织工程气管,然而不同的气管替代物都有一定的缺陷,从而限制了其在临床上的广泛应用。3D打印技术是近年迅速发展的一项技术,由于其个性化,精准化,速度快的特点在医学领域逐渐得到了广泛的应用。越来越多的研究者将3D打印技术与组织工程技术相结合,应用于长段气管缺损修复重建的研究,取得了一定的成果。

关键词: 3D打印, 组织工程, 气管重建

The repair and reconstruction of long tracheal defects is a challenging problem in the clinic. Currently, the tracheal substitutes used for repair and reconstruction include allogeneic trachea, autologous tissue, artificial trachea and tissue engineered trachea. However, different tracheal substitutes have different shortcomings limiting its application in the clinic. 3D printing technology is a technology that has developed rapidly in recent years. Due to its personalized, precise, and fast characteristics, it has gradually been widely used in the medical field. More and more researchers have combined 3D printing technology with tissue engineering technology to study the repair and reconstruction of long tracheal defects, and have achieved some results.

Key words: 3D printing, Tissue engineering, Tracheal reconstruction
表1 不同材料及结构气管支架力学性能
三点弯曲实验 支架材料 圆筒状 波纹状 原生气管
位移/载荷[8] PCL 1.4 mm/12.6 N 1.4 mm/1.8 N
抗压强度[9] PCL 1.088±0.161 MPa 0.214±0.125 MPa
受力分布[8] PCL 集中于受压点 均匀分布
旋转角度[7] PCL 110°±5° 130°±9°
PU 148°±10° 172°±8°
表2 3D打印气管支架对修复长段气管缺损的研究结果
作者 年份 实验对象 气管构成 长度/mm 再生上皮 再生血管 再生软骨 随访时间
再上皮化 ? ? ? ? ? ? ? ?
? Bhora等[12] 2017 PCL+ECM 15 吻合口可见 广泛新生血管伴炎症细胞 2周
? Park等[13] 2018 新西兰兔 PCL+ECM+下鼻甲间充质干细胞 10 整个管腔可见 管腔中部可见 2个月
? 刘春全等[14] 2018 新西兰兔 PLGA+软骨细胞 20 少量纤毛上皮 6个月
? Chan等[15] 2019 新西兰兔 PCL 20 吻合口可见 广泛新生血管伴炎症细胞 7周
再血管化 ? ? ? ? ? ? ? ?
? Gao等[1] 2017 新西兰兔 PCL+软骨细胞+裸鼠皮下包埋 16.5 无上皮组织再生 部分区域可见 6周
? Park等[9] 2018 新西兰兔 PCL+大网膜包埋2周 15 整个管腔可见 大量新生血管 黏膜下可见少量软骨 8周
? Gao等[16] 2019 新西兰兔 PLLA+耳廓软骨细胞+颈旁肌肉包埋2周 15 整个管腔可见 大量新生血管 软骨细胞生存良好 2个月
软骨再生 ? ? ? ? ? ? ? ?
? Park等[8] 2015 鼠(皮下) PCL+TGF-β1+软骨细胞 15.5 软骨细胞生存良好 8周
? 葛阳等[17] 2015 鼠(皮下) 聚酰胺+软骨细胞 20 软骨细胞生存良好 8周
? 张恒一等[18] 2017 新西兰兔 PLCL+GT/PCL膜+软骨细胞 20 软骨细胞生存良好 8周
? Xia等[19] 2019 山羊 PCL+耳廓软骨细胞 30 部分区域可见 吻合口可见 8周
1
Gao M, Zhang H, Dong W,et al.Tissue-engineered trachea from a 3D-printed scaffold enhances whole-segment tracheal repair[J].Sci Rep,2017,7(1):5246.
2
Ghezzi CE, Marelli B, Donelli I,et al.The role of physiological mechanical cues on mesenchymal stem cell differentiation in an airway tract-like dense collagen-silk fibroin construct[J].Biomaterials,2014,35(24):6236-6247.
3
Chan DS, Fnais N, Ibrahim I,et al.Exploring polycaprolactone in tracheal surgery:A scoping review of in-vivo studies[J].Int J Pediatr Otorhinolaryngol,2019,123:38-42.
4
Bedell ML, Navara AM, Du Y,et al.Polymeric Systems for Bioprinting[J].Chem Rev,2020.Online ahead of print.
5
Chang JW, Park SA, Park JK,et al.Tissue-engineered tracheal reconstruction using three-dimensionally printed artificial tracheal graft:preliminary report[J].Artif Organs,2014,38(6):E95-E105.
6
Tsao CK, Ko CY, Yang SR,et al.An ectopic approach for engineering a vascularized tracheal substitute[J].Biomaterials,2014,35(4):1163-1175.
7
Ahn CB, Son KH, Yu YS,et al.Development of a flexible 3D printed scaffold with a cell-adhesive surface for artificial trachea[J].Biomed Mater,2019,14(5):055001.
8
Park JH, Hong JM, Ju YM,et al.A novel tissue-engineered trachea with a mechanical behavior similar to native trachea[J].Biomaterials,2015,62:106-115.
9
Park HS, Lee JS, Jung H,et al.An omentum-cultured 3D-printed artificial trachea:in vivo bioreactor[J].Artif Cells Nanomed Biotechnol,2018,46(sup3): S1131-S1140.
10
Sekine T, Nakamura T, Matsumoto K,et al.Carinal reconstruction with a Y-shaped collagen-conjugated prosthesis[J].J Thorac Cardiovasc Surg,2000,119(6):1162-1168.
11
Best CA, Pepper VK, Ohst D,et al.Designing a tissue-engineered tracheal scaffold for preclinical evaluation[J].Int J Pediatr Otorhinolaryngol,2018,104:155-160.
12
Bhora FY, Lewis EE, Rehmani SS,et al.Circumferential Three-Dimensional-Printed Tracheal Grafts:Research Model Feasibility and Early Results[J].Ann Thorac Surg,2017,104(3):958-963.
13
Park JH, Park JY, Nam IC,et al.A rational tissue engineering strategy based on three-dimensional (3D) printing for extensive circumferential tracheal reconstruction[J].Biomaterials,2018,185:276-283.
14
刘春全,李华伟,蔡先启,等.3D打印复合人工气管移植的实验研究[J].临床和实验医学杂志,2018,17(4):350-354.
15
Chan DS, Gabra N, Baig A,et al.Bridging the gap:Using 3D printed polycaprolactone implants to reconstruct circumferential tracheal defects in rabbits[J].Laryngoscope,2019.Online ahead of print.
16
Gao B, Jing H, Gao M,et al.Long-segmental tracheal reconstruction in rabbits with pedicled Tissue-engineered trachea based on a 3D-printed scaffold[J].Acta Biomater,2019,97:177-186.
17
葛阳,韩露,冯蓓,等.软骨细胞膜片复合3D打印内支撑构建管状软骨的初步研究[J].组织工程与重建外科杂志,2015,11(4):225-228.
18
张恒一,冯蓓,葛阳,等.利用静电纺纳米膜复合3D打印支架构建"C"形环状软骨的初步研究[J].上海交通大学学报(医学版),2017,37(7):896-900.
19
Xia D, Jin D, Wang Q,et al.Tissue-engineered trachea from a 3D-printed scaffold enhances whole-segment tracheal repair in a goat model[J].J Tissue Eng Regen Med,2019,13(4):694-703.
20
Galliger Z, Vogt CD, Panoskaltsis-Mortari A.3D bioprinting for lungs and hollow organs[J].Transl Res,2019,211:19-34.
21
梁娅男,张建华.3D打印与组织工程技术在气管替代治疗中的应用与热点[J].中国组织工程研究,2020,24(5):780-786.
22
Lee DY, Park SA, Lee SJ,et al.Segmental tracheal reconstruction by 3D-printed scaffold:Pivotal role of asymmetrically porous membrane[J].Laryngoscope,2016,126(9):E304-E309.
23
Kang Y, Wang C, Qiao Y,et al.Tissue-Engineered Trachea Consisting of Electrospun Patterned sc-PLA/GO- g-IL Fibrous Membranes with Antibacterial Property and 3D-Printed Skeletons with Elasticity[J].Biomacromolecules,2019,20(4):1765-1776.
24
Hamilton N, Bullock AJ, Macneil S,et al.Tissue engineering airway mucosa:a systematic review[J].Laryngoscope,2014,124(4):961-968.
25
Bae SW, Lee KW, Park JH,et al.3D Bioprinted Artificial Trachea with Epithelial Cells and Chondrogenic-Differentiated Bone Marrow-Derived Mesenchymal Stem Cells[J].Int J Mol Sci,2018,19(6):1624.
26
Park JH, Yoon JK, Lee JB,et al.Experimental Tracheal Replacement Using 3-dimensional Bioprinted Artificial Trachea with Autologous Epithelial Cells and Chondrocytes[J].Sci Rep,2019,9(1):2103.
[1] 陈严城, 符培亮. 组织工程技术在骨软骨缺损中应用的研究进展[J]. 中华关节外科杂志(电子版), 2023, 17(03): 376-384.
[2] 钱嘉天, 符培亮. 3D打印脱细胞的细胞外基质修复软骨缺损的研究进展[J]. 中华关节外科杂志(电子版), 2023, 17(03): 368-375.
[3] 王雪, 程微, 苏建东. 微针法表皮移植应用的新进展[J]. 中华损伤与修复杂志(电子版), 2023, 18(03): 270-273.
[4] 蒯贤东, 郑国爽, 杨佳慧, 赵德伟. 用于关节软骨缺损修复的壳聚糖复合支架的研究进展[J]. 中华损伤与修复杂志(电子版), 2022, 17(06): 535-539.
[5] 刘竹影, 周年苟, 李泳祺, 周丽斌. 空心环钻联合手术导板用于自体牙移植牙槽窝备洞[J]. 中华口腔医学研究杂志(电子版), 2023, 17(06): 418-423.
[6] 王湘滔, 张爱娟, 王万春, 王芳萍, 徐颖婕, 孟洋. 中药白及在口腔疾病中的研究与应用[J]. 中华口腔医学研究杂志(电子版), 2023, 17(05): 371-375.
[7] 张辉, 蔡敏, 黄湘雅. 数字化技术和人工智能在上颌窦底提升术的临床应用[J]. 中华口腔医学研究杂志(电子版), 2023, 17(04): 244-252.
[8] 陈世远, 余朝文, 高涌, 王孝高, 张克霏. 3D打印、体外开窗、CTA与DSA融合在胸腹主动脉瘤腔内治疗中的应用[J]. 中华普通外科学文献(电子版), 2023, 17(02): 128-128.
[9] 钟文文, 李科, 刘碧好, 蔡炳, 脱颖, 叶雷, 马波, 瞿虎, 汪中扬, 王德娟, 邱剑光. 不同比例聚乳酸/丝素蛋白复合支架在兔尿道缺损修复中的疗效[J]. 中华腔镜泌尿外科杂志(电子版), 2023, 17(05): 516-522.
[10] 王祎, 王峻峰, 杨超, 晋云, 胡苹苹. 数字医学技术在肝脏分段及解剖性肝切除中的应用现状[J]. 中华肝脏外科手术学电子杂志, 2023, 12(01): 16-21.
[11] 刘文瑛, 欧阳再兴, 朱剑华, 吴黎明, 谭勇, 宋灏, 朱玉珍, 黄从云. 多模态影像技术在精准肝癌肝切除中的应用[J]. 中华肝脏外科手术学电子杂志, 2022, 11(06): 574-579.
[12] 金浪, 石洁, 黄正, 贾永伟, 张建坡, 魏礼成, 金昊雷. 3D打印数字技术辅助改良交叉PVP对重度骨质疏松性椎体压缩骨折脊柱-骨盆矢状面平衡状态的影响[J]. 中华老年骨科与康复电子杂志, 2023, 09(05): 263-268.
[13] 吕东, 朱盛, 胡秋平, 邹松, 黄文强, 唐全进, 黄海. 基于增强CT与增强MRI融合的3D打印导板辅助脑肿瘤穿刺活检一例报道[J]. 中华脑科疾病与康复杂志(电子版), 2023, 13(04): 251-254.
[14] 高尔涵, 张硕, 齐岩松, 王一帆. 3D打印个别托盘在全口义齿修复中的临床应用[J]. 中华临床医师杂志(电子版), 2023, 17(03): 255-259.
[15] 陈雄焕, 胡培阳. 3D打印模型在骨盆骨折外固定训练中的效果研究[J]. 中华卫生应急电子杂志, 2023, 09(03): 163-165.
阅读次数
全文


摘要

版权所有 中华医学会 中华医学电子音像出版社有限责任公司  京ICP备14006079号-1  网络出版服务许可证:(署)网出证(京)字第075号