Logan M Scheuermann, Daniel D Lewis, Matthew D Johnson, Adam H Biedrzycki, Stanley E Kim
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Guides were 3D printed, sterilized, and applied, in conjunction with transient application of a circular fixator, to facilitate indirect fracture realignment before plate application. Alignment of the stabilized tibiae was assessed using postoperative computed tomography scans.</p><p><strong>Results: </strong>Mean duration required for virtual planning was 2.5 h and a mean of 50.7 h elapsed between presentation and surgery. Guide placement was accurate with minor median discrepancies in translation and frontal, sagittal, and axial plane positioning of 2.9 mm, 3.6°, 2.7°, and 6.8°, respectively. Application of the reduction system restored mean tibial length and frontal, sagittal, and axial alignment within 1.7 mm, 1.9°, 1.7°, and 4.5°, respectively, of the contralateral tibia.</p><p><strong>Conclusion: </strong>Design and fabrication of a 3D-printed, patient-specific fracture reduction system is feasible in a relevant clinical timeline. Intraoperative pin-guide placement was reasonably accurate with minor discrepancies compared to the virtual plan. Custom 3D-printed reduction system application facilitated near-anatomic or acceptable fracture reduction in all dogs.</p><p><strong>Clinical significance: </strong>Virtual planning and fabrication of a 3D-printing patient-specific fracture reduction system is practical and facilitated acceptable, if not near-anatomic, fracture alignment during MIPO.</p>","PeriodicalId":23667,"journal":{"name":"Veterinary Surgery","volume":" ","pages":"1039-1051"},"PeriodicalIF":1.3000,"publicationDate":"2024-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Efficacy of virtual surgical planning and a three-dimensional-printed, patient-specific reduction system to facilitate alignment of diaphyseal tibial fractures stabilized by minimally invasive plate osteosynthesis in dogs: A prospective clinical study.\",\"authors\":\"Logan M Scheuermann, Daniel D Lewis, Matthew D Johnson, Adam H Biedrzycki, Stanley E Kim\",\"doi\":\"10.1111/vsu.14118\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Objective: </strong>To evaluate the efficacy of a three-dimensional (3D)-printed, patient-specific reduction system for aligning diaphyseal tibial fractures stabilized using minimally invasive plate osteosynthesis (MIPO).</p><p><strong>Study design: </strong>Prospective clinical trial.</p><p><strong>Sample population: </strong>Fifteen client owned dogs.</p><p><strong>Methods: </strong>Virtual 3D models of both pelvic limbs were created. Pin guides were designed to conform to the proximal and distal tibia. A reduction bridge was designed to align the pin guides based on the guides' spatial location. Guides were 3D printed, sterilized, and applied, in conjunction with transient application of a circular fixator, to facilitate indirect fracture realignment before plate application. Alignment of the stabilized tibiae was assessed using postoperative computed tomography scans.</p><p><strong>Results: </strong>Mean duration required for virtual planning was 2.5 h and a mean of 50.7 h elapsed between presentation and surgery. Guide placement was accurate with minor median discrepancies in translation and frontal, sagittal, and axial plane positioning of 2.9 mm, 3.6°, 2.7°, and 6.8°, respectively. 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引用次数: 0
摘要
目的评估三维(3D)打印、患者特异性还原系统在对齐使用微创钢板骨合成术(MIPO)稳定的胫骨骺端骨折方面的疗效:研究设计:前瞻性临床试验:研究设计:前瞻性临床试验:方法:创建两个骨盆肢体的虚拟 3D 模型。设计了符合胫骨近端和远端的导针。根据导引器的空间位置,设计了一个缩小桥来对齐针状导引器。导针经过三维打印、消毒和应用,并结合圆形固定器的瞬时应用,以便在应用钢板前进行间接骨折复位。使用术后计算机断层扫描评估稳定胫骨的对齐情况:虚拟规划所需的平均时间为 2.5 小时,从提出到手术的平均时间为 50.7 小时。导板定位准确,平移和正面、矢状面和轴面定位的中位偏差分别为2.9毫米、3.6°、2.7°和6.8°。应用缩小系统后,平均胫骨长度以及正面、矢状面和轴向对齐度分别恢复到对侧胫骨的1.7毫米、1.9°、1.7°和4.5°以内:结论:在相关临床时限内,设计和制造患者特异性的 3D 打印骨折复位系统是可行的。与虚拟计划相比,术中针导定位相当准确,差异较小。定制三维打印骨折复位系统的应用使所有犬的骨折复位接近解剖学或可接受:临床意义:虚拟规划和制造患者专用的三维打印骨折复位系统是切实可行的,有助于在 MIPO 期间实现可接受的骨折对位,即使不是接近解剖。
Efficacy of virtual surgical planning and a three-dimensional-printed, patient-specific reduction system to facilitate alignment of diaphyseal tibial fractures stabilized by minimally invasive plate osteosynthesis in dogs: A prospective clinical study.
Objective: To evaluate the efficacy of a three-dimensional (3D)-printed, patient-specific reduction system for aligning diaphyseal tibial fractures stabilized using minimally invasive plate osteosynthesis (MIPO).
Study design: Prospective clinical trial.
Sample population: Fifteen client owned dogs.
Methods: Virtual 3D models of both pelvic limbs were created. Pin guides were designed to conform to the proximal and distal tibia. A reduction bridge was designed to align the pin guides based on the guides' spatial location. Guides were 3D printed, sterilized, and applied, in conjunction with transient application of a circular fixator, to facilitate indirect fracture realignment before plate application. Alignment of the stabilized tibiae was assessed using postoperative computed tomography scans.
Results: Mean duration required for virtual planning was 2.5 h and a mean of 50.7 h elapsed between presentation and surgery. Guide placement was accurate with minor median discrepancies in translation and frontal, sagittal, and axial plane positioning of 2.9 mm, 3.6°, 2.7°, and 6.8°, respectively. Application of the reduction system restored mean tibial length and frontal, sagittal, and axial alignment within 1.7 mm, 1.9°, 1.7°, and 4.5°, respectively, of the contralateral tibia.
Conclusion: Design and fabrication of a 3D-printed, patient-specific fracture reduction system is feasible in a relevant clinical timeline. Intraoperative pin-guide placement was reasonably accurate with minor discrepancies compared to the virtual plan. Custom 3D-printed reduction system application facilitated near-anatomic or acceptable fracture reduction in all dogs.
Clinical significance: Virtual planning and fabrication of a 3D-printing patient-specific fracture reduction system is practical and facilitated acceptable, if not near-anatomic, fracture alignment during MIPO.
期刊介绍:
Veterinary Surgery, the official publication of the American College of Veterinary Surgeons and European College of Veterinary Surgeons, is a source of up-to-date coverage of surgical and anesthetic management of animals, addressing significant problems in veterinary surgery with relevant case histories and observations.
It contains original, peer-reviewed articles that cover developments in veterinary surgery, and presents the most current review of the field, with timely articles on surgical techniques, diagnostic aims, care of infections, and advances in knowledge of metabolism as it affects the surgical patient. The journal places new developments in perspective, encompassing new concepts and peer commentary to help better understand and evaluate the surgical patient.