Zhihai Su, Chengjie Huang, Zhifei Cui, Yunfei Wang, Wencong Zhang, Lei Zhao, Shumao Pang, Naiwen Zhang, Libin Liang, Zhen Yuan, Qianjin Feng, Xiang Liu, Tao Chen, Hai Lu
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引用次数: 0
Abstract
Background: Transforaminal puncture is a critical element of lumbar transforaminal epidural steroid injections used to manage lumbar radicular pain. Numerous challenges persist, owing to the intricate 3-dimensional (3D) anatomy of the spine and the delicate nature of the neurovascular structures involved. Consequently, performing the puncture expeditiously, precisely, and safely is imperative. Although numerous scholars have explored methods for reconstructing 3D lumbar models from patient data, the practical application of these models in puncture path planning for transpedicular procedures remains limited. Approaches based on artificial intelligence offer promising advantages for constructing patient-specific 3D models to facilitate puncture pathways planning.
Objective: In this experimental study, we proposed a preoperative planning method utilizing 3D artificial intelligence-generated lumbar models to improve the accuracy and efficiency of the transforaminal puncture process.
Study design: A phantoms study.
Setting: The Fifth Affiliated Hospital of Sun Yat-sen University, Zhuhai, P.R. China.
Methods: A total of 24 puncture trials utilizing 12 phantom models were independently conducted by 2 surgeons, employing our developed preoperative planning method and conventional fluoroscopy. After one month, one of the surgeons repeated the procedure. Puncture error, characterized by the discrepancy between the preoperative planning puncture target and the actual postoperative needle puncture point (measured in millimeters), as well as puncture procedure duration (measured in minutes), were evaluated by comparing the newly developed preoperative planning method with the traditional fluoroscopy method employed in the transforaminal puncture process.
Results: The average puncture error associated with the preoperative planning method was significantly lower than the conventional fluoroscopy method (3.33 ± 0.73 mm vs 5.25 ± 0.92 mm, P < 0.001). Additionally, the average puncture time of the preoperative planning method was significantly shorter than the conventional fluoroscopy method (7.29 ± 0.95 minutes vs 11.48 ± 1.27 minutes, P < 0.001).
Limitations: Our study used a small number of models; additional clinical trials are required to validate our preoperative planning methods.
Conclusion: The preoperative planning method utilizing 3D artificial intelligence-generated lumbar models for transforaminal puncture demonstrated superior accuracy and efficiency in phantom trials over the traditional fluoroscopic method. This newly developed preoperative planning technique has the potential to significantly improve the accuracy and efficiency of the transforaminal puncture process.
背景:经椎间孔穿刺是腰椎经椎间孔硬膜外类固醇注射治疗腰椎神经根性疼痛的关键因素。由于脊柱复杂的三维(3D)解剖结构和涉及的神经血管结构的微妙性质,许多挑战仍然存在。因此,执行穿刺迅速,准确,安全是必要的。尽管许多学者已经探索了从患者数据中重建三维腰椎模型的方法,但这些模型在经椎弓根手术穿刺路径规划中的实际应用仍然有限。基于人工智能的方法在构建患者特定的3D模型以促进穿刺路径规划方面具有很好的优势。目的:在本实验研究中,我们提出了一种利用三维人工智能生成腰椎模型的术前规划方法,以提高经椎间孔穿刺过程的准确性和效率。研究设计:模拟研究。单位:中山大学附属第五医院,珠海市方法:由2名外科医生独立进行24次穿刺试验,使用12个假体模型,采用我们开发的术前计划方法和常规透视。一个月后,其中一位外科医生重复了这个过程。通过将新开发的术前计划方法与传统的经椎间孔穿刺透视方法进行比较,评估穿刺误差,其特征是术前计划穿刺目标与术后实际穿刺针点(以毫米计)的差异,以及穿刺过程持续时间(以分钟计)。结果:术前规划方法的平均穿刺误差明显低于常规透视法(3.33±0.73 mm vs 5.25±0.92 mm, P < 0.001)。术前计划法的平均穿刺时间明显短于常规透视法(7.29±0.95 min vs 11.48±1.27 min, P < 0.001)。局限性:我们的研究使用了少量模型;需要更多的临床试验来验证我们的术前计划方法。结论:利用人工智能生成的三维腰椎模型进行经椎间孔穿刺的术前规划方法在模拟试验中比传统的透视方法具有更高的准确性和效率。这项新开发的术前计划技术有潜力显著提高经椎间孔穿刺过程的准确性和效率。
期刊介绍:
Pain Physician Journal is the official publication of the American Society of Interventional Pain Physicians (ASIPP). The open access journal is published 6 times a year.
Pain Physician Journal is a peer-reviewed, multi-disciplinary, open access journal written by and directed to an audience of interventional pain physicians, clinicians and basic scientists with an interest in interventional pain management and pain medicine.
Pain Physician Journal presents the latest studies, research, and information vital to those in the emerging specialty of interventional pain management – and critical to the people they serve.
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