用于计算机断层扫描研究的膝关节医学模型

Ekaterina D. Belyakova, Anastasia A. Nasibullina, Julia V. Bulgakova, Olga Vlasova, Veronika V. Grebennikova, O. Omelyanskaya, A. Petraikin, D. Leonov
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引用次数: 0

摘要

背景:膝关节是临床实践中经常可视化的解剖区域。准确解读 CT 扫描需要对解剖学有全面的了解,并熟练掌握基本技术原理和成像协议。为了保障患者的健康,最重要的是防止因设备质量不佳、设置问题和患者体位造成的错误研究。使用模型预先调整设备,并对医务人员进行扫描技术培训,可以避免这些困难。目的:本研究的目的是开发一种技术,用于制作膝关节的拟人化医学模型,该模型能准确反映相应人体组织的 X 射线密度,从而使计算机断层扫描研究得以使用。材料和方法:膝关节模型由一系列模型组成,分别代表股骨、胫骨、腓骨、髌骨、副韧带、外侧和内侧半月板、股四头肌肌腱、前后交叉韧带和髌韧带。韧带模型是用树脂三维打印的,骨骼是用硅胶浇铸的,软组织是用硅胶类材料的均匀结构建模的,并通过浇铸到硅胶模具中制成。皮肤也是类似的模型。研究中,CT 扫描仪的阳极电压范围为 80 至 140 千伏,切片厚度为 1.25 毫米。结果:开发的拟人膝关节模型展示了建模解剖结构的 X 射线密度,其中韧带的 Hausfield 密度范围为 80-120 个单位,骨骼的 Hausfield 密度范围为 320-370 个单位,软组织和皮肤的 Hausfield 密度范围为 20-60 个单位。添加技术的使用使模型与膝关节之间达到高度相似成为可能。进一步研究的方向可能是创建更复杂的骨组织模型,包括独立的皮质层和海绵物质。结论:使用拟人膝关节模型可以获取高质量的 CT 图像,而无需事先对患者进行扫描。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Medical phantom of the knee joint for computed tomography studies
BACKGROUND: The knee joint is a frequently visualized anatomical region in clinical practice. Accurate interpretation of CT scans necessitates a comprehensive understanding of anatomy and a sound grasp of fundamental technical principles and imaging protocols. To safeguard the patient's well-being, it is of paramount importance to prevent erroneous studies resulting from suboptimal equipment quality, setup issues, and patient positioning. These difficulties can be circumvented by the use of phantoms to pre-adjust the equipment and the provision of training to medical staff in scanning techniques. AIM: The aim of the study was to develop a technique for creating an anthropomorphic medical phantom of the knee joint that would accurately reflect the X-ray density of the corresponding human tissues, thus enabling the use of computed tomography studies. MATERIALS AND METHODS: The knee joint phantom comprises a series of models representing the femur, tibia, fibula, patella, collateral ligaments, lateral and medial menisci, tendon of the quadriceps femoris muscle, anterior and posterior cruciate ligaments, and patellar ligament. Ligament models were 3D-printed from resin, bones were cast from silicone, soft tissues were modeled with a homogeneous structure of silicone-like materials and made by casting into silicone molds. The skin was similarly modeled. In the study, the anode voltage range of the CT scanner varied from 80 to 140 kV, and the slice thickness was equal to 1.25 mm. RESULTS: The developed anthropomorphic knee joint phantom demonstrated the X-ray density of the modeled anatomical structures, with ligaments exhibiting a range of 80–120 units on the Hausfield scale, bones exhibiting a range of 320–370 units, and soft tissues and skin exhibiting a range of 20–60 units. The use of additive technologies made it possible to achieve a high degree of similarity between the phantom forms and the knee joint. Further research may be directed towards the creation of a more complex model of bone tissue, comprising a separate cortical layer and spongy substance. CONCLUSIONS: The use of an anthropomorphic knee phantom allows for the acquisition of high-quality CT images without the need for prior scanning of patients.
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来源期刊
CiteScore
1.30
自引率
0.00%
发文量
44
审稿时长
5 weeks
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