磁共振引导下高强度聚焦超声消融对骨力学性能及建模的影响
Effects of magnetic resonance-guided high-intensity focused ultrasound ablation on bone mechanical properties and modeling.
作者信息
Yeo Sin Yuin, Arias Moreno Andrés J, van Rietbergen Bert, Ter Hoeve Natalie D, van Diest Paul J, Grüll Holger
机构信息
Department of Biomedical Engineering, Eindhoven University of Technology, High Tech Campus 11-p1.243, 5656 AE Eindhoven, The Netherlands.
Department of Pathology, University Medical Center Utrecht, Room H04.312, Utrecht, The Netherlands.
出版信息
J Ther Ultrasound. 2015 Aug 11;3:13. doi: 10.1186/s40349-015-0033-8. eCollection 2015.
BACKGROUND
Magnetic resonance-guided high-intensity focused ultrasound (MR-HIFU) is a promising technique for palliative treatment of bone pain. In this study, the effects of MR-HIFU ablation on bone mechanics and modeling were investigated.
METHODS
A total of 12 healthy rat femurs were ablated using 10 W for 46 ± 4 s per sonication with 4 sonications for each femur. At 7 days after treatments, all animals underwent MR and single photon emission computed tomography/computed tomography (SPECT/CT) imaging. Then, six animals were euthanized. At 1 month following ablations, the remaining six animals were scanned again with MR and SPECT/CT prior to euthanization. Thereafter, both the HIFU-treated and contralateral control bones of three animals from each time interval were processed for histology, whereas the remaining bones were subjected to micro-CT (μCT), three-point bending tests, and micro-finite element (micro-FE) analyses.
RESULTS
At 7 days after HIFU ablations, edema formation around the treated bones coupled with bone marrow and cortical bone necrosis was observed on MRI and histological images. SPECT/CT and μCT images revealed presence of bone modeling through an increased uptake of (99m)Tc-MDP and formation of woven bone, respectively. At 31 days after ablations, as illustrated by imaging and histology, healing of the treated bone and the surrounding soft tissue was noted, marked by decreased in amount of tissue damage, formation of scar tissue, and sub-periosteal reaction. The results of three-point bending tests showed no significant differences in elastic stiffness, ultimate load, and yield load between the HIFU-treated and contralateral control bones at 7 days and 1 month after treatments. Similarly, the elastic stiffness and Young's moduli determined by micro-FE analyses at both time intervals were not statistically different.
CONCLUSIONS
Multimodality imaging and histological data illustrated the presence of HIFU-induced bone damage at the cellular level, which activated the bone repair mechanisms. Despite that, these changes did not have a mechanical impact on the bone.
背景
磁共振引导下的高强度聚焦超声(MR-HIFU)是一种有前景的骨痛姑息治疗技术。在本研究中,研究了MR-HIFU消融对骨力学和骨重塑的影响。
方法
对12根健康大鼠股骨进行消融,每次超声处理功率为10W,持续46±4秒,每根股骨进行4次超声处理。治疗后7天,所有动物接受磁共振成像(MR)和单光子发射计算机断层扫描/计算机断层扫描(SPECT/CT)成像。然后,对6只动物实施安乐死。消融后1个月,对其余6只动物在实施安乐死前再次进行MR和SPECT/CT扫描。此后,对每个时间间隔的3只动物的HIFU治疗骨和对侧对照骨进行组织学处理,其余骨骼进行显微计算机断层扫描(μCT)、三点弯曲试验和微观有限元(micro-FE)分析。
结果
HIFU消融后7天,MRI和组织学图像显示治疗骨周围出现水肿形成,伴有骨髓和皮质骨坏死。SPECT/CT和μCT图像分别显示通过增加(99m)Tc-MDP摄取和编织骨形成存在骨重塑。消融后31天,成像和组织学显示治疗骨和周围软组织愈合,表现为组织损伤量减少、瘢痕组织形成和骨膜下反应。三点弯曲试验结果显示,治疗后7天和1个月时,HIFU治疗骨和对侧对照骨在弹性刚度、极限载荷和屈服载荷方面无显著差异。同样,两个时间间隔的微观有限元分析确定的弹性刚度和杨氏模量在统计学上无差异。
结论
多模态成像和组织学数据表明在细胞水平存在HIFU诱导的骨损伤,这激活了骨修复机制。尽管如此,这些变化对骨没有力学影响。
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