利用计算流体动力学对组织工程气管性能进行量化
Quantification of tissue-engineered trachea performance with computational fluid dynamics.
作者信息
Eichaker Lauren, Li Chengyu, King Nakesha, Pepper Victoria, Best Cameron, Onwuka Ekene, Heuer Eric, Zhao Kai, Grischkan Jonathan, Breuer Christopher, Johnson Jed, Chiang Tendy
机构信息
Department of Otolaryngology-Head and Neck Surgery, Nationwide Children's Hospital, Columbus, Ohio.
Tissue Engineering and Surgical Research, Research Institute at Nationwide Children's Hospital, Columbus, Ohio.
出版信息
Laryngoscope. 2018 Aug;128(8):E272-E279. doi: 10.1002/lary.27233. Epub 2018 May 14.
OBJECTIVES/HYPOTHESIS: Current techniques for airway characterization include endoscopic or radiographic measurements that produce static, two-dimensional descriptions. As pathology can be multilevel, irregularly shaped, and dynamic, minimal luminal area (MLA) may not provide the most comprehensive description or diagnostic metric. Our aim was to examine the utilization of computational fluid dynamics (CFD) for the purpose of defining airway stenosis using an ovine model of tissue-engineered tracheal graft (TETG) implantation.
STUDY DESIGN
Animal research model.
METHODS
TETGs were implanted into sheep, and MLA was quantified with imaging and endoscopic measurements. Graft stenosis was managed with endoscopic dilation and stenting when indicated. Geometries of the TETG were reconstructed from three-dimensional fluoroscopic images. CFD simulations were used to calculate peak flow velocity (PFV) and peak wall shear stress (PWSS). These metrics were compared to values derived from a quantitative respiratory symptom score.
RESULTS
Elevated PFV and PWSS derived from CFD modeling correlated with increased respiratory symptoms. Immediate pre- and postimplantation CFD metrics were similar, and implanted sheep were asymptomatic. Respiratory symptoms improved with stenting, which maintained graft architecture similar to dilation procedures. With stenting, baseline PFV (0.33 m/s) and PWSS (0.006 Pa) were sustained for the remainder of the study. MLA measurements collected via bronchoscopy were also correlated with respiratory symptoms. PFV and PWSS found via CFD were correlated (R = 0.92 and 0.99, respectively) with respiratory symptoms compared to MLA (R = 0.61).
CONCLUSIONS
CFD is valid for informed interventions based on multilevel, complex airflow and airway characteristics. Furthermore, CFD may be used to evaluate TETG functionality.
LEVEL OF EVIDENCE
NA. Laryngoscope, E272-E279, 2018.
目的/假设:目前用于气道特征描述的技术包括内镜或影像学测量,这些测量产生的是静态的二维描述。由于病变可能是多层面的、形状不规则的且动态变化的,最小管腔面积(MLA)可能无法提供最全面的描述或诊断指标。我们的目的是使用组织工程气管移植物(TETG)植入的绵羊模型,研究计算流体动力学(CFD)在定义气道狭窄方面的应用。
研究设计
动物研究模型。
方法
将TETG植入绵羊体内,通过成像和内镜测量对MLA进行量化。必要时,通过内镜扩张和支架置入来处理移植物狭窄。从三维荧光透视图像重建TETG的几何形状。使用CFD模拟计算峰值流速(PFV)和峰值壁面剪应力(PWSS)。将这些指标与从定量呼吸症状评分得出的值进行比较。
结果
CFD建模得出的升高的PFV和PWSS与呼吸症状增加相关。植入前和植入后即刻的CFD指标相似,植入的绵羊无症状。支架置入后呼吸症状改善,其维持的移植物结构与扩张手术相似。通过支架置入,在研究的剩余时间内维持了基线PFV(0.33 m/s)和PWSS(0.006 Pa)。通过支气管镜检查收集的MLA测量值也与呼吸症状相关。与MLA(R = 0.61)相比,通过CFD发现的PFV和PWSS与呼吸症状的相关性分别为(R = 0.92和0.99)。
结论
CFD对于基于多层面、复杂气流和气道特征的明智干预是有效的。此外,CFD可用于评估TETG的功能。
证据水平
无。《喉镜》,E272 - E279,2018年。
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