Tong Yubing, Udupa Jayaram K, Torigian Drew A, Odhner Dewey, Wu Caiyun, Pednekar Gargi, Palmer Scott, Rozenshtein Anna, Shirk Melissa A, Newell John D, Porteous Mary, Diamond Joshua M, Christie Jason D, Lederer David J
Medical Image Processing Group, Department of Radiology, University of Pennsylvania, Philadelphia, Pennsylvania, United States of America.
Department of Medicine, Duke University, Durham, North Carolina, United States of America.
PLoS One. 2017 Jan 3;12(1):e0168932. doi: 10.1371/journal.pone.0168932. eCollection 2017.
Overweight and underweight conditions are considered relative contraindications to lung transplantation due to their association with excess mortality. Yet, recent work suggests that body mass index (BMI) does not accurately reflect adipose tissue mass in adults with advanced lung diseases. Alternative and more accurate measures of adiposity are needed. Chest fat estimation by routine computed tomography (CT) imaging may therefore be important for identifying high-risk lung transplant candidates. In this paper, an approach to chest fat quantification and quality assessment based on a recently formulated concept of standardized anatomic space (SAS) is presented. The goal of the paper is to seek answers to several key questions related to chest fat quantity and quality assessment based on a single slice CT (whether in the chest, abdomen, or thigh) versus a volumetric CT, which have not been addressed in the literature.
Unenhanced chest CT image data sets from 40 adult lung transplant candidates (age 58 ± 12 yrs and BMI 26.4 ± 4.3 kg/m2), 16 with chronic obstructive pulmonary disease (COPD), 16 with idiopathic pulmonary fibrosis (IPF), and the remainder with other conditions were analyzed together with a single slice acquired for each patient at the L5 vertebral level and mid-thigh level. The thoracic body region and the interface between subcutaneous adipose tissue (SAT) and visceral adipose tissue (VAT) in the chest were consistently defined in all patients and delineated using Live Wire tools. The SAT and VAT components of chest were then segmented guided by this interface. The SAS approach was used to identify the corresponding anatomic slices in each chest CT study, and SAT and VAT areas in each slice as well as their whole volumes were quantified. Similarly, the SAT and VAT components were segmented in the abdomen and thigh slices. Key parameters of the attenuation (Hounsfield unit (HU) distributions) were determined from each chest slice and from the whole chest volume separately for SAT and VAT components. The same parameters were also computed from the single abdominal and thigh slices. The ability of the slice at each anatomic location in the chest (and abdomen and thigh) to act as a marker of the measures derived from the whole chest volume was assessed via Pearson correlation coefficient (PCC) analysis.
The SAS approach correctly identified slice locations in different subjects in terms of vertebral levels. PCC between chest fat volume and chest slice fat area was maximal at the T8 level for SAT (0.97) and at the T7 level for VAT (0.86), and was modest between chest fat volume and abdominal slice fat area for SAT and VAT (0.73 and 0.75, respectively). However, correlation was weak for chest fat volume and thigh slice fat area for SAT and VAT (0.52 and 0.37, respectively), and for chest fat volume for SAT and VAT and BMI (0.65 and 0.28, respectively). These same single slice locations with maximal PCC were found for SAT and VAT within both COPD and IPF groups. Most of the attenuation properties derived from the whole chest volume and single best chest slice for VAT (but not for SAT) were significantly different between COPD and IPF groups.
This study demonstrates a new way of optimally selecting slices whose measurements may be used as markers of similar measurements made on the whole chest volume. The results suggest that one or two slices imaged at T7 and T8 vertebral levels may be enough to estimate reliably the total SAT and VAT components of chest fat and the quality of chest fat as determined by attenuation distributions in the entire chest volume.
超重和体重不足状况因其与过高死亡率相关,被视为肺移植的相对禁忌证。然而,近期研究表明,体重指数(BMI)并不能准确反映晚期肺部疾病成年患者的脂肪组织量。因此需要更准确的脂肪量替代测量方法。通过常规计算机断层扫描(CT)成像估计胸部脂肪,对于识别高风险肺移植候选者可能具有重要意义。本文提出一种基于最近提出的标准化解剖空间(SAS)概念的胸部脂肪定量及质量评估方法。本文的目标是寻求解答几个与基于单层CT(无论是胸部、腹部还是大腿部)和容积CT的胸部脂肪量及质量评估相关的关键问题,这些问题在文献中尚未得到解决。
对40例成年肺移植候选者(年龄58±12岁,BMI 26.4±4.3kg/m²)的胸部CT平扫图像数据集进行分析,其中16例患有慢性阻塞性肺疾病(COPD),16例患有特发性肺纤维化(IPF),其余患者患有其他疾病,并对每位患者在L5椎体水平和大腿中部水平获取的单层图像进行分析。在所有患者中一致定义胸部的身体区域以及胸部皮下脂肪组织(SAT)与内脏脂肪组织(VAT)之间的界面,并使用活动轮廓工具进行描绘。然后在此界面引导下对胸部的SAT和VAT成分进行分割。采用SAS方法在每个胸部CT研究中识别相应的解剖切片,并对每个切片以及它们的总体积中的SAT和VAT面积进行定量。同样,对腹部和大腿部切片中的SAT和VAT成分进行分割。分别从每个胸部切片以及整个胸部容积中确定SAT和VAT成分的衰减关键参数(亨氏单位(HU)分布)。也从腹部和大腿部单层切片中计算相同参数。通过皮尔逊相关系数(PCC)分析评估胸部(以及腹部和大腿部)每个解剖位置的切片作为源自整个胸部容积测量指标的标记物的能力。
SAS方法在椎体水平方面正确识别了不同受试者的切片位置。胸部脂肪体积与胸部切片脂肪面积之间的PCC,对于SAT在T8水平最大(0.97),对于VAT在T7水平最大(0.86),而对于SAT和VAT,胸部脂肪体积与腹部切片脂肪面积之间的相关性中等(分别为0.73和0.75)。然而,对于SAT和VAT,胸部脂肪体积与大腿部切片脂肪面积之间的相关性较弱(分别为0.52和0.37),并且对于SAT和VAT的胸部脂肪体积与BMI之间的相关性也较弱(分别为0.65和0.28)。在COPD和IPF组内的SAT和VAT中均发现了具有最大PCC的相同单层位置。COPD组和IPF组之间,源自整个胸部容积和VAT最佳单层切片(但不是SAT)的大多数衰减特性存在显著差异。
本研究展示了一种最佳选择切片的新方法,其测量结果可作为对整个胸部容积进行类似测量的标记物。结果表明,在T7和T8椎体水平成像的一两个切片可能足以可靠地估计胸部脂肪的总SAT和VAT成分以及由整个胸部容积中的衰减分布所确定的胸部脂肪质量。
