Medical Device Research Institute, College of Science and Engineering, Flinders University, Tonsley, South Australia, Australia.
Department of Industrial Engineering, Alma Mater Studiorum - University of Bologna, Italy; Medical Technology Lab, IRCCS Instituto Ortopedico Rizzoli, Bologna, Italy.
J Mech Behav Biomed Mater. 2021 Jun;118:104434. doi: 10.1016/j.jmbbm.2021.104434. Epub 2021 Mar 4.
Logistic regression classification (LRC) is widely used to develop models to predict the risk of femoral fracture. LRC models based on areal bone mineral density (aBMD) alone are poor, with area under the receiver operator curve (AUROC) scores reported to be as low as 0.63. This has led to researchers investigating methods to extract further information from the image to increase performance. Recently, the use of active shape (ASM) and appearance models (AAM) have resulted in moderate improvements, but there is a risk that inclusion of too many modes will lead to overfitting. In addition, there are concerns that the effort required to extract the additional information does not justify the modest improvement in fracture risk prediction. This raises the question, are we reaching the limits of the information that can be extracted from an image? Finite element analysis was used in combination with active shape and appearance modelling to select variables to develop LRC models of fracture risk. Active shape and active appearance models were constructed based on a previously reported cohort of 94 post-menopausal Caucasian women (47 with and 47 without a fracture). T-tests were used to identify differences between the two groups for each mode of variation. Femur strength was predicted for two load cases, stance and a fall. Stepwise multi-variate linear regression was used to identify shape and appearance modes that were predictors of strength for the femurs in the training set. Femurs were also synthetically generated to explore the influence of the first 10 modes of the shape and appearance models. Identified modes of variation were then used to generate LRC models to predict fracture risk. Only 6 modes, 4 active appearance and 2 active shape modes, were identified that had a significant influence on predicted fracture strength. Of these, only two active appearance modes were needed to substantially improve the predictive mode performance (ΔAUROC = 0.080). The addition of 3 more modes (1 AAM and two ASM) further improved the performance of the classifier (ΔAUROC = 0.123). Further addition of modes did not result in any further substantial improvements. Based on these findings, it is suggested that we are reaching the limits of the information that can be extracted from an image to predict fracture risk.
逻辑回归分类(LRC)广泛用于开发预测股骨骨折风险的模型。仅基于面积骨密度(aBMD)的 LRC 模型效果不佳,报道的受试者工作特征曲线(AUROC)下面积得分低至 0.63。这导致研究人员研究从图像中提取更多信息以提高性能的方法。最近,使用主动形状(ASM)和外观模型(AAM)导致了适度的改进,但存在纳入太多模式会导致过拟合的风险。此外,有人担心提取额外信息所需的工作精力并不能证明骨折风险预测的适度改善是合理的。这就提出了一个问题,我们是否已经达到了可以从图像中提取信息的极限?有限元分析与主动形状和外观建模相结合,用于选择变量来开发骨折风险的 LRC 模型。基于之前报道的 94 名绝经后白种女性队列(47 名骨折和 47 名无骨折)构建了主动形状和主动外观模型。使用 t 检验比较两组中每种变化模式的差异。预测了两种负荷情况(站立和跌倒)下的股骨强度。逐步多元线性回归用于识别训练集中预测股骨强度的形状和外观模式。还对合成生成的股骨进行了研究,以探索形状和外观模型的前 10 个模式的影响。然后使用识别出的变化模式生成 LRC 模型来预测骨折风险。仅确定了 6 个模式,4 个主动外观模式和 2 个主动形状模式,这些模式对预测骨折强度有显著影响。其中,仅需要两个主动外观模式就可以大大提高预测模式的性能(ΔAUROC=0.080)。增加 3 个模式(1 个 AAM 和 2 个 ASM)进一步提高了分类器的性能(ΔAUROC=0.123)。进一步增加模式不会导致任何进一步的实质性改进。基于这些发现,建议我们已经达到了从图像中提取信息以预测骨折风险的极限。
