Haine Denis, Dohoo Ian, Dufour Simon
Faculté de médecine vétérinaire, Université de Montréal, Montreal, QC, Canada.
Canadian Bovine Mastitis and Milk Quality Research Network, St-Hyacinthe, QC, Canada.
Front Vet Sci. 2018 May 28;5:99. doi: 10.3389/fvets.2018.00099. eCollection 2018.
Using imperfect tests may lead to biased estimates of disease frequency and measures of association. Many studies have looked into the effect of misclassification on statistical inferences. These evaluations were either within a cross-sectional study framework, assessing biased prevalence, or for cohort study designs, evaluating biased incidence rate or risk ratio estimates based on misclassification at one of the two time-points (initial assessment or follow-up). However, both observations at risk and incident cases can be wrongly identified in longitudinal studies, leading to selection and misclassification biases, respectively. The objective of this paper was to evaluate the relative impact of selection and misclassification biases resulting from misclassification, together, on measures of incidence and risk ratio. To investigate impact on measure of disease frequency, data sets from a hypothetical cohort study with two samples collected one month apart were simulated and analyzed based on specific test and disease characteristics, with no elimination of disease during the sampling interval or clustering of observations. Direction and magnitude of bias due to selection, misclassification, and total bias was assessed for diagnostic test sensitivity and specificity ranging from 0.7 to 1.0 and 0.8 to 1.0, respectively, and for specific disease contexts, i.e., disease prevalences of 5 and 20%, and disease incidences of 0.01, 0.05, and 0.1 cases/animal-month. A hypothetical exposure with known strength of association was also generated. A total of 1,000 cohort studies of 1,000 observations each were simulated for these six disease contexts where the same diagnostic test was used to identify observations at risk at beginning of the cohort and incident cases at its end. Our results indicated that the departure of the estimates of disease incidence and risk ratio from their true value were mainly a function of test specificity, and disease prevalence and incidence. The combination of the two biases, at baseline and follow-up, revealed the importance of a good to excellent specificity relative to sensitivity for the diagnostic test. Small divergence from perfect specificity extended quickly to disease incidence over-estimation as true prevalence increased and true incidence decreased. A highly sensitive test to exclude diseased subjects at baseline was of less importance to minimize bias than using a highly specific one at baseline. Near perfect diagnostic test attributes were even more important to obtain a measure of association close to the true risk ratio, according to specific disease characteristics, especially its prevalence. Low prevalent and high incident disease lead to minimal bias if disease is diagnosed with high sensitivity and close to perfect specificity at baseline and follow-up. For more prevalent diseases we observed large risk ratio biases towards the null value, even with near perfect diagnosis.
使用不完善的检测方法可能会导致疾病频率和关联度测量的偏差估计。许多研究探讨了错误分类对统计推断的影响。这些评估要么是在横断面研究框架内,评估有偏差的患病率,要么是针对队列研究设计,评估基于两个时间点之一(初始评估或随访)的错误分类得出的有偏差的发病率或风险比估计值。然而,在纵向研究中,处于风险中的观察对象和发病病例都可能被错误识别,分别导致选择偏倚和错误分类偏倚。本文的目的是评估错误分类共同导致的选择偏倚和错误分类偏倚对发病率和风险比测量的相对影响。为了研究对疾病频率测量的影响,根据特定的检测和疾病特征,模拟并分析了来自假设队列研究的数据集,该研究相隔一个月收集了两个样本,在抽样间隔期间没有疾病消除或观察对象聚集情况。针对诊断检测灵敏度范围为0.7至1.0、特异性范围为0.8至1.0,以及特定疾病情况,即疾病患病率为5%和20%、疾病发病率为0.01、0.05和0.1例/动物月,评估了选择偏倚、错误分类偏倚和总偏倚的方向和大小。还生成了一个具有已知关联强度的假设暴露因素。针对这六种疾病情况,总共模拟了1000项队列研究,每项研究有1000个观察对象,在队列开始时使用相同的诊断检测来识别处于风险中的观察对象,在队列结束时识别发病病例。我们的结果表明,疾病发病率和风险比估计值与真实值的偏差主要是检测特异性、疾病患病率和发病率的函数。在基线和随访时两种偏倚的组合表明,相对于诊断检测的灵敏度,良好至优异的特异性很重要。随着真实患病率增加和真实发病率降低,与完美特异性的微小差异会迅速扩展为疾病发病率的高估。在基线时使用高灵敏度检测来排除患病对象对于最小化偏倚的重要性不如在基线时使用高特异性检测。根据特定疾病特征,尤其是其患病率,接近完美的诊断检测属性对于获得接近真实风险比的关联度测量更为重要。如果在基线和随访时以高灵敏度和接近完美的特异性诊断疾病,低患病率和高发病率的疾病导致的偏倚最小。对于更常见的疾病,即使诊断接近完美,我们也观察到风险比朝着无效值有较大偏差。
