Department of Livestock and One Health, Institute of Infection, Veterinary and Ecological Sciences, University of Liverpool, Leahurst Campus, Chester High Road, CH64 7TE, United Kingdom.
Department of Clinical Science and Services, Royal Veterinary College, North Mymms, Hertfordshire, AL9 7TA, United Kingdom.
J Dairy Sci. 2021 Sep;104(9):10194-10202. doi: 10.3168/jds.2021-20178. Epub 2021 Jun 5.
Our aims were to (1) determine how interdigital skin temperature (IST), measured using infrared thermography, was associated with different stages of digital dermatitis (DD) lesions and (2) develop and validate models that can use IST measurements to identify cows with an active DD lesion. Between March 2019 and March 2020, infrared thermographic images of hind feet were taken from 2,334 Holstein cows across 4 farms. We recorded the maximum temperature reading from infrared thermographic images of the interdigital skin between the heel bulbs on the hind feet. Pregnant animals were enrolled approximately 1 to 2 mo precalving, reassessed 1 wk after calving, and again at approximately 50 to 100 d postpartum. At these time points, IST and the clinical stage of DD (M-stage scoring system: M1-M4.1) were recorded in addition to other data such as the ambient environmental temperature, height, body condition score, parity, and the presence of other foot lesions. A mixed effect linear regression model with IST as the dependent variable was fitted. Interdigital skin temperature was associated with DD lesions; compared to healthy feet, IST was highest in feet with M2 lesions, followed by M1 and M4.1 lesions. Subsequently, the capacity of IST measurements to detect the presence or absence of an active DD lesion (M1, M2, or M4.1) was explored by fitting logistic regression models, which were tested using 10-fold validation. A mixed effect logistic regression model with the presence of active DD as the dependent variable was fitted first. The average area under the curve for this model was 0.80 when its ability to detect presence of active DD was tested on 10% of the data that were not used for the model's training; an average sensitivity of 0.77 and an average specificity of 0.67 was achieved. This model was then restricted so that only explanatory variables that could be practically recorded in a nonresearch, external setting were included. Validation of this model demonstrated an average area under the curve of 0.78, a sensitivity of 0.88, and a specificity of 0.66 for 1 of the time points (precalving). Lower sensitivity and specificity were achieved for the other 2 time points. Our study adds further evidence to the relationship between DD and foot skin temperature using a large data set with multiple measurements per animal. Additionally, we highlight the potential for infrared thermography to be used for routine on-farm diagnosis of active DD lesions.
(1)确定使用红外热成像测量的指间皮肤温度(IST)与不同阶段的奶牛趾间皮炎(DD)病变之间的关系;(2)开发和验证可使用 IST 测量来识别患有活动性 DD 病变的奶牛的模型。在 2019 年 3 月至 2020 年 3 月期间,对来自 4 个农场的 2334 头荷斯坦奶牛的后脚进行了红外热成像拍摄。我们记录了后脚脚跟之间的指间皮肤的红外热成像图像中的最大温度读数。在大约产前 1-2 个月将妊娠动物纳入研究,产后 1 周再次评估,并在产后约 50-100 天再次评估。在这些时间点,记录了 IST 和 DD 的临床阶段(M 阶段评分系统:M1-M4.1),以及其他数据,如环境温度、身高、体况评分、胎次和其他足部病变的存在。使用 IST 作为因变量拟合了混合效应线性回归模型。指间皮肤温度与 DD 病变有关;与健康的脚相比,M2 病变的脚的 IST 最高,其次是 M1 和 M4.1 病变。随后,通过拟合逻辑回归模型来探索 IST 测量值检测活动性 DD 病变(M1、M2 或 M4.1)的能力,并使用 10 折验证进行测试。首先,以活动性 DD 的存在为因变量拟合了混合效应逻辑回归模型。当在未用于模型训练的数据的 10%上测试该模型检测活动性 DD 存在的能力时,该模型的平均曲线下面积为 0.80;平均灵敏度为 0.77,平均特异性为 0.67。然后限制该模型,只包含在非研究、外部环境中实际可记录的解释变量。该模型的验证表明,在 1 个时间点(产前)的平均曲线下面积为 0.78,灵敏度为 0.88,特异性为 0.66;在另外 2 个时间点的灵敏度和特异性较低。我们的研究使用具有每个动物多次测量的大型数据集进一步证明了 DD 与足部皮肤温度之间的关系。此外,我们强调了红外热成像在农场常规诊断活动性 DD 病变中的潜力。
