Review article Statistical modelling for clinical mastitis in the dairy cow: problems and solutions
Yüklə 166,2 Kb. Pdf görüntüsü
|
- Bu səhifədəki naviqasiya:
- 3.2.3. Contribution of the explanatory designed models
|
3.2.2. Specific survival models
Another method is based on distribution mixtures in survival models. This is devel- oped with the aim of a CMAST statistical model by modelling the dependence between successive events within the lactation, and from one lactation to another (Fig. 3). Such a method easily integrates observable bio- logical parameters [36, 37]. This approach, performed at the udder level, integrates the animal and lactation levels and allows to test individual and/or herd risk factors. Through this work, it is possible to study the distribution of CMAST cases per lactation and the distribution of CMAST occurrence periods. Nevertheless, the method does not integrate at the present time the variability due to mastitis risk factors at the herd level. 3.2.3. Contribution of the explanatory designed models The two proposed explanatory designed models are synthesis paths for CMAST modelling from the results of the generalist exploratory models. These two modelling ways (exploratory or empirical vs. explan- atory) are complementary [22, 58]. These new synthetic approaches could help to solve previously notified problems, such as the confounding factors and the integration of various levels of dependence. With such models, housing and grazing periods, and more generally all time- dependent variables [1, 37], can be consid- ered at the animal level. The study of such variables associated with that of an infec- tion rate effect at calving allows to rule out the lactation stage factor as one of the main Figure 2. Diagram showing the modelling elements making it possible to take into account dynamically different udder-health states in the same animal (adapted from [1]). Statistical modelling for clinical mastitis 501 structural variables for mastitis risk from the modelling process [37]. Consequently, such explanatory designed models intend to decrease the confounding problems. With such models, the dependence between suc- cessive cases within a lactation can explic- itly be considered by these models [36]. In the future, the modelling could be signifi- cantly improved by performing the study at the quarter level since quarter bacteriolog- ical status could be determined. Through this design, it would be possible to combine the two explanatory models already pub- lished [1, 2, 36, 37]. Such explanatory mod- els could also help to define optimum criteria for incidence rate definition at the herd level, even to justify the time lag in order to eliminate successive reoccurrences within a lactation. The model developed from the survival functions [36, 37] only considers the first CMAST occurrence in a lactation, or builds the analysis on a dichot- omous response at the lactation level (in the absence of recurrence parameters, more than one clinical mastitis case per lactation in the epidemiological context of the exper- imental studied herds could not occur). But explanatory modelling techniques require more scientific investment than the generalist exploratory models. Neverthe- less, they allow to add to the modelling, as published through a dynamic discrete event stochastic simulation model [1, 2], the main epidemiological and experimental knowledge concerning the CMAST risk. Yüklə 166,2 Kb. Dostları ilə paylaş:
|