Selection of herds and sampling

In 2000, a total of 14 dairy herds were selected to participate in a field study on the basis of them having high bulk-tank milk enzyme-linked immunosorbent assay (ELISA) results, i.e. above 50 background-corrected optical density values (ODC%) [Reference Andersen, Salman, Morley and Ruch-Galie11, Reference Nielsen12]. Herd size varied between 38 and 154 lactating cows. S. Dublin was isolated from faecal samples of all of these herds at least once during the study period from the beginning of 2000 to the beginning of 2002 [Reference Nielsen and Ersbøll13], with indications of the herd being endemically infected throughout the project period (i.e. continued serological responses in all age groups of cattle and bulk-tank milk throughout the study period). Each of the 14 herds was visited five times – except one that was visited four times – within a time-frame of ∼3-month intervals. At each visit, blood samples were collected from all accessible calves, young stock and dry cows; and milk samples were collected from all lactating cows at the morning milking for serological analysis. Faecal samples were collected rectally from all accessible animals and placed into marked faecal transport containers with a snap cap (549263 NUNC A/S, Denmark), with the aim of obtaining at least 50 g from each animal.

All samples were transported directly to the Danish Cattle Health Laboratory (DCHL) in Ladelund, and stored at <5 °C until analysis could be performed within a few days of the samples' arrival. At the laboratory faecal samples were pooled five at a time using 5 g per sample. This was then mixed in a 25 g pool before analysis. The blood samples were spun to extract the serum fraction for analysis.

Bacteriological culture method

Pooled faecal samples were examined at DCHL for the presence of Salmonella bacteria by mixing the 25 g faecal material in a 225 ml peptone buffer which was then left for pre-enrichment at 37 °C for 18–24 h. A volume of 0·1 ml of the test material was added to modified semi-solid Rappaport–Vassiliadis medium base (MSRV agar) plates and 1 ml of the test material was placed into 9 ml of selenite cystine broth and incubated for 18–24 h at 41·5 °C. Material from the selenite cystine tubes was inoculated on modified Brilliant-green Phenol-red lactose sucrose agar (BPLS agar) plates and incubated at 37 °C for 18–24 h. Positive test results from MSRV were inoculated onto BPLS agar plates and confirmed using triple sugar iron agar tests and lysine iron agar tests. Serotyping and confirmation of positive isolates were conducted at the Danish Veterinary Institute (now the National Food Institute at the Danish Technical University in Copenhagen).

If the pool was found to be positive for Salmonella, then the individual samples would be cultured using 25 g faecal material to try to identify those animals that were positive in the pool. The diagnostic sensitivity of this faecal culture procedure has been evaluated to be about 6–14% in subclinically infected cattle [Reference Nielsen, Toft and Ersbøll14].

Antibody measurements by ELISA

The serum S. Dublin ELISA that was used in this study, was performed at DCHL as slightly modified from a previously described ELISA method [Reference Hoorfar15] and described in detail in Nielsen & Ersbøll [Reference Nielsen and Ersbøll16]. Briefly, an O-antigen based S. Dublin lipopolysaccharide (LPS) preparation produced at the Danish Veterinary Institute in Copenhagen was used to coat microtitration plates. Sera were diluted 1:200 and added to microtitration plate wells in duplicate. Known positive and negative reference sera were added in quadruplicate. The plates were incubated overnight at 4 °C, and washed three times. For detection of immunoglobulins, affinity purified horseradish peroxidase-labelled goat anti-bovine IgG (H + L) conjugate was added. Following incubation for 1 h at 37 °C the plates were washed three times. Substrate and indicator solution was added to the wells and incubated in the dark at room temperature for 10–20 min. The reaction was then stopped when the optical density of the positive reference wells was visually evaluated to be about 2·000 OD values. The OD was read at 492 nm and 620 nm as reference using an ELISA plate reader. Plates were considered valid if the four negative reference wells had an average OD of <0·300, and the four positive reference wells had an average OD of 1·200–2·500. An ODC% value, which is a background-corrected proportion of the test sample OD to a positive reference sample, was calculated as follows:

$${\rm ODC}\percnt \equals {{\left( {\overline{{{\rm OD}}} _{{\rm sample}}\ \mbox {-}\ \overline{{{\rm OD}}} _{{\rm neg\ ref}} } \right)} \over {\left( {\overline{{{\rm OD}}} _{{\rm pos\ ref}} \ \mbox {-}\ \overline{{{\rm OD}}} _{{\rm neg\ ref}} } \right)}} \times 100\percnt $$

where $\overline{{{\rm OD}}} _{{\rm sample}} $ is the mean value of two test wells, $\overline{{{\rm OD}}} _{{\rm neg\ ref}} $ and $\overline{{{\rm OD}}} _{{\rm pos\ ref}} $ are the mean of ELISA plate readings of four test negative and test positive reference wells, respectively.

Serum and milk samples with ODC% >50 were considered seropositive in the consecutive calculations for within-herd and within-age group prevalence estimations. At this cut-off, the sensitivity of the ELISA has previously been estimated to be 0·16–0·26 for calves aged <100 days, 0·66–0·88 in calves and young stock aged 100–300 days, and 0·50–0·68 in cattle aged >300 days old. The specificity was estimated to be 0·93–0·98, 0·93–0·98, and 0·88–0·91 for the same age groups, respectively [Reference Nielsen, Toft and Ersbøll14].

Statistical analyses

SAS version 9.2 (SAS Institute Inc., USA) was used for the data management as well as the descriptive and statistical analyses. Within-herd prevalence of seropositive and bacteriologically positive animals was calculated for rolling intervals of age across all herds. Intervals of serological prevalence contained 200 observations. Due to the low number of faecal culture-positive animals, the intervals used for descriptive statistics of the bacteriological results contained 500 observations in each interval. For each interval, 95% confidence limits were calculated.

For further analysis, the dataset was split into three age groups based on typical management and housing structures in Danish dairy herds: calves aged 0–180 days (usually housed in calf barns with single housing followed by small groups of calves), young stock aged 181 days to 2 years (growing and breeding heifers often kept in larger groups) and adult cattle aged >2 years (adult heifers close to calving or cows). The correlation between seroprevalence and faecal culture-positive prevalence within each age group and across all age groups was investigated using Spearman's correlation. Furthermore, the correlation between the faecal culture-positive prevalences at one visit and the seroprevalences at the next visit for each age group and across all age groups were investigated using Spearman's correlation, because it could be expected that the increase in seroprevalence would be delayed by at least 2–4 weeks compared to the point in time of the shedding of the bacteria [Reference Da17–Reference Robertsson19].

Factors affecting seroprevalence at each herd visit were investigated for each of the age groups using three hierarchical mixed models with seroprevalence as the outcome and season and bacteriological status of the age group on the given visit date as potential risk factors in the model. Repeated sampling at herd level was taken into account in the analysis, and herd was included as a fixed effect in order to determine the actual predicted seroprevalence for each herd and level of significant predictors. Two-way interactions between predictors were tested in the models. Predictors and interactions were considered significantly associated with the outcome if P < 0·05.