Data sources

Data on the farms and number of pigs were obtained from the national CHR, where all farms with production animals are recorded [Reference Houe, Gardner and Nielsen28, Reference Stege29]. The CHR stores information linked to a farm code (ID), which refers to a specific geographical location and includes, e.g. animal species, the number of animals per age group (sows, weaners, finishers), thus the number per unit on any given day. The pigs owned by a producer (the herd) can be kept at many geographical localities (farms). For the sake of simplicity, all animals owned by an individual producer are referred to as a herd throughout the study even though some herds are kept at many farms [Reference Vigre24].

Data on movements of pigs between farms were obtained from the PMD, an integral part of the CHR. The PMD records the number of pigs, date, ID of origin farm and ID of destination farm for each movement [Reference Houe, Gardner and Nielsen28, Reference Stege29].

Data on AM use were obtained from VetStat, which contains data on all medicine prescribed by veterinarians for animals. Records are based on veterinarian prescriptions and contain information on active substances, amounts, target species, age groups, diagnosis groups and farm IDs [Reference Stege29]. The age groups in VetStat correspond to the age groups in the CHR, and the units, sows, weaners and finishers on a farm. In order to produce comparable data across records, active compounds were converted into a unit measuring how many kilograms of pig could be treated per day – Animal Defined Daily Doses per kilogram (ADDkg) [Reference Jensen, Jacobsen and Bager30].

Study design

The study design used was first described by Munk et al. [Reference Munk3]. In brief, based on the average sizes for sow and finisher farms in 2009 [Reference Christiansen31, Reference Jensen32], herds with more than 500 sows and a production of at least 5000 finishers annually were selected using the CHR and PMD. In total, 376 herds met these criteria. From VetStat, the total amounts of AM and tetracycline used in these herds from June to November 2013 were calculated as ADDkg and adjusted according to the number of animals in the herds. To cover a wide span of AM use, the 376 herds were ranked, and the owners of the top and bottom 10% AM and tetracycline use quantiles were invited to participate consecutively until five herds within each quantile had accepted. Each of these 10 herds was located between one and seven farms. In total, 23 herds from the top quantile and 15 herds from the bottom quantile were invited.

In the finisher units of the 10 herds, composite pen-floor samples were collected consisting of single samples from 30 randomly chosen pens within the section(s) with finishers weighing between 80 and 100 kg (in Denmark, pigs are delivered for slaughter weighing 100–105 kg) [Reference Munk3,Reference Schmidt9]. For each herd, the group of pigs from which samples were collected represents a finisher batch. For each of the finisher batches, the 30 single faeces samples were pooled together, resulting in one pooled sample per batch. Sampling took place from March to June 2014.

Measurements of AM use

For each batch of finisher, three quantitative usage measurements of the AM classes: aminoglycoside, lincosamide, macrolide, broad-spectrum penicillin, sulfonamide and tetracycline were calculated. They were based on the day of sampling, as the start from which backward assessment of time periods in the rearing site(s) were established. The measurements varied in terms of exposure, as explained below.

Danish national averages for pig production productivity for 2014 were applied for the rearing periods per unit (in days) [33–Reference Jessen35], resulting in 25, 50 and 85 days in the farrowing (piglet), weaning (weaner) and finisher units (finisher), respectively. Starting with the finisher batches and the day of sampling, the PMD was used to trace the movements of the batches from sampling site back to birth site. Figure 1 shows the pathways of the 10 finisher batches.

Fig. 1. The rearing pathway of each of the 10 finisher batches from birth site to finisher site compared with the day of sampling. The 10 horizontal bars depict the movements of the batches. A colour shift in a bar denotes that a farm has a different geographical location to the farm where sampling took place and P denotes the proportion of pigs being moved. Bars without P are equal to one. Numbers 1–5 denote the initially high users and 6–10 depict the initially low users. The three vertical coloured bars represent the assumed days of exposure to AM in the: sow-piglet (farrowing) unit, weaner unit and finisher unit.

Each farmer in the study had a health advisory contract with an individual veterinarian in accordance with Danish legislation. These contracts permit veterinarians to prescribe AMs for treatment of plausible diseases diagnosed at a farm visit for the subsequent 35 or 63 days (finishers only) at which point the next visit must take place. Therefore, taking into account the rearing period of 160 days, and the maximum period a prescription may cover (63 days), data from VetStat on prescribed AMs 9 months prior to sampling were extracted for the 22 farms comprising the finisher batches’ pathways from birth to sampling site (Fig. 1).

AM exposure was calculated for the classes: aminoglycoside, lincosamide, macrolide, broad-spectrum penicillin, tetracycline and sulfonamide, as these are most commonly used in Danish pig production [25]. By adopting the method used by Vigre et al. [Reference Vigre24], the daily amounts of the six AM classes used were calculated for sows, weaners and finishers in each of the 22 farms based on two assumptions. First, as veterinarians are permitted to prescribe for potential diseases for 35 or 65 days, the interval between two prescriptions was used to calculate the daily use for each prescription of AM, assuming that an average amount of the prescribed AM was used on each day of the interval. The calculations were subsequently added together per day per AM class. Second, if an interval was shorter than 7 days, the following prescription date was used to set the number of days for the interval.

Thus, the daily use of an AM was calculated as an average daily use per farm (F) per age group/unit (U) and adjusted in accordance with the number of pigs at risk per day per unit on each farm, as:

$$\eqalign{&{\rm ADDkg}\;{\rm day}{\rm \;} _{{\rm AM\_}F{\rm \_}U{\rm \;}} \cr&= \displaystyle{{{\rm ADDkg}{\rm \;} _{{\rm AMprescribed\_}F{\rm \_}U}} \over {{\rm day}{\rm s}_{{\rm prescription}\;{\rm interval\_}H} \times {\rm pig}{\rm s}_{{\rm day\_}F{\rm \_}U}}},}$$

where ${\rm ADDk}{\rm g}_{{\rm \; AMprescribed\_}F{\rm \_}U}{\rm \;} $  = the prescribed amount per unit per farm measured as ADDkg, days_{prescription interval} = the interval in days between the day of the initial prescription and the day of the subsequent prescription and pigs_{day_F_U}  = the number of sows, weaners or finishers on any given day. The number of sows substituted the number of piglets, as the latter is not registered in the CHR.

The number of ${\rm ADDkg\;} \;{\rm day}{\rm \;} _{{\rm AM\_}F{\rm \_}U{\rm \;}} $ was then summarised per day for each AM class (AMc):

$${\rm ADDkg\;} \;{\rm da}{\rm y}_{{\rm \; AMc\_}F{\rm \_}U{\rm \;}} = \mathop \sum \limits_{{\rm AM} = 1}^n {\rm ADDkg}\;{\rm day}{\rm \;} _{{\rm AM\_}F{\rm \_}U{\rm \;}}. $$

Based on the finisher batches’ rearing periods in days: days 1–85 in the finisher unit, days 86–135 in the weaning unit and days 136–160 in the sow unit, where day 1 corresponds to the day of sampling (Fig. 1), the number of ${\rm ADDkg\;} \;{\rm da}{\rm y}_{{\rm \; AMc\_}H{\rm \_}U{\rm \;}} $ was summarised for each rearing period (R) per unit, and adjusted to suit the proportion (P) of animals being moved from a farm (Fig. 1):

$${\rm ADDk}{\rm g}_{{\rm \; AMc\_}R{\rm \_}U{\rm \;}} = \mathop \sum \limits_{{\rm date} = 1}^n {\rm ADDkg\; da}{\rm y}_{{\rm \; AMc\_}F{\rm \_}U{\rm \;}} \times P{\rm.} $$

For each AM class, three measurements of exposure were calculated, given the rearing pathways, the rearing periods (Fig. 1) and the unit(s) in each farm (Fig. 2).

$$\eqalign{&{{\rm Finisher}\;{\rm Unit}}{\rm Exposure}_{{\rm \; AMc}} \cr & = {\rm ADDkg}_{{\rm \; AMc\_Finisher}\_{\rm Finisher\;}}}$$

$$\eqalign{ {\rm Lifetime\;} \;{\rm Exposur}{\rm e}_{{\rm \; AMc}}&{\rm = \,ADDk}{\rm g}_{{\rm \; AMc\_Piglet\_Sow}}\cr &\quad+ {\rm ADDk}{\rm g}_{{\rm AMc\_Weaner\_Weaner}} \cr &\quad+ {\rm ADDk}{\rm g}_{{\rm \; AMc\_Finisher\_Finisher\;}}} $$

$$\eqalign{{\rm Herd}\;{\rm Exposur}{\rm e}_{{\rm \; AMc}} =&\; {\rm ADDk}{\rm g}_{{\rm \; AMc\_Piglet\_All}}\cr&+{\rm ADDkg}{\rm \;} _{{\rm AMc\_Weaner\_All}} \cr& +{\rm ADDk}{\rm g}_{{\rm \; AMc\_Finisher\_All}}.} $$

Fig. 2. The exposure measurements of AM usage. The orange square applies to Finisher Unit Exposure and therefore comprises the AM usage in the finisher-rearing period in the finisher unit. Lifetime Exposure applies to the orange, green and blue squares, and therefore comprises the AM usage in the piglet-rearing period in the sow unit, the weaning-rearing period in the weaning unit and the finisher-rearing period in the finisher unit. The red square applies to Herd Exposure, and therefore comprises AM usage throughout the entire rearing period in all units.

For information on the units per farm included in the exposure measurements in the rearing period of the 10 finisher batches, see Figure S1 in the Supplementary data. For information on the obtained exposure variables, see Table S1 in the Supplementary data.

AMR measurements

In this study, the cultivation and metagenomic results of the pooled samples from 10 pig herds described by Munk et al. [Reference Munk3] were used as the AMR results.

Metagenomics

In brief, AMR genes for the classes: aminoglycoside, lincosamide, macrolide, β-lactam, sulfonamide and tetracycline were obtained using whole community sequencing (WCS), and measured as reads per kilobase reference per million (RPKM). For information on the genes within each AMR class, see Table S2 in the Supplementary data.

In order to compare the 10 faeces samples, the raw read counts were normalised to the size of the dataset for each AM class with the following formula:

$$\eqalign{& {\rm Reads}\;{\rm per\;} \;{\rm kilobase}\;{\rm reference}\;{\rm per\;} \;{\rm millio}{\rm n}_{{\rm AMc}} \cr &= \left( {\displaystyle{n \over {N(l - (i - 2m))}}} \right) 10^6R \times 1000\;{\rm bp,}} $$

where n = number of mapped reads, N = total number of reads, l = gene length, i = insert size, m = minimum mapping length, R = reads and bp = base pair.

The normalisation takes into account the fact that the pooling and sequencing of several indexed samples produces varying DNA library sizes, resulting in comparable RPKM values and independence of sequencing depth. For information on the obtained outcome variables, see Table S1 in the Supplementary data.

Data analyses

The quantitative effect of broad-spectrum penicillin and tetracycline use, measured as Finisher Unit Exposure, Lifetime Exposure and Herd Exposure, on ampicillin and tetracycline resistance obtained by cultivation was calculated using simple linear regression, and as a measure of model fit, the coefficient of determination (R ²) was applied. The quantitative effect of exposure for the AM classes: aminoglycoside, lincosamide, macrolide, broad-spectrum penicillin, sulfonamide and tetracycline, measured as Finisher Unit Exposure, Lifetime Exposure and Herd Exposure, on similar AMR gene abundance was calculated using simple linear regression, and as a measure of model fit, the coefficient of determination (R ²) was applied. The assessment of homoscedasticity was performed by visual inspection of the plots, including measured values and regression lines.

WPS Workbench, Version: 3.1.1.0.0, and Microsoft Excel 2010 were applied in data processing, and data analyses were performed using R, version 3.