Textbook recommendations for gavaging rats vary between 1-5 ml for an adult rat. Rats weighing either 130 g or 250 g were gavaged with varying dosages of barium sulphate (BaSO4). After dosing, radiographs were taken at 0, 15 and 60 min. Animals showing a section of the small intestine totally filled with BaSO4 were scored as displaying spontaneous release. Other rats of the same sizes were gavaged with similar doses and subsequently tested in an open-field arena for behavioural abnormalities that might indicate stress or pain resulting from the procedure. Body temperature before and after treatment was recorded using microchip transponders. None of the 250 g rats in the 1 ml dosage group showed spontaneous release through the pyloric sphincter. In the 2 ml and 4 ml dosage groups, only one out of five animals showed spontaneous release. In the 6 ml dosage group, half of the animals showed spontaneous release. In the 8 ml and 10 ml dosage groups, five out of six and four out of five, respectively, showed spontaneous release. If doses were higher than 12 ml, no animal was able to keep all of the BaSO4 in its stomach. In the rats weighing 130 g, the 3 ml dosage group showed only one out of four rats with spontaneous release, whereas in the 5 ml and 7 ml dosage groups, all animals showed spontaneous release. After 15 min, all of the rats in both weight groups showed BaSO4 in the duodenum. Ambulation, rearing up onto the hind legs and defecation, as well as body temperature immediately after dosing, correlated very strongly with the dose (ml kg−1); increasing the dose resulted in reduced ambulation, rearing, defecation and body temperature. However, 10 min after performance of the open-field test, neither body temperature, serum corticosterone nor serum glucose showed any correlation with dose. This study indicates that high doses (ie doses up to 10 ml for a 250 g rat) might be safe to use; however, if an adverse impact on the rat is to be avoided, use of much lower doses should be considered—for example, doses that do not enforce opening of the pyloric sphincter in any rat. This would be less than 4 ml kg−1 in a 250 g rat.

In sheep (Ovis aries) and other farm animals, routine husbandry procedures can cause negative emotions, such as fear, which are generally considered to reduce animal welfare. The open-field test (OFT) is the most widely used test to measure fearfulness in animals. The induction of psychological stress is often accompanied by an elevation of core body temperature, referred to as stress-induced hyperthermia (SIH) and both OFT and SIH were used in this study to measure fearfulness in sheep: the aim being to examine associations between behaviour in the OFT and the SIH response, using data from two breeds of sheep tested repeatedly over time. Twentyfour ewes from two breeds, Lacaune and Ripollesa, were tested for 10 min with all behaviours recorded throughout. Rectal temperature was measured immediately prior to the start of the test (T1) and 10 min after its completion (T2). SIH was measured as the difference between T2 and T1. Sheep were tested over three periods of three experimental days each. Ewes of both breeds showed consistent changes in behaviour in the OFT and a clear SIH response. Bleats and visits to the water bucket showed a clear pattern between rounds. Differences between T1 and T2 were found, T2 was higher than T1 suggesting that exposure to a novel arena caused SIH. Breed differences were found whereby T2 was 0.12°C higher in Ripollesa than Lacaune. These findings have implications for selection programmes, creating the possibility of selecting less fearful animals that will cope better with handling procedures that may induce fear. Further, they also demonstrate the importance of using both behavioural and physiological variables to evaluate fear.

An open-field test was conducted in southern France to assess the host-specificity of Ceratapion basicorne (Illiger), a candidate for biological control of yellow starthistle. Test plants were infested by naturally occurring populations of C. basicorne but were also exposed to sympatric herbivore species, including other Ceratapion spp. Insects from the test plants were collected directly into tubes of ethanol and were subsequently identified to species according to DNA sequence similarity with morphologically identified reference specimens. This integrated, morphological and molecular identification method was used in an effort to maximize the amount of data gained in the field bioassay and to minimize the number of taxonomist–hours necessary to complete the study. The results obtained showed that the French C. basicorne population only attacked yellow starthistle and cornflower, another known host of C. basicorne. Molecular phylogenetic analysis of the insects collected from all other nonhost plants rejected the possibility that any were C. basicorne.