The roles of head movements in the search and capture strategy of a tern (Aves, Laridae)

 Gull-billed terns (Gelochelidon nilotica) were video-filmed while searching for and capturing fiddler crabs. Search consists of a vertical head nystagmus, with fast upward flicks and downward slow phases made at the angular speed of the substrate in the approximate direction of the bill. The bill points down at about 60° during hunting, but is brought up to 15° from time to time, which brings the visual streak into line with the horizon; 45° roll movements of the head are consistent with alternation between the use of the temporal and central foveas to view the same object. When a crab has been detected the nystagmus is suspended, and the tern tracks the crab continuously as it manoeuvres into a catching position. This may involve tucking the head under the body so that the bill is 45° behind the vertical, and flying up and backwards for some metres, straightening up the head at the same time. Accepted: 7 November 1998     

Effect of pre-slaughter handling,exercise and the presence of a dog on lamb welfare and meat quality

Before slaughter, lambs may experience several stressors such as feed and water deprivation, handling and transport that have the potential to negatively impact welfare and meat quality. The objective of this study was to evaluate the effect of pre-slaughter handling, exercise and the presence of a dog on the behaviour and physiology of lambs and meat quality at slaughter. At 6 months of age, 60 lambs (n=20 lambs/replicate; three replicates) were allocated to one of the two treatment groups (n=30 lambs/treatment): low (LOW) intensive handling or high (HIGH) intensive handling. LOW lambs were moved short distances, quietly and without the use of a dog before transport. HIGH lambs were moved quickly, long distances and with a dog present before transport. Lamb behaviour (standing, lying, rumination and panting) was recorded for 1 h before (post-treatment) and after transport (post-transport), and for 30 min before slaughter (pre-slaughter). Blood samples were collected before (baseline), after transport (post-transport) and at exsanguination (at slaughter) to assess cortisol, lactate and non-esterified fatty acid (NEFA) concentrations. At slaughter, lamb carcases (M. longissimus lumborum) were evaluated for pH levels, drip and cook loss, and tenderness. HIGH lambs spent more time standing (P<0.001) and panting (P<0.001) and less time lying (P<0.001) and ruminating (P<0.001) post-treatment than LOW lambs, but more (P<0.001) time ruminating post-transport. All lambs spent more time standing (P<0.001) and less time lying (P<0.001) and panting (P<0.001) post-transport and pre-slaughter than post-treatment. Cortisol concentrations were greater (P<0.001) in lambs post-transport and at slaughter compared with baseline values. Lactate concentrations were lower (P=0.002) in HIGH than LOW lambs. In addition, NEFA concentrations were higher (P<0.001) post-transport and at slaughter in HIGH compared with LOW lambs. Ultimate pH was higher (P<0.001) in HIGH than LOW lambs and pH declined quicker (P=0.012) in LOW than HIGH lambs. Cook loss, drip loss and shear force were lower (P⩽0.05) in HIGH than LOW lambs. The HIGH intensive pre-slaughter handling regime used in the present study caused stress in lambs and increased ultimate pH that could potentially negatively impact welfare, product quality and consistency.     

Assessing the effect of complex ground types on ground‐dwelling arthropod movements with video monitoring: Dealing with concealed movements under a layer of plant residues

Understanding the effect of ground types on foraging movements of ground‐dwelling arthropods is a key step to managing their spatial distribution as required for successful conservation biological control. Indeed, fine movements at the centimeter scale can strongly influence the foraging ability of pest predators. However, because radio frequency identification or harmonic tracking techniques are not yet suitable for small species and video tracking focuses on uniform and light backgrounds, foraging movements have rarely been studied in relation to ground types. We present a method to track a ground‐dwelling arthropod (the earwig Euborellia caraibea) at night, walking on two contrasted ground types: bare soil and soil partly covered with a stratum of banana plant residues allowing individuals to hide periodically. The tracking of individuals within these ground types was achieved by infrared light, tagging individuals, video treatments, and semi‐automatic cleaning of trajectories. We tested different procedures to obtain segments with identical durations to quantify speeds and sinuosities. These procedures were characterized by the junction time gap between trajectory fragments, the rediscretization time of trajectories, and whether or not to use interpolation to fill in missing points in the trajectories. Earwigs exhibited significantly slower and more sinuous movements on soil with banana plant residues than on bare soil. Long time gaps for trajectory junction, extended rediscretization times, and interpolation were complementary means to integrate concealed movements in the trajectories. The highest slowdown in plant residues was detected when the procedure could account for longer periods under the residues. These results suggest that earwigs spent a significant amount of time concealed by the residues. Additionally, the residues strongly decreased the earwigs'' movement. Since the technical solutions presented in this study are inexpensive, easy to set up, and replicate, they represent valuable contributions to the emerging field of video monitoring.     

Field observations and feeding experiments on the responses of rufous-tailed jacamars (Galbula ruficauda) to free-flying butterflies in a tropical rainforest

Wild rufous-tailed jacamars (Galbula ruficauda) were shown to prey frequently, but selectively, upon butterflies in a Costa Rican rainforest. Two individually caged birds (a male and a female) were further tested with over 1000 butterflies of 114 morphs. Both wild jacamars and the two captive individuals were able to capture and handle all kinds and sizes of local butterflies. These butterflies (and other winged insects) were recognized by the jacamars as prey only through their movement. The captive birds discriminated between an unacceptable group of butterflies, which generally fly slowly or regularly, are warningly coloured and mimetic, with transparent, or white, orange, red, and/or black coloration, and an acceptable group that generally fly fast or erratically, are cryptic (on one or both sides), and have yellow, orange, green, blue, and/or brown coloration. These different morphological and behavioural characteristics of butterflies presumably helped the jacamars to assess their palatability. Most individuals of unacceptable butterflies (e.g. Battus and Parides (Papilionidae), some Pieridae, Diaethria and Callicore (Nymphalinae), Heliconiinae, Acraeinae, Ithomiidae, and Danaidae) were sight-rejected by the male jacamar (Jacamar 2), and many of the same were also sight-rejected by the female (Jacamar 1). In cases when the above butterflies were attacked, they were quickly released and usually unharmed. The captive female bird, after long periods without food, consumed many pierid and heliconiine butterflies that were consistently rejected by the male for their distasteful and dangerous qualities. In contrast, palatable butterflies (e.g. Papilio, Charaxinae, most Nymphalinae, Morpho, Brassolinae, and Satyrinae) were usually quickly attacked and consumed. The captive jacamars were able to discriminate between the very similar colour patterns of some Batesian mimics and their models, and could memorize the palatability of a large variety of butterflies. The discriminatory abilities of specialized insectivorous birds such as jacamars are likely to play a major role in the evolution of neotropical butterfly mimicry.