An inexpensive, deep-water limnocorral that compensates for wave action

SUMMARY. 1. A large reusable limnocorral is described, suitable for use in water bodies with substantial wave action. The clear plastic enclosure is 1 m in diameter, 25m deep, lightweight (∼50 kg), and inexpensive ($350 U.S.A.).
2. The lower portion of the limnocorral is designed to hang motionless below the water surface, while an expandable floating collar section moves freely up and down with any wave action.
3. Two limnocorrals, equipped with removable sedimentation traps at the bottom, were field tested successfully for 6 weeks in Flathead Lake, Montana, withstanding wave heights up to 1m. Chlorophyll levels and profiles of various physical-chemical parameters measured inside the limnocorrals were comparable to Flathead Lake values.
4. Despite their large size, the limnocorrals are relatively easy to transport, install and retrieve.     

Vision and the foraging technique of Great Cormorants Phalacrocorax carbo: pursuit or close‐quarter foraging?

Predatory diving birds, such as cormorants (Phalacrocoracidae), have been generally regarded as visually guided pursuit foragers. However, due to their poor visual resolution underwater, it has recently been hypothesized that Great Cormorants do not in fact employ a pursuit-dive foraging technique. They appear capable of detecting typical prey only at short distances, and primarily use a foraging technique in which prey may be detected only at close quarters or flushed from a substratum or hiding place. In birds, visual field parameters, such as the position and extent of the region of binocular vision, and how these are altered by eye movements, appear to be determined primarily by feeding ecology. Therefore, to understand further the feeding technique of Great Cormorants we have determined retinal visual fields and eye movement amplitudes using an ophthalmoscopic reflex technique. We show that visual fields and eye movements in cormorants exhibit close similarity with those of other birds, such as herons (Ardeidae) and hornbills (Bucerotidae), which forage terrestrially typically using a close-quarter prey detection or flushing technique and/or which need to examine items held in the bill before ingestion. We argue that this visual field topography and associated eye movements is a general characteristic of birds whose foraging requires the detection of nearby mobile prey items from within a wide arc around the head, accurate capture of that prey using the bill, and visual examination of the caught prey held in the bill. This supports the idea that cormorants, although visually guided predators, are not primarily pursuit predators, and that their visual fields exhibit convergence towards a set of characteristics that meet the perceptual challenges of close-quarter prey detection or flush foraging in both aquatic and terrestrial environments.     

Home Range and Movement Rates of Female Exurban White-Tailed Deer

ABSTRACT White-tailed deer (Odocoileus virginianus) thrive in fragmented exurban habitats, resulting in increased occurrences of deer-human conflicts. To develop successful management regimes managers must understand exurban deer ecology, an area deficient in current literature. We investigated exurban white-tailed deer spatial ecology on Fair Hill Natural Resource Management Area in Cecil County, Maryland, USA. From June 2004 to January 2006, we collected 37,384 telemetry locations and 1,194 visual observations on 66 radiocollared female white-tailed deer to investigate seasonal home range sizes, home range fidelity, and hourly movement rates. Annual adaptive-kernel home range size ranged from 8.1 ha to 21.7 ha and 70.9 ha to 144.5 ha among seasons (early, middle, and late-hunting, posthunting, and fawning) at the 50% and 95% utilization distributions, respectively. Seasonal home range size generally increased from the fawning through posthunting seasons. Seasonal home range overlap differed at 50% and 95% utilization distributions, with the least overlap occurring between the posthunting and fawning seasons (50%: x̄ = 19.4%, 95%: x̄ = 33.3%). Circadian activity varied among seasons with dusk movement rates greatest in all seasons. Our results suggest that this exurban white-tailed deer population resided on similar ranges throughout the year, making individuals available for harvest during traditional harvest seasons. To maximize deer—hunter contact, efforts should be focused around the dusk activity period to coincide with peak deer activity.     

Methods for Locating African Lion Kills Using Global Positioning System Movement Data

ABSTRACT Knowledge of the range, behavior, and feeding habits of large carnivores is fundamental to their successful conservation. Traditionally, the best method to obtain feeding data is through continuous observation, which is not always feasible. Reliable automated methods are needed to obtain sample sizes sufficient for statistical inference. Identification of large carnivore kill sites using Global Positioning System (GPS) data is gaining popularity. We assessed performance of generalized linear regression models (GLM) versus classification trees (CT) in a multipredator, multiprey African savanna ecosystem. We applied GLMs and CTs to various combinations of distance-traveled data, cluster durations, and environmental factors to predict occurrence of 234 female African lion (Panthera leo) kill sites from 1,477 investigated GPS clusters. Ratio of distance moved 24 hours before versus 24 hours after a cluster was the most important predictor variable in both GLM and CT analysis. In all cases, GLMs outperformed our cost-complexity-pruned CTs in their discriminative ability to separate kill from nonkill sites. Generalized linear models provided a good framework for kill-site identification that incorporates a hierarchal ordering of cluster investigation and measures to assess trade-offs between classification accuracy and time constraints. Implementation of GLMs within an adaptive sampling framework can considerably increase efficiency of locating kill sites, providing a cost-effective method for increasing sample sizes of kill data.     

Revision of diplectanid monogeneans (Monopisthocotylea, Diplectanidae) in sillaginid fishes, with a description of a new species of Monoplectanum

Five species of diplectanids are described or redescribed on the basis of sclerotised parts, from a survey of 26 species of Sillaginidae in the Indo-west Pacific. Diplectanum sillagonum Tripathi is widespread, and is recorded on Sillago sihama from tropical Australia north to Hong Kong and west to India, as well as on S. vincenti (in India) and S. attenuata (Persian Gulf). Diplectanum blairense Gupta & Khanna infects S. sihama and S. indica and is sympatric with D. sillagonum over some of its range (Hong Kong to India and south to Bali). Diplectanum flagritubus Nagibina is synonymised with D. blairense. Diplectanum puriense Tripathi is redescribed from S. chondropus in western Thailand, but was not found on specimens of its type host, Sillaginopsis panijus from the Bay of Bengal. Monoplectanum youngi sp. n. is described from Sillago analis, S. ciliata, S. sihama, S. parvisquamis, S. lutea and S. attenuata and is more widespread than D. sillagonum , extending into subtropical waters in Australia. Monoplectanum australe Young infects S. maculata and S. burrus , and appears to be endemic to Australia. The diagnosis of Monoplectanum , until now monotypic, is emended, the genus is unlikely to contain more new species on sillaginid fishes, and its two species probably share a common ancestor with D. blairense. Parasitological evidence favours a close relationship between Sillaginidae and Sciaenidae.