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  1. Staying hot to fight the heat-high body temperatures accompany a diurnal endothermic lifestyle in the tropics
    Levesque DL, Tuen AA, Lovegrove BG
    J. Comp. Physiol. B, Biochem. Syst. Environ. Physiol., 2018 07;188(4):707-716.
    PMID: 29623412 DOI: 10.1007/s00360-018-1160-7
    Much of our knowledge of the thermoregulation of endotherms has been obtained from species inhabiting cold and temperate climates, our knowledge of the thermoregulatory physiology of tropical endotherms is scarce. We studied the thermoregulatory physiology of a small, tropical mammal, the large treeshrew (Tupaia tana, Order Scandentia) by recording the body temperatures of free-ranging individuals, and by measuring the resting metabolic rates of wild individuals held temporarily in captivity. The amplitude of daily body temperature (~ 4 °C) was higher in treeshrews than in many homeothermic eutherian mammals; a consequence of high active-phase body temperatures (~ 40 °C), and relatively low rest-phase body temperatures (~ 36 °C). We hypothesized that high body temperatures enable T. tana to maintain a suitable gradient between ambient and body temperature to allow for passive heat dissipation, important in high-humidity environments where opportunities for evaporative cooling are rare. Whether this thermoregulatory phenotype is unique to Scandentians, or whether other warm-climate diurnal small mammals share similar thermoregulatory characteristics, is currently unknown.
    Matched MeSH terms: Shrews/physiology*
  2. Different threshold responses in spontaneously changing postagrogenic forest and unmanaged grassland. Shifts in small mammal populations and communities triggered by an extraordinary drought
    Shchipanov NA, Tumasian PA, Kuptsov AV, Raspopova AA, Kasatkin MV, Kalinin AA, et al.
    Environ Monit Assess, 2025 Feb 04;197(3):234.
    PMID: 39903331 DOI: 10.1007/s10661-025-13694-3
    Due to their resilience, various biological systems under environmental changes typically exhibit nonlinear responses with sudden, abrupt shifts. Although such shifts are theoretically expected, few studies traced state-and-transition dynamics in nature (Liu et al., Science 317:1513-1516, 2007). We analysed 18 years' data to trace biomass patterns, species assemblages and small mammals' population trajectories in spontaneously growing forest on formerly ploughed field, hereafter, the postagrogenic forest, and in unmanaged former pasture, hereafter, the grassland. The clear response at individual, populational and ecosystem scales triggered by extraordinary 2010 drought was observed. In the postagrogenic forest, transitioning to the historical ecosystem state, we found a shift from the grassland type of the small mammals' biomass pattern to the forest type with the abrupt reorganisation of the small mammals' community. In the grassland, a relatively steady novel ecosystem, we revealed only a long-term diminishing of total small mammals' biomass, i.e. a regime shift, while maintaining the same functional structure. The changes were based on population response. The bank vole did not show any population reaction, which testifies the ability of individuals to tolerate the drought. The common shrew experienced a population depression, which in postagrogenic forest resulted in the regimen shift after recovery, but in the grassland in only temporal decline with following return to the initial state. The root vole showed a delayed population response with the general decline of population in the grassland, and population collapse in the postagrogenic forest. Therefore, the same impact triggered various responses among different species and resulted in different effects in the successional and steady ecosystems.
    Matched MeSH terms: Shrews/physiology
  3. Fulltext Classification of Suncus murinus species complex (Soricidae: Crocidurinae) in Peninsular Malaysia using image analysis and machine learning approaches
    Abu A, Leow LK, Ramli R, Omar H
    BMC Bioinformatics, 2016 Dec 22;17(Suppl 19):505.
    PMID: 28155645 DOI: 10.1186/s12859-016-1362-5
    BACKGROUND: Taxonomists frequently identify specimen from various populations based on the morphological characteristics and molecular data. This study looks into another invasive process in identification of house shrew (Suncus murinus) using image analysis and machine learning approaches. Thus, an automated identification system is developed to assist and simplify this task. In this study, seven descriptors namely area, convex area, major axis length, minor axis length, perimeter, equivalent diameter and extent which are based on the shape are used as features to represent digital image of skull that consists of dorsal, lateral and jaw views for each specimen. An Artificial Neural Network (ANN) is used as classifier to classify the skulls of S. murinus based on region (northern and southern populations of Peninsular Malaysia) and sex (adult male and female). Thus, specimen classification using Training data set and identification using Testing data set were performed through two stages of ANNs.

    RESULTS: At present, the classifier used has achieved an accuracy of 100% based on skulls' views. Classification and identification to regions and sexes have also attained 72.5%, 87.5% and 80.0% of accuracy for dorsal, lateral, and jaw views, respectively. This results show that the shape characteristic features used are substantial because they can differentiate the specimens based on regions and sexes up to the accuracy of 80% and above. Finally, an application was developed and can be used for the scientific community.

    CONCLUSIONS: This automated system demonstrates the practicability of using computer-assisted systems in providing interesting alternative approach for quick and easy identification of unknown species.

    Matched MeSH terms: Shrews/physiology*
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