ライフサイエンスコーパス: amphibious

1 the endemic moth genus Hyposmocoma are truly amphibious.

2 Many species are aquatic; perhaps most are amphibious.

3 ene-to-Recent proboscideans are derived from amphibious ancestors.

4 h major mammalian aquatic lineage and infers amphibious ancestries of echidnas, moles, hyraxes, and e

5 e for which a skeleton was known was clearly amphibious and lived in coastal environments.

6 ating such evolutionary novelty because this amphibious ecology is unknown anywhere else.

7 i in the lungs of the American alligator, an amphibious ectotherm without air sacs, which suggests th

8 However, modern horseshoe crabs undertake amphibious excursions onto land to reproduce [12], rende

9 arwater and petrel relatives, despite having amphibious eyes(2), and an a priori mass advantage for o

10 verage mudskippers (Oxudercinae), a clade of amphibious fishes that have convergently evolved blinkin

11 Mudskippers are amphibious fishes that have developed morphological and

12 the animal transforms from an aquatic to an amphibious form.

13 whose primitive skeleton indicates possible amphibious habits.

14 by the opposing selective pressures of their amphibious habits.

15 Such truly amphibious insects are unrecorded.

16 accular input alone during the transition to amphibious life.

17 ransitions from a strictly terrestrial to an amphibious lifestyle across small mammals (Afrosoricida,

18 indicating that monotremes first evolved an amphibious lifestyle in the Mesozoic, and providing supp

19 89 species of Hyposmocoma reveals that this amphibious lifestyle is an example of parallel evolution

20 ually high photosynthetic capacities through amphibious lifestyles and numerous anatomical convergenc

21 nsight into ecological plasticity, including amphibious lifestyles.

22 erians acquired physiological adaptations to amphibious lives by such regulation of the body fluids.

23 noids in the Cambrian and Ordovician reveals amphibious locomotion in tidal environments and fills a

24 ed robot that can morph its limbs' shape for amphibious locomotion.

25 Aquatic and amphibious mammals face olfactory and thermoregulatory c

26 ized that to cope with aquatic environments, amphibious mammals have expanded their thermoregulatory

27 Inspired by amphibious mammals that use air plastrons for thermal in

28 ndition and (2) evidence for a predominantly amphibious or fossorial mode of life in Pappochelys, whi

29 here are no indications that it was aquatic, amphibious, or unusual with respect to the ecology or be

30 Here we report a magnetically actuated amphibious origami millirobot that integrates capabiliti

31 We anticipate the amphibious origami millirobots can potentially serve as

32 Amphibious plants are adapted to both aerial and aquatic

33 In general, underwater leaves of amphibious plants are devoid of stomata, yet their molec

34 We suggest amphibious refraction and protection from UV irradiation

35 nts when compared with their terrestrial and amphibious relatives.

36 sea snakes, plus eight independently marine, amphibious sea kraits [1].

37 Using the emerging model of the Brassicaceae amphibious species Rorippa aquatica, we lay the foundati

38 the thermoregulatory-olfaction trade-off in amphibious species.

39 system transitions, or the development of an amphibious symbiotic ecosystem.

40 d with gains in thermoregulatory capacity in amphibious taxa sampled from across mammalian phylogenet

41 spectrum from entirely terrestrial, through amphibious, to highly aquatic.

42 he physiological and ecological diversity of amphibious yeasts and their key evolutionary adaptations