ライフサイエンスコーパス: electric fish

1 res of the sensorimotor system of the weakly electric fish.

2 nisms underlying shape perception for weakly electric fish.

3 tions in the electrosensory system of weakly electric fish.

4 tor adaptation in the electromotor output of electric fish.

5 y pyramidal cells in the hindbrain of weakly electric fish.

6 , the jamming-avoidance response of a weakly electric fish.

7 ion and cross-innervation in the brown ghost electric fish.

8 ns in the electric organ of the elasmobranch electric fish.

9 r systems of the two families of mormyriform electric fish.

10 ily novel electric organ in both lineages of electric fishes.

11 y active sensing animals, including bats and electric fish, alter the frequency of their emissions to

12 new insights into the evolution of strongly electric fish and showing electric eels to be far more s

13 xists in the electrosensory lobe of mormyrid electric fish and that it has the necessary properties f

14 sensory systems, such as electrolocation in electric fish and the computation of binocular disparity

15 ice forms are equally expressed in muscle in electric fish and zebrafish but Na(v)1.4bL is the domina

16 ns of the dorsal telencephalon of the weakly electric fish Apteronotus leptorhynchus and Gymnotus sp.

17 The gymnotiform weakly electric fish Apteronotus leptorhynchus can capture prey

18 lary electroreceptor afferents of the weakly electric fish Apteronotus leptorhynchus These related sy

19 idbrain electrosensory neurons in the weakly electric fish Apteronotus leptorhynchus to stimuli with

20 t connections of the pituitary in the weakly electric fish Apteronotus leptorhynchus using the in vit

21 ectrosensory stimulus features in the weakly electric fish Apteronotus leptorhynchus While some sourc

22 der or envelope) varied slowly in the weakly electric fish Apteronotus leptorhynchus.

23 ing to perception and behavior in the weakly electric fish Apteronotus leptorhynchus.

24 uccessive stages of processing in the weakly electric fish Apteronotus leptorhynchus.

25 The weakly electric fish, Apteronotus leptorhynchus (Apt), has been

26 in the localization behaviors of the weakly electric fish, Apteronotus leptorhynchus.

27 Mormyrid electric fish are a model system for understanding how n

28 Weakly electric fish are able to resolve intensity differences

29 Purkinje cells in the cerebellum of mormyrid electric fish are characterized by a different architect

30 The electrosensory systems of weakly electric fish are recognized as very tractable model sys

31 nd water displacement stimuli in this weakly electric fish are recorded with multiple semimicroelectr

32 -producing cells of electric organs (EOs) in electric fish, are unique in that they derive from stria

33 by using the electrosensory system in weakly electric fish as a model.

34 from midbrain neurons in the mormyrid weakly electric fish Brienomyrus brachyistius during stimulatio

35 ere we addressed this question in the weakly electric fish Brienomyrus brachyistius, which varies the

36 vation onto electrosensory neurons in weakly electric fish by eliciting endogenous release through el

37 erator, the pacemaker nucleus in gymnotiform electric fish, carrying distinctly different behavioral

38 Mormyrid electric fish communicate by varying the intervals betwe

39 ar to serve as the mechanism by which weakly electric fish couple socially regulated and stress-regul

40 Understanding how electric fish decode the perturbations of their electric

41 The electric organ of electric fish develops from a myogenic lineage.

42 aphical analyses suggest that local mainstem electric fish diversity is enhanced by tributaries.

43 Electric signaling in the weakly electric fish Eigenmannia virescens requires that specia

44 of 27 neurons in the midbrain of the weakly electric fish Eigenmannia were recorded.

45 In the weakly electric fish Eigenmannia, P- and T-type primary afferen

46 to low-pass temporal filtering in the weakly electric fish Eigenmannia.

47 elencephalon (Vv) was examined in the weakly electric fish, Eigenmannia virescens.

48 The JAR of the South American electric fish, Eigenmannia, also occurs in response to s

49 and an independently evolved South American electric fish, Eigenmannia, exhibit nearly identical JAR

50 Many species of electric fish emit sexually dimorphic electrical signals

51 The retina of the weakly electric fish Gnathonemus petersii is a so-called groupe

52 The weakly electric fish Gnathonemus petersii uses its electric sen

53 , that a nonmammalian vertebrate, the weakly electric fish Gnathonemus petersii, is capable of perfor

54 n during object discrimination in the weakly electric fish Gnathonemus petersii.

55 jamming avoidance response (JAR), the weakly electric fish Gymnarchus detects time disparities on the

56 The jamming avoidance response of the weakly electric fish Gymnarchus niloticus relies on determining

57 nsory lateral line lobe (ELL) of the African electric fish, Gymnarchus niloticus, are sensitive to ti

58 osensory lateral line lobe (ELL) of a weakly electric fish, Gymnarchus niloticus, fire an action pote

59 An African wave-type electric fish, Gymnarchus, compares timing on the order

60 tion, are essential for an African wave-type electric fish, Gymnarchus, to perform the jamming avoida

61 Mormyrid electric fish have species- and sex-typical electric org

62 Electric fish image their environments and communicate b

63 nalysis of communication signals in mormyrid electric fishes improved detection of subtle signal vari

64 creasing diversity in communication signals (electric fish), in protection against lethal Nav channel

65 The electrosensory lobe (ELL) of mormyrid electric fish is a cerebellum-like brainstem structure t

66 The cerebellum of mormyrid electric fish is large and unusually regular in its hist

67 The electrosensory lobe (ELL) of mormyrid electric fish is one of several cerebellum-like sensory

68 The electrosensory lobe (ELL) of mormyrid electric fish is the first stage in the central processi

69 The cerebellum of mormyrid electric fish is unusual for its size and for the regula

70 s paper is a scheme that explains how weakly electric fish might identify and classify a target, know

71 gulation of Na(+) current inactivation in an electric fish model in which systematic variation in the

72 Gymnotiform electric fish modulate their electric organ discharges (

73 ously oscillating electroreceptors in weakly electric fish (Mormyridae) respond to electrosensory sti

74 enerated against the intracellular domain of electric fish neurexin were used in immunocytochemical a

75 t a diverse array of endemic taxa, including electric fishes of the order Gymnotiformes.

76 at predation pressure on neotropical, weakly electric fish (order Gymnotiformes) seems to have select

77 In weakly electric fish, previous work suggested a role of ACh, vi

78 In weakly electric fish, probability coding (P-type) electrosensor

79 Gymnotiform weakly electric fish produce electric organ discharges (EODs) t

80 tive regeneration of myogenic tissues in the electric fish S. macrurus.

81 In the electrosensory system of weakly electric fish, single P-type electroreceptor afferents a

82 taries (>2000-kilometer transect) yielded 43 electric fish species.

83 on kinetics of the Na+ current of the weakly electric fish Sternopygus are modified by treatment with

84 The electric organ (EO) of the weakly electric fish Sternopygus macrurus derives from striated

85 uring regeneration of the tail in the weakly electric fish Sternopygus macrurus.

86 are expressed in mature electrocytes of the electric fish Sternopygus.

87 generation of the kilowatt pulses with which electric fish stun their prey-to the quotidian-the acidi

88 In most groups of electric fish, the electric organ (EO) derives from stri

89 of the first-order electrosensory nucleus in electric fish, the electrosensory lateral line lobe, res

90 behavior that is found in a subset of weakly electric fishes, the jamming avoidance response, was use

91 haracterized electrosensory system of weakly electric fish to address how stimulus-dependent burst fi

92 the electrosensory system of mormyrid weakly electric fish to investigate how a population of neurons

93 ation of the electrosensory system of weakly electric fish to shift their tuning properties based on

94 unizing mice with heterologous AChR from the electric fish Torpedo californica, has been used extensi

95 South American weakly electric fish use a self-generated quasi-sinusoidal elec

96 These electric fish use elaborate electrical displays for agon

97 Weakly electric fish use their electric fields to locate object

98 Weakly electric fish use tuberous electroreceptor organs to det

99 ity in two independently evolved lineages of electric fishes was accompanied by convergent changes on