ライフサイエンスコーパス: neural connection

1 y, we evolve neural networks with a cost for neural connections.

2 that are thought to act in concert to shape neural connections.

3 depends on both formation and refinement of neural connections.

4 ly influence the specificity and strength of neural connections.

5 thus enabling the establishment of specific neural connections.

6 ted, and they are important for establishing neural connections.

7 ic system as well as changes in hypothalamic neural connections.

8 both replacement of cells and rebuilding of neural connections.

9 t plays essential roles in the refinement of neural connections.

10 erience is a powerful sculptor of developing neural connections.

11 for understanding the development of complex neural connections.

12 is essential in the refinement of developing neural connections.

13 cipants of sensory-dependent modification of neural connections.

14 tually orchestrates the final arrangement of neural connections.

15 ls could occur based on changes in the local neural connections.

16 ortant for the development and plasticity of neural connections.

17 al experiments were conducted to examine the neural connections and cellular mechanisms of GLP-1R sig

18 lasticity has been described at a variety of neural connections and its signaling has been implicated

19 e role of activity in formation of patterned neural connections and their plasticity.

20 ies on the careful balance of these opposing neural connections, and understanding how this balance i

21 exity and synapse number, and entirely novel neural connections are formed through the process of neu

22 ctively change the rate of learning for each neural connection based on environmental stimuli (e.g. t

23 od-borne Ang II can influence the RVLM via a neural connection between the circumventricular organs a

24 A neural connection between the trigeminal ganglion and th

25 de tract-tracing techniques, we examined the neural connection between this complex and the preoptic

26 The neural connections between coitus and GnRH release invol

27 ape and viewing geometry, although there are neural connections between colour and two-dimensional fo

28 We found that the strength of neural connections between motor cortex and spinal cord

29 extensive sublesional bone loss and disrupts neural connections between the central nervous system (C

30 Here we show that neural connections between the nucleus accumbens and hyp

31 However, direct neural connections between the telencephalic output of t

32 e onset of the critical period, during which neural connections can be altered by visual experience.

33 abel neurons so that detailed morphology and neural connections can be evaluated.

34 oles in learning and memory and in sculpting neural connections during development.

35 nal growth cone, and direct the formation of neural connections during development.

36 atomical changes that support strong learned neural connections early in life can persist even after

37 experiments have led to the expectation that neural connections established during development would

38 us RA (robust nucleus of arcopallium) by its neural connections, expression of glutamate receptors an

39 The demonstration of extant neural connections for high spatial frequencies may have

40 he functional characteristics of these early neural connections have not been assayed.

41 al differentiation and abnormal formation of neural connections; however, the mechanisms underlying t

42 We find that a critical neural connection in Aplysia, which is modified with dif

43 non-invasive probe to diagnose the status of neural connections in other visual deficits.

44 Neural connections in the adult central nervous system a

45 Neural connections in the adult nervous system are estab

46 Our results suggest that neural connections in the amblyopic visual cortex, at le

47 The structural phenotype of neural connections in the auditory brainstem is sculpted

48 ncluding estimation of comprehensive maps of neural connections in the brain ("connectomes").

49 t imaging studies show that the formation of neural connections in the central nervous system is a hi

50 known to be important for the refinement of neural connections in the developing brain.

51 sion through the regeneration of neurons and neural connections in the eye and visual system." An AGI

52 ate in the sensory-dependent modification of neural connections in the visual cortex.

53 tial for the formation of a mature system of neural connections; in some instances, the pattern of ne

54 The existing literature suggests that neural connections, information integration, and conscio

55 nervous system to help refine early sets of neural connections into their highly precise adult patte

56 ntrol the development of the organization of neural connections into topographic maps.

57 effects.SIGNIFICANCE STATEMENT Plasticity of neural connections is important for development, learnin

58 suggest that it may function in establishing neural connections key to vocal learning.

59 similar for each cortical area, specialized neural connections likely mediate unique information pro

60 s whether recovery involves new and aberrant neural connections or whether any change in function is

61 Neural connections, providing the substrate for function

62 strengthening and suppress the weakening of neural connections representing events that fall within

63 l plasticity contribute to the refinement of neural connections that broadly shape brain development.

64 es of reactivations induce a labile state at neural connections that lead to reversal of different ty

65 The olfactory system maintains well-defined neural connections that regenerate throughout life.

66 nes can be required for normally functioning neural connections to form.

67 gest that the brain handles this by reducing neural connections to the previous context and adding co

68 3 of 14 sites remained positive, suggesting neural connections to the PV were disrupted by both PV i

69 protein, we found that efferent bone marrow-neural connections trace to sympathetic centers of the c

70 ional factors; differential vulnerability of neural connection types (e.g., clustered versus distribu

71 f interhemispheric functional and structural neural connection were derived with analyses of voxel mi

72 ctivation could be elicited through a direct neural connection with the AcbSh or secondarily through

73 he deficits are somehow linked to the shared neural connections with the area of brain damage.

74 sist of functional deficits in areas sharing neural connections with the damaged area.

75 The development of peripheral to central neural connections within the auditory, visual, and olfa

76 The hypothalamus maintains both direct neural connections within the brain and it also controls

77 he molecules required for the development of neural connections within the brain.

78 abnormal connectivity in ASD may also affect neural connections within the cortical gray matter.

79 These results suggest that abnormal neural connections within the limbic system may contribu

80 ells and extensive rewiring of the remaining neural connections, yet about 50% of stroke survivors li