ライフサイエンスコーパス: neuropile

1 ATs) that follow stereotyped pathways in the neuropile.

2 changes in the trajectory of SATs within the neuropile.

3 tion pattern of the lineage tract within the neuropile.

4 restrict the number of branches entering the neuropile.

5 h the glial cell processes that surround the neuropile.

6 cant part of the glial layer surrounding the neuropile.

7 ulate the development of the first olfactory neuropile.

8 s follow a straight radial course toward the neuropile.

9 letely explained by dilution in an expanding neuropile.

10 acts for each of the components of the brain neuropile.

11 lia to proper destinations in the optic lobe neuropiles.

12 Olfactory neuropiles across different phyla organize into glomerul

13 Neuropile glia ensheath the neuropile and form septa within the neuropile that defin

14 that tends to reduce the total volume of the neuropile and hence the volume of the inclusions in it.

15 tudies on the functional architecture of the neuropile and the identification of candiate circuit ele

16 ith connective tissues, glia, blood vessels, neuropile, and areas with intercellular spaces), 4-190 m

17 the trajectory of the axon bundles into the neuropile, and the relationship of these bundles to the

18 life, develops into the prominent optic lobe neuropiles, and the larval photoreceptor (Bolwig's organ

19 n the "rudiments" of many parts of the adult neuropile are readily identifiable, it was possible to a

20 First, segmental neuropiles are established which then become connected b

21 found in peripheral nerves and connectives: neuropile areas were stained weakly or unstained.

22 Neuropile-associated glial cells arise from a cluster lo

23 travel parallel to each other and reach the neuropile at similar positions.

24 glial cell precursors in relationship to the neuropile, brain surface, and peripheral nerves.

25 val brain, appear very late in the embryonic neuropile, clearly after the compartments themselves hav

26 cation of the lineage within the cortex, the neuropile compartment contacted by the lineage tract, an

27 oblasts and their lineages to the individual neuropile compartments and long axon tracts introduced i

28 ial cells, we have analyzed the formation of neuropile compartments and their relationship to neurobl

29 The map further shows the growth of neuropile compartments at specific locations around the

30 ocesses formed by glial cells, establish the neuropile compartments of the larval brain.

31 te embryonic stages form a sheath around all neuropile compartments, including the supraesophageal co

32 Neuropile compartments, representing easily identifiable

33 e of the PD type, are restricted to distinct neuropile compartments.

34 specifies the location and initial shape of neuropile compartments.

35 ta within the neuropile that define distinct neuropile compartments.

36 The core of each neuropile component is formed by numerous axon fascicles

37 f the embryonic pioneer tracts to definitive neuropile components, including the median bundle, anten

38 increased amount of branching of SATs at the neuropile-cortex boundary, as well as subtle changes in

39 ment of neuronal cell bodies relative to the neuropile differs among species and brain areas.

40 neurite branching and synapses; they are the neuropile domains in which signal processing takes place

41 he correct time, to enable axon guidance and neuropile formation.

42 main (primary) branches that grow around the neuropile, forming a perineuropilar tracheal plexus (PNP

43 Neuropile glia ensheath the neuropile and form septa wit

44 ation, the range of functions for cortex and neuropile glia is less well understood.

45 r to visualize the association of cortex and neuropile glia with axon tracts formed by different brai

46 en identified including surface, cortex, and neuropile glia.

47 ract with a characteristic trajectory in the neuropile; groups of spatially related tracts congregate

48 , six to ten tracheal branches penetrate the neuropile in a variable pattern.

49 rossing gaps, implicating this central brain neuropile in the visual control of goal-directed behavio

50 urface, cortical cell body layer, and cortex-neuropile interface.

51 d glial cells, we show that the early larval neuropile is subdivided by glial sheaths into numerous c

52 dy glia), and an inner layer surrounding the neuropile (longitudinal glia, midline glia, nerve root g

53 The neuropile of the Drosophila brain is subdivided into ana

54 have analyzed the architecture of the brain neuropile of the Drosophila larva, which is formed by tw

55 a subset of central neurons that pioneer the neuropile of the larval brain.

56 The neuropile of the late embryonic Drosophila brain can be

57 f the thoracic ganglia, and ventral part and neuropiles of the abdominal ganglia.

58 itry of the lobula--one of the four, primary neuropiles of the fly optic lobe--performs this visual d

59 from serial-section TEM (ssTEM) of the optic neuropiles of the miniature parasitic wasp Trichogramma

60 including the brain, the midline region and neuropiles of the thoracic ganglia, and ventral part and

61 y in primary neurons (located closest to the neuropile), others in early secondary neurons (near the

62 hese bundles to the early-formed scaffold of neuropile pioneer tracts.

63 While entering and traversing the brain neuropile, SATs interact in a characteristic way with gl

64 entral ipsilateral half of the corresponding neuropile segment and do not project to the brain.

65 perineuropilar tracheal plexus (PNP) at the neuropile surface.

66 eath the neuropile and form septa within the neuropile that define distinct neuropile compartments.

67 tracts form a scaffold of connections in the neuropile that foreshadows adult nerve connections.

68 t into the CNS; their projections within the neuropile; the pattern, extent, and orientation of their

69 Within the neuropile, tracts of neighboring lineages bundle togethe

70 r of secondary branches entering the central neuropile was increased.

71 oints are arranged concentrically around the neuropile, with the DE-cadherin-positive neuroblasts and

72 minantly located in the synapse-rich central neuropile zone but are rare in the cell body zone.