ライフサイエンスコーパス: aqueduct

1 al cells along the ventricular lining of the aqueduct.

2 G from the greater signal variability in the aqueduct.

3 e floor of the fourth ventricle and cerebral aqueduct.

4 morphology, and obliteration of the cerebral aqueduct.

5 locally in the area surrounding the cerebral aqueduct.

6 f the endolymphatic duct/sac, the vestibular aqueduct.

7 cclusion of the third ventricle and cerebral aqueduct.

8 raphe nucleus, just ventral to the cerebral aqueduct.

9 l gray, and in glia surrounding the cerebral aqueduct.

10 from the subependymal layer of the cerebral aqueduct.

11 ing measurements of CSF flow in the cerebral aqueduct.

12 ess frequent close to the final years of the aqueduct.

13 local carbonate removal and repairs in this aqueduct.

14 d serve as the headwaters to the Los Angeles Aqueduct.

15 to the auditory system through the cochlear aqueduct.

16 ocephalus, deregulates Yap in the developing aqueduct.

17 r PVN in rats with open or occluded cerebral aqueducts.

18 tial removal during maintenance work in some aqueducts.

19 In meditators, aqueduct absolute CSF flow motion decreased from MW to F

20 teries, veins, and sinuses and CSF SV in the aqueduct (all P < 0.05).

21 h a total of 39 ears with a large vestibular aqueduct and an otherwise normal cochlea, modiolar defic

22 mice is preceded by stenosis of the Sylvian aqueduct and malformation or absence of the subcommissur

23 for hearing loss with an enlarged vestibular aqueduct and Pendred syndrome.

24 model showed a positive association between aqueduct and perivascular CSF velocity in three regions

25 alculated between CSF velocity curves in the aqueduct and perivascular spaces to assess their relatio

26 lack of ependymal flow causes closure of the aqueduct and subsequent formation of triventricular hydr

27 ic to the subependymal layer of the cerebral aqueduct and third ventricle resides in the structural r

28 CSF velocity was measured in the cerebral aqueduct and three manually segmented perivascular regio

29 d absolute CSF flow and velocity through the aqueduct, and using blood oxygenation level-dependent (B

30 rmal maturation of ependymal cells along the aqueduct are critical for preventing physical blockage b

31 d volumes of human CSF flow within the brain aqueduct as part of the internal ventricular system and

32 icity and regurgitation through the cerebral aqueduct associating with aging and neurodegeneration.

33 led trial (RCT) was designed to evaluate the AQUEDUCT Best Practice Tool and online Resource Kit (RK)

34 drocephalus due to closure of their cerebral aqueduct between embryonic day 18 and post-natal day 5.

35 blockage of CSF flow occurs in the cerebral aqueduct, between the third and fourth ventricles, at em

36 ury BC, considerably later than Rome's first aqueduct built in the late fourth century BC.

37 ected via a bony channel called the cochlear aqueduct, but previous studies have not explored the pos

38 ring observed in analogous coral reef, Roman aqueduct, cave, deep subsurface and hot-spring deposits.

39 rystalline morphologies deposited within the aqueduct channel record the hydraulic history of gravity

40 nd kinematic viscosity within the Anio Novus aqueduct channel, the travertine crystal growth ripple w

41 We assessed net cerebral aqueduct CSF flow and velocity in 29 HD participants (17

42 No aqueduct CSF flow changes were observed in control group

43 my defect, foramen magnum (FM), and cerebral aqueduct CSF flow.

44 y, 8-OH-DPAT delivery through a probe in the aqueduct did not increase REM sleep but rather tended to

45 ing activity and promoted aberrant growth of aqueduct ependymal cells, resulting in aqueduct stenosis

46 ing loss associated with enlarged vestibular aqueduct (EVA), also known as "DFNB4," a large percentag

47 nsyndromic deafness with enlarged vestibular aqueduct (EVA; OMIM #600791).

48 ing loss associated with enlarged vestibular aqueducts (EVA).

49 humans and distinguish it from the cerebral aqueduct, examining its in vivo function during a workin

50 aphy of the travertine within the Anio Novus aqueduct, flow velocity and rate have been quantified by

51 ripples indicate that large-scale sustained aqueduct flows scaled directly with the thickness of the

52 uggest that all ears with a large vestibular aqueduct have associated cochlear modiolar deficiencies.

53 yndromic hearing loss and dilated vestibular aqueducts identified three people (15%) with PDS mutatio

54 s) comprised 16 ears with a large vestibular aqueduct in 10 patients, and group D (1-mm section thick

55 s) comprised 23 ears with a large vestibular aqueduct in 12 patients.

56 ear by dispersive transport via the cochlear aqueduct in adult mice.

57 Here, we showed that the cochlear aqueduct in mice exhibits lymphatic-like characteristics

58 side of the midbrain ventral to the cerebral aqueduct in the central gray matter.

59 The cerebral aqueducts in Rnd3-null mice were partially or completely

60 inspiration was seen in all subjects at the aqueduct, in 11/12 subjects at thoracic level 2, and in

61 this new state, a functional water channel (aqueduct) is formed from the active site to a water clus

62 Thus, a large vestibular aqueduct may be only occasionally, if ever, an isolated

63 access to the internal sites by a transient aqueduct mechanism, migrating as single-file water chain

64 repeated bolus injections into the cerebral aqueduct of an antisense oligonucleotide against the alp

65 he early hydraulic history of the Anio Novus aqueduct of ancient Rome.

66 intenance in carbonate deposits of the Roman aqueduct of Divona (Cahors, France).

67 first to third ventricles, flow through the aqueduct of Sylvius en route to the fourth ventricle, ci

68 O) is a gland located at the entrance of the aqueduct of Sylvius in the brain.

69 ant for cerebrospinal fluid flow through the aqueduct of Sylvius, and resulted in congenital hydrocep

70 S), and CSF SV and flow rate in the cerebral aqueduct of Sylvius.

71 ymal cells line the ventricular surfaces and aqueducts of the brain.

72 an author Frontinus about maintenance of the aqueducts of the city of Rome.

73 PV1-CTF) was identified ventrolateral to the aqueduct on the edge of the PAG.

74 massive infrastructure in the form of dams, aqueducts, pipelines, and complex centralized treatment

75 The PAG region lying near the cerebral aqueduct projects to five lateral PB sites: external lat

76 Carbonate deposits formed in Roman aqueducts provide a window onto the environment and wate

77 dbrain structure that surrounds the cerebral aqueduct, regulates brain-body communication, and is oft

78 At the aqueduct, RHG decreased the absolute CSF flow rate (P =

79 The higher incidence of aqueduct stenosis and hydrocephalus formation in patient

80 ct in folate metabolism can lead to prenatal aqueduct stenosis and resultant hydrocephalus.

81 th of aqueduct ependymal cells, resulting in aqueduct stenosis and the development of congenital hydr

82 nital hydrocephalus, most commonly involving aqueduct stenosis, has been linked to genes that regulat

83 as optic pathway gliomas, dural ectasia and aqueduct stenosis.

84 ing vertically-oriented perforated lamellae, aqueduct structures (vertical lamellar walls with substr

85 normal anatomy (NA) and enlarged vestibular aqueduct syndrome (EVAS) anatomical types was greater th

86 l, circumscribed column ventrolateral to the aqueduct, the prime target of the PV1 nucleus.

87 induce apical flow from the patent cochlear aqueduct to the canalostomy due to influx of cerebral sp

88 inuses and CSF stroke volume at the cerebral aqueduct were positively correlated with each other duri

89 of cerebrospinal fluid through the cerebral aqueduct, which we term as 'ependymal flow'.

90 of lateral, third, and fourth ventricles and aqueduct), with some accumulation at the lateral ventric