ライフサイエンスコーパス: temporal bone

1 structure, and embedded location within the temporal bone.

2 uld reflect covariation with the surrounding temporal bone.

3 mative morphology of the canine, maxilla and temporal bone.

4 c or magnetic resonance imaging study of the temporal bone.

5 of the cochlea, which is embedded within the temporal bone.

6 n intricate structure deeply embedded in the temporal bone.

7 ith measurements reported in patients and in temporal bones.

8 ly decreased in clinical samples of infected temporal bones.

9 al lobe and brain and thin-section CT of the temporal bones.

10 FFPE tissue can be applied to human archival temporal bones.

11 dequacy of acoustic windows in the squama of temporal bones.

12 ure the output characteristics in four human temporal bones.

13 ogies manifesting with distinct radiological temporal bone abnormalities.

14 on stimuli, the vCAP magnitude switches from temporal bone acceleration sensitive to linear jerk sens

15 technique for evaluating cochleas from human temporal bones, an important but understudied area of re

16 ovides a practical approach to understanding temporal bone anatomy, localizing a pathologic process w

17 an essential modality in the imaging of the temporal bone and lateral skull base.

18 second part will first discuss trauma to the temporal bone and posttraumatic complications.

19 CT scan of the temporal bone and surgery were performed in all patients

20 er, due to its location beneath the squamous temporal bone and temporalis muscle, the STG, like other

21 common surgical procedures performed in the temporal bone and their postoperative imaging appearance

22 Observer 1 diagnosed SSCD in 25 of 108 (23%) temporal bones and had no discordances between the two r

23 Observer 2 diagnosed SSCD in 21 of 108 (19%) temporal bones and had one intraobserver discordance.

24 mandibular condyle, the glenoid fossa of the temporal bone, and a fibrocartilagenous disc interposed

25 isease also involves the skull base, palate, temporal bone, and deep neck spaces.

26 MRI imaging of brain and temporal bone are normal.

27 mmatory nonneoplastic entities involving the temporal bone are reviewed.

28 formations from multi-detector row CT of the temporal bone are sufficient for the evaluation of SSCD.

29 occipital bone and non-squamous parts of the temporal bones are mesoderm derived.

30 f the temporal bone discussed anatomy of the temporal bone as well as inflammatory and neoplastic pro

31 n (0.7-mm section thickness) CT image of the temporal bone at a level slightly inferior to that shown

32 n (0.7-mm section thickness) CT image of the temporal bone at the level of the internal auditory cana

33 He initially underwent MRI of the temporal bones at an outside hospital.

34 he archival collection of celloidin-embedded temporal bones at the Massachusetts Eye and Ear.

35 f chondrocytes to osteoblasts in the petrous temporal bone autonomous to paraflocculus/flocculus cell

36 s is important because the majority of human temporal bone banks have specimens preserved in formalin

37 abnormal processes in the paranasal sinuses, temporal bones, base of the skull, and neck.

38 directed toward the facial nerve within the temporal bone by placing a 6.5 cm figure-8 stimulation c

39 These results show that the hominoid temporal bone contains a strong phylogenetic signal and

40 ctions in mean CTDIvol were most notable for temporal bone CT (-56.1%), peripheral runoff CT angiogra

41 up was composed of 50 patients who underwent temporal bone CT for causes unrelated to SNHL.

42 one with 9 years of experience interpreting temporal bone CT images, independently reviewed the 108

43 Temporal bone CT scans with 1.0-mm and/or 0.5-mm collima

44 Temporal bone CT studies obtained before and after a maj

45 d solution for the automated segmentation of temporal bone CT using convolutional neural networks (CN

46 d with both OCT and high-resolution clinical temporal bone CT.

47 The first part of this review of the temporal bone discussed anatomy of the temporal bone as

48 -dimensional landmark data from the hominoid temporal bone effectively quantify the shape of a comple

49 Modelling data from 10 temporal bones enabled definition of a safe trajectory f

50 cted vs. non-affected side) groups geometric temporal bone features (lengths, widths, contours), air

51 Radiological temporal bone features known to be only weakly or incons

52 to determine the prevalence of radiological temporal bone features that in previous studies showed o

53 Temporal bone features with significant intergroup diffe

54 in ( Figs 1 - 4 ) and thin-section CT of the temporal bones ( Figs 5 , 6 ).

55 Within this framework, temporal bones from subjects with ARHL may be classified

56 issure and cerebral sulci greatest) with the temporal bones' greatest internal distance.

57 sinus, or jugular bulb, those of the petrous temporal bone had a higher risk (50%, 36 of 72 fractures

58 siology is largely unknown, studies in human temporal bones have found an accumulation of endolymph i

59 modeling, auditory nerve imaging, and human temporal bone histology are all potential options for va

60 Temporal bone histology in a patient with severe xeroder

61 Medical records and temporal bone images of patients with NTM otomastoiditis

62 ed here now provide a means to analyze human temporal bones in a way that had not previously been fea

63 in-section polytomography, especially of the temporal bone, in 1954.

64 d skulls in which the petrous pyramid of the temporal bone is accessible.

65 ilaginous structure between the mandible and temporal bone, is implicated in temporomandibular disord

66 Because the cochlea is encased in the temporal bone, it can only be accessed from its basal en

67 in close proportion to macular velocity and temporal bone (linear) acceleration, rather than other k

68 50 years; range, 18-87 years), who underwent temporal bone multi-detector row CT for other reasons, w

69 ears) suspected of having SSCD who underwent temporal bone multi-detector row CT were retrospectively

70 stibular endorgans microdissected from human temporal bones obtained at autopsy.

71 The discordance involved the right temporal bone of a patient suspected of having SSCD in t

72 The histological examination of temporal bones of cadaver animals and the intensity of i

73 y associated with fractures of the mandible, temporal bone or other facial bones.

74 In those without temporal bone osteomyelitis, antibiotic treatment can be

75 of pulsatile tinnitus include neoplasms and temporal bone pathologic abnormalities.

76 stapes) housed in the tympanic cavity of the temporal bone play an important role in audition.

77 gery (commonly including radical excision of temporal bone), radiotherapy, and chemotherapy.

78 inflammatory and neoplastic processes in the temporal bone region (1).

79 of an in vitro turtle brainstem in which the temporal bones remained attached.

80 e, hypervascular lesions that arise from the temporal bone retrolabyrinthine region.

81 of inner ear tissues from post-mortem DFNA9 temporal bone samples of an individual from a large Dutc

82 placed by eosinophilic acellular material in temporal bone sections of individuals affected with DFNA

83 By immunohistochemistry on the DFNA9 temporal bone sections, we have shown cochlin staining o

84 patient suspected of having SSCD in the left temporal bone, so no clinical follow-up was available.

85 Human temporal bone specimens are used in experiments measurin

86 hleas from formalin-fixed celloidin-embedded temporal bone specimens of three different types of pati

87 used on 20 serially sectioned archival human temporal bone specimens.

88 Evidence from human temporal bone studies and auditory brainstem response me

89 per unit input and were placed in four human temporal bones to measure their output performances.

90 h these lesions from more common, aggressive temporal bone tumors.

91 ne CT images, independently reviewed the 108 temporal bones twice.

92 f cochlear implantation experience underwent temporal bone UHSR CT and residual hearing assessment.

93 underwent magnetic resonance imaging of the temporal bone using both EPI and non-EPI DWI.

94 l access was validated on 9 additional human temporal bones using radio-opaque markers and contrast i

95 In some animals, the temporal bone was harvested for histologic analysis of c

96 Thin-section computed tomography (CT) of the temporal bone was performed.

97 Sixteen human temporal bones were cut around the cochlea in blocks of

98 Sprague-Dawley rat temporal bones were harvested and decalcified.

99 euroanatomical studies on 10 cadaveric human temporal bones were undertaken to identify a potentially

100 the subarcuate fossa, a part of the petrous temporal bone, which encapsulates the paraflocculus/floc

101 Anatomical analyses of the temporal bone, which is derived in part from the otic me

102 to a subset of patients with an insufficient temporal bone window, improving efficacy in unselected p

103 er of structures and disease entities in the temporal bone with which one must be familiar in order t

104 d guinea pig inner ears were imaged as whole temporal bones with cochlea in situ.

105 thresholds and has been documented in human temporal bones with SNHL.

106 mandibular condyle and glenoid fossa of the temporal bone, with important roles in TMJ functions.