ライフサイエンスコーパス: tympanic

1 1.27), oral 0.34 degrees C (-0.86 to 1.54), tympanic 0.62 degrees C (-0.40 to 1.64) and mode not sta

2 Clinical examination revealed a distended tympanic abdomen with generalized tenderness but no evid

3 Trans-tympanic administration of the A1AR agonist R-phenylisop

4 na, mediolateral abbreviation of the lateral tympanic, and a shortened, trapezoidal basioccipital ele

5 ed that it showed evidence of this stylohyal-tympanic articulation, from which they concluded that O.

6 d a reduction in the epithelial cells on the tympanic aspect.

7 that supports the throat and larynx) and the tympanic bone, which forms the floor of the middle ear.

8 helium is terminally differentiated, whereas tympanic border cells (TBCs) beneath the sensory epithel

9 se of temperature measurement with the oral, tympanic (both core and oral equivalence modes were used

10 on of the limbic cortex against the adjacent tympanic bulla and subsequent neuronal cytoskeletal coll

11 measure the vibrational dynamics between the tympanic bullae and the skull.

12 ly showed amplification of vibrations at the tympanic bullae compared to the base of the skull, demon

13 olesteatoma according to its location in the tympanic cavity (T); extension into the mastoid (M); and

14 omica cranial nerve VII was accessed via the tympanic cavity and injected with dextran coupled to Tex

15 unctional properties of the ossicles and the tympanic cavity and make comparisons with recent and ext

16 d Neandertals, leading to differences in the tympanic cavity and, consequently, the shape and spatial

17 icles (malleus, incus, stapes) housed in the tympanic cavity of the temporal bone play an important r

18 ); tympanic oral, x = 36.80 (SD = 0.93); and tympanic core, x = 37.12 (SD = 1.0).

19 ee methods (oral-PA core, -0.15 [SD = 0.36]; tympanic core-PA core, -0.11 [SD = 0.57], tympanic oral-

20 Therefore, trans-tympanic delivery of A1AR agonists could effectively tre

21 Among these, the evolution of a tympanic ear contributed to mitigating the problem of an

22 ogical data to evaluate the evolution of the tympanic ear in reptiles from two complementary perspect

23 g studies advocated that similarities in the tympanic ear of tetrapods could only result from a singl

24 acoustic perception in arthropods that lack tympanic ears (e.g., spiders) [2].

25 Trans-tympanic electrocochleography (ECochG) showed prolonged

26 within the catchment area and presented with tympanic (>/=38.0 degrees C) or axillary temperature (>/

27 Some have suggested that tympanic hearing evolved independently in each major lin

28 current paradigm of multiple acquisitions of tympanic hearing in living reptiles.

29 Mammals and diapsids evolved tympanic hearing independently, and local optima can be

30 )(6) but it remains uncertain how many times tympanic hearing originated in crown reptiles.(9)(,)(10)

31 chlear adenosine A1 receptor (A1AR) by trans-tympanic injections of the agonist R-phenylisopropyladen

32 surface of the middle ear is composed of the tympanic membrane (TM) and the middle ear mucosa (MEM).

33 The tympanic membrane (TM) is critical for hearing and requi

34 Tympanic membrane (TM) perforation, in particular chroni

35 oid the systemic treatment side-effects, the tympanic membrane (TM) represents an impenetrable barrie

36 Lateralized changes in tympanic membrane (TM) temperature were assessed in chim

37 on of MEE as well as biofilm adherent to the tympanic membrane (TM) was longitudinally assessed as OM

38 he placement of a small drainage tube in the tympanic membrane (TM), is the most common surgical proc

39 ly, or locally after opening the impermeable tympanic membrane (TM).

40 ars, the size of the input areas of both the tympanic membrane and the columella footplate of the mid

41 ear-canal air volume interposed between the tympanic membrane and the tip of the measuring tube.

42 Retracted tympanic membrane and tympanic sclerosis were more commo

43 of early reptiles point to the presence of a tympanic membrane as the ancestral condition of the crow

44 es examined diagnosis; otoscopic findings of tympanic membrane bulging (positive likelihood ratio, 51

45 The tympanic membrane in mammals is a trilaminar structure f

46 itis media unlikely whereas a distinctly red tympanic membrane increases the likelihood significantly

47 ard growth of the squamous epithelium of the tympanic membrane into the middle ear, can also occur.

48 A distinctly red tympanic membrane is also helpful (adjusted LR, 8.4; 95%

49 CSOM occurs when perforation of the tympanic membrane is associated with severe or persisten

50 Identifying an effusion through the tympanic membrane is critical to diagnostic success but

51 bias, a cloudy, bulging, or clearly immobile tympanic membrane is most helpful for detecting AOM.

52 as well as a Brighton grading of II or III (tympanic membrane obscure but without systemic illness).

53 ly immobile (adjusted LR, 31; 95% CI, 26-37) tympanic membrane on pneumatic otoscopy are the most use

54 or persistent disease, surgery to repair the tympanic membrane or remove cholesteatoma might offer lo

55 Tympanic membrane perforation (TMP) was identified as 2

56 ung injury was identified in one patient and tympanic membrane perforation in seven patients, as the

57 Tympanic membrane perforation/otorrhea rates gradually i

58 Although tympanic membrane perforation/otorrhea rates steadily in

59 method for noninvasive ICP monitoring using tympanic membrane pulsation (TMp).

60 Tympanic membrane rupture (TMR) effectively deafens a ra

61 vide a basis for understanding the different tympanic membrane structures across species.

62 t it is detached from the mandible and has a tympanic membrane supported by a ring-like ectotympanic.

63 ncertain regions spatially spread out on the tympanic membrane surface.

64 e response to pyrogen, decreasing integrated tympanic membrane temperatures from 7.5+/-2.2 degrees C

65 s that are less reliable such as axillary or tympanic membrane temperatures, noninvasive temporal art

66 the probe tube is sufficiently close to the tympanic membrane to capture the highest frequency of in

67 r canal to the eardrum, causing its flexible tympanic membrane to vibrate.

68 At frequencies above 3 kHz, the tympanic membrane vibrates chaotically.

69 associated acoustic-impedance changes at the tympanic membrane with an acoustic bridge.

70 similarities, including the formation of the tympanic membrane within the second pharyngeal arch, whi

71 s at the tympanal level (one branch for each tympanic membrane), creating two additional narrow inter

72 scopy (72% for the ear canal and 86% for the tympanic membrane), throat and oral examination (72%), a

73 , incus and ectotympanic (which supports the tympanic membrane).

74 y (66.1% for the ear canal and 64.4% for the tympanic membrane).

75 ization of middle ear structures through the tympanic membrane, including the ossicular chain, promon

76 Cerebral cortex, tympanic membrane, inferior vena cava, rectal temperatur

77 r ear (e.g., short external ear canal, small tympanic membrane, large oval window).

78 ates disease in the external auditory canal, tympanic membrane, or middle ear; CT with thin bone algo

79 acteria due to a defect or retraction of the tympanic membrane.

80 imposing different sound velocities for each tympanic membrane.

81 occus pneumoniae (1 x 10(6) CFU) through the tympanic membrane.

82 the acoustic impedance they produced at the tympanic membrane.

83 arch-derived membrane bone that anchors the tympanic membrane.

84 inty in the model outputs (umbo, stapes, and tympanic-membrane displacements).

85 ncreased the risk of perforation with intact tympanic membranes and acute otitis externa (AOE).

86 Perforation of tympanic membranes and middle ear hemorrhage were observ

87 proportions of children with healing of the tympanic membranes by 16 weeks were 15% (10-21) in the d

88 This mechanism also protects the thin tympanic membranes from injury during swallowing of live

89 ammals, sound is received externally via two tympanic membranes in each ear and internally via a narr

90 speaker in free space were delivered to the tympanic membranes of barbiturized cats via sealed and c

91 were resolution of otorrhoea and healing of tympanic membranes on otoscopy by 8, 12, and 16 weeks af

92 to treat self-limited conditions with intact tympanic membranes should consider TMP risk.

93 Tympanic membranes were normal, and hearing loss was con

94 The tympanic membranes were translucent and mobile at pneuma

95 ithelium of the external auditory canals and tympanic membranes.

96 greatest variability is associated with the tympanic method.

97 Most anurans possess a tympanic middle ear (TME) that transmits sound waves to

98 In air, the tympanic middle ear acts as an impedance matcher that in

99 logical data suggest a single origin for the tympanic middle ear in the group, challenging the curren

100 After the transition to life on land, tympanic middle ears emerged separately in different gro

101 =37.5 degrees C axillary or >=38.0 degrees C tympanic) or reporting fever for three consecutive days

102 33 (SD = 0.89); oral, x = 37.18 (SD = 0.92); tympanic oral, x = 36.80 (SD = 0.93); and tympanic core,

103 ]; tympanic core-PA core, -0.11 [SD = 0.57], tympanic oral-PA core, -0.52 [SD = 0.53]), indicating th

104 There were no persistent tympanic perforations and no serious adverse events in t

105 icating that non-specific stimulation of the tympanic plexus, an intervening neural structure with va

106 tem, or pulmonary artery catheter) or manual tympanic recordings.

107 s and malleus) and two membranous bones, the tympanic ring and the gonium, which act as structural co

108 A developmental analysis of the tympanic ring bone, a bone that is always absent in Gsc-

109 However, analysis of the tympanic ring bones of 18.5 d.p.c. chimeras suggests tha

110 Experimental loss of the tympanic ring by retinoic acid treatment, or duplication

111 Gsc-null cells had the capacity to form the tympanic ring condensation in the presence of wild-type

112 The participation of Gsc-null cells in the tympanic ring condensation of chimeras may be an epigene

113 We suggest that the tympanic ring primordium induces formation and morphogen

114 xternal acoustic meatus and formation of the tympanic ring, a first arch-derived membrane bone that a

115 sc is required for development of the entire tympanic ring, the role of Bapx1 is restricted to the sp

116 middle ear-associated bones, the gonium and tympanic ring.

117 isplay hypoplasia of the anterior end of the tympanic ring.

118 specification of the gonium and the anterior tympanic ring.

119 nd hypoplasia of the mandible, otic cup, and tympanic ring.

120 between +0.25 and -1.4 MegaPascal (MPa) for tympanic rupture, +3 and -1 MPa for lung damage, and +20

121 and orbit apex for pressures known to cause tympanic rupture, lung damage, and 50% chance of mortali

122 Retracted tympanic membrane and tympanic sclerosis were more commonly seen among adults.

123 hronic suppurative OM and/or perforations or tympanic sclerosis) and 370 individuals without this phe

124 derived condition associated with changes in tympanic shape and the extent of its contact with the pe

125 splaced proximodistally at values similar to tympanic squamates.

126 Tympanic temperature 10 degrees C (n = 3) was achieved a

127 In the four dogs within protocol, tympanic temperature 10 degrees C was achieved after flu

128 For 90 mins of cardiac arrest (n = 6), tympanic temperature 10 degrees C was achieved after flu

129 induction of profound cerebral hypothermia (tympanic temperature 10 degrees C) by aortic flush of co

130 For 60 mins of cardiac arrest (n = 14), tympanic temperature 20 degrees C (n = 6) was achieved a

131 a venovenous extracorporeal shunt cooling to tympanic temperature 27 degrees C; in group 3 (n = 6, 2

132 bypass, postcardiac arrest mild hypothermia (tympanic temperature 34 degrees C) to 12 hrs, controlled

133 ll dogs were maintained at mild hypothermia (tympanic temperature 34 degrees C) to 12 hrs.

134 group 2 but with mild hypothermia, that is, tympanic temperature 34 degrees C; and in group 4 (n = 5

135 ective of this study was to compare oral and tympanic temperature measurements (in both the oral and

136 ons of up to 90 mins, perhaps 120 mins, at a tympanic temperature of 10 degrees C and complete recove

137 Tympanic temperature of 15 degrees C (n = 5) was achieve

138 with a history of fever within 72 hours or a tympanic temperature of 38.0 C or higher at screening we

139 at 2 degrees C (at a rate of 1 L/min), until tympanic temperature reached 20 degrees C (for 60 mins o

140 nd in combination, on salivary melatonin and tympanic temperature were assessed in humans.

141 ects of environmental variables on skin- and tympanic temperature, but not on heart rate, within a co

142 iac arrest of up to 90 min no-flow at brain (tympanic) temperature of 10 degrees C, with functionally

143 me to train experienced nurses in the use of tympanic thermometry than oral thermometry.

144 t direct TRPV1 activation by localized trans-tympanic (TT) or oral administration of capsaicin (TRPV1