ライフサイエンスコーパス: ear canal

1 cochlear nucleus following occlusion of the ear canal.

2 h functions comparable to stimulation in the ear canal.

3 of the middle ear cavity and opening of the ear canal.

4 at the stapes, and as sound pressure in the ear canal.

5 e exposure, and increased after ligating the ear canal.

6 measures of speech recorded in the external ear canal.

7 survey organisms present in the human outer ear canal.

8 ransfer function (HRTF) from sound source to ear canal.

9 ion and music privately without blocking the ear canal.

10 lar surface formed by the dorsal wall of the ear canal.

11 citation at the entrance of the guinea pig's ear canal.

12 issions (SOAEs) can often be measured in the ear canal.

13 rms from nearby speakers mix together in our ear canals.

14 dge practically eliminates the effect of the ear-canal air volume interposed between the tympanic mem

15 The tilted eardrum within the ear canal allows it to have a larger area for the same c

16 ination (52.7%), and otoscopy (66.1% for the ear canal and 64.4% for the tympanic membrane).

17 values were lower for otoscopy (72% for the ear canal and 86% for the tympanic membrane), throat and

18 detaching from their location, invading the ear canal and blocking the cristae.

19 reasingly used in headphones that bypass the ear canal and the middle ear.

20 Hearing concerns range from narrow ear canals and cerumen impactions to eustachian tube dys

21 sked to capture pictures and videos of their ear canals and oropharynx with digital videoscopes and t

22 e, lies at a steep angle with respect to the ear canal, and has organized radial and circumferential

23 to developing tumors in the skin, the inner ear canal, and the oral epithelium after 1 year of age.

24 hearing aids generate amplified sound in the ear canal, and they are the standard of care for patient

25 stortion-products that are detectable in the ear canal as distortion-product otoacoustic emissions (D

26 Defects in ear canal development can cause severe hearing loss as s

27 the vertex, with simultaneous recordings of ear canal distortion product otoacoustic emissions.

28 omical feature, a computer simulation of the ear canal, eardrum, and ossicles was developed.

29 anes in each ear and internally via a narrow ear canal (EC) derived from the respiratory tracheal sys

30 ce (usually via pinnae) or internally via an ear canal (EC).

31 middle ear effusion (MEE) samples, external ear canal (EEC) lavages, and nasopharynx (NPH) samples f

32 frequency modulation (FM) cues measured with ear canal EEG recordings.

33 We found an optimal configuration using an ear canal electrode and low-frequency (<300 Hz) sinusoid

34 6/Adgrg6 regulates Schwann cell myelination, ear canal formation, and heart development; and GPR126 m

35 s, corresponding mainly to the natural outer ear canal gain.

36 Its ear canal has a fully ossified tubular ectotympanic, a d

37 d sound delivery devices and receiver-in-the-ear-canal hearing aid configuration) to reduce the occlu

38 of 10,000 FE simulations of stapes velocity, ear-canal input impedance, and absorbance, paired with s

39 The ear canal is usually described as an S-shaped funnel.

40 Occlusion of the ear canal led to a rapid decrease in EPSC amplitude thro

41 r results suggest, therefore, that the outer ear canal may serve as a reservoir for normally commensa

42 chlear-generated wave activity by 4 days and ear canal opening by at least 2 weeks.

43 n animals 7 to 14 d prior to eye-opening and ear canal opening, spontaneous activity in both sensory

44 h then slows until PND11, around the time of ear canal opening; subsequently, MGv accelerates growth

45 he mouse auditory cortex (ACX) starts before ear-canal opening (ECO).

46 stnatal day (P)7-P9) and after (P14-P20) the ear canal opens and when circuits are mature (P60-P80).

47 imple as an otoscope to better visualize the ear canal or as complex as a wireless capsule endoscope

48 amic afferents coincides with the opening of ear canal (~P11 in mice) and precedes the later critical

49 ough the air, and internally via a narrowing ear canal running through the leg from an acoustic spira

50 In attempting to classify ear-canal shapes obtained from point clouds digitized fr

51 n) and, through them, introduced 14 types of ear-canal shapes.

52 , middle and inner ear (e.g., short external ear canal, small tympanic membrane, large oval window).

53 and amplitude growth were calculated for an ear canal speaker versus the intracochlear actuator for

54 s (EMREOs), pressure changes recorded in the ear canal that occur in conjunction with simultaneous ey

55 greater than 70% (ranging from 74.5% for the ear canal to 99.7% for hemorrhagic suffusion) for all va

56 Owing to the proximity of the ear canal to the central nervous system, in-ear electrop

57 Sound travels down the ear canal to the eardrum, causing its flexible tympanic

58 ed from microphones placed in each subject's ear canals, which preserved the interaural time and leve

59 s from the relatively stable position of the ear canal with respect to vital organs.