The Eustachian tube is a small canal that connects the tympanic cavity with the nasal part of the pharynx. The epithelial lining of the Eustachian tube contains a ciliated columnar epithelium at the tympanic cavity and a pseudostratified, ciliated columnar epithelium with goblet cells near the pharynx. The tube serves to equalize air pressure across the eardrum and drains mucus away from the middle ear into the nasopharynx. Blockage of the Eustachian tube is the most common cause of all forms of otitis media, which is common in children. In the present study, we examined the epithelial lining of the Eustachian tube in neonatal and adult gerbils, with a focus on the morphological and functional development of ciliated cells in the mucosa. The length of the tube is ~8.8 mm in adult gerbils. Scanning electron microscopy showed that the mucosal member near the pharyngeal side contains a higher density of ciliated cells and goblet cells than that near the tympanic side. The cilia beat frequency is 11 Hz. During development, the length of the Eustachian tube increased significantly between postnatal day 1 (P1) and P18. Scanning electron microscopy showed that the mucosa contained a high density of ciliated cells with a few goblet cells at P1. The density of ciliated cells decreased while the density of goblet cells increased during development. At P18, the mucosa appeared to be adult-like. Interestingly, the ciliary beat frequency measured from ciliated cells at P1 was not statistically different from that measured from adult animals. Our study suggests that the Eustachian tube undergoes significant anatomical and histological changes between P1 and P18. The tube is morphologically and functionally mature at P18, when the auditory function (sensitivity and frequency selectivity) is mature in this species.
References
[1]
Bluestone CD (2005) Eustachian Tube: Structure, Function, and Role in Otitis Media. Hamilton; Lewiston, NY: BC Decker, 219 p.
[2]
Cunsolo E, Marchioni D, Leo G, Incorvaia C, Presutti L (2010) Functional anatomy of the Eustachian tube. Int J Immunopathol Pharmacol 23 (Suppl): 4–7.
[3]
Lim DJ, Anniko M (1985) Developmental morphology of the mouse inner ear. A scanning electron microscopic observation. Acta Otolaryngol Suppl 422: 1–69.
[4]
Huangfu M, Saunders JC (1983) Auditory development in the mouse: structural maturation of the middle ear. J Morphol 176: 249–259.
[5]
Wake M, Smallman LA (1992) Ciliary beat frequency of nasal and middle ear mucosa in children with otitis media with effusion. Clin Otolaryngol Allied Sci 17: 155–157.
[6]
Jia SP, He DZ (2005) Motility-associated hair bundle motion of outer hair cells. Nature Neurosci 8: 1028–1034.
[7]
Jia S, Zhang X, He DZ, Segal M, Berro A, et al. (2011) Expression and function of a novel variant of estrogen receptor-α36 in murine airways. Am J Respir Cell Mol Biol 45: 1084–1089.
[8]
Cohen YE, Bacon CK, Saunders JC (1992) Middle ear development. III: Morphometric changes in the conducting apparatus of the Mongolian gerbil. Hear Res 62: 187–193.
[9]
Woolf NK, Ryan AF (1984) The development of auditory function in the cochlea of the mongolian gerbil. Hear Res 13: 277–283.
[10]
McGuirt JP, Schmiedt RA, Schulte BA (1995) Development of cochlear potentials in the neonatal gerbil. Hear Res 84: 52–60.
[11]
Overstreet EH 3rd, Richter CP, Temchin AN, Cheatham MA, Ruggero MA (2003) High-frequency sensitivity of the mature gerbil cochlea and its development. Audiol Neurootol 8: 19–27.
[12]
Woolf NK, Ryan AF (1988) Contributions of the middle ear to the development of function in the cochlea. Hear Res 35: 131–142.
[13]
Lim DJ (1976) Functional morphology of the mucosa of the middle ear and Eustachian tube. Ann Otol Rhinol Laryngol 85 (2 Suppl 25 Pt 2)36–43.
[14]
Harada Y (1977) Scanning electron microscopic study on the distribution of epithelial cells in the Eustachian tube. Acta Otolaryngol 83: 284–290.
[15]
Daniel HJ 3rd, Fulghum RS, Brinn JE, Barrett KA (1982) Comparative anatomy of eustachian tube and middle ear cavity in animal models for otitis media. Ann Otol Rhinol Laryngol 91: 82–89.
[16]
Albiin N, Hellstr?m S, Stenfors LE, Cerne A (1986) Middle ear mucosa in rats and humans. Ann Otol Rhinol Laryngol Suppl 126: 2–15.
[17]
Watanuki K, Tanaka K, Kawamoto K (1975) Cell renewal in the eustachian tube epithelium of guinea pigs. Arch Otorhinolaryngol 211: 65–68.
[18]
Lim DJ, Paparella MM, Kimura RS (1967) Ultrastructure of the eustachian tube and middle ear mucosa in the guinea pig. Acta Otolaryngol (Stockh) 63: 425–444.
[19]
Maeda S, Mogi G, Oh M (1976) Fine structures of the normal mucosa in developing rat middle ear. Ann Otol Rhinol Laryngol 85 (Suppl 31)1–19.
[20]
Park K, Lim DJ (1992) Development of the mucociliary system in the Eustachian tube and middle ear: Murine model. Ynsei Medical J 33: 64–71.
[21]
Honjo I, Hayashi M, Ito S, Takahashi H (1985) Pumping and clearance function of the eustachian tube. Am J Otolaryngol 6: 241–244.
[22]
Morris LM, DeGagne JM, Kempton JB, Hausman F, Trune DR (2012) Mouse middle ear ion homeostasis channels and intercellular junctions. PLoS One 7(6): e39004 doi:10.1371/journal.pone.0039004.
[23]
Ohashi Y, Nakai Y, Kihara S (1985) Ciliary activity of the middle ear lining in guinea pigs. Ann Otol Rhinol Laryngol 94: 419–423.
[24]
Roth Y, Ostfeld E (1984) Ciliary beat frequency of human middle-ear mucosa measured in vitro. J Laryngol Otol 98: 853–856.
[25]
Gurr A, Stark T, Pearson M, Borkowski G, Dazert S (2009) The ciliary beat frequency of middle ear mucosa in children with chronic secretory otitis media. Eur Arch Otorhinolaryngol 266: 1865–1870.
[26]
Sutto Z, Conner GE, Salathe M (2004) Regulation of human airway ciliary beat frequency by intracellular pH. J Physiol 560: 519–32.
[27]
Clary-Meinesz CF, Cosson J, Huitorel P, Blaive B (1992) Temperature effect on the ciliary beat frequency of human nasal and tracheal ciliated cells. Biol Cell 76: 335–8.
[28]
Salathe M (2007) Regulation of mammalian ciliary beating. Annu Rev Physiol 69: 401–22.
[29]
Chilvers MA, O'Callaghan C (2000) Analysis of ciliary beat pattern and beat frequency using digital high speed imaging: comparison with the photomultiplier and photodiode methods. Thorax 55: 314–317.
[30]
Dimova S, Maes F, Brewster M, Jorissen M, Noppe M, et al. (2005) High-speed digital imaging method for ciliary beat frequency measurement. J Pharm Pharmacol 57: 521–526.
[31]
Kim W, Han TH, Kim HJ, Park MY, Kim KS, et al. (2011) An automated measurement of ciliary beating frequency using a combined optical flow and peak detection. Healthc Inform Res 17: 111–119.
[32]
Oldenburg AL, Chhetri RK, Hill DB, Button B (2012) Monitoring airway mucus flow and ciliary activity with optical coherence tomography. Biomed Opt Express 3: 1978–92.
