The Incudopetrosal Joint of the Human Middle Ear: a Transient Morphology in Fetuses

Overview

Journal J Anat

Specialty Anatomy & Histology

Date 2020 Mar 12

PMID 32159229

Citations 3

Authors

Jose Francisco Rodriguez-Vazquez

Masahito Yamamoto

Ji Hyun Kim

Zhe-Wu Jin

Yukio Katori

Gen Murakami

Affiliations

Soon will be listed here.

Abstract

In spite of the amount of research on fetal development of the human middle ear and ear ossicles, there has been no report showing a joint between the short limb of incus and the otic capsule or petrous part of the temporal bone. According to observations of serial histological sections from 65 embryos and fetuses at 7-17 weeks of development, the incudopetrosal joint exhibited a developmental sequence similar to the other joints of ossicles, with an appearance of an interzone followed by a trilaminar configuration at 7-12 weeks, a joint cavitation at 13-15 weeks and development of intraarticular and capsular ligaments at 16-17 weeks. These processes occurred at the same time or slightly later than any other joint. Thus, the joint development might coordinate with vibrating ossicles in utero. The growing short limb of incus appeared to accelerate an expansion of the epitympanic recess of the tympanic cavity. Additional observations of five late-stage fetuses demonstrated the incudopetrosal joint located in the fossa incudis joint changing to syndesmosis. Consequently, a real joint with a cavity existed transiently between the human neurocranium and the first pharyngeal arch derivative (i.e. incus) in contrast to the tympanostapedial joint or syndesmosis between the neurocranium and the second arch derivative. The newly described joint might have an effect on the widely accepted primary jaw concept: the mammalian jaw should thus have been created within the first pharyngeal arch, although the connection with neurocranium by the stapes is of a different origin.

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The incudopetrosal joint of the human middle ear: a transient morphology in fetuses.

Rodriguez-Vazquez J, Yamamoto M, Kim J, Jin Z, Katori Y, Murakami G J Anat. 2020; 237(1):176-187.

PMID: 32159229 PMC: 7309281. DOI: 10.1111/joa.13181.

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