Prenatal development of the human mandible

Lee, Suk Keun; Kim, So Hyun; Oh, Hee Soo; Yang, Kyu Ho; Kim, Eun Cheol; G., Je

doi:10.1002/ar.1110

Cited by 117 publications

(113 citation statements)

References 36 publications

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“…The mandibular growth pattern is characterized by intramembranous ossification of the mandibular body and endochondral ossification of the condyle (Lee et al, 2001). The mammalian mandible is a complex morphological structure consisting of multiple morphogenetic components that form the final structure (Atchley, 1993).…”

Section: Discussionmentioning

confidence: 99%

Mathematical Analysis of Mandibular Morphogenesis by Micro‐CT‐Based Mouse and Alizarin Red S‐Stained‐Based Human Studies During Development

Rafiq

Udagawa

Lundh

et al. 2011

The Anatomical Record

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Prenatal development of the mandible is an important factor in its postnatal function. To examine quantitatively normal and abnormal developmental changes of the mandible, we here evaluated morphological changes in mineralizing mandibles by thin-plate spline (TPS) including bending energy (BE) and Procrustes distance (PD), and by Procrustes analyses including warp analysis, regression analysis, and discriminant function analysis. BE and PD were calculated from lateral views of the mandibles of mice or of human fetuses using scanned micro-computed tomography (CT) images or alizarin red S-stained specimens, respectively. BE and PD were compared (1) between different developmental stages, and further, to detect abnormalities in the data sets and to evaluate the deviation from normal development in mouse fetuses, (2) at embryonic day (E) 18.5 between the normal and deformed mandibles, the latter being caused by suturing the jaw at E15.5, (3) at E15.5 and E18.5 between normal and knockout mutant mice of receptor tyrosine kinaselike orphan receptor (Ror) 2. In mice, BE and PD were large during the prenatal period and small after postnatal day 3, suggesting that the mandibular shape changes rapidly during the prenatal and early postnatal periods. In humans, BE of the mandibles peaked at 16-19 weeks of gestation, suggesting the time-dependent change in the mandibular shape. TPS and Procrustes analyses statistically separated the abnormal mandibles of the sutured or Ror2 mutant mouse fetuses from the normal mandible. These results suggest that TPS and Procrustes analyses are useful for assessing the morphogenesis and deformity of the mandible. Anat Rec, 295:313-327, 2012 The mammalian mandible is a complex morphological structure formed by various morphogenetic components of different embryological origins. These morphogenetic components were assembled during development to form the final structure (Atchley, 1993). The mandible originates from cells of the neural crest that migrate to the first mandibular arch and form the embryonic mesenchyme, which later develops into skeletal, dental, and connective tissues. The mesenchymal cells aggregate and produce condensations before undergoing differentiation to produce the morphogenetic components of the mandible (Atchley and Hall, 1991). The mandible consists of two symmetrical halves (right and left), each formed by a dentary bone with four morphogenetic regions: the mandibular body (ramus) and three processes (coronoid, condylar, and angular).Establishing normative expectations for experimentally induced changes in size and shape will be an important innovation in three-dimensional (3-D) micro-computed tomography (CT)-based morphological assessments, especially in quantifying differences in the values of those parameters between sets of developing mandibles as a primary aim. Nondestructive methods such as micro-magnetic resonance imaging (Pieles et al., 2007) and micro-CT (Johnson et al., 2006;Boughner et al., 2008;Nagase et al., 2008;Parsons et al., 2008;Hallgrimss...

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Section: Discussionmentioning

confidence: 99%

Mathematical Analysis of Mandibular Morphogenesis by Micro‐CT‐Based Mouse and Alizarin Red S‐Stained‐Based Human Studies During Development

Rafiq

Udagawa

Lundh

et al. 2011

The Anatomical Record

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“…In our results, radiographic density level at the MS of the mandible gradually increased from 16 weeks to 28 weeks. Lee et al (2001) suggested that the genioglossus muscle was attached to the connective tissue of Meckel's cartilage in the early stage (12 weeks gestation) and masseter and suprahyoid muscles were not attached in this stage. However, tendon of muscle fiber in human hyoid muscles (digastric and geniohyoid muscles) was inserted into the periosteum and endosteum connective tissue of immature and mature bone at the medial region of the mandible at 28 weeks gestation.…”

Section: Discussionmentioning

confidence: 99%

“…The mandibular symphysis (MS) (Lee et al, 2001) undergoes a different ossification process to that of the mandibular body (Bareggi et al, 1994). In the formation of human mandible, the mental protuberance comes from fibrous cartilage in the syndesmosis and synostosis (Sperber, 2001).…”

mentioning

confidence: 99%

“…In comparison with the MS, the cartilage assists in the formation of the mandibular body via endochondral ossification. Condensed cellular mesenchyme of the condylar blastema is closely associated with the perichondral fibrous tissue of Meckel's cartilage (Lee et al, 2001). The function and development of masticatory muscles affect the development of the human mandible (Bresin et al, 1999;Kiliaridis and Katsaros, 1998;Sato et al, 1994).…”

mentioning

confidence: 99%

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Distribution of Tenascin-C and -X, and Soft X-ray Analysis of the Mandibular Symphysis during Mandible Formation in the Human Fetus

Kurihara

Sato

2004

Okajimas Folia Anat. Jpn.

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Summary: In the development of the human mandible, the process of bone calcification, distribution and expression of tenascin-C and -X in the mental symphyseal region are unknown. The purpose of this study was to determine the distribution of these extracellular matrices in the connective tissue around calcified tissues located on the mental symphyseal region of the human fetus during development through histological and radiographical studies.The radiographic density increased from 16 weeks to 24 weeks gestation in all examined regions; in contrast, the diameter of muscle fiber in the suprahyoid muscles (digastric anterior and geniohyoid muscles) inserted into the inner mental symphyseal region increased from 24 weeks gestation. The extracellular matrices (tenascin) were shown to have a different distribution in the mental symphyseal region of the human fetus at each stage. These different distributions of tenascin-C and -X were found around the epithelium and the endomysium of the mental symphyseal region, and affect the specific formation of the mandible during ossification with hyoid muscle development in human fetus.

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“…Since amputated urodele limbs know how to do this, unraveling how they of the first pharyngeal arch at 5-6 weeks post-conception. 72,73 Ossification begins at each side of the mandible in the region of the bifurcation of the inferior alveolar nerve and artery into mental and incisive branches. The ossification spreads upwards, dorsally and ventrally to form a trough for the developing teeth, the body and the ramus of the mandibles, respectively.…”

Section: Radiograms Of Control (A B A' and B') And Ra-treated (Cmentioning

confidence: 99%