ABSTRACT
The bony notch on the inferior border of the mandible, anterior to the attachment of the masseter muscle, where the facial vessels commonly pass, has been called different names in the literature, e.g., premasseteric notch, antegonial notch, and notch for the facial vessels. Interestingly, various disciplines have leaned toward different names for this notch. Therefore, to aid in consistent communication among professionals, the present study aimed to analyze usage of these varied terms and make recommendations for the best terminology. Based on the adjacent anatomical structures used to name this notch, three groups were analyzed in this study, a group using masseter in the term, a group using gonion in the term, and a group using facial vessels in the term. A literature search found that the group using gonion in the term was found most in the literature.The orthodontics field used gonion in the term the most (29.0%: 31/107) followed by the oral and maxillofacial surgery field (14.0%: 15/107), the plastic surgery field (4.7%: 5/107), and the anatomy field (3.7%: 4/107). The dental field used gonion in this term the most (43.9%: 47/107) and the medical field used facial vessels in the term the most (33.3%: 6/18). Based on these results, the use of gonial terms for this notch seems to be preferred.
ABSTRACT
Fibers of the facial muscles occasionally extend, cross the midline, and connect to surrounding structures on the contralateral side, perhaps enabling the mouth to make more delicate movements and generate more facial expressions. This case report describes a variant in which the extended fibers of the mentalis crossed the midline and indicates the relationship of these fibers to the surrounding structures. Some of the deepest fibers of the mentalis descended inferomedially and crossed transversely just below the chin prominence to attach to the periosteum of the mandible on the contralateral side. The variation presented in this study shed light on the interactions of the mentalis with the surrounding muscles.
ABSTRACT
The nerve to the mylohyoid muscle has been well studied but there are no specific anatomical landmarks for identifying it. Therefore, we aimed to identify anatomical landmarks for localizing the nerve to the mylohyoid muscle in the submandibular region. Sixteen sides from eight embalmed Caucasian cadaveric heads were used in this study. The mean age at the time of death of the specimens was 80.3 years. The anterior and posterior bellies of the digastric muscle, submental artery, and mylohyoid muscle were dissected to verify their relationships with the nerve to the mylohyoid muscle. The nerve to the mylohyoid muscle was found medial to the submental artery, lateral to the anterior belly of the digastric muscle, and anterior to the posterior border of the mylohyoid muscle on all sides. Herein, we identified what we term the mylohyoid triangle. This anatomical region can help localize the nerve to the mylohyoid muscle.
ABSTRACT
The nerve to the mylohyoid muscle has been well studied but there are no specific anatomical landmarks for identifying it. Therefore, we aimed to identify anatomical landmarks for localizing the nerve to the mylohyoid muscle in the submandibular region. Sixteen sides from eight embalmed Caucasian cadaveric heads were used in this study. The mean age at the time of death of the specimens was 80.3 years. The anterior and posterior bellies of the digastric muscle, submental artery, and mylohyoid muscle were dissected to verify their relationships with the nerve to the mylohyoid muscle. The nerve to the mylohyoid muscle was found medial to the submental artery, lateral to the anterior belly of the digastric muscle, and anterior to the posterior border of the mylohyoid muscle on all sides. Herein, we identified what we term the mylohyoid triangle. This anatomical region can help localize the nerve to the mylohyoid muscle.
ABSTRACT
The mandibular condyle formation during temporomandibular joint (TMJ) development exhibits endochondral bone formation, and the elongation process is dependent on the normal cartilage proliferation and differentiation. Retinoids are important for maturation of growth-plate chondrocytes, but the identity of their downstream effectors remains unclear. In this study, we carried out a series of studies at the cellular, biochemical, and molecular levels to determine whether, and if so how, retinoid signaling is related to the expression and function of Indian hedgehog (Ihh) in chondrocyte proliferation. First we analyzed the RA receptor (RAR) and Ihh expression pattern in E18 mandibular condyle. <i>RARα<i/> and RARβ</i> mRNA were characterized in the perichondrium around the condyle, whereas <i>RARγ</i> mRNA was expressed in the immature and prehypertrophic chondrocytes and the expression was overlapped with Ihh gene expression. Next we established a high-density culture model of chick cephalic chondrocytes in the prehypertrophic stage. We found that all-trans retinoic acid (RA) induced Ihh mRNA gene expression in this system. The RA pan-antagonist Ro 41-5253 inhibited both endogenous and RA-induced Ihh mRNA in a dose-dependent manner. The Ihh mRNA expression induced by RA required <i>de novo</i> protein synthesis, and was mediated by RARγ. Immunoblots showed that the prehypertrophic chondrocytes contained sizable levels of phosphorylated p38 mitogen-activated protein (MAP) kinase that were time- and dose-dependently increased by the RA treatment. Experimental p38 inhibition led to a severe drop in baseline and RA-stimulated Ihh expression. Exogenous recombinant Ihh stimulated the proliferation of proliferating chondrocytes, whereas RA inhibited the proliferation of these chondrocytes through p38 MAPK. Retinoids appear to play a primary role in controlling both the expression and function of Ihh in prehypertrophic chondrocytes and do so via p38 MAP kinase.