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Sains Malaysiana 50(5)(2021):
1467-1472
http://doi.org/10.17576/jsm-2021-5005-25
Morphologic
Evaluations of Hypoglossal Canal using Cone Beam Computed Tomography
(Penilaian
Morfologi Saluran Hipoglosus menggunakan Tomografi Pemancaran Kon Berkomputer)
ŞUAYİP BURAK DUMAN1*,
MEHMET SEYREK2, YASİN YAŞA3, İSMAİL
GÜMÜŞSOY4, NUMAN DEDEOĞLU1 &
İBRAHİM ŞEVKİ BAYRAKDAR5
1Department of Oral and Maxillofacial Radiology, Faculty of
Dentistry, Inonu University Malatya, Turkey
2Department of Ortodontics, Faculty of Dentistry, Fırat
University, Elazığ, Turkey
3Department of Dentomaxillofacial Radiology, Faculty of
Dentistry, Ordu University, Ordu, Turkey
4Department of Dentomaxillofacial Radiology, Faculty of
Dentistry, Sakarya University, Sakarya, Turkey
5Department of Dentomaxillofacial Radiology, Faculty of
Dentistry, Eskişehir Osmangazi University, Eskişehir, Turkey
Received: 29 October 2019/Accepted: 6 October 2020
ABSTRACT
Hypoglossal canal (HC) which begins from very slightly above
the inner part of the anterolateral portion of the foramen magnum and is
located above the occipital condyle of the occipital bone. The aim of this
study is to examine HC morphology and variations using cone beam computed
tomography (CBCT). The morphology and types of HC were investigated with
303 CBCT images (606 side). Type 1 variation in 606 HC examined becomes the
most commonly observed type (57.3%) while type 5 variation was the least common
type of variation (0.8%). Type 1 HC was statistically higher in males
(p=0.004). Because of HC, which is an anthropologically important point and
enters the field of images in CBCT scan, it is recommended that dental
radiologists should be aware of their variations and be wary of the pathologies
that may occur in this region.
Keywords:
CBCT; foramen magnum; hypoglossal canal; occipital condyle
ABSTRAK
Saluran hipoglosus (HC) yang bermula di bahagian atas sedikit
pada bahagian dalaman anterosisi foramen magnum dan terletak di atas kondil
oksipital tulang oksipital. Tujuan kajian ini adalah untuk mengkaji morfologi
dan variasi HC menggunakan tomografi pemancar kon berkomputer (CBCT).
Morfologi dan jenis HC dikaji dengan 303 imej CBCT (sisi 606). Variasi jenis 1
pada 606 HC yang disemak menjadi jenis yang paling sering diperhatikan (57.3%)
sementara variasi jenis 5 adalah jenis variasi yang paling jarang (0.8%). HC
Jenis 1 secara statistik lebih tinggi pada lelaki (p = 0.004). Oleh kerana HC,
yang merupakan titik penting antropologi dan memasuki bidang pengimejan dalam
imbasan CBCT, disarankan agar ahli radiologi gigi harus mengetahui variasinya
dan berhati-hati dengan patologi yang mungkin berlaku pada bahagian ini.
Kata kunci:
CBCT; foramen magnum; kondil oksipital; saluran hipoglosus
REFERENCES
Ari, I., Kurt, M., Oygucu, I. & Sendemir, E. 2005. Variations
in the bridging trait of the hypoglossal canal in 13th century Byzantine
skulls. International Journal of
Osteoarchaeology 15(2): 140-145.
Cheverud, J.M. & Buikstra, J.E. 1978. A study of intragroup
biological change induced by social group fission in Macaca mulatta using discrete cranial traits. American Journal of Physical Anthropology 48(1): 41-45.
DeGusta, D., Gilbert, W.H. & Turner, S.P. 1999. Hypoglossal
canal size and hominid speech. In Proceedings
of the National Academy of Sciences. United States National Academy of
Sciences. pp. 1800-1804.
Geist, J.R., Geist, S.R.Y. & Lin, L. 2014. A cone beam CT
investigation of ponticulus posticus and lateralis in children and adolescents. Dentomaxillofacial Radiology 43(5):
1-7.
Hadley, K.S. & Shelton, C. 2004. Infratemporal fossa approach
to the hypoglossal canal: Practical landmarks for elusive anatomy. The Laryngoscope 114(9): 1648-1651.
Hauser, G. & De Stefano, G. 1985. Variations in form of the
hypoglossal canal. American Journal of
Physical Anthropolog 67(1): 7-11.
Jones, F.W. & Wen, I.C. 1934. The development of the external
ear. Journal
of Anatomy 68(4): 525-533.
Kadooka, K., Tanaka, M., Sakata, Y., Ideguchi, M., Inaba, M. &
Hadeishi, H. 2018. Efficacy of cone beam computed tomography in treating
cavernous sinus dural arteriovenous fistula. World Neurosurgery 109: 328-332.
Kanda, T., Kiritoshi, T., Osawa, M., Toyoda, K., Oba, H., Kotoku,
J., Kitajima, K. & Furui, S. 2015. The incidence of double hypoglossal
canal in Japanese: Evaluation with multislice computed tomography. PLoS ONE 10(2): 1-8.
Kay, R.F., Cartmill, M. & Balow, M. 1998. The hypoglossal
canal and the origin of human vocal behavior. Proceedings of the National Academy of Sciences 95(9): 5417-5419.
Kondo, Y., Kiyose, H.,
Hori, Y., Kashiwagi, J., Sagara, Y. & Tanoue, S. 2007. Anterior condylar
vein dural AVF with intraosseous vascular nidus in the hypoglossal canal: A
case report. Journal of Neuroendovascular
Therapy 1: 31-35.
Lang, J. & Hornung, G. 1993. The hypoglossal channel and its
contents in the posterolateral access to the petroclival area. Neurochirurgia 36(3): 75-80.
Mah, J. 2003. 3-Dimensional
Visualization of Impacted Maxillary Cuspids. http://www.aadmrt.com/article-1---2003.html. Accessed on 15 September 2019.
Muthukumar, N., Swaminathan, R., Venkatesh, G. & Bhanumathy,
S. 2005. A morphometric analysis of the foramen magnum region as it relates to
the transcondylar approach. Acta
Neurochirurgica 147(8): 889-895.
Myatt, H., Holland, N. & Cheesman, A. 1998. A skull base
extradural hypoglossal neurilemmoma resected via an extended posterolateral
approach. The Journal of Laryngology
& Otology 112(11): 1052-1057.
Okamura, A., Nakaoka, M., Ohbayashi, N., Yahara, K. & Nabika,
S. 2016. Intraoperative cone-beam computed tomography contributes to avoiding
hypoglossal nerve palsy during transvenous embolization for dural arteriovenous
fistula of the anterior condylar confluence. Interventional Neuroradiolog 22(5): 584-589.
Paraskevas, G.K., Tsitsopoulos, P.P., Papaziogas, B., Kitsoulis,
P., Spanidou, S. & Tsitsopoulos, P. 2009. Osseous variations of the
hypoglossal canal area. Medical Science
Monitor 15(3): 75-83.
Self, S.G. & Leamy, L. 1978. Heritability of quasi-continuous
skeletal traits in a randombred population of house mice. Genetics 88(1): 109-120.
Sjøvold, T. 1984. A report on the heritability of some cranial
measurements and non-metric traits. In Multivariate
Statistical Methods in Physical Anthropology, edited by Van Vark G.N. &
Howells, W.W. Dordrecht: Springer. pp. 223-246.
Standring, S. 2005. Gray's
Anatomy: The Anatomical Basis of Clinical Practice. 39th ed. New York:
Elsevier Churchill Livingstone.
Steenbergen, T.R.V., Geest, I.C.M.V.D, Janssen, D., Rovers, M.M.
& Fütterer, J.J. 2019. Feasibility study of intraoperative cone‐beam
CT navigation for benign bone tumour surgery. The International Journal of Medical Robotics and Computer Assisted
Surgery 15(3): 1-8
Takahata, M., Yamada, K., Akira, I., Endo, T., Sudo, H., Yokoyama,
H. & Iwasaki, N. 2018. A novel technique of cervical pedicle screw
placement with a pilot screw under the guidance of intraoperative 3D imaging
from C-arm cone-beam CT without navigation for safe and accurate insertion. European Spine Journal 27(11):
2754-2762.
Tatagiba, M., Koerbel, A. & Roser, F. 2006. The midline
suboccipital subtonsillar approach to the hypoglossal canal: Surgical anatomy
and clinical application. Acta Neurochirurgica 148(9): 965-969.
Voyvodic, F., Whyte, A. & Slavotinek, J. 1995. The hypoglossal
canal: Normal MR enhancement pattern. American
Journal of Neuroradiology 16(8): 1707-1710.
Williams, P., Warwick, R., Dyson, M. & Bannister, L. 1989. The
individual cranial bones: Occipital bone. In Gray's Anatomy: The Anatomical Basis
of Clinical Practice, edited by Standring, S. London: Elsevier Churchill
Livingstone. pp. 371-373.
*Corresponding author; email: suayipburakduman@gmail.com
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