Regular patterns in the size ratio of the cervical vertebral bodies registered by MRI in the axial plane

Andrei S. Moshkin; Мошкин Андрей Сергеевич; Vladimir N. Nikolenko; Николенко Владимир Николаевич; Maksud A. Khalilov; Халилов Максуд Абдуразакович

doi:10.35693/SIM601839

Regular patterns in the size ratio of the cervical vertebral bodies registered by MRI in the axial plane

Authors: Moshkin A.S.¹, Nikolenko V.N.²^,3, Khalilov M.A.³
Affiliations:
1. Orel State University named after I.S. Turgenev
2. Sechenov First Moscow State Medical University
3. Lomonosov Moscow State University
Issue: Vol 9, No 1 (2024)
Pages: 8-13
Section: Human Anatomy
URL: https://ogarev-online.ru/2500-1388/article/view/256860
DOI: https://doi.org/10.35693/SIM601839
ID: 256860

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Abstract

Aim – to find regular patterns in the morphometric characteristics for the bodies of the cervical vertebrae when performing measurements in the axial (transverse) plane in men and women with different severity of degenerative-dystrophic changes of the cervical spine.

Material and methods. The material of the study was the tomograms of 75 men and 128 women aged 18 to 84 years, obtained on magnetic resonance tomographs with a magnetic field strength of 1 Tl and 1.5 Tl. The data was divided into several groups according to the patients' sex and severity of degenerative-dystrophic changes of the cervical spine. The length and width of the vertebral bodies in the axial plane were measured with the subsequent calculation of their ratio.

Results. Significant differences were found between the 1st and 2nd groups for the width of C7-C4 in women, as well as for the length of C3 and width of C3, C2 in men. Significant difference in the ratio of the sizes of vertebral bodies was registered in the 1st and 2nd groups of women at the level of C7. When comparing the data of all observation groups among men, significant differences were noted in the 2nd and 3rd groups for C7, C6, C3. With progression of degenerative-dystrophic changes, the differences in length were significant for C7-C4, C2 vertebrae in the 1st group, for C7-C5, C2 – in the 2nd and C7, C6, C4-C2 in the 3rd group. In the group of men with pronounced changes in the cervical spine region, in most cases there was an increase in coefficients (with significant differences in data for the 2nd and 3rd groups).

Conclusion. Among men, significant differences were observed between the 2nd and 3rd groups for C7, C6, C3. For the C2 vertebra, significant differences were noted, taking into account sex, for length in the 1st and 3rd groups, width – in the 1st and 2nd groups, when assessing the mutual ratio of the sizes of the vertebral bodies – in the 2nd and 3rd groups.

Keywords

cervical spine, morphometry, vertebral bodies

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About the authors

Andrei S. Moshkin

Orel State University named after I.S. Turgenev

Email: as.moshkin@internet.ru
ORCID iD: 0000-0003-2085-0718
SPIN-code: 9718-2516
Scopus Author ID: 37067774100

PhD, Associate professor of the Department of Anatomy, Operative Surgery and Disaster Medicine

Russian Federation, 25 Oktyabrskaya str., Orel, 302028

Vladimir N. Nikolenko

Sechenov First Moscow State Medical University; Lomonosov Moscow State University

Email: vn.nikolenko@yandex.ru
ORCID iD: 0000-0001-9532-9957
SPIN-code: 8257-9084
Scopus Author ID: 14016274500

PhD, Professor, Head of the Department of Human Anatomy and Histology, Head of the Department of the Normal and Topographic Anatomy

Russian Federation, Moscow; Moscow

Maksud A. Khalilov

Lomonosov Moscow State University

Author for correspondence.
Email: halilov.66@mail.ru
ORCID iD: 0000-0003-3529-0557
SPIN-code: 2044-1797
Scopus Author ID: 37067449100

PhD, Professor, Head of the Department of Anatomy, Operative Surgery and Disaster Medicine

Russian Federation, Moscow

References

Abramov AS, Ternovoy SK, Serova NS. Possibilities of the methods or radiation diagnostic in the estimation of cervical spine vertebral-motor segment instability. Modern problems of science and education. 2019;3:184. (In Russ.). [Абрамов А.С., Терновой С.К., Серова Н.С. Возможности рентгеновских методов диагностики в оценке нестабильности позвоночно-двигательных сегментов шейного отдела позвоночника. Современные проблемы науки и образования. 2019;3:184].
Mikhaylov AN, Abelskaya IS, Lukyanenko TN. Modern problems of radiology imaging of the cervical osteochondrosis. Medical news. 2015;7:4-11. (In Russ.). [Михайлов А.Н., Абельская И.С., Лукьяненко Т.Н. Современные проблемы лучевой диагностики шейного остеохондроза. Медицинские новости. 2015;7: 4-11].
Sharmazanova EP, Myagkov SA, Rybak IR. MRI morphometry of vertebral bodies and intervertebral discs of the lumbar spine in patients with impaired bone mineral density. Pain. Joints. Spine. 2015;18(2):71-77. (In Russ.). [Шармазанова Е.П., Мягков С.А., Рыбак И.Р. МРТ-морфометрия тел позвонков и межпозвоночных дисков поясничного отдела позвоночника у больных с нарушением минеральной плотности костной ткани. Боль. Суставы. Позвоночник. 2015;18(2):71-77].
Alekseenko SN, Kostylev AN, Bondina VM, et al. Prevalence of early cervical osteochondrosis in university students and its effect on the adaptive capabilities of the organism. Kuban Scientific Medical Bulletin. 2019;26(1):36-44. (In Russ.). [Алексеенко С.Н., Костылев А.Н., Бондина В.М., и др. Распространенность раннего шейного остеохондроза у студентов в вузе и его влияние на адаптационные возможности организма. Кубанский научный медицинский вестник. 2019;26(1):36-44]. https://doi.org/10.25207/1608-6228-2019-26-1-36-44
Gubin AV, Ulrikh EV, Ryabykh SO, et al. Surgical roadmap for congenital cervical spine abnormalities. The genius of orthopedics. 2017;23(2):147-53. (In Russ.). [Губин А.В., Ульрих Э.В., Рябых С.О., и др. Хирургическая дорожная карта при врожденных аномалиях развития шейного отдела позвоночника. Гений ортопедии. 2017;23(2):147-53]. https://doi.org/10.18019/1028-4427-2017-23-2-147-153
Demyanova LM, Gurkina OV. Osteochondrosis of the cervical spine: Fundamentals of prevention and treatment. Alley of Science. 2018;21(5):334-8. (In Russ.). [Демьянова Л.М., Гуркина О.В. Остеохондроз шейного отдела позвоночника: основы профилактики и лечения. Аллея науки. 2018;21(5):334-8].
Gavrilenko AV, Nikolenko VN, Al-Yusef NN, et al. Correlation between morphological and biomechanical features and carotid atherosclerosis. Science and Innovations in Medicine. 2022;7(3):160-163. (In Russ.) [Гавриленко А.В., Николенко В.Н., Аль-Юсеф Н.Н., и др. Корреляция между морфологическими и биомеханическими особенностями и атеросклерозом сонных артерий. Наука и инновации в медицине. 2022;7(3):160-163]. https://doi.org/10.35693/2500-1388-2022-7-3-160-163
Nikolenko VN, Fomkina OA, Gladilin YuA. The anatomy of intracranial arteries of the vertebrobasilar system. Moscow. I.M. Sechenov First Moscow State Medical University. 2014:108. (In Russ.). [Николенко В.Н., Фомкина О.А., Гладилин Ю.А. Анатомия внутричерепных артерий вертебробазилярной системы. Москва: Первый Московский государственный медицинский университет имени И.М. Сеченова. 2014:108]. ISBN 978-5-7213-0443-9
Nikolenko VN, Fomkina OA. Deformation-strength parameters of arteries of the brain in the II period of mature age. Sechenovsky Bulletin. 2019;10(1):41-46. (In Russ.). [Николенко В.Н., Фомкина О.А. Деформационно-прочностные параметры артерий головного мозга во II периоде зрелого возраста. Сеченовский вестник. 2019;10(1):41-46]. https://doi.org/10.26442/22187332.2019.1.41-46
Nell C, Bülow R, Hosten N, at al. Reference values for the cervical spinal canal and the vertebral bodies by MRI in a general population. PLoS One. 2019;14(9):e0222682. https://doi.org/10.1371/journal.pone.0222682
Chazono M, Tanaka T, Kumagae Y, et al. Ethnic differences in pedicle and bony spinal canal dimensions calculated from computed tomography of the cervical spine: A review of the English-language literature. Eur Spine J. 2012;21(8):1451-8. https://doi.org/10.1007/s00586-012-2295-y
Remes VM, Heinänen MT, Kinnunen JS, Marttinen EJ. Reference values for radiological evaluation of cervical vertebral body shape and spinal canal. Pediatr Radiol. 2000;30(3):190-5. https://doi.org/10.1007/s002470050044
Kirienko AN, Sorokovikov VA, Pozdeeva NA, Alekseeva NV. Degenerative-dystrophic lesions of the cervical spine. Siberian Medical Journal. 2015;7:21-26. (In Russ.). [Кириенко А.Н., Сороковиков В.А., Поздеева Н.А. Дегенеративно-дистрофические поражения шейного отдела позвоночника. Сибирский медицинский журнал. 2015;7:21-26].
Yakhyaeva SA, Garabova NI, Burzhunova MG. Concrescence of the cervical vertebrae and neurological complications. Bulletin of Neurology, Psychiatry and Neurosurgery. 2021;3:195-201. (In Russ.). [Яхьяева С.А., Гарабова Н.И., Буржунова М.Г. Конкресценция шейных позвонков и неврологические осложнения. Вестник неврологии, психиатрии и нейрохирургии. 2021;3:195-201]. https://doi.org/10.33920/med-01-2103-03

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2. Figure 1. Participant No. 20, female, 26 years old. MRI in T2 mode, performed in the sagittal plane and transversely at the C5 vertebra level, diagnostic equipment – 1.5 Tl Brivo MR355 (General Electric, USA).

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