MORPHOLOGY OF THE DURAL SINUSES OF THE BRAIN
Keywords:
Morphogenesis, embryonic development, brain, sinuses of the brain.Abstract
Based on the literature review, clarified the main stages of development of
the sinuses of the Dura mater of the brain in the antenatal period of development. Data on
the sinus Dura brain is aligned with the international anatomical terminology. The process
in which undifferentiated venous network consolidates in the venous sinuses and large veins
of the brain, explains most of the numerous variants and anomalies of extracerebral veins.
Knowledge of the development of the sinuses of the Dura mater of the brain facilitates the
understanding of many anatomical facts.
References
Kamalova M.I., Ismoilov O.I. – Morphological changes in the microcirculatory vascular
system of the brain in hemorrhagic stroke.
Kamalova Malika Ilhomovna, Islamov Shavkat Eriyigitovich, Khaidarov Nodir
Kadyrovich. – Morphological features of microvascular tissues in the brain during
hemorrhagic stroke. The American Journal of Medical Sciences and Pharmaceutical
Research, 2020, 2(10), pp. 53-59.
Kamalova M.I., Khaidarov N.K., Islamov Sh.E. – Pathomorphological characteristics of
hemorrhagic stroke. Journal of Biomedicine and Practice, 2020, Special Issue, pp. 101
Kamalova M.I., Eriyigitovich I.S., Khaydarov N.K. – Morphological changes in cerebral
vessels in ischemic stroke. Journal of Biomedicine and Practice, 2020, 6(5).
Kamalova M.I., Khaidarov N.K. – Prevention and risk factors of brain infarction
(literature review). Journal of Neurology and Neurosurgical Research, 2020, 1(2).
Malika K.I., Nodir Kh.K., Shavkat I.E. – Modern risk factors and prevention concepts of
brain infarction (literature review). Journal of Neurology and Neurosurgical Research,
, 3(1).
Khaidarov Nodir Kadyrovich, Shomurodov Kahramon Erkinovich, Kamalova Malika
Ilhomovna. – Microscopic examination of postcapillary venules in the brain during
hemorrhagic stroke. The American Journal of Medical Sciences and Pharmaceutical
Research, 2021, 3(08), pp. 69–73.
Kamalova M.I., Tirkashev A.Sh., Morphological Features of Cerebral Vessels and their
Age-Related Changes. International Journal of Integrative and Modern Medicine
Volume 3, Issue 1, 2025
Kamalova M.I., Tirkashev A.Sh., Age-related changes in the vascular networks of the
lateral ventricles of the human brain. Multidisciplinary Journal fa science and
Technology volume-5, issue-4
Agarwal N., Carare R.O. Overview of the anatomy, physiology, and drainage role of
brain blood vessels in fluid and solute clearance. Front Neurol., 2021, Vol. 11, Article
DOI: 10.3389/fneur.2020.611485.
Louveau A., Smirnov I., Keyes T.J., Eccles J.D., Rouhani S.J., Peske J.D., et al.
Structural and functional features of lymphatic vessels in the central nervous system.
Nature, 2015, Vol. 523, pp. 337–341. DOI: 10.1038/nature14432.
Iadecola C., Nedergaard M. Regulation of brain microcirculation by glial cells. Nat
Neurosci., 2007, Vol. 10, pp. 1369–1376. DOI: 10.1038/nn2003.
Benkovich I.L. An integrative clinical approach to neurological diseases. Veins
Lymphat., 2019, Vol. 8, pp. 49–58. DOI: 10.4081/vl.2019.8470.
Agarwal N., Port J.D. Neuroimaging: Anatomy Meets Function. Switzerland: Springer
International, 2017, 275 pages. DOI: 10.1007/978-3-319-57427-1.
Hill M.A., Nourian Z., Ho I.L., Clifford P.S., Martinez-Lemus L., Meininger G.A.
Elastin distribution and structure in small arteries — emphasis on three-dimensional
organization. Microcirculation, 2016, Vol. 23, pp. 614–620. DOI: 10.1111/micc.12294.
Blinder P., Tsai P.S., Kaufhold J.P., Knutsen P.M., Suhl H., Kleinfeld D. Cortical
angiome: interconnected vascular networks and unconventional blood flow patterns. Nat
Neurosci., 2013, Vol. 16, pp. 889–897. DOI: 10.1038/nn.3426.
MacGregor Sharp M., Bulters D., Brandner S., Holton J., Verma A., Werring D.J., et al.
The precise anatomy of perivascular spaces in the human brain: association with enlarged spaces in cerebral amyloid angiopathy. Neuropathol Appl Neurobiol., 2018,
Vol. 45, pp. 305–308. DOI: 10.1111/nan.12480.
Kravtsova I.L., Nedzved M.K. Morphological features and location of Virchow-Robin
spaces in the brain. Problems of Health and Ecology, 2013, Vol. 37, No. 3, pp. 21-27.
Wardlaw J.M., Smith E.E., Biessels G.J., Cordonnier C., Fazekas F., Frayne R., et al.
Neuroimaging standards for research into small vessel disease and its contribution to
ageing and neurodegeneration. Lancet Neurol., 2013, Vol. 12, pp. 822–838. DOI:
1016/S1474-4422(13)70124-8.
Hamel E. Perivascular nerves and the regulation of cerebrovascular tone. J. Appl
Physiol., 2006, Vol. 100, pp. 1059–1064. DOI: 10.1152/japplphysiol.00954.2005.
Fantini S., Sassaroli A., Tgavalekos K.T., Kornbluth J. Brain blood flow and
autoregulation: current measurement methods and prospects of non-invasive optical
techniques.
Neurophotonics,
,
Vol.
,
Article
DOI:
1117/1.NPh.3.3.031411.
Reutov V.P., Chertok V.M. New insights into the role of nitric oxide-producing systems
in the autonomic nervous system and cerebral vessels. Pacific Medical Journal, 2016,
Vol. 64, No. 2, pp. 10-19.
Weed L.H. – Studies on cerebrospinal fluid. Part IV: The dual source of cerebrospinal
fluid. Journal of Medical Research, September 1914, Vol. 31(1), pp. 93-118.
Hochstetter F. On a variety of the basilar cerebral vein in humans, with remarks on the
development of certain brain veins // Z. Anat. Entwicklungsgesch.- 1938.- 108.-P.311
