静脉窦蛛网膜颗粒与年龄关系的MRI研究

doi:10.13418/j.issn.1001-165x.2020.05.005

中国临床解剖学杂志 ›› 2020, Vol. 38 ›› Issue (5) : 518-522. DOI: 10.13418/j.issn.1001-165x.2020.05.005

颅内静脉解剖与循环障碍

静脉窦蛛网膜颗粒与年龄关系的MRI研究

李克磊¹，　魏梁锋¹，　陶伟伟¹，　李军¹，　鲜亮¹，　王守森^{1, 2}

作者信息 +

MRI study on the relationship between dural sinus arachnoid granulation and age

LI Ke-lei¹, WEI Liang-feng², TAO Wei-wei¹, LI Jun¹, XIAN Liang¹, WANG Shou-sen^1,2

Author information +

文章历史 +

摘要

目的　研究静脉窦内蛛网膜颗粒（arachnoid granulation，AG）随年龄变化的规律。方法　按年龄分组收集360例核磁共振检查颅内未见异常的患者临床及影像资料，观察静脉窦内AG的分布、各年龄组AG的形状、大小和数量及同例患者AG形态随年龄变化情况。结果　经MRI检查发现，AG最常出现的部位是横窦，其次是上矢状窦、直窦、窦汇，海绵窦未见；未成年组随着年龄的增加，AG的直径逐步增大，数量逐步增多，分叶型AG数量也增多；中青年组AG直径、数量随着年龄的增加而波动于某范围内，形状基本保持不变，能检测出AG的患者的例数及AG直径与未成年组相比均有统计学意义；老年组随着年龄的增加，AG直径减小，数量减少，分叶型AG数量也呈减少趋势，能检测出AG的患者例数及AG直径与中青年组相比均有统计学意义。结论　不同年龄段人群的蛛网膜颗粒数量、大小及形状有所差异，这些变化可能与生长发育、衰老及脑脊液吸收调节有密切关系。

Abstract

Objective　To study the relationship between the arachnoid granulation (AG) in dural sinus and age. Methods The clinical and imaging data of 360 patients with intracranial no abnormalities were collected according to the age. The distribution of AG in venous sinus and the shape, size, number and the changes of morphology in the same patients of AG in each age group were observed. Results MR examination showed that the most common site of AG was transverse sinus, followed by superior sagittal sinus, straight sinus, torcular, cavernous sinus. With the increasing of age in the juveniles patients group, the AG diameter became larger, the quantity and the number of lobulated of AG gradually increased. With the increasing of age in the middle-aged patients group, the diameter and number fluctuations in the fixed range, the shape remained basically unchanged. There were statistical difference in the number and diameter of patients who could detect AG between the juveniles group and the middle-aged group. With the increasing of age in the old-aged patients group, the AG diameter became small, number and the number of lobulated also reduced. There were statistical difference in the number and diameter of patients who could detect AG between the middle-aged group and the old-aged group. Conclusions The number, size and shape of the arachnoid granulation are variable in different age groups, and these changes may be closely related to growth and development, aging and regulation of cerebrospinal fluid reabsorption.

导出引用

李克磊, 魏梁锋, 陶伟伟, 李军, 鲜亮, 王守森. 静脉窦蛛网膜颗粒与年龄关系的MRI研究[J]. 中国临床解剖学杂志. 2020, 38(5): 518-522 https://doi.org/10.13418/j.issn.1001-165x.2020.05.005

LI Ke-lei, WEI Liang-feng, TAO Wei-wei, LI Jun, XIAN Liang, WANG Shou-sen. MRI study on the relationship between dural sinus arachnoid granulation and age [J]. Chinese Journal of Clinical Anatomy. 2020, 38(5): 518-522 https://doi.org/10.13418/j.issn.1001-165x.2020.05.005

中图分类号： R323.1 R445.2

参考文献

[1] Tsutsumi S, Ogino I, Miyajima M, et al. Cranial arachnoid protrusions and contiguous diploic veins in CSF drainage[J]. AJNR Am J Neuroradiol, 2014, 35(9): 1735-1739.
[2] Watane GV, Patel B, Brown D, et al. The significance of arachnoid granulation in patients with idiopathic intracranial hypertension[J]. J Comput Assist Tomogr, 2018, 42(2): 282-285.
[3] Liebo GB, Lane JJ, Van Gompel JJI, et al. Brain herniation into arachnoid granulations: clinical and neuroimaging features[J]. J Neuroimaging, 2016, 26(6): 592-598.
[4] Gailloud P, Muster M, Khaw N, et al. Anatomic relationship between arachnoid granulations in the transverse sinus and the termination of the vein of labbé: an angiographic study[J]. Neuroradiology, 2001, 43(2): 139-143.
[5] Leach JL, Jones BJ, Tomsick TA, et al. Normal appearance of arachnoid granulations on contrast-enhanced CT and MR of the brain: differentiation from dural sinus disease[J]. AJNR Am J Neuroradiol, 1996, 17(8): 1523-1532.
[6] Roche J, Warner D. Arachnoid granulations in the transverse and sigmoid sinuses: CT, MR, and MR angiographic appearance of a normal anatomic variation[J]. AJNR Am J Neuroradiol 1996, 17(4): 677-683.
[7] 宋海民, 李东海. 颅内蛛网膜与脑池研究进展[J]. 中国临床解剖学杂志, 2015, 33(6): 726-727.
[8] Sade R, Ogul H, Polat G, et al. Brain herniation into the transverse sinuses’ arachnoid granulations in the pediatric population investigated with 3T MRI[J]. Acta Neurol Belg, 2019, 119(2): 225-231.
[9] 罗琳, 鱼博浪, 王泽忠. 蛛网膜颗粒及其影像学表现[J]. 实用放射学杂志, 2001, 17(2): 142-143.
[10]Góomez DG, Dibenedetto AT, Pavese AM, et al. Development of arachnoid villi and granulation in man[J]. Acta Anat (Basel), 1982, 111(3): 247-258.
[11]肖俊强, 卢光明, 程传虎. 静脉窦蛛网膜颗粒CT、MRI表现[J]. 中国临床医学影像杂志, 2012, 23(11): 805-807.
[12] Ikushima I, Korogi Y, Makita O, et al. MRI of arachnoid granulations within the dural sinuses using a FLAIR pulse sequence[J]. Br J Radiol, 1999, 72 (863): 1046-1051.
[13]Liang L, Korogi Y, Sugahara T, et al. Normal structures in the intracranial dural sinuses: delineation with 3D contrast-enhanced magnetization prepared rapid acquisition gradient-echo imaging sequence[J]. AJNR Am J Neuroradiol, 2002, 23(10): 1739-1746.
[14] 孙金龙, 崔庆轲, 张庆林, 等. 国人上矢状窦窦腔内结构的内镜解剖[J]. 中华神经外科杂志, 2006, 22(9): 525-527.
[15] 康晓雨, 黄理金. 上矢状窦及其静脉属支的解剖学研究进展[J]. 中国临床解剖学杂志, 2015, 33(4): 491-493.
[16]Haroun AA, Mahafza WS, Najar MSA. Arachnoid granulations in the cerebral dural sinuses as demonstrated by contrast-enhanced 3D magnetic resonance venography[J]. Surg Radiol Anat, 2007, 29(4): 323-328.
[17]Grossman CB, Potts DG. Arachnoid granulations: radiology and anatomy[J]. Radiology, 1974, 113(1): 95-100.