Chinese Journal of Stroke ›› 2019, Vol. 14 ›› Issue (11): 1124-1128.DOI: 10.3969/j.issn.1673-5765.2019.11.009
Previous Articles Next Articles
Received:
2019-05-19
Online:
2019-11-20
Published:
2019-11-20
马琳,王伊龙
通讯作者:
王伊龙 yilong528@aliyun.com
基金资助:
国家自然科学基金委员会杰出青年科学基金项目(81825007)
北京高校卓越青年科学家计划项目(BJJWZYJH01201910025030)
科技部“十三五”国家重点研发计划“症状性颅内外大动脉狭窄复发进展预测模型与干预策略研究”(2017YFC1307900)
北京市科学技术委员会“动脉粥样硬化性颅内动脉狭窄的他汀药物治疗研究”(D171100003017001)
北京市优秀人才培养资助青年拔尖团队(2016000021223TD03)
MA Lin, WANG Yi-Long. Advance in Relationship between Cerebral Hemodynamics and Enlarged Perivascular Space[J]. Chinese Journal of Stroke, 2019, 14(11): 1124-1128.
马琳, 王伊龙. 血流动力学与脑部血管周围间隙扩大关系的研究进展[J]. 中国卒中杂志, 2019, 14(11): 1124-1128.
[1] ABBOTT N J. Evidence for bulk flow of braininterstitial fluid:significance for physiology andpathology[J]. Neurochem Int,2004,45(4):545-552.[2] KWEE R M,KWEE T C. Virchow-robin spaces atMR imaging[J]. Radiographics,2007,27(4):1071-1086.[3] DOUBAL F N,MACLULLICH A M,FERGUSONK J,et al. Enlarged perivascular spaces on MRI area feature of cerebral small vessel disease[J]. Stroke,2010,41(3):450-454.[4] WUERFEL J,HAERTLE M,WAICZIES H,etal. Perivascular spaces-MRI marker of inflamatoryactivity in the brain?[J]. Brain,2008,131(Pt 9):2332-2340.[5] RIBEIRO M,HOWARD P,WILLSKY R A,et al.Subarachnoid hemorrhage in perivascular spacesmimicking brainstem hematoma[J]. Can J Neurol Sci,2010,37(2):286-288.[6] 张晓玲,李咏梅. 脑部血管周围间隙扩大及其相关疾病研究进展[J]. 磁共振成像,2015,6(6):476-480.[7] ILIFF J J,WANG M,ZEPPENFELD D M,et al.Cerebral arterial pulsation drives paravascular CSFinterstitialfluid exchange in the murine brain[J]. JNeurosci,2013,33(46):18190-18199.[8] BALL K K,CRUZ N F,MRAK R E,et al.Trafficking of glucose,lactate,and amyloid-β fromthe inferior colliculus through perivascular routes[J].J Cereb Blood Flow Metab,2010,30(1):162-176.[9] WANG M H,XIE M J,WANG W. The transportfunction of cerebral paravascular space in vivo usingtwophoton imaging[J]. Nerve Injure and FunctionalReconstruction,2012,7(4):253-257.[10] ROUHL R P,DAMOISEAUX J G,LODDER J,etal. Vascular inflammation in cerebral small vesseldisease[J]. Neurobiol Aging,2012,33(8):1800-1806.[11] LIM A T,CHANDRA R V,TROST N M,et al.Large anterior temporal Virchow-Robin spaces:unique MR imaging features[J]. Neuroradiology,2015,57(5):491-499.[12] MACLULLICH A M,WARDLAW J M,FERGUSON K J,et al. Enlarged perivascular spacesare associated with cognitive function in healthyelderly men[J]. J Neurol Neurosurg Psychiat,2004,75(11):1519-1523.[13] ZHU Y C,TZOURIO C,SOUMARÉ A,etal. Severity of dilated Virchow-Robin spaces isassociated with age,blood pressure,and MRImarkers of small vessel disease:a population-basedstudy[J]. Stroke,2010,41(11):2483-2490.[14] WARDLAW J M,SMITH C,DICHGANS M.Mechanisms of sporadic cerebral small vessel disease:insights from neuroimaging[J]. Lancet Neurol,2013,12(5):483-497.[15] YANG S,YUAN J,ZHANG X,et al. Higherambulatory systolic blood pressure independentlyassociated with enlarged perivascular spaces in basalganglia[J]. Neurol Res,2017,39(9):787-794.[16] DEL BRUTTO O H,MERA R M,Atahualpa ProjectInvestigators. Enlarged basal ganglia perivascularspaces are associated with pulsatile components ofblood pressure[J]. Eur Neurol,2018,79(1-2):86-89.[17] GUTIERREZ J,ELKIND M S,CHEUNG K,et al.Pulsatile and steady components of blood pressureand subclinical cerebrovascular disease:theNorthern Manhattan Study[J]. J Hypertens,2015,33(10):2115-2122.[18] FLEURY J,GHERARDI R,POIRIER J. Theperivascular spaces of the central nervous system.Histophysiological data[J]. Ann Pathol,1984,4(4):245-247.[19] MARMAROU A,TAKAGI H,SHULMAN K.Biomechanics of brain edema and effects on localcerebral blood flow[J]. Adv Neurol,1980,28:345-358.[20] TOMIYAMA H,MATSUMOTO C,SHIINA K,etal. Brachial-Ankle PWV:current status and futuredirections as a useful marker in the management ofcardiovascular disease and/or cardiovascular riskfactors[J]. J Atheroscler Thromb,2016,23(2):128-146.[21] RIBA-LLENA I,JIMÉNEZ-BALADO J,CASTAÑÉ X,et al. Arterial stiffness is associatedwith basal ganglia enlarged perivascular spaces andcerebral small vessel disease load[J]. Stroke,2018,49(5):1279-1281.[22] SHI Y,THRIPPLETON M J,BLAIR G W,etal. Small vessel disease is associated with altered cerebrovascular pulsatility but not resting cerebralblood flow[J/OL]. J Cereb Blood Flow Metab,2018.https://doi.org/10.1177/0271678X18803956.[23] JUNG S J,JEON Y,LEE G,et al. Stressful lifeevents and augmentation index:results from theCardiovascular and Metabolic Diseases EtiologyResearch Center[J/OL]. Hypertens Res,2019. https://doi.org/10.1038/s41440-019-0331-6.[24] MESTRE H,TITHOF J,DU T,et al. Flow ofcerebrospinal fluid is driven by arterial pulsationsand is reduced in hypertension[J]. Nat Commun,2018,9(1):4878.[25] FILOMENA J,RIBA-LLENA I,VINYOLES E,etal. Short-term blood pressure variability relates tothe presence of subclinical brain small vessel diseasein primary hypertension[J]. Hypertension,2015,66(3):634-640.[26] YANG S,YUAN J,QIN W,et al. Twenty-four-hourambulatory blood pressure variability is associatedwith total magnetic resonance imaging burden ofcerebral small-vessel disease[J/OL]. Clin IntervAging,2018,13:1419-1427. https://doi.org/10.2147/CIA.S171261.[27] FERRARI A U,FRANZELLI C,DAFFONCHIOA,et al. Sympathovagal interplay in the control ofoverall blood pressure variability in unanesthetizedrats[J]. Am J Physiol,1996,270(6 Pt 2):H2143-H2148.[28] PALATINI P. Sympathetic overactivity inhypertension:a risk factor for cardiovasculardisease[J]. Curr Hypertens Rep,2001,3(Suppl 1):S3-S9.[29] SU D F,MIAO C Y. Blood pressure variability andorgan damage[J]. Clin Exp Pharmacol Physiol,2001,28(9):709-715.[30] BILSTON L E,FLETCHER D F,BRODBELT AR,et al. Arterial pulsation-driven cerebrospinalfluid flow in the perivascular space:a computationalmodel[J]. Comput Methods Biomech Biomed Engin,2003,6(4):235-241. |
[1] | ZHENG Zhanjun, ZHAO Xingquan. Advances in Correlation of Imaging Markers of Cerebral Small Vessel Disease with Spontaneous Hypertensive Intracerebral Hemorrhage [J]. Chinese Journal of Stroke, 2022, 17(12): 1396-1402. |
[2] | CHEN Chao, WAN Huijuan, DONG Wenyu, WANG Shengsong, YU Ping, SHAO Xiaoqiu. The Association between Total Cerebral Small Vessel Disease Burden and Cognitive Function in Middle-aged and Elderly Patients With Epilepsy [J]. Chinese Journal of Stroke, 2022, 17(06): 622-627. |
[3] | MA Jiali, WANG Yuqing, WANG Kaiwen, DONG Jingjing, LI Yongqiu. Clinical Prediction Model and Influencing Factors of Total Cerebral Small Vessel Disease Burden [J]. Chinese Journal of Stroke, 2022, 17(05): 523-528. |
[4] | YE Yichao, YU Shi, SHE Yajun, FANG Zheng, WANG Yi. Progress of Vascular Parkinsonism [J]. Chinese Journal of Stroke, 2022, 17(04): 346-350. |
[5] | ZHU Cuiting, HU Wenli. Analysis on Risk Factors for Total Cerebral Small Vessel Disease Burden in Patients with Dizziness or Vertigo [J]. Chinese Journal of Stroke, 2022, 17(04): 354-359. |
[6] | LIU Hui-Lin, LIU Dong-Tao, BU Qiao, LI Kun, PAN Zhen-Yu, FAN Xiao-Wei, ZHOU Li-Chun. Microstructural Changes of Limbic System in Patients with Mild Cognitive Impairment Induced by Cerebral Small Vessel Disease [J]. Chinese Journal of Stroke, 2021, 16(08): 793-798. |
[7] | HAN Dong-Shan, LYU Jin-Hao, LIN Lan, WANG Liu-Xian, LUO Chun-Cai, ZHANG Sen-Hao,WEI Meng-Ting, WANG Xin-Rui, LIN Jia-Ji, LOU Xin. Association between Perfusion Defect and Collateral Circulation in Patients with Symptomatic Intracranial Artery Occlusion [J]. Chinese Journal of Stroke, 2021, 16(05): 427-432. |
[8] | QIN Wei, HU Hong-Mei, LI Xuan-Ting, WANG Yun, YANG Shu-Na, HU Wen-Li. Analysis on Risk Factors for Total Cerebral Small Vessel Disease Burden in Young Patients with Ischemic Stroke [J]. Chinese Journal of Stroke, 2021, 16(05): 470-474. |
[9] | LU Hao-Xuan, MA Xiao-Xiao, LOU Xin. Progress of Hyperuricemia Related Cerebrovascular Diseases [J]. Chinese Journal of Stroke, 2021, 16(05): 524-528. |
[10] | MENG Li-Fang, PENG Xue, LIU Hao, WANG Jin, LIU Jun-Li, JIA Xiang-Lei, ZHAO Pan-Pan,WANG Fan, WANG Chao-Wei, ZHANG Li-Jun, LI Qing, JI Si-Bei, YUAN Bin, CAI Rui-Yan, YANG Ru, LI Shao-Min,ZHAO Jian-Hua. Correlation between Serum Brain Derived Neurotrophic Factor Level and Cognitive Impairment due to Cerebral Small Vessel Disease [J]. Chinese Journal of Stroke, 2021, 16(04): 371-375. |
[11] | LU Pei-Wen, YANG Jie, DENG Qiu-Qiong, YU Ling, CAO Wen-Wei, DU Jing, WANG Yao, ZHOU Yan,XU Qun. Functional Network Connectivity in Patients with Early Cognitive Impairment due to Cerebral Small Vessel Disease [J]. Chinese Journal of Stroke, 2020, 15(12): 1268-1275. |
[12] | WANG Jie-Qun, WU Yi-Tai, WANG Xing, XU Sheng, LI Ren-Ren,NIE Zhi-Yu, LI Yun-Xia. Correlation between the Total Cerebral Small Vessel Disease Load and Cognitive Function, Brain Atrophy and Cerebral Perfusion in Patients with Memory Loss [J]. Chinese Journal of Stroke, 2020, 15(12): 1276-1280. |
[13] | LU Pei-Wen, XU Qun. Advances in Machine Learning-based Neuroimaging Studies on Cognitive Impairment due to Cerebral Small Vessel Disease [J]. Chinese Journal of Stroke, 2020, 15(12): 1281-1286. |
[14] | GONG Ling-Yu, Xu Qun. Progress of Perivascular Spaces in Cerebral Small Vessel Disease [J]. Chinese Journal of Stroke, 2020, 15(12): 1287-1291. |
[15] | ZHOU Li-Xin, NI Jun. Advances in Branch Atheromatous Disease [J]. Chinese Journal of Stroke, 2020, 15(12): 1342-1351. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||