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Translational Stroke Research
Published in: Translational Stroke Research 4/2020

Open Access 01-08-2020 | Stroke | Review Article

Neurovascular Unit as a Source of Ischemic Stroke Biomarkers—Limitations of Experimental Studies and Perspectives for Clinical Application

Authors: Aleksandra Steliga, Przemysław Kowiański, Ewelina Czuba, Monika Waśkow, Janusz Moryś, Grażyna Lietzau

Published in: Translational Stroke Research | Issue 4/2020

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Abstract

Cerebral stroke, which is one of the most frequent causes of mortality and leading cause of disability in developed countries, often leads to devastating and irreversible brain damage. Neurological and neuroradiological diagnosis of stroke, especially in its acute phase, is frequently uncertain or inconclusive. This results in difficulties in identification of patients with poor prognosis or being at high risk for complications. It also makes difficult identification of these stroke patients who could benefit from more aggressive therapies. In contrary to the cardiovascular disease, no single biomarker is available for the ischemic stroke, addressing the abovementioned issues. This justifies the need for identifying of effective diagnostic measures characterized by high specificity and sensitivity. One of the promising avenues in this area is studies on the panels of biomarkers characteristic for processes which occur in different types and phases of ischemic stroke and represent all morphological constituents of the brains’ neurovascular unit (NVU). In this review, we present the current state of knowledge concerning already-used or potentially applicable biomarkers of the ischemic stroke. We also discuss the perspectives for identification of biomarkers representative for different types and phases of the ischemic stroke, as well as for different constituents of NVU, which concentration levels correlate with extent of brain damage and patients’ neurological status. Finally, a critical analysis of perspectives on further improvement of the ischemic stroke diagnosis is presented.
Literature
1.
Chalela JA, Kidwell CS, Nentwich LM, Luby M, Butman JA, Demchuk AM, et al. Magnetic resonance imaging and computed tomography in emergency assessment of patients with suspected acute stroke: a prospective comparison. Lancet. NIH Public Access; 2007 [cited 2019 Aug 27];369:293–298. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​17258669.​
2.
Amarenco P, Bogousslavsky J, Caplan LR, Donnan GA, Hennerici MG. Classification of stroke subtypes. Cerebrovasc. Dis. 2009 Karger Publishers [cited 2019 Aug 27]. p. 493–501. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19342825.​
3.
4.
Whiteley W, Tseng MC, Sandercock P. Blood biomarkers in the diagnosis of ischemic stroke: a systematic review. Stroke. 2008 [cited 2018 Dec 8]. p. 2902–9. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​18658039.​
5.
Atkinson AJ, Colburn WA, DeGruttola VG, DeMets DL, Downing GJ, Hoth DF, et al. Biomarkers and surrogate endpoints: preferred definitions and conceptual framework. Clin. Pharmacol. Ther. 2001 [cited 2019 Aug 27]. p. 89–95. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11240971.​
6.
Hasan N, McColgan P, Bentley P, Edwards RJ, Sharma P. Towards the identification of blood biomarkers for acute stroke in humans: a comprehensive systematic review. Br J Clin Pharmacol. 2012 [cited 2018 Dec 8];74:230–40. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22320313.​
7.
Jickling GC, Sharp FR. Biomarker panels in ischemic stroke. Stroke. 2015 [cited 2018 Dec 8];46:915–20. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25657186.​
8.
Makris K, Haliassos A, Chondrogianni M, Tsivgoulis G. Blood biomarkers in ischemic stroke: potential role and challenges in clinical practice and research. Crit. Rev. Clin. Lab. Sci. 2018 [cited 2018 Dec 12]. p. 294–328. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29668333.​
9.
Del Zoppo GJ. Toward the neurovascular unit A journey in clinical translation: 2012 Thomas Willis lecture. Stroke. 2013 [cited 2018 Dec 8];44:263–269. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23033344.​
10.
11.
Iadecola C. The Neurovascular unit coming of age: a journey through neurovascular coupling in health and disease. Neuron. 2017 [cited 2018 Dec 8]. p. 17–42. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28957666.​
12.
13.
Reynolds MA, Kirchick HJ, Dahlen JR, Anderberg JM, McPherson PH, Nakamura KK, et al. Early biomarkers of stroke. Clin Chem. 2003 [cited 2018 Dec 8]. p. 1733–9. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​14500614.​
14.
Magaki SD, Williams CK, Vinters H V. Glial function (and dysfunction) in the normal & ischemic brain . Neuropharmacology. 2018 [cited 2018 Dec 8]. p. 218–25. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29122627.​
15.
Del Zoppo GJ. The neurovascular unit in the setting of stroke. J Intern Med. 2010 [cited 2018 Dec 8]. p. 156–71. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20175864.​
16.
Girouard H. Neurovascular coupling in the normal brain and in hypertension, stroke, and Alzheimer disease. J Appl Physiol. 2006 [cited 2018 Dec 8];100:328–335. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16357086.​
17.
Cavaglia M, Dombrowski SM, Drazba J, Vasanji A, Bokesch PM, Janigro D. Regional variation in brain capillary density and vascular response to ischemia. Brain Res. 2001 [cited 2018 Dec 8];910:81–93. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11489257.​
18.
Dohmen C, Kumura E, Rosner G, Heiss WD, Graf R. Extracellular correlates of glutamate toxicity in short-term cerebral ischemia and reperfusion: a direct in vivo comparison between white and gray matter. Brain Res. 2005 [cited 2018 Dec 8];1037:43–51. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​15777751.​
19.
Guo ZH, Li F, Wang WZ. The mechanisms of brain ischemic insult and potential protective interventions . Neurosci. Bull. 2009 [cited 2018 Dec 8]. p. 139–52. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19448688.​
20.
Manzanero S, Santro T, Arumugam T V. Neuronal oxidative stress in acute ischemic stroke: sources and contribution to cell injury. Neurochem. Int. 2013 [cited 2018 Dec 8]. p. 712–8. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23201332.​
21.
22.
23.
Liebner S, Dijkhuizen RM, Reiss Y, Plate KH, Agalliu D, Constantin G. Functional morphology of the blood–brain barrier in health and disease . Acta Neuropathol. 2018 [cited 2018 Dec 8]. p. 311–36. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29411111.​
24.
Stanimirovic D, Satoh K. Inflammatory mediators of cerebral endothelium: a role in ischemic brain inflammation. Brain Pathol . 2000 [cited 2018 Dec 8];10:113–126. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​10668901.​
25.
Gragnano F, Sperlongano S, Golia E, Natale F, Bianchi R, Crisci M, et al. The role of von Willebrand factor in vascular inflammation: from pathogenesis to targeted therapy. Mediators Inflamm. 2017 [cited 2018 Dec 8]. p. 1–13. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28634421.​
26.
Ishitsuka K, Ago T, Arimura K, Nakamura K, Tokami H, Makihara N, et al. Neurotrophin production in brain pericytes during hypoxia: a role of pericytes for neuroprotection. Microvasc Res. 2012 [cited 2018 Dec 8];83:352–359. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22387236.​
27.
Badaut J, Lasbennes F, Magistretti PJ, Regli L. Aquaporins in brain: distribution, physiology, and pathophysiology. J. Cereb. Blood Flow Metab. 2002 [cited 2018 Dec 8]. p. 367–78. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11919508.​
28.
Badaut J, Ashwal S, Tone B, Regli L, Tian HR, Obenaus A. Temporal and regional evolution of aquaporin-4 expression and magnetic resonance imaging in a rat pup model of neonatal stroke. Pediatr Res. 2007 [cited 2018 Dec 8];62:248–254. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​17622964.​
29.
Sofroniew M V., Vinters H V. Astrocytes: biology and pathology. Acta Neuropathol. 2010 [cited 2018 Dec 8]. p. 7–35. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20012068.​
30.
Liddelow SA, Barres BA. Reactive astrocytes: production, function, and therapeutic potential. Immunity. 2017 [cited 2018 Dec 9]. p. 957–67. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28636962.​
31.
Magistretti PJ, Allaman I. A cellular perspective on brain energy metabolism and functional imaging. Neuron. 2015 [cited 2018 Dec 9]. p. 883–901. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25996133.​
32.
Barr TL, Conley Y, Ding J, Dillman A, Warach S, Singleton A, et al. Genomic biomarkers and cellular pathways of ischemic stroke by RNA gene expression profiling. Neurology. 2010 [cited 2018 Dec 9];75:1009–1014. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20837969.​
33.
Stamova B, Xu H, Jickling G, Bushnell C, Tian Y, Ander BP, et al. Gene expression profiling of blood for the prediction of ischemic stroke. Stroke. 2010 [cited 2018 Dec 9];41:2171–2177. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20798371.​
34.
35.
Sofroniew M V. Molecular dissection of reactive astrogliosis and glial scar formation. Trends Neurosci. 2009 [cited 2018 Dec 9]. p. 638–47. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19782411.​
36.
Dvorak F, Haberer I, Sitzer M, Foerch C. Characterisation of the diagnostic window of serum glial fibrillary acidic protein for the differentiation of intracerebral haemorrhage and ischaemic stroke. Cerebrovasc Dis. 2009 [cited 2018 Dec 9];27:37–41. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19018136.​
37.
Foerch C, Curdt I, Yan B, Dvorak F, Hermans M, Berkefeld J, et al. Serum glial fibrillary acidic protein as a biomarker for intracerebral haemorrhage in patients with acute stroke. J Neurol Neurosurg Psychiatry. BMJ Publishing Group; 2006 [cited 2018 Dec 9];77:181–184. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16174653.​
38.
Brouns R, De Vil B, Cras P, De Surgeloose D, Mariën P, De Deyn PP. Neurobiochemical markers of brain damage in cerebrospinal fluid of acute ischemic stroke patients. Clin Chem. 2010 [cited 2018 Dec 9];56:451–458. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19959621.​
39.
Honda M, Tsuruta R, Kaneko T, Kasaoka S, Yagi T, Todani M, et al. Serum glial fibrillary acidic protein is a highly specific biomarker for traumatic brain injury in humans compared with S-100B and neuron-specific enolase. J Trauma - Inj Infect Crit Care. 2010 [cited 2019 Aug 27];69:104–109. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20093985.​
40.
Barger SW, Van Eldik LJ, Mattson MP. S100β protects hippocampal neurons from damage induced by glucose deprivation. Brain Res. 1995 [cited 2018 Dec 9];677:167–170. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​7606463.​
41.
Van Eldik LJ, Wainwright MS. The Janus face of glial-derived S100B: beneficial and detrimental functions in the brain. Restor Neurol Neurosci. 2003 [cited 2018 Dec 9];21:97–108. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​14530573.​
42.
Adami C, Bianchi R, Pula G, Donato R. S100B-stimulated NO production by BV-2 microglia is independent of RAGE transducing activity but dependent on RAGE extracellular domain. Biochim Biophys Acta - Mol Cell Res. 2004 [cited 2018 Dec 9]. p. 169–77. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​15590067.​
43.
Foerch C, Otto B, Singer OC, Neumann-Haefelin T, Yan B, Berkefeld J, et al. Serum S100B predicts a malignant course of infarction in patients with acute middle cerebral artery occlusion. Stroke. 2004 [cited 2018 Dec 9];35:2160–2164. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​15297628.​
44.
Aurell A, Rosengren LE, Karlsson B, Olsson JE, Zbornikova V, Haglid KG. Determination of S-100 and glial fibrillary acidic protein concentrations in cerebrospinal fluid after brain infarction. Stroke. 1991 [cited 2019 Aug 27];22:1254–1258. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​1926235.​
45.
Petzold A, Michel P, Stock M, Schluep M. Glial and axonal body fluid biomarkers are related to infarct volume, severity, and outcome. J Stroke Cerebrovasc Dis. 2008 [cited 2019 Aug 27];17:196–203. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​18589339.​
46.
Hsu Y, Tran M, Linninger AA. Dynamic regulation of aquaporin-4 water channels in neurological disorders. Croat Med J. Medicinska Naklada; 2015 [cited 2018 Dec 9];56:401–21. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26526878.​
47.
Manley GT, Zador Z, Stiver S, Wang V. Role of aquaporin-4 in cerebral edema and stroke. Handb. Exp. Pharmacol. 2009 Berlin, Heidelberg: Springer Berlin Heidelberg; [cited 2018 Dec 9]. p. 159–70. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19096776.​
48.
He ZP, Lu H. Aquaporin-4 gene silencing protects injured neurons after early cerebral infarction. Neural Regen Res. 2015 [cited 2018 Dec 9];10:1082–1087. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26330830.​
49.
Suzuki Y, Nakamura Y, Yamada K, Huber VJ, Tsujita M, Nakada T. Aquaporin-4 positron emission tomography imaging of the human brain: first report. J Neuroimaging . 2013 [cited 2018 Dec 9];23:219–223. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22817997.​
50.
Wunderlich MT, Hanhoff T, Goertler M, Spener F, Glatz JFC, Wallesch CW, et al. Release of brain-type and heart-type fatty acid-binding proteins in serum after acute ischaemic stroke. J Neurol. 2005 [cited 2018 Dec 9];252:718–724. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​15834650.​
51.
52.
53.
Zimmermann-Ivol CG, Burkhard PR, Le Floch-Rohr J, Allard L, Hochstrasser DF, Sanchez J-C. Fatty acid binding protein as a serum marker for the early diagnosis of stroke. Mol Cell Proteomics. 2004 [cited 2018 Dec 9];3:66–72. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​14581522.​
54.
Castillo J, Dávalos A, Noya M. Progression of ischaemic stroke and excitotoxic aminoacids. Lancet. 1997 [cited 2018 Dec 9];349:79–83. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8996418.​
55.
Castillo J, Dávalos A, Naveiro J, Noya M. Neuroexcitatory amino acids and their relation to infarct size and neurological deficit in ischemic stroke. Stroke. 1996 [cited 2018 Dec 9];27:1060–1065. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8650715.​
56.
Dávalos A, Castillo J, Serena J, Noya M. Duration of glutamate release after acute ischemic stroke. Stroke. 1997 [cited 2018 Dec 9];28:708–710. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9099183.​
57.
Pérez-Torres I, Zuniga-Munoz AM, Guarner-Lans V. Beneficial effects of the amino acid glycine. Mini Rev Med Chem. 2017 [cited 2019 mar 5];17:15–32. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27292783.​
58.
Zeilhofer HU, Acuña MA, Gingras J, Yévenes GE. Glycine receptors and glycine transporters: targets for novel analgesics?. Cell. Mol. Life Sci. 2018 [cited 2019 Mar 5]. p. 447–65. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28791431.​
59.
Boison D. The biochemistry and epigenetics of epilepsy: focus on adenosine and glycine. Front Mol Neurosci. 2016 [cited 2019 mar 5];9:26. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27147960.​
60.
61.
Park J. Movement Disorders following cerebrovascular lesion in the basal ganglia circuit. J Mov Disord. 2016 Korean Movement Disorders Society; [cited 2019 mar 5];9:71–9. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27240808.​
62.
63.
Babaev O, Piletti Chatain C, Krueger-Burg D. Inhibition in the amygdala anxiety circuitry. Exp. Mol. Med. 2018 [cited 2019 Mar 5]. p. 18. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29628509.​
64.
65.
66.
Serena J, Leira R, Castillo J, Pumar JM, Castellanos M, Dávalos A. Neurological deterioration in acute lacunar infarctions: the role of excitatory and inhibitory neurotransmitters. Stroke. 2001 [cited 2018 Dec 9];32:1154–1161. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11340225.​
67.
Erecińska M, Nelson D, Wilson DF, Silver IA. Neurotransmitter amino acids in the CNS. I. Regional changes in amino acid levels in rat brain during ischemia and reperfusion. Brain Res. 1984 [cited 2019 Aug 28];304:9–22. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​6146383.​
68.
Sims NR. The stimulus-evoked release of glutamate and GABA from brain subregions following transient forebrain ischemia in the rat. Neurochem Res. 1993 [cited 2019 Aug 28];18:1073–1079. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​7902957.​
69.
Qian Z, Lin Y, Xing J, Qiu Y, Ren L. Expression and functions of Glutamate and γ-aminobutyric acid transporters in ischemic models. Mol Med Rep. 2018 [cited 2019 Aug 28];17:8196–8202. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29693164.​
70.
Abe T, Suzuki M, Sasabe J, Takahashi S, Unekawa M, Mashima K, et al. Cellular origin and regulation of D- and L-serine in in vitro and in vivo models of cerebral ischemia. J Cereb Blood Flow Metab. 2014 SAGE Publications; [cited 2018 Dec 9];34:1928–35. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25294127.​
71.
Mustafa AK, Ahmad AS, Zeynalov E, Gazi SK, Sikka G, Ehmsen JT, et al. Serine racemase deletion protects against cerebral ischemia and excitotoxicity. J Neurosci. 2010 NIH Public Access; [cited 2018 Dec 9];30:1413–6. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20107067.​
72.
Lee A, Lingwood BE, Bjorkman ST, Miller SM, Poronnik P, Barnett NL, et al. Rapid loss of glutamine synthetase from astrocytes in response to hypoxia: Implications for excitotoxicity. J Chem Neuroanat. 2010 [cited 2018 Dec 9];39:211–20. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20034557.​
73.
Jeitner TM, Battaile K, Cooper AJL. Critical Evaluation of the changes in glutamine synthetase activity in models of cerebral stroke. Neurochem Res. 2015 [cited 2018 Dec 9];40:2544–2556. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26233464.​
74.
Gao J, Yang H, Chen J, Fang J, Chen C, Liang R, et al. Analysis of serum metabolites for the discovery of amino acid biomarkers and the effect of galangin on cerebral ischemia. Mol Biosyst. 2013 [cited 2018 Dec 9];9:2311–2321. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23793526.​
75.
Lee DR, Helps SC, Gibbins IL, Nilsson M, Sims NR. Losses of NG2 and NeuN immunoreactivity but not astrocytic markers during early reperfusion following severe focal cerebral ischemia. Brain Res. 2003 [cited 2018 Dec 9];989:221–230. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​14556944.​
76.
Wang L, Zhu X. Serine racemase expression in mouse cerebral cortex after permanent focal cerebral ischemia. Acta Pharmacol Sin. 2004 [cited 2018 Dec 9];25:436–441. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​15066209.​
77.
Zuo L, Zhan Y, Liu F, Chen C, Xu L, Calic Z, et al. Clinical and laboratory factors related to acute isolated vertigo or dizziness and cerebral infarction. Brain Behav. 2018 Wiley-Blackwell; [cited 2018 Dec 9];8:e01092. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​30099862.​
78.
Kim BJ, Kim YJ, Ahn SH, Kim NY, Kang DW, Kim JS, et al. The second elevation of neuron-specific enolase peak after ischemic stroke is associated with hemorrhagic transformation. J Stroke Cerebrovasc Dis. 2014 [cited 2018 Dec 9];23:2437–2443. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25183561.​
79.
Stammet P. Blood biomarkers of hypoxic-ischemic brain injury after cardiac arrest. Semin Neurol. 2017 [cited 2018 Dec 9];37:75–80. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28147421.​
80.
81.
Goksuluk H, Gulec S, Ozcan OU, Gerede M, Vurgun VK, Ozyuncu N, et al. Usefulness of neuron-specific enolase to detect silent neuronal ischemia after percutaneous coronary intervention. Am J Cardiol. 2016 [cited 2018 Dec 9];117:1917–1920. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27134059.​
82.
Lu K, Xu X, Cui S, Wang F, Zhang B, Zhao Y. Serum neuron specific enolase level as a predictor of prognosis in acute ischemic stroke patients after intravenous thrombolysis. J Neurol Sci. 2015 [cited 2018 Dec 9];359:202–206. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26671113.​
83.
Fahmi RM, Elsaid AF. Infarction size, interleukin-6, and their interaction are predictors of short-term stroke outcome in young Egyptian adults. J Stroke Cerebrovasc Dis. 2016 [cited 2018 Dec 9];25:2475–2481. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27402591.​
84.
Tarkowski E, Rosengren L, Blomstrand C, Wikkelsö C, Jensen C, Ekholm S, et al. Early intrathecal production of interleukin-6 predicts the size of brain lesion in stroke. Stroke. 1995 [cited 2018 Dec 9];26:1393–1398. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​7631343.​
85.
Martinic-Popovic I, Simundic AM, Dukic L, Lovrencic-Huzjan A, Popovic A, Seric V, et al. The association of inflammatory markers with cerebral vasoreactivity and carotid atherosclerosis in transient ischaemic attack. Clin Biochem. 2014 [cited 2018 Dec 9];47:182–186. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25046654.​
86.
Miwa K, Tanaka M, Okazaki S, Furukado S, Sakaguchi M, Mochizuki H, et al. Association between interleukin-6 levels and first-ever cerebrovascular events in patients with vascular risk factors. Arterioscler Thromb Vasc Biol. 2013 [cited 2018 Dec 9];33:400–405. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23175672.​
87.
Oto J, Suzue A, Inui D, Fukuta Y, Hosotsubo K, Torii M, et al. Plasma proinflammatory and anti-inflammatory cytokine and catecholamine concentrations as predictors of neurological outcome in acute stroke patients. J Anesth. 2008 [cited 2019 Aug 28];22:207–212. Available from: http://​link.​springer.​com/​10.​1007/​s00540-008-0639-x
88.
Diao ZY, Wang CL, Qi HS, Jia GY, Yan CZ. Significance of decreased serum interleukin-10 levels in the progression of cerebral infarction. Clin Exp Med. 2016 [cited 2018 Dec 9];16:203–211. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25847570.​
89.
Wang L, Wei C, Deng L, Wang Z, Song M, Xiong Y, et al. The accuracy of serum matrix metalloproteinase-9 for predicting hemorrhagic transformation after acute ischemic stroke: a systematic review and meta-analysis. J Stroke Cerebrovasc Dis. 2018 [cited 2018 Dec 9];27:1653–1665. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29598905.​
90.
Choi J Il, Ha SK, Lim DJ, Kim SD, Kim SH. S100ß, matrix metalloproteinase-9, D-dimer, and heat shock protein 70 are serologic biomarkers of acute cerebral infarction in a mouse model of transient MCA occlusion. J Korean Neurosurg Soc. 2018 [cited 2018 Dec 9];61:548–558. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29724092.​
91.
Zhong C, Yang J, Xu T, Xu T, Peng Y, Wang A, et al. Serum matrix metalloproteinase-9 levels and prognosis of acute ischemic stroke. Neurology. 2017 [cited 2018 Dec 9];89:805–812. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28747453.​
92.
Castellanos M, Leira R, Serena J, Pumar JM, Lizasoain I, Castillo J, et al. Plasma metalloproteinase-9 concentration predicts hemorrhagic transformation in acute ischemic stroke. Stroke. 2003 [cited 2019 Aug 28];34:40–46. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​12511748.​
93.
Montaner J, Molina CA, Monasterio J, Abilleira S, Arenillas JF, Ribó M, et al. Matrix metalloproteinase-9 pretreatment level predicts intracranial hemorrhagic complications after thrombolysis in human stroke. Circulation. 2003 [cited 2019 Aug 28];107:598–603. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​12566373.​
94.
95.
Castellanos M, Sobrino T, Millán M, García M, Arenillas J, Nombela F, et al. Serum cellular fibronectin and matrix metalloproteinase-9 as screening biomarkers for the prediction of parenchymal hematoma after thrombolytic therapy in acute ischemic stroke: a multicenter confirmatory study. Stroke. 2007 [cited 2019 Aug 28];38:1855–1859. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​17478737.​
96.
Abdelnaseer MM, Elfauomy NM, Esmail EH, Kamal MM, Elsawy EH. Matrix metalloproteinase-9 and recovery of acute ischemic stroke. J Stroke Cerebrovasc Dis. 2017 [cited 2018 Dec 9];26:733–740. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28063771.​
97.
Liu T, Clark RK, McDonnell PC, Young PR, White RF, Barone FC, et al. Tumor necrosis factor-α expression in ischemic neurons. Stroke. 1994 [cited 2018 Dec 9];25:1481–1488. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8023366.​
98.
Kim CR, Kim JH, Park HYL, Park CK. Ischemia reperfusion injury triggers TNFα induced-necroptosis in rat retina. Curr Eye Res. 2017 [cited 2018 Dec 9];42:771–779. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27732109.​
99.
Wang K, Ye L, Lu H, Chen H, Zhang Y, Huang Y, et al. TNF-α promotes extracellular vesicle release in mouse astrocytes through glutaminase. J Neuroinflammation. BioMed Central; 2017 [cited 2018 Dec 9];14:87. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28427419.​
100.
Šumanović-G Lamuzina D, Čulo F, Čulo MI, Konjevoda P, Raguž MJ. A comparison of blood and cerebrospinal fluid cytokines (IL-1β, IL-6, IL-18, TNF-α) in neonates with perinatal hypoxia. Bosn J Basic Med Sci. 2017 Association of Basic Medical Sciences of Federation of Bosnia and Herzegovina; [cited 2018 Dec 9];17:203–10. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28418828.​
101.
Lin C, Tang X, Shi Z, Zhang L, Yan D, Niu C, et al. Serum tumor necrosis factor α levels are associated with new ischemic brain lesions after carotid artery stenting. J Vasc Surg. 2018 [cited 2018 Dec 9];68:771–778. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29567026.​
102.
Tuttolomondo A, Pecoraro R, Di Raimondo D, Di Sciacca R, Canino B, Arnao V, et al. Immune-inflammatory markers and arterial stiffness indexes in subjects with acute ischemic stroke with and without metabolic syndrome. Diabetol Metab Syndr. 2014 BioMed Central; [cited 2019 Aug 28];6:28. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24571954.​
103.
Tuttolomondo A, Di Raimondo D, Pecoraro R, Arnao V, Pinto A, Licata G. Inflammation in ischemic stroke subtypes. Curr Pharm Des. 2012 [cited 2019 Aug 28];18:4289–4310. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22390641.​
104.
Licata G, Tuttolomondo A, Corrao S, Di Raimondo D, Fernandez P, Caruso C, et al. Immunoinflammatory activation during the acute phase of lacunar and non-lacunar ischemic stroke: association with time of onset and diabetic state. Int J Immunopathol Pharmacol. 2006 [cited 2019 Aug 28];19:639–646. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​17026849.​
105.
Bongers TN, De Maat MPM, Van Goor MLPJ, Bhagwanbali V, Van Vliet HHDM, García EBG, et al. High von Willebrand factor levels increase the risk of first ischemic stroke: influence of ADAMTS13, inflammation, and genetic variability. Stroke. 2006 [cited 2018 Dec 9];37:2672–2677. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16990571.​
106.
Tobin WO, Kinsella JA, Kavanagh GF, O’Donnell JS, McGrath RT, Tierney S, et al. Profile of von Willebrand factor antigen and von Willebrand factor propeptide in an overall TIA and ischaemic stroke population and amongst subtypes. J Neurol Sci. 2017 [cited 2018 Dec 9];375:404–410. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28320178.​
107.
Hanson E, Jood K, Karlsson S, Nilsson S, Blomstrand C, Jern C. Plasma levels of von Willebrand factor in the etiologic subtypes of ischemic stroke. J Thromb Haemost. 2011 [cited 2018 Dec 9];9:275–281. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21054779.​
108.
Menih M, Križmarić M, Hojs Fabjan T. Clinical role of von Willebrand factor in acute ischemic stroke. Wien Klin Wochenschr. 2017 [cited 2018 Dec 9];129:491–496. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28409234.​
109.
Liu X, Liu J, Zhao S, Zhang H, Cai W, Cai M, et al. Interleukin-4 is essential for microglia/macrophage M2 polarization and long-term recovery after cerebral ischemia. Stroke. 2016 [cited 2018 Dec 9];47:498–504. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26732561.​
110.
Zhao X, Wang H, Sun G, Zhang J, Edwards NJ, Aronowski J. Neuronal interleukin-4 as a modulator of microglial pathways and ischemic brain damage. J Neurosci. 2015 [cited 2018 Dec 9];35:11281–11291. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26269636.​
111.
García-Berrocoso T, Giralt D, Bustamante A, Llombart V, Rubiera M, Penalba A, et al. Role of beta-defensin 2 and interleukin-4 receptor as stroke outcome biomarkers. J Neurochem. 2014 [cited 2018 Dec 9];129:463–472. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24386991.​
112.
Protti GG, Gagliardi RJ, Forte WCN, Sprovieri SRS. Interleukin-10 may protect against progressing injury during the acute phase of ischemic stroke. Arq Neuropsiquiatr. 2013 [cited 2018 Dec 9];71:846–51. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24394869.​
113.
Vila N, Castillo J, Dávalos A, Esteve A, Planas AM, Chamorro A. Levels of anti-inflammatory cytokines and neurological worsening in acute ischemic stroke. Stroke. 2003 [cited 2018 Dec 9];34:671–675. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​12624290.​
114.
Chang LT, Yuen CM, Liou CW, Lu CH, Chang WN, Youssef AA, et al. Link between interleukin-10 level and outcome after ischemic stroke. Neuroimmunomodulation. 2010 [cited 2018 Dec 9];17:223–228. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20203528.​
115.
Jiang Y, Wei N, Zhu J, Lu T, Chen Z, Xu G, et al. Effects of brain-derived neurotrophic factor on local inflammation in experimental stroke of rat. Mediators Inflamm. 2010 Hindawi; [cited 2018 Dec 12];2010:372423. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21490702.​
116.
Pikula A, Beiser AS, Chen TC, Preis SR, Vorgias D, Decarli C, et al. Serum brain-derived neurotrophic factor and vascular endothelial growth factor levels are associated with risk of stroke and vascular brain injury framingham study. Stroke. 2013 [cited 2018 Dec 10];44:2768–2775. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23929745.​
117.
Stanne TM, Aberg ND, Nilsson S, Jood K, Blomstrand C, Andreasson U, et al. Low circulating acute brain-derived neurotrophic factor levels are associated with poor long-term functional outcome after ischemic stroke. Stroke. 2016 [cited 2018 Dec 12];47:1943–1945. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27301948.​
118.
Lu H, Liu X, Zhang N, Zhu X, Liang H, Sun L, et al. Neuroprotective effects of brain-derived neurotrophic factor and Noggin-modified bone mesenchymal stem cells in focal cerebral ischemia in rats. J Stroke Cerebrovasc Dis. 2016 [cited 2018 Dec 12];25:410–418. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26654668.​
119.
Chen HH, Zhang N, Li WY, Fang MR, Zhang H, Fang YS, et al. Overexpression of brain-derived neurotrophic factor in the hippocampus protects against post-stroke depression. Neural Regen Res. 2015 [cited 2018 Dec 12];10:1427–1432. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26604903.​
120.
Zhang ZH, Wu LN, Song JG, Li WQ. Correlations between cognitive impairment and brain-derived neurotrophic factor expression in the hippocampus of post-stroke depression rats. Mol Med Rep. 2012 [cited 2018 Dec 12];6:889–893. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22842820.​
121.
Wang Y, Chang CF, Morales M, Chiang YH, Hoffer J. Protective effects of glial cell line-derived neurotrophic factor in ischemic brain injury. Ann N Y Acad Sci. 2002 [cited 2018 Dec 12]. p. 423–37. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​12076993.​
122.
Narantuya D, Nagai A, Abdullah M, Masuda J, Kobayashi S, Yamaguchi S, et al. Human microglia transplanted in rat focal ischemia brain induce neuroprotection and behavioral improvement. Gendelman HE, editor. PLoS One. 2010 Public Library of Science; [cited 2018 Dec 12];5:e11746. Available from: http://​dx.​plos.​org/​10.​1371/​journal.​pone.​0011746
123.
Ou Y, Yu S, Kaneko Y, Tajiri N, Bae EC, Chheda SH, et al. Intravenous infusion of GDNF gene-modified human umbilical cord blood CD34+ cells protects against cerebral ischemic injury in spontaneously hypertensive rats. Brain Res. 2010 [cited 2018 Dec 12];1366:217–225. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20888805.​
124.
Miyazaki H, Nagashima K, Okuma Y, Nomura Y. Expression of glial cell line-derived neurotrophic factor induced by transient forebrain ischemia in rats. Brain Res. 2001 [cited 2018 Dec 12];922:165–172. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11743946.​
125.
Liu Y, Wang S, Luo S, Li Z, Liang F, Zhu Y, et al. Intravenous PEP-1-GDNF is protective after focal cerebral ischemia in rats. Neurosci Lett. 2016 [cited 2018 Dec 12];617:150–155. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26876444.​
126.
127.
Wang Y, Cao M, Liu A, Di W, Zhao F, Tian Y, et al. Changes of inflammatory cytokines and neurotrophins emphasized their roles in hypoxic-ischemic brain damage. Int J Neurosci. 2013 [cited 2018 Dec 12];123:191–195. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23110519.​
128.
Zhang ZH, Xi GM, Li WC, Ling HY, Qu P, Fang XB. Cyclic-AMP response element binding protein and tau are involved in the neuroprotective mechanisms of nerve growth factor during focal cerebral ischemia/reperfusion in rats. J Clin Neurosci. 2010 [cited 2018 Dec 12];17:353–356. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20071183.​
129.
Ke XJ, Zhang JJ. Changes in HIF-1α, VEGF, NGF and BDNF levels in cerebrospinal fluid and their relationship with cognitive impairment in patients with cerebral infarction. J Huazhong Univ Sci Technol - Med Sci. 2013 Huazhong University of Science and Technology; [cited 2018 Dec 12];33:433–7. Available from: http://​link.​springer.​com/​10.​1007/​s11596-013-1137-4
130.
Lietzau G, Kowiański P, Karwacki Z, Dziewia̧tkowski J, Witkowska M, Sidor-Kaczmarek J, et al. The molecular mechanisms of cell death in the course of transient ischemia are differentiated in evolutionary distinguished brain structures. Metab Brain Dis. 2009 [cited 2018 Dec 9];24:507–523. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19693659.​
131.
132.
Missler U, Wiesmann M, Wittmann G, Magerkurth O, Hagenström H. Measurement of glial fibrillary acidic protein in human blood: analytical method and preliminary clinical results. Clin Chem. 1999 [cited 2018 Dec 9];45:138–141. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9895354.​
133.
134.
Kleindienst A, McGinn MJ, Harvey HB, Colello RJ, Hamm RJ, Bullock MR. Enhanced Hippocampal neurogenesis by intraventricular S100B infusion is associated with improved cognitive recovery after traumatic brain injury. J Neurotrauma. 2005 [cited 2018 Dec 9];22:645–655. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​15941374.​
135.
Hu J, Castets F, Guevara JL, Van Eldiki LJ. S100β stimulates inducible nitric oxide synthase activity and mRNA levels in rat cortical astrocytes. J Biol Chem. American Society for Biochemistry and Molecular Biology; 1996 [cited 2018 Dec 9];271:2543–7. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8576219.​
136.
Koppal T, Lam AGM, Guo L, Van Eldik LJ. S100B proteins that lack one or both cysteine residues can induce inflammatory responses in astrocytes and microglia. Neurochem Int. 2001 [cited 2018 Dec 9];39:401–407. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11578775.​
137.
Büttner T, Weyers S, Postert T, Sprengelmeyer R, Kuhn W. S-100 protein: serum marker of focal brain damage after ischemic territorial MCA infarction. Stroke. 1997 [cited 2018 Dec 9];28:1961–1965. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9341704.​
138.
Missler U, Wiesmann M, Friedrich C, Kaps M. S-100 protein and neuron-specific enolase concentrations in blood as indicators of infarction volume and prognosis in acute ischemic stroke. Stroke. 1997 [cited 2018 Dec 9];28:1956–1960. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9341703.​
139.
Fassbender K, Schmidt R, Schreiner A, Fatar M, Mühlhauser F, Daffertshofer M, et al. Leakage of brain-originated proteins in peripheral blood: temporal profile and diagnostic value in early ischemic stroke. J Neurol Sci. 1997 [cited 2018 Dec 9];148:101–105. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9125396.​
140.
Tang G, Yang GY. Aquaporin-4: a potential therapeutic target for cerebral edema. Int. J. Mol. Sci. 2016 [cited 2018 Dec 9]. p. 1413. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27690011.​
141.
Friedman B, Schachtrup C, Tsai PS, Shih AY, Akassoglou K, Kleinfeld D, et al. Acute vascular disruption and aquaporin 4 loss after atroke. Stroke. 2009 [cited 2019 Aug 27];40:2182–2190. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​19372455.​
142.
Zhou J, Kong H, Hua X, Xiao M, Ding J, Hu G. Altered blood-brain barrier integrity in adult aquaporin-4 knockout mice. Neuroreport. 2008 [cited 2019 Aug 27];19:1–5. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​18281883.​
143.
Nakada T. The molecular mechanisms of neural flow coupling: a new concept. J Neuroimaging. 2015 [cited 2019 Aug 27];25:861–865. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25704766.​
144.
Igarashi H, Tsujita M, Suzuki Y, Kwee IL, Nakada T. Inhibition of aquaporin-4 significantly increases regional cerebral blood flow. Neuroreport. 2013 [cited 2019 Aug 27];24:324–328. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23462267.​
145.
Nito C, Kamada H, Endo H, Narasimhan P, Lee Y-S, Chan PH. Involvement of mitogen-activated protein kinase pathways in expression of the water channel protein aquaporin-4 after ischemia in rat cortical astrocytes. J Neurotrauma. 2012 Mary Ann Liebert, Inc.; [cited 2018 Dec 9];29:2404–12. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22676888.​
146.
Veerkamp JH, Zimmerman AW. Fatty acid-binding proteins of nervous tissue. J Mol Neurosci. 2001 [cited 2018 Dec 9]. p. 133–42. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11478368.​
147.
Kirsch J. Glycinergic transmission. Cell Tissue Res. 2006 [cited 2019 Mar 5]. p. 535–40. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16807723.​
148.
Głodzik-Sobańska L, Słowik A, Kozub J, Sobiecka B, Urbanik A, Szczudlik A. GABA in ischemic stroke. Proton magnetic resonance study. Med Sci Monit. 2004 [cited 2019 Aug 28];10 Suppl 3:88–93. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16538207.​
149.
150.
Shuaib A, Ijaz MS, Miyashita H, Hussain S, Kanthan R. GABA and glutamate levels in the substantia nigra reticulata following repetitive cerebral ischemia in gerbils. Exp Neurol. 1997 [cited 2019 Aug 28];147:311–315. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9344556.​
151.
Clarkson AN, Huang BS, MacIsaac SE, Mody I, Carmichael ST. Reducing excessive GABA-mediated tonic inhibition promotes functional recovery after stroke. Nature. 2010 [cited 2019 Aug 28];468:305–309. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21048709.​
152.
Schmidt D, Loscher W. Plasma and cerebrospinal fluid γ-aminobutyric acid in neurological disorders. J Neurol Neurosurg Psychiatry. 1982 BMJ Publishing Group; [cited 2019 Aug 28];45:931–5. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​7143013.​
153.
Mayor D, Tymianski M. Neurotransmitters in the mediation of cerebral ischemic injury. Neuropharmacology. 2018 [cited 2019 Aug 28]. p. 178–88. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29203179.​
154.
Benke D, Balakrishnan K, Zemoura K. Regulation of cell surface GABAB receptors: contribution to synaptic plasticity in neurological diseases. Adv Pharmacol. 2015 [cited 2019 Aug 28]. p. 41–70. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25637437.​
155.
Huang L, Li Q, Wen R, Yu Z, Li N, Ma L, et al. Rho-kinase inhibitor prevents acute injury against transient focal cerebral ischemia by enhancing the expression and function of GABA receptors in rats. Eur J Pharmacol. 2017 [cited 2019 Aug 28];797:134–142. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28109911.​
156.
Costa C, Leone G, Saulle E, Pisani F, Bernardi G, Calabresi P. Coactivation of GABAA and GABAB Receptor Results in Neuroprotection during In Vitro Ischemia. Stroke. 2004 [cited 2019 Aug 28];35:596–600. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​14726544.​
157.
158.
Mele M, Ribeiro L, Inácio AR, Wieloch T, Duarte CB. GABAA receptor dephosphorylation followed by internalization is coupled to neuronal death in in vitro ischemia. Neurobiol Dis. 2014 [cited 2019 Aug 28];65:220–232. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24513087.​
159.
Wang X, Shimizu-Sasamata M, Moskowitz MA, Newcomb R, Lo EH. Profiles of glutamate and GABA efflux in core versus peripheral zones of focal cerebral ischemia in mice. Neurosci Lett. 2001 [cited 2019 Aug 28];313:121–4. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11682142.​
160.
Miya K, Inoue R, Takata Y, Abe M, Natsume R, Sakimura K, et al. Serine racemase is predominantly localized in neurons in mouse brain. J Comp Neurol. 2008 [cited 2018 Dec 9];510:641–654. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​18698599.​
161.
Li S, Uno Y, Rudolph U, Cobb J, Liu J, Anderson T, et al. Astrocytes in primary cultures express serine racemase, synthesize D-serine and acquire A1 reactive astrocyte features. Biochem Pharmacol. 2018 [cited 2018 Dec 9];151:245–251. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29305854.​
162.
Jayakumar AR, Norenberg MD. Glutamine synthetase: role in neurological disorders. Adv Neurobiol [Internet]. 2016 [cited 2018 Dec 9]. p. 327–50. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27885636.​
163.
Snyder SH, Ferris CD. Novel neurotransmitters and their neuropsychiatric relevance. Am. J. Psychiatry. 2000 [cited 2018 Dec 9]. p. 1738–51. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11058466.​
164.
Yoshikawa M, Takayasu N, Hashimoto A, Sato Y, Tamaki R, Tsukamoto H, et al. The serine racemase mRNA is predominantly expressed in rat brain neurons. Arch Histol Cytol. 2007 [cited 2018 Dec 9];70:127–134. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​17827670.​
165.
Cunningham RT, Watt M, Winder J, McKinstry S, Lawson JT, Johnston CF, et al. Serum neurone-specific enolase as an indicator of stroke volume. Eur J Clin Invest. 1996 [cited 2018 Dec 9];26:298–303. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8732487.​
166.
Hu Y, Meng R, Zhang X, Guo L, Li S, Wu Y, et al. Serum neuron specific enolase may be a marker to predict the severity and outcome of cerebral venous thrombosis. J Neurol. 2018 [cited 2018 Dec 9];265:46–51. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29128928.​
167.
Stammet P, Collignon O, Hassager C, Wise MP, Hovdenes J, Åneman A, et al. Neuron-specific enolase as a predictor of death or poor neurological outcome after out-of-hospital cardiac arrest and targeted temperature management at 33°C and 36°C. J Am Coll Cardiol. 2015 [cited 2018 Dec 9];65:2104–2114. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​25975474.​
168.
Fassbender K, Rossol S, Kammer T, Daffertshofer M, Wirth S, Dollman M, et al. Proinflammatory cytokines in serum of patients with acute cerebral ischemia: kinetics of secretion and relation to the extent of brain damage and outcome of disease. J Neurol Sci. 1994 [cited 2018 Dec 9];122:135–139. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8021695.​
169.
Perini F, Morra M, Alecci M, Galloni E, Marchi M, Toso V. Temporal profile of serum anti-inflammatory and pro-inflammatory interleukins in acute ischemic stroke patients. Neurol Sci. 2001 [cited 2018 Dec 9];22:289–296. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11808851.​
170.
Nakamachi T, Tsuchida M, Kagami N, Yofu S, Wada Y, Hori M, et al. IL-6 and PACAP receptor expression and localization after global brain ischemia in mice. J Mol Neurosci . 2012 [cited 2018 Dec 9];48:518–525. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22669509.​
171.
Lambertsen KL, Biber K, Finsen B. Inflammatory cytokines in experimental and human stroke. J. Cereb. Blood Flow Metab. 2012 [cited 2018 Dec 9]. p. 1677–98. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22739623.​
172.
Pusch G, Debrabant B, Molnar T, Feher G, Papp V, Banati M, et al. Early dynamics of P-selectin and interleukin 6 predicts outcomes in ischemic stroke. J Stroke Cerebrovasc Dis. 2015 [cited 2018 Dec 9];24:1938–1947. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26051664.​
173.
Muroi C, Hugelshofer M, Seule M, Tastan I, Fujioka M, Mishima K, et al. Correlation among systemic inflammatory parameter, occurrence of delayed neurological deficits, and outcome after aneurysmal subarachnoid hemorrhage. Neurosurgery. 2013 [cited 2019 Aug 28];72:367–375. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23208059.​
174.
Osuka K, Suzuki Y, Tanazawa T, Hattori K, Yamamoto N, Takayasu M, et al. Interleukin-6 and development of vasospasm after subarachnoid haemorrhage. Acta Neurochir (Wien). 1998 [cited 2019 Aug 28];140:943–951. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9842432.​
175.
Ferrarese C, Mascarucci P, Zoia C, Cavarretta R, Frigo M, Begni B, et al. Increased cytokine release from peripheral blood cells after acute stroke. J Cereb Blood Flow Metab. 1999 [cited 2019 Aug 28];19:1004–1009. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​10478652.​
176.
Han YH. Association between IL6 polymorphism and risk of cerebral infarction. Genet Mol Res. 2015 [cited 2018 Dec 9];14:16438–16443. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26662441.​
177.
Kumar P, Kumar A, Sagar R, Misra S, Faruq M, Suroliya V, et al. Association between interleukin-6 (G174C and C572G) promoter gene polymorphisms and risk of ischemic stroke in North Indian population: a case-control study. Neurol Res. 2016 [cited 2018 Dec 9];38:69–74. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26883819.​
178.
Kumar P, Yadav AK, Kumar A, Sagar R, Pandit AK, Prasad K. Association between interleukin-6 (G174C and G572C) promoter gene polymorphisms and risk of ischaemic stroke: a meta-analysis. Ann Neurosci. 2015 Karger Publishers; [cited 2018 Dec 9];22:61–9. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26130909.​
179.
Ramos-Fernandez M, Bellolio MF, Stead LG. Matrix metalloproteinase-9 as a marker for acute ischemic stroke: a systematic review. J Stroke Cerebrovasc Dis. 2011 [cited 2019 Aug 28];20:47–54. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21044610.​
180.
Montaner J, Alvarez-Sabín J, Molina CA, Anglés A, Abilleira S, Arenillas J, et al. Matrix metalloproteinase expression is related to hemorrhagic transformation after cardioembolic stroke. Stroke. 2001 [cited 2019 Aug 28];32:2762–2767. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​11739970.​
181.
Akpinar A, Ucler N, Erdogan U, Baydin SS, Gungor A, Tugcu B. Measuring serum matrix metalloproteinase-9 levels in peripheral blood after subarachnoid hemorrhage to predict cerebral vasospasm. Springerplus. 2016 [cited 2018 Dec 9];5:1153. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27504251.​
182.
Triglia T, Mezzapesa A, Martin JC, Verdier M, Lagier D, Dufour H, et al. Early matrix metalloproteinase-9 concentration in the first 48h after aneurysmal subarachnoid haemorrhage predicts delayed cerebral ischaemia. Eur J Anaesthesiol. 2016 [cited 2018 Dec 9];33:662–669. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27355865.​
183.
Misra S, Talwar P, Kumar A, Kumar P, Sagar R, Vibha D, et al. Association between matrix metalloproteinase family gene polymorphisms and risk of ischemic stroke: a systematic review and meta-analysis of 29 studies. Gene. 2018 [cited 2018 Dec 9]. p. 180–94. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29906531.​
184.
Zhao JH, Xu YM, Xing HX, Su LL, Tao SB, Tian XJ, et al. Associations between matrix metalloproteinase gene polymorphisms and the development of cerebral infarction. Genet Mol Res. 2015 [cited 2018 Dec 9];14:19418–19424. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26782596.​
185.
186.
Gabel S, Koncina E, Dorban G, Heurtaux T, Birck C, Glaab E, et al. Inflammation promotes a conversion of astrocytes into neural progenitor cells via NF-κB activation. Mol Neurobiol. 2016 [cited 2018 Dec 9];53:5041–5055. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26381429.​
187.
Kim M, Jung K, Kim IS, Lee IS, Ko Y, Shin JE, et al. TNF-α induces human neural progenitor cell survival after oxygen-glucose deprivation by activating the NF-κB pathway. Exp Mol Med. 2018 [cited 2018 Dec 9];50:14. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​29622770.​
188.
Salama H, Hammad E. Risk Association between TNF-α-308 G>A and IL-6-174 G/C polymorphisms and recurrent transient ischemic attacks. Egypt J Immunol. 2015 [cited 2018 Dec 9];22:49–56. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28502144.​
189.
190.
Sonneveld MAH, De Maat MPM, Leebeek FWG. Von Willebrand factor and ADAMTS13 in arterial thrombosis: a systematic review and meta-analysis. Blood Rev. 2014 [cited 2018 Dec 9]. p. 167–78. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24825749.​
191.
Shi D, Xia T, Feng H, Cheng Q. Evaluating the diagnostic value of vWF: Ag, D-D and FDP in patients with acute cerebral infarction using ROC curves. Exp Ther Med. 2014 Spandidos Publications; [cited 2018 Dec 9];7:1573–7. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24926346.​
192.
Kraft P, Drechsler C, Gunreben I, Nieswandt B, Stoll G, Heuschmann PU, et al. Von Willebrand factor regulation in patients with acute and chronic cerebrovascular disease: a pilot, case-control study. Minnerup J, editor. PLoS One. 2014 Public Library of Science; [cited 2018 Dec 9];9:e99851. Available from: https://​dx.​plos.​org/​10.​1371/​journal.​pone.​0099851
193.
Lively S, Hutchings S, Schlichter LC. Molecular and cellular responses to interleukin-4 treatment in a rat model of transient ischemia. J Neuropathol Exp Neurol. 2016 [cited 2018 Dec 9]. p. 1058–71. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​27634961.​
194.
Kim HM, Shin HY, Jeong HJ, An HJ, Kim NS, Chae HJ, et al. Reduced IL-2 but elevated IL-4, IL-6, and IgE serum levels in patients with cerebral infarction during the acute stage. J Mol Neurosci. 2000 [cited 2018 Dec 9];14:191–196. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​10984195.​
195.
Marousi SG, Ellul J, Antonacopoulou A, Gogos C, Papathanasopoulos P, Karakantza M. Functional polymorphisms of interleukin 4 and interleukin 10 may predict evolution and functional outcome of an ischaemic stroke. Eur J Neurol. 2011 [cited 2018 Dec 9];18:637–643. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20880001.​
196.
Zee RYL, Cook NR, Cheng S, Reynolds R, Erlich HA, Lindpaintner K, et al. Polymorphism in the P-selectin and interleukin-4 genes as determinants of stroke: a population-based, prospective genetic analysis. Hum Mol Genet. 2004 [cited 2018 Dec 9];13:389–396. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​14681304.​
197.
Ledeboer A, Brevé JJP, Wierinckx A, Van Der Jagt S, Bristow AF, Leysen JE, et al. Expression and regulation of interleukin-10 and interleukin-10 receptor in rat astroglial and microglial cells. Eur J Neurosci. 2002 [cited 2018 Dec 9];16:1175–1185. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​12405978.​
198.
Norden DM, Fenn AM, Dugan A, Godbout JP. TGFβ produced by IL-10 redirected astrocytes attenuates microglial activation. Glia. 2014 [cited 2018 Dec 9];62:881–895. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​24616125.​
199.
Zhai QH, Futrell N, Chen FJ. Gene expression of IL-10 in relationship to TNF-α, IL-1β and IL-2 in the rat brain following middle cerebral artery occlusion. J Neurol Sci. 1997 [cited 2018 Dec 9];152:119–124. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​9415530.​
200.
He ML, Lv ZY, Shi X, Yang T, Zhang Y, Li TY, et al. Interleukin-10 release from astrocytes suppresses neuronal apoptosis via the TLR2/NFκB pathway in a neonatal rat model of hypoxic-ischemic brain damage. J Neurochem. 2017 [cited 2018 Dec 9];142:920–933. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28700093.​
201.
Perez-Asensio FJ, Perpina U, Planas AM, Pozas E. Interleukin-10 regulates progenitor differentiation and modulates neurogenesis in adult brain. J Cell Sci. 2013 [cited 2018 Dec 9];126:4208–4219. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23843621.​
202.
Ozkan A, Silan F, Uludag A, Degirmenci Y, Karaman HIO. Tumour necrosis factor alpha, interleukin 10 and interleukin 6 gene polymorphisms of ischemic stroke patients in south Marmara region of Turkey. Int J Clin Exp Pathol. 2015 [cited 2018 Dec 9];8:13500–13504. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26722564.​
203.
He W, Song H, Ding L, Li C, Dai L, Gao S. Association between IL-10 gene polymorphisms and the risk of ischemic stroke in a Chinese population. Int J Clin Exp Pathol. 2015 e-Century Publishing Corporation; [cited 2018 Dec 9];8:13489–94. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26722562.​
204.
Béjot Y, Prigent-Tessier A, Cachia C, Giroud M, Mossiat C, Bertrand N, et al. Time-dependent contribution of non neuronal cells to BDNF production after ischemic stroke in rats. Neurochem Int. 2011 [cited 2018 Dec 9];58:102–111. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21074587.​
205.
206.
Qiao HJ, Li ZZ, Wang LM, Sun W, Yu JC, Wang B. Association of lower serum Brain-derived neurotrophic factor levels with larger infarct volumes in acute ischemic stroke. J Neuroimmunol. 2017 [cited 2018 Dec 12];307:69–73. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28495141.​
207.
Lasek-Bal A, Jędrzejowska-Szypułka H, Różycka J, Bal W, Holecki M, Duława J, et al. Low concentration of BDNF in the acute phase of ischemic stroke as a factor in poor prognosis in terms of functional status of patients. Med Sci Monit. 2015 International Scientific Information, Inc.; [cited 2018 Dec 12];21:3900–5. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​26656843.​
208.
Yang L, Zhang Z, Sun D, Xu Z, Yuan Y, Zhang X, et al. Low serum BDNF may indicate the development of PSD in patients with acute ischemic stroke. Int J Geriatr Psychiatry. 2011 [cited 2018 Dec 12];26:495–502. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20845405.​
209.
Gottlieb M, Bonova P, Danielisova V, Nemethova M, Burda J, Cizkova D. Brain-derived neurotrophic factor blood levels in two models of transient brain ischemia in rats. Gen Physiol Biophys. 2013 [cited 2018 Dec 12];32:139–142. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​23531843.​
210.
Shen LH, Li Y, Chopp M. Astrocytic endogenous glial cell derived neurotrophic factor production is enhanced by bone marrow stromal cell transplantation in the ischemic boundary zone after stroke in adult rats. Glia. 2010 [cited 2018 Dec 12];58:1074–1081. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​20468049.​
211.
Hwang IK, Yoo KY, Kim DW, Lee BH, Kang TC, Choi SY, et al. Ischemia-related changes of glial-derived neurotrophic factor and phosphatidylinositol 3-kinase in the hippocampus: their possible correlation in astrocytes. Brain Res. 2006 [cited 2018 Dec 12];1072:215–223. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16412399.​
212.
Kuno R, Yoshida Y, Nitta A, Nabeshima T, Wang J, Sonobe Y, et al. The role of TNF-alpha and its receptors in the production of NGF and GDNF by astrocytes. Brain Res. 2006 [cited 2018 Dec 12];1116:12–18. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​16956589.​
213.
Yang JP, Liu HJ, Yang H, Feng PY. Therapeutic time window for the neuroprotective effects of NGF when administered after focal cerebral ischemia. Neurol Sci. 2011 [cited 2018 Dec 12];32:433–441. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21409508.​
214.
Lee TH, Kato H, Kogure K, Itoyama Y. Temporal profile of nerve growth factor-like immunoreactivity after transient focal cerebral ischemia in rats. Brain Res. 1996 [cited 2019 Aug 28];713:199–210. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​8724992.​
215.
Hashimoto Y, Kawatsura H, Shiga Y, Furukawa S, Shigeno T. Significance of nerve growth factor content levels after transient forebrain ischemia in gerbils. Neurosci Lett. 1992 [cited 2019 Aug 28];139:45–46. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​1407681.​
216.
Hasan N, McColgan P, Bentley P, Edwards RJ, Sharma P. Towards the identification of blood biomarkers for acute stroke in humans: a comprehensive systematic review. Br J Clin Pharmacol. 2012 [cited 2018 Dec 12];74:230–240. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​22320313.​
217.
Jickling GC, Sharp FR. Blood biomarkers of ischemic stroke. Neurotherapeutics. 2011 [cited 2018 Dec 12]. p. 349–60. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​21671123.​
218.
Monbailliu T, Goossens J, Hachimi-Idrissi S. Blood protein biomarkers as diagnostic tool for ischemic stroke: a systematic review. Biomark. Med. 2017 [cited 2019 Aug 28]. p. 503–12. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28598212.​
219.
Bustamante A, López-Cancio E, Pich S, Penalba A, Giralt D, García-Berrocoso T, et al. Blood biomarkers for the early diagnosis of stroke: the stroke-chip study. Stroke. 2017 [cited 2018 Dec 12];48:2419–2425. Available from: http://​www.​ncbi.​nlm.​nih.​gov/​pubmed/​28716979.​
220.
221.
Metadata
Title
Neurovascular Unit as a Source of Ischemic Stroke Biomarkers—Limitations of Experimental Studies and Perspectives for Clinical Application
Authors
Aleksandra Steliga
Przemysław Kowiański
Ewelina Czuba
Monika Waśkow
Janusz Moryś
Grażyna Lietzau
Publication date
01-08-2020
Publisher
Springer US
Keywords
Stroke
Biomarkers
Published in
Translational Stroke Research / Issue 4/2020
Print ISSN: 1868-4483
Electronic ISSN: 1868-601X
DOI
https://doi.org/10.1007/s12975-019-00744-5

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