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• W2103418085 abstract "Acta Neurologica ScandinavicaVolume 80, Issue s127 p. 36-48 Effect of hemodilution on regional cerebral blood flow Alexander Hartmann, Corresponding Author Alexander Hartmann Neurologische Universitätsklinik, 5300 Bonn, Fed. Rep. Germany.Address Alexander Hartmann Neurologische Universitätsklinik 5300 Bonn Fed. Rep. GermanySearch for more papers by this authorChristian Dettmers, Christian Dettmers Neurologische Universitätsklinik, 5300 Bonn, Fed. Rep. Germany.Search for more papers by this authorStefan Beyenburg, Stefan Beyenburg Neurologische Universitätsklinik, 5300 Bonn, Fed. Rep. Germany.Search for more papers by this author Alexander Hartmann, Corresponding Author Alexander Hartmann Neurologische Universitätsklinik, 5300 Bonn, Fed. Rep. Germany.Address Alexander Hartmann Neurologische Universitätsklinik 5300 Bonn Fed. Rep. GermanySearch for more papers by this authorChristian Dettmers, Christian Dettmers Neurologische Universitätsklinik, 5300 Bonn, Fed. Rep. Germany.Search for more papers by this authorStefan Beyenburg, Stefan Beyenburg Neurologische Universitätsklinik, 5300 Bonn, Fed. Rep. Germany.Search for more papers by this author First published: December 1989 https://doi.org/10.1111/j.1600-0404.1989.tb01809.xCitations: 10AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL References 1 Italian Acute Stroke Study Group. Haemodilution in acute stroke: results of the Italian hemodilution trial. Lancet 1988: I: 318– 321. 2 Hsu, CY, Norris JW, Hogan EL, Bladin P, Dinsdale HB, Yatsu FM, Earnest MP, Scheinberg P, Caplan LR, Karp HR, Swanson PD, Feldman RG, Mayman CT, Cobert B, Savitsky JP. Pentoxifylline in acute nonhemorrhagic stroke – a randomized placebo-controlled double blind trial. Stroke 1988: 19: 716– 722. 3 The Haemodilution in Stroke Study Group. Hypervolemic hemodilution treatment of acute stroke. Stroke 1989: 20: 317– 323. 4 Scandinavian Stroke Study Group. Multicenter trial of hemodilution in acute ischemic stroke. I. Results in the total patient population. Stroke 1987: 18: 691– 699. 5 Brassel F, Dettmers C, Nierhaus A, Hartmann A, Solymosi L. An intravascular technique to occlude the middle cerebral artery in baboons. Neuroradiology (in press). 6 Symon L, Branston NM, Chikovani O. Ischemic brain edema following middle cerebral artery occlusion in baboons. Stroke 1979: 10: 184– 191. 7 Hartmann A, Menzel J, Buttinger D, Lange E, Alberti E. Die regionale Gehirndurchblutung des Pavians beim ischämischen Hirninfarkt unter Dexamethason-Behandlung. Fortschr Neurol Psychiat 1981: 49: 380– 393. 8 Feeney DM, Baron J-C. Diaschisis. Stroke 1986: 17: 817– 830. 9 Whitmore RL. Rheology of the circulation. Pergamon Press, New York, 76. 10 Barbosa-Coutinho LM, Hartmann A, Hossmann KA, Rommel T. Effect of dexametasone on serum protein extravasation in experimental brain infarcts of monkey: an immunohistochemical study. Acta Neuropathol 1985: 65: 225– 259. 11 Ackermann RH. Positron imaging in stroke patients. In: 12th Research (Princeton) Conference eds: J Moossy, OM. Reinmuth Raven Press, New York 1981: 67– 72. 12 Wood HJ, Simeone FA, Finke EA, Golden MA. Correlative aspects of hypervolemic hemodilution with low-molecular-weight dextran after experimental cerebral arterial occlusion. Neurology 1984: 34: 24– 34. 13 Merrill EW. Rheology of blood. Physiol Rev 1969: 49: 863– 888. 14 Sakuta S. Blood filtrability in cerebrovascular disorders, with special reference to erythrocyte deformability and ATP content. Stroke 1981: 12: 824– 827. 15 Crotta J, Ackermann R, Correia J, Faillick G, Chang J. Whole blood viscosity parameters in cerebral blood flow. Stroke 1982: 13: 296– 301. 16 Thomas DJ, DuBoulay GH, Marshall J, Pearson TC, Russel RWR, Symon L, Whetherlay-Mein G, Zilkha E. Effect of haematocrit on cerebral flood flow in man. Lancet 1977: 2: 941– 943. 17 Toghi H, Uchiyama S, Ogawa M, Tabuchi M, Naguara H, Yamanouchi H. The role of blood constituents in the pathogenesis of cerebral infarction. Acta Neurol Scand 1979:(Supp. 1) 72: 616– 617. 18 Harrison MJ, Pollock S, Kendell BE, Marshall J. Effect of haematocrit on carotid stenosis and cerebral infarction. Lancet 1981: II: 114– 115. 19 Kannel WB, Gordon T, Wolf PA, McNamara P. Hemoglobin and the risk of cerebral infarction. The Framingham study. Stroke 1972: 3: 409– 420. 20 Meyer JS, Shimazu K, Fukuuchi Y, Ohuchi T, Okamoto S, Koto A, Ericsson AD. Impaired neurogenic cerebrovascular control and dysautoregulation after stroke. Stroke 1973: 4: 169– 186. 21 Schmid-Schönbein H. Factors promoting and preventing the fluidity of blood. In: Microcirculation, eds. RM Effrons, H Schmid-Schönbein, J. Ditzel Academic Press, New York, 1981: 249– 2166. 22 Wood JH, Kee DB. Clinical rheology of stroke and hemodilution. In: Stroke, Pathophysiology, Diagnosis and Management. eds. HJM Barnett, JP Mohr, BM Stein, FM. Yatsu Churchill Livingstone, New York, 1986: 97– 108. 23 Dintenfass L. Blood microrheology: Viscosity factors in blood flow, ischemia and thrombosis. Appleton-Centrury-Crofts, New York, 1971: 5– 129, 266–355. 24 Fahreaeus R, Linqvist T. The viscosity of blood in narrow capillary tubes. Am J Physiol 1931: 96: 562– 568. 25 Gaehtgens P, Albrecht KH, Kreutz F. Fahraeus effect on cell screening during tube flow in human blood. I: Effect of variation of flow rate. Biorheology 1978: 15: 147– 154. 26 Hochmuth RM, Davis DO. Changes in hematocrit for blood flow in narrow tubes. Bibl. Anat 1985: 10: 59– 65. 27 Wells RE. Rheology of blood in the microvasculature. N Engl J Med 1964: 270: 832– 839. 28 Dintenfass L. Inversion of the Fahraeus-Linqvist phenomenon in blood flow through capillaries of diminishing radius. Nature 1967: 275: 1099– 1100. 29 Yen RT, Fung YC. Inversion of Fahraeus effect and effect of mainstream flow of capillary hematocrit. J Appl Physiol 1977: 4: 578– 586. 30 Mchedlishvili G, Varazashvili M. Red cell/plasma ratio in blood flowing in microvascular bed under control and ischemic conditions. Microvasc Res 1981: 21: 302– 307. 31 Whitmore RL. Rheology of circulation. Pergamon Press, Oxford, 1969: 37– 46, 109–133. 32 Johnson G, Kreagy BY, Ross DW, Gabriel DA, Lucas CI, Hardison VS. Viscous factors in peripheral tissue perfusion. J Vasc Surg 1985: 2: 530– 535. 33 McHenry LD, West JW, Cooper ES, Goldberg HI, Jaffe ME. Cerebral autoregulation in man. Stroke 1974: 5: 695– 704. 34 Symon L, Branston NM, Strong AJ. Autoregulation in acute focal ischemia: An experimental study. Stroke 1976: 7: 547– 554. 35 Thomas DJ. Whole blood viscosity and cerebral blood flow. Stroke 1982: 13: 285– 287. 36 Wade JPH. Transport of exygen to the brain in patients with elevated haematocrit values before and after venesection. Brain 1983: 106: 513– 523. 37 Kee DB, Wood JH. Rheology of the cerebral circulation. Neurosurgery 1984: 15: 125– 131. 38 Wood JH, Simeone FA, Fink EA, Golden MA. Hypervolemic hemodilution in experimental focal cerebral ischemia: Elevations of cardiac output, regional cortical blood flow, and ICP after intravascular volume expansion with low molecular dextran. J Neurosurg 1983: 59: 500– 509. 39 Wood JH, Simeone FA, Snyder LL, Fink EA, Golden MA. Hemodilution and non-hemodilutional hypervolemia in treatment of focal cerebral ischemia. J Cereb Blood Flow Metab 1981: 1:(Suppl. 1) 178– 179. 40 Sundt TM, Waltz AC, Sayre GP. Experimental cerebral infarction: Modification by treatment with hemodilution, hemoconcentrating and dehydrating agents. J Neurosurg 1967: 26: 46– 56. 41 Wood JH, Simeone FA, Kron RE, Litt M. Rheological aspects of experimental hypervolemio hemodilution with low-molecular-weight dextran. Relations of cortical blood flow, cardiac output and intracraniel pressure to fresh blood viscosity and plasma volume. Neurosurger 1982: 11: 739– 753. 42 Tsuda Y, Hartmann A, Weiand J, Solymosi L. Comparison of the effects of infusion with hydroxyethyl starch and low molecular weight dextran on cerebral blood flow and hemorheology in normal baboon J Neurol Sci 1987: 82: 171– 180. 43 Wood JJ, Snyder LL, Simeone FA. Failure of intravascular volume expansion without hemodilution to elevate cortical blood flow in region of experimental focal ischemia. J Neurosurg 1982: 56: 80– 91. 44 Wood JH, Simeone FA, Snyder LL. Cortical oxygen transport during hypervolemic hemodilutional therapy for focal cerebral ischemia. Neurosurg 1982: 10: 781 (abstract). 45 Kummer VR, Scharf J, Reich H, Machens HG, Wildemann B, Back T. The effect of isovolemic hemodilution on local cerebral blood flow under normotensive and dypotensive conditions. J Cer Blood Floow Metab 1987 7:Suppl. 1, s. 289. 46 Kummer VR, Scharf J, Back T, Reich H, Machens HG, Wildemann B. Autoregulatory capacity and the effect of isovolemic hemodilution on local cerebral blood flow. Stroke 1987: 19: 594– 597. 47 Muizelaar JP, Wei EP, Kontos HA, Becker DP. Cerebral blood flow is regulated by changes in blood presure and in blood viscosity alike. Stroke 1986: 17: 44– 48. 48 Hint H. The parmacology of dextran and the physiological background for the clinical use of rheomacrodex and macrodex. Acta Anaesthesiol Belg 1968: 19: 119– 138. 49 Czer LSC, Shoemaker WC. Optimal hematocrit value in critically ill postoperative patients. Surg Gynecol Obstet 1978: 147: 363– 368. 50 Fan F-C, Chen RYZ, Schuessler GB, Chien S. Effects of hematocrit variations on regional hemodynamics and oxygen transport in the dog. Am J Physiol 1980: 238: H45– H52. 51 Michenfelder JD, Theye RA. The effects of profound hypocapnia and dilutional anemia on canine cerebral metabolism and blood flow. Anesthesiology 1969: 31: 449– 457. 52 Johannsson H, Siesjo BK. Blood flow and oxygen consumption in the rat brain in dilutional anemia. Acta Physiol Scand 1974: 91: 136– 138. 53 Kee DB, Wood JH. Experimental hemodynamics and rheologic alterations of blood flow through carotid stenosis following hemodilution. Neurology 1986: 36: 230 (abstract). 54 Wells RE, Merrill EW. Influence of flow properties of blood upon viscosity- - hematocrit relationships. J Clin Invest 1962: 41: 1591– 1598. 55 Ott EO, Ladurner G, Lechner H. Relationship between disturbed rheological properties and cerebral hemodynamics in recent cerebral infarction. Prog Biochem Pharmacol 1977: 13: 349– 352. 56 Sakuta S. Blood filtrability in cerebrovascular disorders, with special references to erythrocyte deformability and ATP content. Stroke 1981: 12: 824– 828. 57 Couch JR, Hassanein RS. Platelet aggregation, stroke and transient ischemic attack in middle-aged and elderly patients. Neurology 1976: 26: 88– 895. 57a Chan R, Leniger-Follert E. Effect of isovolemic hemodilution on oxygen supply and electrocorticogram in cat brain during focal ischemia and in normal tissue. Int J Microciro Clin Exp 1973: 2: 297– 395. 58 Eisenberg S. Blood viscosity and fibrinogen concentration following cerebral infarction. Circulation 1966: 33:(Suppl. 2), 10– 14. 59 Kee DB, Wood JH. Blood viscosity and cerebral blood flow. In: 14th Princeton Conference eds. F Plum, WA Pulsinelli Raven Press, New York, 1985: 107– 117. 60 Heiss WD, Prosenz P, Tschabitscher H, Lasek C, Herles HJ. Effect of low molecular weight dextran on total cerebral blood flow and on regional flow within ischemic brain lesions. Eur Neurol 1972: 8: 129– 133. 61 Wood JH, Polyzoidis KS, Epstein CM, Gibby GL, Tindall GT. Improvements in cerebral blood flow and power spectral EEG after isovolemic hemodilution in stroke patients. J Cereb Blood Flow Metab 1983: 3(Suppl 1) 588– 589. 62 Wood JH, Polyzoidis KS, Epstein CM, Gibby GL, Tindall GT Quantitative EEG alterations after isovolemic hemodilutional augmentation of cerebral perfusion in stroke patients. Neurology 1984: 34: 764– 768. Citing Literature Volume80, Issues127December 1989Pages 36-48 ReferencesRelatedInformation" @default.
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