Verfügbarkeit: Biofluid mechanics

Biofluid mechanics: proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany

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Format:	Tagungsbericht Buch
Sprache:	Undetermined
Veröffentlicht:	Düsseldorf VDI-Verl. 1994
Ausgabe:	Als Ms. gedr.
Schriftenreihe:	Fortschritt-Berichte / VDI : Reihe 17, Biotechnik 107
Schlagworte:	Biofluidmechanik Kardiovaskuläre Krankheit Blutkreislauf Kardiovaskuläres System Hämodynamik Konferenzschrift > 1994 > München
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Literaturangaben
Beschreibung:	X, 741 S. Ill., graph. Darst.
ISBN:	3183107171

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Datensatz im Suchindex

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adam_text	Table of Contents Foreword .................................................................................................................................. ι Sponsors .................................................................................................................................... и Table of contents ............................................................................................................... m Clinical Studies: Anatomical and Physiological Models Secondary flows in the cardiovascular system: The pivotal role of phase separation Schmid-Schönbein, H ...........................................................................................................1 Hemodynamics and the afferent artery of arteriovenous fistulae Stehbens W.E., Jones, G. T. .................................................................................................5 Special fluid dynamic profiles in different models of arteriovenous fistulas: Consequences for patients on dialysis Pflugbeil, G. .Tröster, J., Kurz, P., Liepsch, D., Maurer.P.C ............................................... U Determination of pulse wave velocity in arteries with pressure tip catheters leads to incorrect results Schima, H., Raderer, F., Tsangaris, S., Siegl, H.Jrubel, W., Moritz W............................. /5 Angjography method for fluid mechanical studies Smedby, Ö .........................................................................................................................21 The role of geometry and distensibility of the infra-renal and aorto-iliac bifurcations in arterial disease Roach, МЯ. Fung, K., MacLean, NJ> ................................................................................27 Shear rate and thrombin transport Affeld,K.,Gadischke,J ......................................................................................................35 Physiological and Clinical Studies Biomechanics and the transport function of veins Kenner, T ...........................................................................................................................41 Validation and use of an optical technique for the measurements of pulse wave velocity in conduit arteries Bonner, S.E., Dawson, R., Martyn, CJV., Greenwald, S.E ...................................................43 Endothelial and vein wall response to turbulent shear stress from arteriovenous anastomoses (AVAs) Schalin, L., Moberger, G ....................................................................................................53 In vitro blood flow visualization in vein models with different size clots trapped in a classical Opcetra and a symmetrical Antheor caval filter Morin, G., Perrault, R., Doffin, J., Fourgeau P.................................................................. 67 Is reflux necessary for closng a venous valve? Qui, Y., Wang, S.-K., Hwang, N.H.C .................................................................................73 Mechanoluminescence of blood flow Orel,V.E ............................................................................................................................S3 Noninvasive estimation of left ventricular max (dP/dt) from aortic flow acceleration and pulse wave velocity Sugawara, M., Senda S., Masugata H., Nishiya T., Matsuo H............................................ 89 Heart rate influence on arterial compliance using pressure contour wave analysis Segers, P., Verdonck, P., Verhoeven R., Duprez D., Debuyzere, M..................................... 91 Effects of cardiac contraction on the microvessels in the interveniricular system Pfeffer, M., Goto, M., Yada T., Tachibana, H., Hiramatsu, O., Kajiya F ..........................103 СТ analysis of the role of uiac distensibility in balloon angioplasty MacLean, N.F., Boyd, CJ., Sherebrin, M.H., Rankin RU., Fenster Α., Roach,MJ( ...................................................................................................................... IW Coronary bypass monitoring with a new method for the assessment of bypass hemodynamic-methods and clinical experiences Schmidt, P., Lass, M., Brucher. R., Paulát, К. Ven U. Helferich., D., FrenkenbergerH., НаппекшпА ..................................................................................... Н7 Blood pressure and velocity relation in tissue Wang, WX., Hsu TL., Chen HL ..................................................................................... 1 19 Surface properties of airway mucus exposed to acid aerosol Lee, MM., Green, F.H.Y., Zhang, Y., Schurch, S .............................................................133 MRI Studies Magnetic resonance (MR) angiography of the coronary arteries Scheidegger, MB., Vassalli, G., Hess, ОМ., Boesiger, P.................................................145 In vivo magnetic resonance blood flow measurements in vessels with complex flow patterns Botnar, R., Scheidegger, MB., Meier D., Boesiger, P. .....................................................149 Magnetic resonance angiography of the human carotid bulb 1. Flow visualization in human arterial castings. Kerber, C.W., Buxton, R£, Knox, К .................................................................................153 Magnetic resonance angiography of the human carotid bulb 2. Experimental evaluation of MR accuracy and artifacts Buxton, RB, Frank, LM., Kerber C.W .....................................,.......................................154 New methods for the evaluation of pressure and flow patterns in the coronary arteries and aortic root Einav,S.,Zaretsky, U .......................................................................................................155 Magnetic resonance: a new method for studying the hemodynamics of artificial bean valves? A comparison with LDA Walker, P.G., Oyre S., Pedersen EM.. Fontaine, Α Α., Yoganathan AJ>.........................167 Vascular imaging: Current status and problems Hübsch, Ρ......................................................................................................................... 173 Curvature and Branching Studies Quantitative morphology of arterial casts Matsuo,T.,Okeda,R ........................................................................................................ ¡si Contribution of flow choking to dynamic stenosis resistance Ku, DJN., Powell, B.E., Downing, JM ..............................................................................187 Dependence of fibrin thrombsis formation in an arterial branching model on shear and residence time Reininger, AJ., Reininger, СВ., Heinzmann, W., Wurzinger. LJ. ....................................197 Secondary flow augmentation in the diastolk; phase of physiologically intermittent fio w in a curved tube Konno, T., Satoh. Y.. Tanishita, К........................................................ 205 Analysis of error in arterial propagation coefficient measurement Bertram, CD., She, J .......................................................................................................271 Shear stress and exposure times within severely stenosed coronary and carotid arteries Ringers, S.E., Boreda R., Fatemi, R.S ..............................................................................225 Potential for hemodynamic stimulation of platelets at critical coronary stenoses Rittgers, S.E., Acharya, S., Mugler, DM ..........................................................................237 Analysis of blood flow field in glass capillaries and in vivo microvessels by axial tomographic and image velocimetry techniques Singh, M., Prakash В ........................................................................................................239 Experimental analysis of Newtonian and non-Newtonian fluids pulsatile flow through elastic Y models Mijovic,B.,Liepsch,D .....................................................................................................255 Collapsible Tubes Mathematical modeling for the unsteady flow separation through a collapsible channel Matsumoto, T., Matsuzaki, Y. ..........................................................................................261 Towards a rational description of flow in collapsible tubes. Pedley, TJ., Lowe, T.W., їмо, СУ., Rast, M.P.................................................................271 On the collapse of compliant axisymmetric stenoses: conditions and nature of collapse and effects on velocity distribution Stergiopulos.N., Moore J.E.,GolayX.,Ku DJV., Meister J.-J ..........................................273 Measurement of oscillatory flow pressure gradient in an elastic tube Cohen, MJ., Wang, D.M. Tárbeli, JM............................................................................. 283 Heart and Heart Valve Studies Hydrodynamic characteristics of a new stentless mitral valve allograft: in vitro results Vetter, H.O., Yoganathan A.P., Fontaine Α., Erhorn, А.ДеіспапВ .................................287 In vitro study of occluder cinematics of the SJM aortic heart valve protheses in pulsatile flow Brücker, С, Köhler, J.......................................................................................................295 In vitro steady flow 3-D turbulence structure distal to normal and stenosed aortic valve prostheses Fontaine, AA., Walker P.G., Yoganathan, AJ>.................................................................307 In vitro steady leakage jet formation of technical heart valves protheses- a photo-video optical and colour Doppler study Köhler, J., Wim, R., Fehske, W ........................................................................................5/5 Influence of rheological behavior of model fluids on the in-vitro testing of artificial heart valves Pohl, M., Wendt, M.O., Werner, S., Koch, В., Lerche, D., Affeid, К., Schicht, К ........................................................................................................................324 In vitro evaluation of the hydraulic opening area of heart valve prostheses- the influence of test fluid rheology and valve type Wendt, MO., Werner, S. Kuhnei R., Pohl M., Koch В., Lerche D.....................................325 Prosthetic heart valve cavitation in blood Garrison, LA., Lamson, T.C. Deutsch S., GeselowitzDB., Tárbeli, JM .........................................................................·........................................... 327 ¡п -vitro imaging of nomai and thrombosed bileaflet valves: mechanics of impaired leaflet opening. Rambod, £., Gharib, M., Einav. S ...................................................................................331 Hydrodynamic aspects of artificial heart valves and total artificial heart replacement Klimeš, F .......................................................................................................................... 333 The influence of rheological components on blood flow in vascular prostheses Yurechko, VJt., Shtengold, EM., Ilminsky, VM., Filin, EM., Frey, R............................. 341 Dynamic filling characteristics of the left ventricle Gharib, M., Hammache, M., Rambod.E., Shiota, T., Sahn, D..........................................343 Ultrasound Studies Slosh phenomenon of coronary arterial flow and its patholphysiological significance Kajiya, F., Matsumoto, T., Yoda, T., Hiramatsu, O., Kimura Α., Goto, M., Ogasawara, Y., Tachibana, H., Tsujioka, К ......................................................347 Color-Doppler-rheography: Principles and experimental results Hammentgen, R., Schmidt, H., Klapp, Α., Godder, VS., Schiffmann, J., Papenfuß, HJ-.G/eichman, U ..................................................................354 Color-Doppler-rheography: Physiological range of the fluid dynamics in large vessels Hammentgen, R., Schmidt H., Schiffmann, J., Papenfuß, HJ., Gleichmann, U ................................................................................................................355 Color-Doppler rheography: Monitoring of the fluid dynamics in die common carotid artery during extracorporal circulation in open heart surgery Hammentgen. R., Шпаті, J., Schmidt, HJ., Nirow, N., Dramburg. W., Schiffmann, J., Papenfuß, H. J., Gleichmann, U., Körfer, R ............................................356 Evaluation of wall and atherosclerotic plaque motion in the carotid bifurcation using 4D ultrasound Meairs, S., Hennerici, M .................................................................................................357 Dynamics of asymmetric régurgitant jets: effect on color Doppler jet areas Rambod, E., Einav, S ......................................................................................................363 On the use of the Womersley s theory for nie computing of hemodynamical parameters from ultrasonic velocity profiles: an in vivo application to the case of the blood viscosity. Bensalah, Α., F laud, Ρ..................................................................................................... 365 Duplex sonography with color flow imaging for the assessment of hemodynamics in carotid artery disease vonReutern.GM ............................................................................................................366 Analysis of LDA and ultrasound Doppler data obtained in models of carotid bifurcation with rough surface in carotid sinus Kaluzynski, W.Mepsch.D.W. .........................................................................................367 Doppler frequency of spectral broadening as an indicator of the severity of arterial stenoses Talukder, NX. Talukder, K. ..................................................................................375 Understanding Doppler ultrasound data of mitral valve flow using lumped parameter modeling Verdonck, P., Segers, P., Verhoeven, R............................................................................. 381 Mathematical Models Nonlinear wave and chaos in large blood vessels Bao, G.............................................................................................................................. 392 The axisymmetric haemodynamic analysis of blood flow with intra aortic balloon pumping Chen.B.-F ........................................................................................................................393 Optimisation of blood flow measurement in large vessels Ciupa, R.V., Ciupa, AA ..................................................................................................395 A mock arterial circulation via computer Duros, J., Kufahl, R.H., Clark, M.E .................................................................................399 A theoretical model for wave propagation in arteries Gupta, R.S ........................................................................................................................411 A mathematical hypothesis for renal arterial stenosis in renal transplantation Coli, L., Buscaroli, В., Mosconi, G., Guiidicissi, G., De Giovanni, P., Moschetta, МЯ., Paltotti, Α., Pallotti.G., Pettazzoni, P., Stefoni, S ..................................421 Modeling of flow field around aortic artificial valves Wojnarowski, J., Mirota, К ...............................................................................................429 Numerical Studies Respiratory rhythm effects on the total cavopulmonary connection fluid dynamics Dubini, G., Capprarucci, L., de Levai МЯ., Pietrabissafi-, Montevescchi, FM., Fumerò Д .........................................................................................445 Pulsatile flow in aorto-coronary bypass 3-D model Inzoli, F., Migliavacca, F., Maniero, S .............................................................................455 Numerical simulation of blood flow in large vessels on massively parallel computers Matsuzawa.T ...................................................................................................................464 Numerical simulation of mass transport in arterial systems Rappitsch, G., Përktold, К............................................................................................... .465 Problems in application of viscoelastic models to the numerical analysis of arterial blood flow Perktold, K., Leuprecht, Α., Peter R.0 ..............................................................................471 The effect of moving walls on pulsating flows: relation to the coronary blood flow Tsangaris, S., Rammos, KS., Pappou Th., Koullias G., Panagopoulos, F.G .....................477 Particle flow behaviour and pressure distribution in a 3-D T-junction Xu.XY., Collins,M.W. ....................................................................................................489 Row details and fluid particle paths in model by-pass grafts Henry, FS., Hughes, P.E., How, T.V., Collins, M.W. ........................................................497 Endothelial Cells Hemodynamics, the endothelium and atherosclerosis Nerem,R.M .....................................................................................................................-508 The intracellular calcium response of single endothelial cells subjected to fluid- imposed steady and pulsatile shear stress. Helmlinger. G., Berk, B.C., Nerem. RM.......................................................................... 509 The role of GPiB and GPIIb -Ша in the adhesion and aggregation of platelets on human type VI collagen under physiological shear conditions. Ross, JM., Mclnňre, L.V., MoakeJL., Rand, J M ..........................................................523. Fluid shear stress changes the levels of expression of adhesion molecules on human umbilical vein endothelial cells in vitro Sampath, R., Kukiełka, GL., Smith, C.W., Eskin, S. G. Mclntire, L.V. .............................531 The design of an apparatus for subjecting vascular endothelium to physiologic levels of boui fluid shear stress and circumferential cyclic stretch Suciu, A, Zhao, S. Moore, J.E. Burki, E., Burnier, M., Brunner, НЯ., Meister, J J .....................................................................................................................541 Flow direction affects shape and cytoskeletal structure of cultured bovine aortic endothelial cells Kataoka, N.. Ujita S., Ogawa Y., Sato, M ........................................................................551 Arterial endothelial cells align to reduce the local shear stress Yamaguchi.T. .................................................................................................................-557 Endothelial glycosaminoglycan synthesis increased by laminar shear stress Mitsumata, M., Arisaka, T., Kawasumi, M., Yoshida, Y ...................................................563 Flow Visualization and LDA Studies Determination of low wall shear stress regions within ventricular assist devices using mass transfer techniques Clark, C, Jin, W ..............................................................................................................564 Particle-Image-Velocimetry (PTV)-a tool for measuring unsteady vortical flows in models of branching vessels: Application to the confluent flow in a rigid W-T-junction Bräcker, С ....................................................................................................................... J65 Swirl in Fontän connections: flow visualization and LDA studies Kim, YM., Fontaine, Α Α., Walker, P.G., На, В., Lucas, CL., Yoganathan, A.P............................................................................................................. _577 Experimental study of pulsatile flow in elastic model of PETP vascular graft Konfrst, J., Uepsch, D.W., Weigernd, К........................................................................... 582 Development of fiber optic laser Doppler velocimeter for measurements of local blood velocity Ohba,K.,YoshiokaK ...................................................................................................... S83 An in vitro arterial preparation for acute study of endothelial permeability responses to defined shear stress conditions Waliszweski, M., FryD., Kuban В., Friedman, M ............................................................585 LDA measurements in anatomically distensible carotid artery models under physiological conditions. Uepsch, D.W., Pflugbeil, G.. Maurer, P.C, Weigand, K ..................................................593 Effect of secondary flow on wall shear stress through asymmetrical branch during laminar steady flow Yamaguchi, R ................................................................................................................... 6О3 Laser fluorescence detection of plaque Unsold, £., Ischinger, T., Pesarini, A ...............................................................................612 Arterial Grafts-Anastomosis Flow patterns and wall shear stress in a mildly stenosed femoral artery Cavalcanti, S.................................................................................................................... 613 Hemodynamic effects of arterial graft design: A simulation study Cavalcanti, S., Gnudi, G................................................................................................... 619 An in vitro model study of cerebral circulation in presence of carotid stenoses BossuetPh., Cassot, F., Marc-Vergnes, J.P., Fušeri J., Rieu, R ........................................627 Fluid mechanical simulation of left ventricular aneurysms Merzkirch, W., Hodlaná, P. H ...........................................................................................635 Wall shear stress and flow pattern through the anterior communicating artery model in steady flow Ujiie, H., Okabe, H., Yamaguchi, R., Takakura, K............................................................ 641 The hemodynamics of arterial prosthesis Pelle, G., Radier, C, Oddou, C ........................................................................................652 New volumetric parameters and ratios in abdominal aortic aneurysms and their potential influence on indication for elective surgery Coppellar, WA., Engelmann, H., Furst H., Blechschmidt, S., Wild, M., Lauterjung, L..................................................................................................................653 Effects of compliance and diameter mismatch on the wall shear rate distribution near an end-to-end anastomosis model Weston, M.W., Rhee, K., Tárbeli J . M ...............................................................................657 Rheological Studies The effect of blood viscoelasticity on pulsatile flow in straight tubes Sharp, M ..........................................................................................................................663 Structural dynamics of red blood cell aggregates under flow Chen, S., Barshteinß., Gavish, В., Yedgar, S ...................................................................681 Model fluids for blood, rheological and shear induced damage behavior of polymer solutions Lerche, D., Koch, В., Pohl, M., Vlastos, G., Affled, К ......................................................682 Other methods to determine the viscosity of blood Silber, G.R.......................................................................................................................683 Microstructure of viscous aqueous solutions Barshtein, G., Almagor, Α., Yedgar, S., Gavish, В ............................................................691 Simulation of non-Newtonian blood flow in human fetal branches with complex geometry Hellevik, LA., Irgens, F., Kiserud. T., Ytrehus. T., Eik-Nes,H .........................................692 Influence of non-Newtonian blood properties on numerical flow simulation at mechanical heart valves prostheses Eilers, R.., Ritter, Chr., Reul, H., Rau, G ..........................................................................693 Influence of blood rheology on cancer therapy Shulman, Z.P., Makhanek, A. A ........................................................................................701 Arterial Wall A model for blood flow through a tapered tube with mild stenosis Tandon, PN., Rana, U.V. S ................................................................................................703 Models of arterial permeability dynamics Friedman, M.H., Henderson, J.M., Fry DZ......................................................................717 Wave propagation of blood velocity and vessel diameter influence of the wall rheology Rogova J., Bensalah, Α., Flaud P., Oddou, С ...................................................................726 Analysis of the forward and backward running waves in arteries: the role of nonlinear wall elasticity Stergiopulos, N., Pythoud, F., Meister, J.-J. .....................................................................727 Blood pressure and mechanical properties of arterial wall in aortic dissection He, СМ., Roach, M Л..................................................................................................... 733
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genre	(DE-588)1071861417 Konferenzschrift 1994 München gnd-content
genre_facet	Konferenzschrift 1994 München
id	DE-604.BV009780717
illustrated	Illustrated
indexdate	2024-07-09T17:40:47Z
institution	BVB
institution_GND	(DE-588)2138603-1
isbn	3183107171
language	Undetermined
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-006472031
oclc_num	231625295
open_access_boolean
owner	DE-29T DE-M347 DE-12 DE-91G DE-BY-TUM DE-210
owner_facet	DE-29T DE-M347 DE-12 DE-91G DE-BY-TUM DE-210
physical	X, 741 S. Ill., graph. Darst.
publishDate	1994
publishDateSearch	1994
publishDateSort	1994
publisher	VDI-Verl.
record_format	marc
series2	Fortschritt-Berichte / VDI : Reihe 17, Biotechnik
spelling	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany Dieter Liepsch (ed.) Als Ms. gedr. Düsseldorf VDI-Verl. 1994 X, 741 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Fortschritt-Berichte / VDI : Reihe 17, Biotechnik 107 Literaturangaben Biofluidmechanik (DE-588)4203925-3 gnd rswk-swf Kardiovaskuläre Krankheit (DE-588)4024666-8 gnd rswk-swf Blutkreislauf (DE-588)4134345-1 gnd rswk-swf Kardiovaskuläres System (DE-588)4024665-6 gnd rswk-swf Hämodynamik (DE-588)4022810-1 gnd rswk-swf (DE-588)1071861417 Konferenzschrift 1994 München gnd-content Kardiovaskuläres System (DE-588)4024665-6 s Hämodynamik (DE-588)4022810-1 s DE-604 Kardiovaskuläre Krankheit (DE-588)4024666-8 s Biofluidmechanik (DE-588)4203925-3 s Blutkreislauf (DE-588)4134345-1 s Liepsch, Dieter 1940- Sonstige (DE-588)108692086 oth International Symposium on Biofluid Mechanics and Biorheology 3 1994 München Sonstige (DE-588)2138603-1 oth VDI Fortschritt-Berichte Reihe 17, Biotechnik ; 107 (DE-604)BV000903783 107 Digitalisierung TU Muenchen application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=006472031&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany Biofluidmechanik (DE-588)4203925-3 gnd Kardiovaskuläre Krankheit (DE-588)4024666-8 gnd Blutkreislauf (DE-588)4134345-1 gnd Kardiovaskuläres System (DE-588)4024665-6 gnd Hämodynamik (DE-588)4022810-1 gnd
subject_GND	(DE-588)4203925-3 (DE-588)4024666-8 (DE-588)4134345-1 (DE-588)4024665-6 (DE-588)4022810-1 (DE-588)1071861417
title	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany
title_auth	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany
title_exact_search	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany
title_full	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany Dieter Liepsch (ed.)
title_fullStr	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany Dieter Liepsch (ed.)
title_full_unstemmed	Biofluid mechanics proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany Dieter Liepsch (ed.)
title_short	Biofluid mechanics
title_sort	biofluid mechanics proceedings of the 3rd international symposium july 16 19 1994 munich germany
title_sub	proceedings of the 3rd International Symposium, July 16 - 19 1994, Munich, Germany
topic	Biofluidmechanik (DE-588)4203925-3 gnd Kardiovaskuläre Krankheit (DE-588)4024666-8 gnd Blutkreislauf (DE-588)4134345-1 gnd Kardiovaskuläres System (DE-588)4024665-6 gnd Hämodynamik (DE-588)4022810-1 gnd
topic_facet	Biofluidmechanik Kardiovaskuläre Krankheit Blutkreislauf Kardiovaskuläres System Hämodynamik Konferenzschrift 1994 München
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=006472031&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
volume_link	(DE-604)BV000903783
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