Access the full text.
Sign up today, get DeepDyve free for 14 days.
N. Otsu (1979)
A Threshold Selection Method from Gray-Level HistogramsIEEE Trans. Syst. Man Cybern., 9
YC Fung (1996)
Biomechanics: circulation
P. Blennerhassett (1976)
Secondary motion and diffusion in unsteady flow in a curved pipe
Satjit Adlakha, M. Sheikh, Jason Wu, M. Burket, U. Pandya, William Colyer, E. Eltahawy, C. Cooper (2010)
Stent fracture in the coronary and peripheral arteries.Journal of interventional cardiology, 23 4
P. Sengupta, R. Burke, B. Khandheria, M. Belohlavek (2008)
Following the flow in chambers.Heart failure clinics, 4 3
J. Womersley (1955)
Method for the calculation of velocity, rate of flow and viscous drag in arteries when the pressure gradient is knownThe Journal of Physiology, 127
R. González, R. Woods, S. Eddins (2006)
Digital image processing using MATLAB
Kartik Bulusu, M. Plesniak (2013)
Secondary flow morphologies due to model stent-induced perturbations in a 180° curved tube during systolic decelerationExperiments in Fluids, 54
P. Stonebridge, P. Hoskins, P. Allan, J. Belch (1996)
Spiral laminar flow in vivo.Clinical science, 91 1
D. Alexopoulos, I. Xanthopoulou (2011)
Coronary stent fracture: how frequent it is? Does it matter?Hellenic journal of cardiology : HJC = Hellenike kardiologike epitheorese, 52 1
J. Popma, K. Tiroch, A. Almonacid, Sidney Cohen, D. Kandzari, M. Leon (2009)
A qualitative and quantitative angiographic analysis of stent fracture late following sirolimus-eluting stent implantation.The American journal of cardiology, 103 7
M. Friedman (2009)
Variability of arterial wall shear stress, its dependence on vessel diameter and implications for Murray's Law.Atherosclerosis, 203 1
T. Karino, H. Goldsmith, M. Motomiya, S. Mabuchi, Y. Sohara (1987)
Flow Patterns in Vessels of Simple and Complex Geometries aAnnals of the New York Academy of Sciences, 516
K. Sudo, M. Sumida, R. Yamane (1992)
Secondary motion of fully developed oscillatory flow in a curved pipeJournal of Fluid Mechanics, 237
E. Cecchi, C. Giglioli, S. Valente, C. Lazzeri, G. Gensini, R. Abbate, L. Mannini (2011)
Role of hemodynamic shear stress in cardiovascular disease.Atherosclerosis, 214 2
A. Varun, K. Balasubramanian, R. Sujith (2008)
An automated vortex detection scheme using the wavelet transform of the d2 fieldExperiments in Fluids, 45
S. Robinson (1991)
Coherent Motions in the Turbulent Boundary LayerAnnual Review of Fluid Mechanics, 23
A. Malek, S. Alper, S. Izumo (1999)
Hemodynamic shear stress and its role in atherosclerosis.JAMA, 282 21
A. Glenn (2011)
Classification of Secondary Vortices in a Curved Pipe Model of an Artery
J. Montanero, C. Ferrera, V. Shevtsova (2008)
Experimental study of the free surface deformation due to thermal convection in liquid bridgesExperiments in Fluids, 45
(1996)
The ineffectiveness of the correlation coefficient for image comparisons
S. Deutsch, J. Tarbell, K. Manning, G. Rosenberg, A. Fontaine (2006)
EXPERIMENTAL FLUID MECHANICS OF PULSATILE ARTIFICIAL BLOOD PUMPSAnnual Review of Fluid Mechanics, 38
G. Dai, M. Kaazempur-Mofrad, S. Natarajan, Yuzhi Zhang, Saran Vaughn, B. Blackman, R. Kamm, G. Garcı́a-Cardeña, M. Gimbrone (2004)
Distinct endothelial phenotypes evoked by arterial waveforms derived from atherosclerosis-susceptible and -resistant regions of human vasculature.Proceedings of the National Academy of Sciences of the United States of America, 101 41
B. Lieber (1999)
Arterial Macrocirculatory Hemodynamics
Williams Kj, I. Tabas (1999)
Atherosclerosis--an inflammatory disease.The New England journal of medicine, 340 24
Y. Hoi, Yu-Qing Zhou, Xiaoli Zhang, R. Henkelman, D. Steinman (2011)
Correlation Between Local Hemodynamics and Lesion Distribution in a Novel Aortic Regurgitation Murine Model of AtherosclerosisAnnals of Biomedical Engineering, 39
H. Himburg, M. Friedman (2006)
The Frequency Dependent Response of the Vascular Endothelium to Pulsatile Shear StressThe FASEB Journal, 20
S. Peterson, M. Plesniak (2008)
The influence of inlet velocity profile and secondary flow on pulsatile flow in a model artery with stenosisJournal of Fluid Mechanics, 616
A. Neto, L. Rittner, N. Leite, D. Zampieri, R. Lotufo, André Mendeleck (2007)
Pearson's Correlation Coefficient for Discarding Redundant Information in Real Time Autonomous Navigation System2007 IEEE International Conference on Control Applications
S. Kailas, R. Narasimha (1999)
The eduction of structures from flow imagery using wavelets Part I. The mixing layerExperiments in Fluids, 27
(1999)
degradation along medial and lateral walls of the rabbit aortoiliac bifurcation. Arteriosclerosis 10:686–694
Sung Kim, Hyun Kim, Seong Han, Sang Jung, Jun Kim, H. Chee, K. Ryu (2009)
A fractured sirolimus-eluting stent with a coronary aneurysm.The Annals of thoracic surgery, 88 2
M. Thiriet, K. Parker (2009)
Physiology and pathology of the cardiovascular system: A physical perspective
(1996)
Biomechanics: circulation, 2nd edn
Yang, Mohiaddin (1999)
Automatic tracking of vortical flow patterns with MR velocity mapping, 1
M. Carbonaro (2004)
von Karman Institute for Fluid Dynamics
WR Dean (1928)
The streamline motion of a fluid in a curved pipePhil Mag, 7
H. Mallubhotla, G. Belfort, W. Edelstein, T. Early (2001)
Dean vortex stability using magnetic resonance flow imaging and numerical analysisAiche Journal, 47
Ronald Adrian, Kenneth Christensen, Z. Liu (2000)
Analysis and interpretation of instantaneous turbulent velocity fieldsExperiments in Fluids, 29
E. Vega, J. Montanero, J. Fernández (2009)
On the precision of optical imaging to study free surface dynamics at high frame ratesExperiments in Fluids, 47
David Holdsworth, David Holdsworth, C. Norley, Richard Frayne, David Steinman, David Steinman, B. Rutt, B. Rutt (1999)
Characterization of common carotid artery blood-flow waveforms in normal human subjectsPhysiological Measurement, 20
C. Schram, M. Riethmuller (2001)
Vortex ring evolution in an impulsively started jet using digital particle image velocimetry and continuous wavelet analysisMeasurement Science and Technology, 12
M. Jarrahi, C. Castelain, H. Peerhossaini (2011)
Secondary flow patterns and mixing in laminar pulsating flow through a curved pipeExperiments in Fluids, 50
R. Ponzini, C. Vergara, G. Rizzo, A. Veneziani, A. Roghi, A. Vanzulli, O. Parodi, A. Redaelli (2010)
Womersley Number-Based Estimates of Blood Flow Rate in Doppler Analysis: In Vivo Validation by Means of Phase-Contrast MRIIEEE Transactions on Biomedical Engineering, 57
W. Dean, J. Hurst (1959)
Note on the motion of fluid in a curved pipeMathematika, 6
A. Glenn, Kartik Bulusu, F. Shu, M. Plesniak (2012)
SECONDARY FLOW STRUCTURES UNDER STENT-INDUCED PERTURBATIONS FOR CARDIOVASCULAR FLOW IN A CURVED ARTERY MODELProceeding of Seventh International Symposium on Turbulence and Shear Flow Phenomena
H. Bogren, M. Buonocore, D. Follette (2000)
Four-dimensional aortic blood flow patterns in thoracic aortic grafts.Journal of cardiovascular magnetic resonance : official journal of the Society for Cardiovascular Magnetic Resonance, 2 3
C. Fung, Kien-Ping Chung, D. Myers (2001)
Application of Hough transform for the identification of secondary flow patternsProceedings of IEEE Region 10 International Conference on Electrical and Electronic Technology. TENCON 2001 (Cat. No.01CH37239), 2
H. Himburg, D. Grzybowski, A. Hazel, J. LaMack, Xue-mei Li, M. Friedman (2004)
Spatial comparison between wall shear stress measures and porcine arterial endothelial permeability.American journal of physiology. Heart and circulatory physiology, 286 5
Jonas Lantz, M. Karlsson (2012)
Large eddy simulation of LDL surface concentration in a subject specific human aorta.Journal of biomechanics, 45 3
O. Boiron, V. Deplano, R. Pélissier (2007)
Experimental and numerical studies on the starting effect on the secondary flow in a bendJournal of Fluid Mechanics, 574
P. Stonebridge, C. Brophy (1991)
Spiral laminar flow in arteries?The Lancet, 338
Brahim Timité, C. Castelain, H. Peerhossaini (2010)
Pulsatile viscous flow in a curved pipe: Effects of pulsation on the development of secondary flowInternational Journal of Heat and Fluid Flow, 31
HA Himburg, SE Dowd, MH Friedman (2007)
Frequency-dependent response of the vascular endothelium to pulsatile shear stressAm J Physiol Heart Circ Physiol, 293
H. Bogren, R. Mohiaddin, G. Yang, P. Kilner, D. Firmin (1995)
Magnetic resonance velocity vector mapping of blood flow in thoracic aortic aneurysms and grafts.The Journal of thoracic and cardiovascular surgery, 110 3
J Lewalle (1998)
von Karman institute lecture series on advanced measurement techniques, VKI LS 1998–06
RN Nair, K Quadros (2011)
Coronary stent fracture: a review of the literatureCard Cath Lab Dir, 1
M. Farge, Y. Guezennec, C. Ho, C. Meneveau (1990)
Continuous wavelet analysis of coherent structures
AL Glenn, KV Bulusu, F Shu, MW Plesniak (2012)
Secondary flow structures under stent-induced perturbations for cardiovascular flow in a curved artery modelInt J Heat Fluid Flow, 35
J. Houston, S. Gandy, W. Milne, J. Dick, J. Belch, P. Stonebridge (2004)
Spiral laminar flow in the abdominal aorta: a predictor of renal impairment deterioration in patients with renal artery stenosis?Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association, 19 7
H. Bogren, M. Buonocore (1999)
Complex flow patterns in the great vessels: a reviewThe International Journal of Cardiac Imaging, 15
WH Lyne (1970)
Unsteady flow in a curved pipeJ Fluid Mech, 45
J. Houston, S. Gandy, D. Sheppard, J. Dick, J. Belch, P. Stonebridge (2003)
Two‐dimensional flow quantitative MRI of aortic arch blood flow patterns: Effect of age, sex, and presence of carotid atheromatous disease on prevalence of spiral blood flowJournal of Magnetic Resonance Imaging, 18
H. Himburg, M. Friedman (2006)
Correspondence of low mean shear and high harmonic content in the porcine iliac arteries.Journal of biomechanical engineering, 128 6
(2009)
BLOOD FLOW IN ARTERIES
HA Himburg, MH Friedman (2006)
Correspondence of low mean shear and high harmonic content in the porcine iliac arteriesTrans ASME J Biomed Eng, 128
S. Berceli, V. Warty, R. Sheppeck, W. Mandarino, S Tanksale, H. Borovetz (1990)
Hemodynamics and low density lipoprotein metabolism. Rates of low density lipoprotein incorporation and degradation along medial and lateral walls of the rabbit aorto-iliac bifurcation.Arteriosclerosis, 10 5
J. Lewalle, F. Peek, S. Murphy (1995)
Wavelet analysis of olfactory nerve response to stimulus.Journal of theoretical biology, 177 3
J. Hargreaves, A. Abe‐Ouchi (2003)
Timing of ice‐age terminations determined by wavelet methodsPaleoceanography, 18
C. Rindt, V. Steenhoven, J. Janssen, G. Vossers (1991)
Unsteady entrance flow in a 90° curved tubeJournal of Fluid Mechanics, 226
AV Varun, K Balasubraminian, RI Sujith (2008)
An automated vortex detection scheme using the wavelet transform of the $$d_2$$ d 2 fieldExp Fluids, 45
Secondary flow vortical patterns in arterial curvatures have the potential to affect several cardiovascular phenomena, e.g., progression of atherosclerosis by altering wall shear stresses, carotid atheromatous disease, thoracic aortic aneurysms and Marfan’s syndrome. Temporal characteristics of secondary flow structures vis-à-vis physiological (pulsatile) inflow waveform were explored by continuous wavelet transform (CWT) analysis of phase-locked, two-component, two-dimensional particle image velocimeter data. Measurements were made in a 180° curved artery test section upstream of the curvature and at the 90° cross-sectional plane. Streamwise, upstream flow rate measurements were analyzed using a one-dimensional antisymmetric wavelet. Cross-stream measurements at the 90° location of the curved artery revealed interesting multi-scale, multi-strength coherent secondary flow structures. An automated process for coherent structure detection and vortical feature quantification was applied to large ensembles of PIV data. Metrics such as the number of secondary flow structures, their sizes and strengths were generated at every discrete time instance of the physiological inflow waveform. An autonomous data post-processing method incorporating two-dimensional CWT for coherent structure detection was implemented. Loss of coherence in secondary flow structures during the systolic deceleration phase is observed in accordance with previous research. The algorithmic approach presented herein further elucidated the sensitivity and dependence of morphological changes in secondary flow structures on quasiperiodicity and magnitude of temporal gradients in physiological inflow conditions.
Experiments in Fluids – Springer Journals
Published: Nov 4, 2014
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.