Modelling solute transport in the brain microcirculation: is it really well mixed inside the blood vessels?

Most network models describing solute transport in the brain microcirculation use the well-mixed hypothesis and assume that radial gradients inside the blood vessels are negligible. Recent experimental data suggest that these gradients, which may result from heterogeneities in the velocity field or consumption in the tissue, may in fact be important. Here, we study the validity of the well-mixed hypothesis in network models of solute transport using theoretical and computational approaches. We focus on regimes of weak coupling where the transport problem inside the vasculature is independent of the concentration field in the tissue. In these regimes, the boundary condition between vessels and tissue can be modelled by a Robin boundary condition. For this boundary condition and for a single cylindrical capillary, we derive a one-dimensional cross-section average transport problem with dispersion and exchange coefficients capturing the effects of radial gradients. We then extend this model to a network of connected tubes and solve the problem in a complex anatomical network. By comparing with results based on the well-mixed hypothesis, we find that dispersive effects are a fundamental component of transport in transient situations with relatively rapid injections, i.e. frequencies above one Hertz. For slowly varying signals and steady states, radial gradients also significantly impact the spatial distribution of vessel/tissue exchange for molecules that easily cross the blood brain barrier. This suggests that radial gradients cannot be systematically neglected and that there is a crucial need to determine the impact of spatio-temporal heterogeneities on transport in the brain microcirculation.

[1]  D. Holmes,et al.  Spatial Distributions of Red Blood Cells Significantly Alter Local Haemodynamics , 2014, PloS one.

[2]  Dispersion of Ostwald‒de Waele fluid in laminar flow through a cylindrical tube , 1965, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[3]  Alan C. Evans,et al.  A three-dimensional MRI atlas of the mouse brain with estimates of the average and variability. , 2005, Cerebral cortex.

[4]  A Ziemys,et al.  A composite smeared finite element for mass transport in capillary systems and biological tissue. , 2017, Computer methods in applied mechanics and engineering.

[5]  Timothy W. Secomb,et al.  Green's Function Methods for Analysis of Oxygen Delivery to Tissue by Microvascular Networks , 2004, Annals of Biomedical Engineering.

[6]  M. Brundel,et al.  Cerebral microinfarcts: A systematic review of neuropathological studies , 2011, Alzheimer's & Dementia.

[7]  Ashley N Watson,et al.  Microvascular basis for growth of small infarcts following occlusion of single penetrating arterioles in mouse cortex , 2016, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[8]  Peter Atkins,et al.  Physical Chemistry for the Life Sciences , 2005 .

[9]  T. Secomb,et al.  A Green's function method for analysis of oxygen delivery to tissue by microvascular networks. , 1989, Mathematical biosciences.

[10]  Iuliu Sorin Pop,et al.  Effective dispersion equations for reactive flows with dominant Péclet and Damkohler numbers , 2007 .

[11]  H. Borovetz,et al.  Characterisation of the unsteady transport of labelled species in permeable capillaries: role of convective dispersion. , 1983, Physics in medicine and biology.

[12]  Sylvie Lorthois,et al.  Velocimetry of red blood cells in microvessels by the dual-slit method: effect of velocity gradients. , 2012, Microvascular research.

[13]  A Krogh,et al.  The number and distribution of capillaries in muscles with calculations of the oxygen pressure head necessary for supplying the tissue , 1919, The Journal of physiology.

[14]  S. Whitaker The method of volume averaging , 1998 .

[15]  Jean-Louis Auriault,et al.  Transport in Porous Media: Upscaling by Multiscale Asymptotic Expansions , 2005 .

[16]  Howard Brenner,et al.  Taylor dispersion of chemically reactive species: Irreversible first-order reactions in bulk and on boundaries , 1986 .

[17]  B. Friedman,et al.  Axial Oxygen Diffusion in the Krogh Model , 2005 .

[18]  P. Celsis,et al.  Kinetic modeling in the context of cerebral blood flow quantification by H2(15)O positron emission tomography: the meaning of the permeability coefficient in Renkin-Crone׳s model revisited at capillary scale. , 2014, Journal of theoretical biology.

[19]  G. Biros,et al.  Quantification of mixing in vesicle suspensions using numerical simulations in two dimensions. , 2016, Physics of fluids.

[20]  Sylvie Lorthois,et al.  Fractal analysis of vascular networks: insights from morphogenesis. , 2010, Journal of theoretical biology.

[21]  D. Bruley,et al.  A digital simulation of transient oxygen transport in capillary‐tissue systems (cerebral grey matter). Development of a numerical method for solution of transport equations describing coupled convection‐diffusion systems , 1969 .

[22]  A. Pries,et al.  Blood flow in microvascular networks. Experiments and simulation. , 1990, Circulation research.

[23]  Nozomi Nishimura,et al.  In vivo two-photon excited fluorescence microscopy reveals cardiac- and respiration-dependent pulsatile blood flow in cortical blood vessels in mice. , 2012, American journal of physiology. Heart and circulatory physiology.

[24]  D. Kleinfeld,et al.  Two-Photon Microscopy as a Tool to Study Blood Flow and Neurovascular Coupling in the Rodent Brain , 2012, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[25]  S. Black,et al.  Vascular Contributions to Cognitive Impairment and Dementia: A Statement for Healthcare Professionals From the American Heart Association/American Stroke Association , 2011, Stroke.

[26]  Timothy W. Secomb,et al.  Blood Flow in the Microcirculation , 2017 .

[27]  David Kleinfeld,et al.  The capillary bed offers the largest hemodynamic resistance to the cortical blood supply , 2017, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[28]  G. Taylor Dispersion of soluble matter in solvent flowing slowly through a tube , 1953, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[29]  George Em Karniadakis,et al.  Blood flow in small tubes: quantifying the transition to the non-continuum regime , 2013, Journal of Fluid Mechanics.

[30]  Pierre M. Adler,et al.  Taylor dispersion in porous media: analysis by multiple scale expansions , 1995 .

[31]  H. Brenner,et al.  Dispersion resulting from flow through spatially periodic porous media , 1980, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[32]  Michael L. Smith,et al.  Estimation of viscosity profiles using velocimetry data from parallel flows of linearly viscous fluids: application to microvascular haemodynamics , 2004, Journal of Fluid Mechanics.

[33]  S. Lorthois,et al.  Going beyond 20 μm-sized channels for studying red blood cell phase separation in microfluidic bifurcations. , 2016, Biomicrofluidics.

[34]  Aleksander S Popel,et al.  Effect of aggregation and shear rate on the dispersion of red blood cells flowing in venules. , 2002, American journal of physiology. Heart and circulatory physiology.

[35]  Grégoire Allaire,et al.  Two-scale expansion with drift approach to the Taylor dispersion for reactive transport through porous media , 2010 .

[36]  T. Secomb Krogh‐Cylinder and Infinite‐Domain Models for Washout of an Inert Diffusible Solute from Tissue , 2015, Microcirculation.

[37]  A. Pries,et al.  Biophysical aspects of blood flow in the microvasculature. , 1996, Cardiovascular research.

[38]  G. Zaharchuk,et al.  Recommended implementation of arterial spin-labeled perfusion MRI for clinical applications: A consensus of the ISMRM perfusion study group and the European consortium for ASL in dementia. , 2015, Magnetic resonance in medicine.

[39]  Dispersion in Core-Annular Flow with a Solid Annulus , 2005 .

[40]  Myriam Peyrounette,et al.  Multiscale modelling of blood flow in cerebral microcirculation: Details at capillary scale control accuracy at the level of the cortex , 2018, PloS one.

[41]  Francis Cassot,et al.  Simulation study of brain blood flow regulation by intra-cortical arterioles in an anatomically accurate large human vascular network: Part I: Methodology and baseline flow , 2011, NeuroImage.

[42]  Roland Bammer,et al.  Magnetic resonance imaging techniques: fMRI, DWI, and PWI. , 2008, Seminars in neurology.

[43]  S. Lorthois,et al.  Simulation study of brain blood flow regulation by intra-cortical arterioles in an anatomically accurate large human vascular network. Part II: Flow variations induced by global or localized modifications of arteriolar diameters , 2011, NeuroImage.

[44]  A. Auchus,et al.  Vascular contributions to cognitive impairment and dementia: the emerging role of 20-HETE. , 2021, Clinical science.

[45]  Christopher J. Elkins,et al.  Three-dimensional concentration field measurements in a mixing layer using magnetic resonance imaging , 2010 .

[46]  Modeling the Effect of Intra-Voxel Diffusion of Contrast Agent on the Quantitative Analysis of Dynamic Contrast Enhanced Magnetic Resonance Imaging , 2014, PloS one.

[47]  Amir Faghri,et al.  Heat Pipe Science And Technology , 1995 .

[48]  Rebecca J Shipley,et al.  Insights into cerebral haemodynamics and oxygenation utilising in vivo mural cell imaging and mathematical modelling , 2017, Scientific Reports.

[49]  A. Bensoussan,et al.  Asymptotic analysis for periodic structures , 1979 .

[50]  Anna Devor,et al.  Oxygen advection and diffusion in a three- dimensional vascular anatomical network. , 2008, Optics express.

[51]  W. Denk,et al.  Two-photon laser scanning fluorescence microscopy. , 1990, Science.

[52]  A. Pries,et al.  Microvascular blood viscosity in vivo and the endothelial surface layer. , 2005, American journal of physiology. Heart and circulatory physiology.

[53]  F. Cassot,et al.  Tortuosity and other vessel attributes for arterioles and venules of the human cerebral cortex. , 2014, Microvascular research.

[54]  P. Righetti,et al.  Use of Taylor-Aris Dispersion for Measurement of a Solute Diffusion Coefficient in Thin Capillaries , 1994, Science.

[55]  H. Flyvbjerg,et al.  Contributions of the glycocalyx, endothelium, and extravascular compartment to the blood–brain barrier , 2018, Proceedings of the National Academy of Sciences.

[56]  B. Zlokovic Neurovascular pathways to neurodegeneration in Alzheimer's disease and other disorders , 2011, Nature Reviews Neuroscience.

[57]  David A Boas,et al.  Shear‐induced diffusion of red blood cells measured with dynamic light scattering‐optical coherence tomography , 2018, Journal of biophotonics.

[58]  Nicolas P Smith,et al.  Estimation of Blood Flow Rates in Large Microvascular Networks , 2012, Microcirculation.

[59]  D. Kleinfeld,et al.  The cortical angiome: an interconnected vascular network with noncolumnar patterns of blood flow , 2013, Nature Neuroscience.

[60]  A. Linninger,et al.  Cerebral Microcirculation and Oxygen Tension in the Human Secondary Cortex , 2013, Annals of Biomedical Engineering.

[61]  Myriam Peyrounette,et al.  Neutrophil adhesion in brain capillaries contributes to cortical blood flow decreases and impaired memory function in a mouse model of Alzheimer’s disease , 2017, bioRxiv.

[62]  Wen Wang,et al.  Taylor dispersion in finite-length capillaries , 2011 .

[63]  Anna Devor,et al.  Quantifying the Microvascular Origin of BOLD-fMRI from First Principles with Two-Photon Microscopy and an Oxygen-Sensitive Nanoprobe , 2015, The Journal of Neuroscience.

[64]  J. Sirs,et al.  Influence of diffusion on dispersion of indicators in blood flow. , 1973, Journal of applied physiology.

[65]  E. Lightfoot,et al.  Transient convective mass transfer in Krogh tissue cylinders , 1978, Annals of Biomedical Engineering.

[66]  A. Popel,et al.  Computational modeling of oxygen transport from complex capillary networks. Relation to the microcirculation physiome. , 1999, Advances in experimental medicine and biology.

[67]  Michel Quintard,et al.  Heat and Mass Transfer in Tubes: An Analysis Using the Method of Volume Averaging , 2002 .

[68]  Laurent Risser,et al.  Coupling and robustness of intra-cortical vascular territories , 2012, NeuroImage.

[69]  Geert Jan Biessels,et al.  Cerebral Microinfarcts: A Systematic Review of Neuropathological Studies , 2012, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[70]  John F. Brady,et al.  Dispersion in fixed beds , 1985, Journal of Fluid Mechanics.

[71]  Chiang C. Mei,et al.  Method of homogenization applied to dispersion in porous media , 1992 .

[72]  J. Sirs,et al.  Indicator dilution measurement of mean transit time and flow in a straight tube , 1974 .

[73]  Patrick Jenny,et al.  Red blood cell distribution in simplified capillary networks , 2010, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[74]  Daniel A. Beard,et al.  Taylor dispersion of a solute in a microfluidic channel , 2001 .

[75]  Charles Nicholson,et al.  Diffusion and related transport mechanisms in brain tissue , 2001 .

[76]  Yohan Davit,et al.  Homogenization via formal multiscale asymptotics and volume averaging: How do the two techniques compare? , 2013 .

[77]  R. Jain,et al.  Pharmacokinetic analysis of the perivascular distribution of bifunctional antibodies and haptens: comparison with experimental data. , 1992, Cancer research.

[78]  D. Levitt,et al.  Capillary-tissue exchange kinetics: an analysis of the Krogh cylinder model. , 1972, Journal of theoretical biology.

[79]  Patrick Jenny,et al.  Depth-dependent flow and pressure characteristics in cortical microvascular networks , 2017, PLoS Comput. Biol..

[80]  D. Kleinfeld,et al.  Correlations of Neuronal and Microvascular Densities in Murine Cortex Revealed by Direct Counting and Colocalization of Nuclei and Vessels , 2009, The Journal of Neuroscience.

[81]  P. Yager,et al.  Microfluidic Diffusion-Based Separation and Detection , 1999, Science.

[82]  J D Hellums,et al.  The resistance to oxygen transport in the capillaries relative to that in the surrounding tissue. , 1977, Microvascular research.

[83]  Myriam Peyrounette,et al.  Neutrophil adhesion in brain capillaries reduces cortical blood flow and impairs memory function in Alzheimer’s disease mouse models , 2018, Nature Neuroscience.

[84]  E. Leonard,et al.  The analysis of convection and diffusion in capillary beds. , 1974, Annual review of biophysics and bioengineering.

[85]  Norio Ohshima,et al.  Simulation of intraluminal gas transport processes in the microcirculation , 1995, Annals of Biomedical Engineering.

[86]  Mauro Ferrari,et al.  The Transport of Nanoparticles in Blood Vessels: The Effect of Vessel Permeability and Blood Rheology , 2008, Annals of Biomedical Engineering.

[87]  Anders M. Dale,et al.  Large arteriolar component of oxygen delivery implies safe margin of oxygen supply to cerebral tissue , 2014, Nature Communications.

[88]  R. Aris On the dispersion of a solute in a fluid flowing through a tube , 1956, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[89]  David J. Begley,et al.  Structure and function of the blood–brain barrier , 2010, Neurobiology of Disease.

[90]  Tim David,et al.  A Computational Model of Oxygen Transport in the Cerebrocapillary Levels for Normal and Pathologic Brain Function , 2013, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[91]  A. Pries,et al.  Red cell distribution at microvascular bifurcations. , 1989, Microvascular research.

[92]  Anders M. Dale,et al.  Interstitial solute transport in 3D reconstructed neuropil occurs by diffusion rather than bulk flow , 2017, Proceedings of the National Academy of Sciences.