Your search keyword '"Wood, David K."' showing total 17 results

1. Less-deformable erythrocyte subpopulations biomechanically induce endothelial inflammation in sickle cell disease.

Author

Caruso C, Cheng X, Michaud ME, Szafraniec HM, Thomas BE, Fay ME, Mannino RG, Zhang X, Sakurai Y, Li W, Myers DR, Joiner CH, Wood DK, Bhasin M, Graham MD, and Lam WA

Subjects

Humans, Erythrocytes pathology, Erythrocytes metabolism, Erythrocytes, Abnormal pathology, Erythrocytes, Abnormal metabolism, Endothelium, Vascular pathology, Endothelium, Vascular metabolism, Mechanotransduction, Cellular, Endothelial Cells pathology, Endothelial Cells metabolism, Anemia, Sickle Cell pathology, Anemia, Sickle Cell blood, Erythrocyte Deformability, Inflammation pathology

Abstract

Abstract: Sickle cell disease (SCD) is canonically characterized by reduced red blood cell (RBC) deformability, leading to microvascular obstruction and inflammation. Although the biophysical properties of sickle RBCs are known to influence SCD vasculopathy, the contribution of poor RBC deformability to endothelial dysfunction has yet to be fully explored. Leveraging interrelated in vitro and in silico approaches, we introduce a new paradigm of SCD vasculopathy in which poorly deformable sickle RBCs directly cause endothelial dysfunction via mechanotransduction, during which endothelial cells sense and pathophysiologically respond to aberrant physical forces independently of microvascular obstruction, adhesion, or hemolysis. We demonstrate that perfusion of sickle RBCs or pharmacologically-dehydrated healthy RBCs into small venule-sized "endothelialized" microfluidics leads to pathologic physical interactions with endothelial cells that directly induce inflammatory pathways. Using a combination of computational simulations and large venule-sized endothelialized microfluidics, we observed that perfusion of heterogeneous sickle RBC subpopulations with varying deformability, as well as suspensions of dehydrated normal RBCs admixed with normal RBCs, leads to aberrant margination of the less-deformable RBC subpopulations toward the vessel walls, causing localized, increased shear stress. Increased wall stress is dependent on the degree of subpopulation heterogeneity and oxygen tension and leads to inflammatory endothelial gene expression via mechanotransductive pathways. Our multifaceted approach demonstrates that the presence of sickle RBCs with reduced deformability leads directly to pathological physical (ie, direct collisions and/or compressive forces) and shear-mediated interactions with endothelial cells and induces an inflammatory response, thereby elucidating the ubiquity of vascular dysfunction in SCD., (© 2024 American Society of Hematology. Published by Elsevier Inc. All rights are reserved, including those for text and data mining, AI training, and similar technologies.)

Published

2024

2. Computational Analysis of Flow and Transport Suggests Reduced Oxygen Levels Within Intracranial Aneurysms, Especially in Individuals With Sickle-Cell Disease.

Author

Bazzi MS, Wiputra H, Wood DK, and Barocas VH

Subjects

Humans, Biological Transport, Computer Simulation, Hemodynamics, Models, Cardiovascular, Intracranial Aneurysm metabolism, Intracranial Aneurysm physiopathology, Anemia, Sickle Cell metabolism, Anemia, Sickle Cell physiopathology, Anemia, Sickle Cell complications, Oxygen metabolism

Abstract

Sickle cell disease (SCD) is a genetic condition characterized by an abundance of sickle hemoglobin in red blood cells. SCD patients are more prone to intracranial aneurysms (ICA) compared to the general population, with distinctive features such as multiple intracranial aneurysms: 66% of SCD patients with ICAs have multiples ICAs, compared to 20% in nonsickle patients. The exact mechanism behind these associations is not fully understood, but there is a hypothesized link between hypoxic conditions in blood vessels and impaired synthesis of extracellular matrix, which may weaken the vessel walls, favoring aneurysm formation and rupture. SCD patients experience reduced oxygen levels in their blood, potentially exacerbating hypoxia in intracranial aneurysms, and potentially creating a feedback loop that could contribute to aneurysm development and early onset in these patients. In this work, we performed a series of computational studies (Fluent) using idealized geometries to investigate the key differences in the oxygen transport and blood flow dynamics inside an aneurysm formation for sickle and nonsickle cases. We found that using sickle cell disease parameters resulted in a 14% to 68% reduction in blood flow and a 37% to 70% reduction in oxygen availability within the aneurysm, depending on the vessel curvature and the aneurysm throat diameter, due to factors including oxygen-dependent viscosity and alteration in the oxygen transport. The results indicate that depending on geometry and flow characteristics, some degree of hypoxia maybe present in aneurysm bulb and would be more severe in sickle-cell disease patients. This study hopes to bring into attention the potential presence of hypoxic environment in the aneurysm bulb., (Copyright © 2025 by ASME.)

Published

2025

3. High-throughput quantification of red blood cell deformability and oxygen saturation to probe mechanisms of sickle cell disease.

Author

Williams DC and Wood DK

Subjects

Humans, Erythrocytes, Erythrocyte Deformability, Polymers, Oxygen, Oxygen Saturation, Anemia, Sickle Cell

Abstract

The complex, systemic pathology of sickle cell disease is driven by multiple mechanisms including red blood cells (RBCs) stiffened by polymerized fibers of deoxygenated sickle hemoglobin. A critical step toward understanding the pathologic role of polymer-containing RBCs is quantifying the biophysical changes in these cells in physiologically relevant oxygen environments. We have developed a microfluidic platform capable of simultaneously measuring single RBC deformability and oxygen saturation under controlled oxygen and shear stress. We found that RBCs with detectable amounts of polymer have decreased oxygen affinity and decreased deformability. Surprisingly, the deformability of the polymer-containing cells is oxygen-independent, while the fraction of these cells increases as oxygen decreases. We also find that some fraction of these cells is present at most physiologic oxygen tensions, suggesting a role for these cells in the systemic pathologies. Additionally, the ability to measure these pathological cells should provide clearer targets for evaluating therapies., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2023

4. Simultaneous quantification of blood rheology and oxygen saturation to evaluate affinity-modifying therapies in sickle cell disease.

Author

Hansen S and Wood DK

Subjects

Humans, Oxygen, Rheology, Hemoglobins, Hemoglobin, Sickle metabolism, Hemoglobin, Sickle therapeutic use, Oxygen Saturation, Anemia, Sickle Cell drug therapy

Abstract

Sickle cell blood demonstrates oxygen-dependent flow behavior as a result of HbS polymerization during hypoxia, and these rheological changes provide a biophysical metric that can be used to quantify the pathological behavior of the blood. Relating these rheological changes directly to hemoglobin oxygen saturation would improve our understanding of SCD pathogenesis and the potential effects of therapeutic drugs. Towards this end, we have developed a microfluidic platform capable of spectrophotometric quantification of Hb-O 2 saturation and simultaneous evaluation of the accompanying rheological changes in SCD blood flow. We demonstrated the ability to measure changes in Hb-O 2 affinity and a restoration of oxygen-independent blood flow behavior after incubation with voxelotor, an oxygen affinity modifying drug approved for use in SCD. We also identified regimes in Hb-O 2 saturation where the effects of HbS polymerization begin to take effect in contributing to pathological flow behavior, independent of voxelotor treatment. In contrast, incubation with voxelotor recovered oxygen-dependent blood flow over a range of P O 2 , providing a framework for understanding voxelotor's therapeutic effect in lowering the P O 2 at which the requisite Hb-O 2 saturation is reached to observe pathological blood flow. These results help explain the mechanistic effects of voxelotor and show the potential of this platform to identify affinity-modifying compounds and evaluate their therapeutic effect on blood flow.

Published

2022

5. Fluorescence Lifetime Measurement of Prefibrillar Sickle Hemoglobin Oligomers as a Platform for Drug Discovery in Sickle Cell Disease.

Author

Vunnam N, Hansen S, Williams DC, Been MO, Lo CH, Pandey AK, Paulson CN, Rohde JA, Thomas DD, Sachs JN, and Wood DK

Subjects

Drug Discovery, Hemoglobins, Humans, Oxygen metabolism, Anemia, Sickle Cell drug therapy, Anemia, Sickle Cell metabolism, Hemoglobin, Sickle chemistry, Hemoglobin, Sickle metabolism

Abstract

The molecular origin of sickle cell disease (SCD) has been known since 1949, but treatments remain limited. We present the first high-throughput screening (HTS) platform for discovering small molecules that directly inhibit sickle hemoglobin (HbS) oligomerization and improve blood flow, potentially overcoming a long-standing bottleneck in SCD drug discovery. We show that at concentrations far below the threshold for nucleation and rapid polymerization, deoxygenated HbS forms small assemblies of multiple α 2 β 2 tetramers. Our HTS platform leverages high-sensitivity fluorescence lifetime measurements that monitor these temporally stable prefibrillar HbS oligomers. We show that this approach is sensitive to compounds that inhibit HbS polymerization with or without modulating hemoglobin oxygen binding affinity. We also report the results of a pilot small-molecule screen in which we discovered and validated several novel inhibitors of HbS oligomerization.

Published

2022

6. Microfluidic methods to advance mechanistic understanding and translational research in sickle cell disease.

Author

Azul M, Vital EF, Lam WA, Wood DK, and Beckman JD

Subjects

Hemoglobin, Sickle, Hemolysis, Humans, Translational Research, Biomedical, Anemia, Sickle Cell drug therapy, Anemia, Sickle Cell therapy, Microfluidics

Abstract

Sickle cell disease (SCD) is caused by a single point mutation in the β-globin gene of hemoglobin, which produces an altered sickle hemoglobin (HbS). The ability of HbS to polymerize under deoxygenated conditions gives rise to chronic hemolysis, oxidative stress, inflammation, and vaso-occlusion. Herein, we review recent findings using microfluidic technologies that have elucidated mechanisms of oxygen-dependent and -independent induction of HbS polymerization and how these mechanisms elicit the biophysical and inflammatory consequences in SCD pathophysiology. We also discuss how validation and use of microfluidics in SCD provides the opportunity to advance development of numerous therapeutic strategies, including curative gene therapies., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

7. Ionophore-mediated swelling of erythrocytes as a therapeutic mechanism in sickle cell disease.

Author

Geisness AC, Azul M, Williams D, Szafraniec H, De Souza DC, Higgins JM, and Wood DK

Subjects

Hemoglobin, Sickle, Humans, Hypoxia, Anemia, Sickle Cell drug therapy, Erythrocytes drug effects, Ionophores pharmacology, Ionophores therapeutic use, Monensin pharmacology, Monensin therapeutic use

Abstract

Sickle cell disease (SCD) is characterized by sickle hemoglobin (HbS) which polymerizes under deoxygenated conditions to form a stiff, sickled erythrocyte. The dehydration of sickle erythrocytes increases intracellular HbS concentration and the propensity of erythrocyte sickling. Prevention of this mechanism may provide a target for potential SCD therapy investigation. Ionophores such as monensin can increase erythrocyte sodium permeability by facilitating its transmembrane transport, leading to osmotic swelling of the erythrocyte and decreased hemoglobin concentration. In this study, we treated 13 blood samples from patients with SCD with 10 nM of monensin ex vivo. We measured changes in cell volume and hemoglobin concentration in response to monensin treatment, and we perfused treated blood samples through a microfluidic device that permits quantification of blood flow under controlled hypoxia. Monensin treatment led to increases in cell volume and reductions in hemoglobin concentration in most blood samples, though the degree of response varied across samples. Monensin-treated samples also demonstrated reduced blood flow impairment under hypoxic conditions relative to untreated controls. Moreover, there was a significant correlation between the improvement in blood flow and the decrease in hemoglobin concentration. Thus, our results demonstrate that a reduction in intracellular HbS concentration by osmotic swelling improves blood flow under hypoxic conditions. Although the toxicity of monensin will likely prevent it from being a viable clinical treatment, these results suggest that osmotic swelling should be investigated further as a potential mechanism for SCD therapy.

Published

2022

8. Feature tracking microfluidic analysis reveals differential roles of viscosity and friction in sickle cell blood.

Author

Szafraniec HM, Valdez JM, Iffrig E, Lam WA, Higgins JM, Pearce P, and Wood DK

Subjects

Friction, Humans, Oxygen, Plant Extracts, Rheology, Viscosity, Anemia, Sickle Cell, Microfluidic Analytical Techniques

Abstract

Characterization of blood flow rheology in hematological disorders is critical for understanding disease pathophysiology. Existing methods to measure blood rheological parameters are limited in their physiological relevance, and there is a need for new tools that focus on the microcirculation and extract properties at finer resolution than overall flow resistance. Herein, we present a method that combines microfluidic systems and powerful object-tracking computational technologies with mathematical modeling to separate the red blood cell flow profile into a bulk component and a wall component. We use this framework to evaluate differential contributions of effective viscosity and wall friction to the overall resistance in blood from patients with sickle cell disease (SCD) under a range of oxygen tensions. Our results demonstrate that blood from patients with SCD exhibits elevated frictional and viscous resistances at all physiologic oxygen tensions. Additionally, the viscous resistance increases more rapidly than the frictional resistance as oxygen tension decreases, which may confound analyses that extract only flow velocities or overall flow resistances. Furthermore, we evaluate the impact of transfusion treatments on the components of the resistance, revealing patient variability in blood properties that may improve our understanding of the heterogeneity of clinical responses to such treatments. Overall, our system provides a new method to analyze patient-specific blood properties and can be applied to a wide range of hematological and vascular disorders.

Published

2022

9. The effect of rigid cells on blood viscosity: linking rheology and sickle cell anemia.

Author

Perazzo A, Peng Z, Young YN, Feng Z, Wood DK, Higgins JM, and Stone HA

Subjects

Erythrocytes, Humans, Rheology, Viscosity, Anemia, Sickle Cell, Blood Viscosity

Abstract

Sickle cell anemia (SCA) is a disease that affects red blood cells (RBCs). Healthy RBCs are highly deformable objects that under flow can penetrate blood capillaries smaller than their typical size. In SCA there is an impaired deformability of some cells, which are much stiffer and with a different shape than healthy cells, and thereby affect regular blood flow. It is known that blood from patients with SCA has a higher viscosity than normal blood. However, it is unclear how the rigidity of cells is related to the viscosity of blood, in part because SCA patients are often treated with transfusions of variable amounts of normal RBCs and only a fraction of cells will be stiff. Here, we report systematic experimental measurements of the viscosity of a suspension varying the fraction of rigid particles within a suspension of healthy cells. We also perform systematic numerical simulations of a similar mixed suspension of soft RBCs, rigid particles, and their hydrodynamic interactions. Our results show that there is a rheological signature within blood viscosity to clearly identify the fraction of rigidified cells among healthy deformable cells down to a 5% volume fraction of rigidified cells. Although aggregation of RBCs is known to affect blood rheology at low shear rates, and our simulations mimic this effect via an adhesion potential, we show that such adhesion, or aggregation, is unlikely to provide a physical rationalization for the viscosity increase observed in the experiments at moderate shear rates due to rigidified cells. Through numerical simulations, we also highlight that most of the viscosity increase of the suspension is due to the rigidity of the particles rather than their sickled or spherical shape. Our results are relevant to better characterize SCA, provide useful insights relevant to rheological consequences of blood transfusions, and, more generally, extend to the rheology of mixed suspensions having particles with different rigidities, as well as offering possibilities for developments in the field of soft material composites.

Published

2022

10. MetAP2 inhibition modifies hemoglobin S to delay polymerization and improves blood flow in sickle cell disease.

Author

Demers M, Sturtevant S, Guertin KR, Gupta D, Desai K, Vieira BF, Li W, Hicks A, Ismail A, Gonçalves BP, Di Caprio G, Schonbrun E, Hansen S, Musayev FN, Safo MK, Wood DK, Higgins JM, and Light DR

Subjects

Aminopeptidases, Animals, Antisickling Agents pharmacology, Humans, Kinetics, Metalloendopeptidases, Methionyl Aminopeptidases, Mice, Polymerization, Anemia, Sickle Cell drug therapy, Hemoglobin, Sickle

Abstract

Sickle cell disease (SCD) is associated with hemolysis, vascular inflammation, and organ damage. Affected patients experience chronic painful vaso-occlusive events requiring hospitalization. Hypoxia-induced polymerization of sickle hemoglobin S (HbS) contributes to sickling of red blood cells (RBCs) and disease pathophysiology. Dilution of HbS with nonsickling hemoglobin or hemoglobin with increased oxygen affinity, such as fetal hemoglobin or HbS bound to aromatic aldehydes, is clinically beneficial in decreasing polymerization. We investigated a novel alternate approach to modify HbS and decrease polymerization by inhibiting methionine aminopeptidase 2 (MetAP2), which cleaves the initiator methionine (iMet) from Val1 of α-globin and βS-globin. Kinetic studies with MetAP2 show that βS-globin is a fivefold better substrate than α-globin. Knockdown of MetAP2 in human umbilical cord blood-derived erythroid progenitor 2 cells shows more extensive modification of α-globin than β-globin, consistent with kinetic data. Treatment of human erythroid cells in vitro or Townes SCD mice in vivo with selective MetAP2 inhibitors extensively modifies both globins with N-terminal iMet and acetylated iMet. HbS modification by MetAP2 inhibition increases oxygen affinity, as measured by decreased oxygen tension at which hemoglobin is 50% saturated. Acetyl-iMet modification on βS-globin delays HbS polymerization under hypoxia. MetAP2 inhibitor-treated Townes mice reach 50% total HbS modification, significantly increasing the affinity of RBCs for oxygen, increasing whole blood single-cell RBC oxygen saturation, and decreasing fractional flow velocity losses in blood rheology under decreased oxygen pressures. Crystal structures of modified HbS variants show stabilization of the nonpolymerizing high O2-affinity R2 state, explaining modified HbS antisickling activity. Further study of MetAP2 inhibition as a potential therapeutic target for SCD is warranted., (© 2021 by The American Society of Hematology.)

Published

2021

11. An Experimental-Computational Approach to Quantify Blood Rheology in Sickle Cell Disease.

Author

Bazzi MS, Valdez JM, Barocas VH, and Wood DK

Subjects

Erythrocyte Deformability, Erythrocytes, Humans, Rheology, Anemia, Sickle Cell

Abstract

In sickle cell disease, aberrant blood flow due to oxygen-dependent changes in red cell biomechanics is a key driver of pathology. Most studies to date have focused on the potential role of altered red cell deformability and blood rheology in precipitating vaso-occlusive crises. Numerous studies, however, have shown that sickle blood flow is affected even at high oxygen tensions, suggesting a potentially systemic role for altered blood flow in driving pathologies, including endothelial dysfunction, ischemia, and stroke. In this study, we applied a combined experimental-computation approach that leveraged an experimental platform that quantifies sickle blood velocity fields under a range of oxygen tensions and shear rates. We computationally fitted a continuum model to our experimental data to generate physics-based parameters that capture patient-specific rheological alterations. Our results suggest that sickle blood flow is altered systemically, from the arterial to the venous circulation. We also demonstrated the application of this approach as a tool to design patient-specific transfusion regimens. Finally, we demonstrated that patient-specific rheological parameters can be combined with patient-derived vascular models to identify patients who are at higher risk for cerebrovascular complications such as aneurysm and stroke. Overall, this study highlights that sickle blood flow is altered systemically, which can drive numerous pathologies, and this study demonstrates the potential utility of an experimentally parameterized continuum model as a predictive tool for patient-specific care., (Copyright © 2020 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2020

12. High-throughput assessment of hemoglobin polymer in single red blood cells from sickle cell patients under controlled oxygen tension.

Author

Di Caprio G, Schonbrun E, Gonçalves BP, Valdez JM, Wood DK, and Higgins JM

Subjects

Erythrocytes chemistry, Erythrocytes cytology, Hemoglobin, Sickle chemistry, Hemoglobins chemistry, Humans, Kinetics, Oxygen chemistry, Single-Cell Analysis, Anemia, Sickle Cell metabolism, Erythrocytes metabolism, Hemoglobin, Sickle metabolism, Hemoglobins metabolism, High-Throughput Screening Assays methods, Oxygen metabolism

Abstract

Sickle cell disease (SCD) is caused by a variant hemoglobin molecule that polymerizes inside red blood cells (RBCs) in reduced oxygen tension. Treatment development has been slow for this typically severe disease, but there is current optimism for curative gene transfer strategies to induce expression of fetal hemoglobin or other nonsickling hemoglobin isoforms. All SCD morbidity and mortality arise directly or indirectly from polymer formation in individual RBCs. Identifying patients at highest risk of complications and treatment candidates with the greatest curative potential therefore requires determining the amount of polymer in individual RBCs under controlled oxygen. Here, we report a semiquantitative measurement of hemoglobin polymer in single RBCs as a function of oxygen. The method takes advantage of the reduced oxygen affinity of hemoglobin polymer to infer polymer content for thousands of RBCs from their overall oxygen saturation. The method enables approaches for SCD treatment development and precision medicine., Competing Interests: The authors declare no competing interest.

Published

2019

13. Oxygen-dependent flow of sickle trait blood as an in vitro therapeutic benchmark for sickle cell disease treatments.

Author

Lu X, Chaudhury A, Higgins JM, and Wood DK

Subjects

Anemia, Sickle Cell therapy, Benchmarking, Blood Flow Velocity, Blood Viscosity, Equipment Design, Exchange Transfusion, Whole Blood, Hemoglobin, Sickle chemistry, Humans, In Vitro Techniques, Lab-On-A-Chip Devices, Oxygen blood, Phenotype, Shear Strength, Sickle Cell Trait blood, Anemia, Sickle Cell blood, Oxygen pharmacology

Abstract

Although homozygous sickle cell disease is often clinically severe, the corresponding heterozygous state, sickle cell trait, is almost completely benign despite the fact that there is only a modest difference in sickle hemoglobin levels between the two conditions. In both conditions, hypoxia can lead to polymerization of sickle hemoglobin, changes in red cell mechanical properties, and impaired blood flow. Here, we test the hypothesis that differences in the oxygen-dependent rheological properties in the two conditions might help explain the difference in clinical phenotypes. We use a microfluidic platform that permits quantification of blood rheology under defined oxygen conditions in physiologically sized microchannels and under physiologic shear rates. We find that, even with its lower sickle hemoglobin concentration, sickle trait blood apparent viscosity increases with decreasing oxygen tension and may stop flowing under completely anoxic conditions, though far less readily than the homozygous condition. Sickle cell trait blood flow becomes impaired at significantly lower oxygen tension than sickle cell disease. We also demonstrate how sickle cell trait can serve as a benchmark for sickle cell disease therapies. We characterize the rheological effects of exchange transfusion therapy by mixing sickle blood with nonsickle blood and quantifying the transfusion targets for sickle hemoglobin composition below which the rheological response resembles sickle trait. These studies quantify the differences in blood flow phenotypes of sickle cell disease and sickle cell trait, and they provide a potentially powerful new benchmark for evaluating putative therapies in vitro., (© 2018 Wiley Periodicals, Inc.)

Published

2018

14. Extracellular fluid tonicity impacts sickle red blood cell deformability and adhesion.

Author

Carden MA, Fay ME, Lu X, Mannino RG, Sakurai Y, Ciciliano JC, Hansen CE, Chonat S, Joiner CH, Wood DK, and Lam WA

Subjects

Biomechanical Phenomena, Cell Adhesion physiology, Cells, Cultured, Erythrocytes, Abnormal physiology, Extracellular Fluid chemistry, Hemorheology, Human Umbilical Vein Endothelial Cells metabolism, Human Umbilical Vein Endothelial Cells physiology, Humans, Osmolar Concentration, Anemia, Sickle Cell blood, Anemia, Sickle Cell physiopathology, Erythrocyte Deformability physiology, Extracellular Fluid physiology

Abstract

Abnormal sickle red blood cell (sRBC) biomechanics, including pathological deformability and adhesion, correlate with clinical severity in sickle cell disease (SCD). Clinical intravenous fluids (IVFs) of various tonicities are often used during treatment of vaso-occlusive pain episodes (VOE), the major cause of morbidity in SCD. However, evidence-based guidelines are lacking, and there is no consensus regarding which IVFs to use during VOE. Further, it is unknown how altering extracellular fluid tonicity with IVFs affects sRBC biomechanics in the microcirculation, where vaso-occlusion takes place. Here, we report how altering extracellular fluid tonicity with admixtures of clinical IVFs affects sRBC biomechanical properties by leveraging novel in vitro microfluidic models of the microcirculation, including 1 capable of deoxygenating the sRBC environment to monitor changes in microchannel occlusion risk and an "endothelialized" microvascular model that measures alterations in sRBC/endothelium adhesion under postcapillary venular conditions. Admixtures with higher tonicities (sodium = 141 mEq/L) affected sRBC biomechanics by decreasing sRBC deformability, increasing sRBC occlusion under normoxic and hypoxic conditions, and increasing sRBC adhesion in our microfluidic human microvasculature models. Admixtures with excessive hypotonicity (sodium = 103 mEq/L), in contrast, decreased sRBC adhesion, but overswelling prolonged sRBC transit times in capillary-sized microchannels. Admixtures with intermediate tonicities (sodium = 111-122 mEq/L) resulted in optimal changes in sRBC biomechanics, thereby reducing the risk for vaso-occlusion in our models. These results have significant translational implications for patients with SCD and warrant a large-scale prospective clinical study addressing optimal IVF management during VOE in SCD., (© 2017 by The American Society of Hematology.)

Published

2017

15. A microfluidic platform to study the effects of vascular architecture and oxygen gradients on sickle blood flow.

Author

Lu X, Galarneau MM, Higgins JM, and Wood DK

Subjects

Blood Vessels physiopathology, Humans, Microfluidics instrumentation, Oxygen blood, Regional Blood Flow, Anemia, Sickle Cell physiopathology, Blood Vessels anatomy & histology, Microfluidics methods

Abstract

Our goal was to develop a model of the microvasculature that would allow us to quantify changes in the rheology of sickle blood as it traverses the varying vessel sizes and oxygen tensions in the microcirculation. We designed and implemented a microfluidic model of the microcirculation that comprises a branching microvascular network and physiologic oxygen gradients. We used computational modeling to determine the parameters necessary to generate stable, linear gradients in our devices. Sickle blood from six unique patients was perfused through the microvascular network and subjected to varying oxygen gradients while we observed and quantified blood flow. We found that all sickle blood samples fully occluded the microvascular network when deoxygenated, and we observed that sickle blood could cause vaso-occlusions under physiologic oxygen gradients during the microvascular transit time. The number of occlusions observed under five unique oxygen gradients varied among the patient samples, but we generally observed that the number of occlusions decreased with increasing inlet oxygen tension. The model system we have developed is a valuable tool to address fundamental questions about where in the circulation sickle-cell vaso-occlusions are most likely to occur and to test new therapies., (© 2017 John Wiley & Sons Ltd.)

Published

2017

16. Deoxygenation Reduces Sickle Cell Blood Flow at Arterial Oxygen Tension.

Author

Lu X, Wood DK, and Higgins JM

Subjects

Dimethylpolysiloxanes, Electric Conductivity, Equipment Design, Humans, Lab-On-A-Chip Devices, Microfluidic Analytical Techniques, Anemia, Sickle Cell blood, Hemorheology physiology, Oxygen metabolism

Abstract

The majority of morbidity and mortality in sickle cell disease is caused by vaso-occlusion: circulatory obstruction leading to tissue ischemia and infarction. The consequences of vaso-occlusion are seen clinically throughout the vascular tree, from the relatively high-oxygen and high-velocity cerebral arteries to the relatively low-oxygen and low-velocity postcapillary venules. Prevailing models of vaso-occlusion propose mechanisms that are relevant only to regions of low oxygen and low velocity, leaving a wide gap in our understanding of the most important pathologic process in sickle cell disease. Progress toward understanding vaso-occlusion is further challenged by the complexity of the multiple processes thought to be involved, including, but not limited to 1) deoxygenation-dependent hemoglobin polymerization leading to impaired rheology, 2) endothelial and leukocyte activation, and 3) altered cellular adhesion. Here, we chose to focus exclusively on deoxygenation-dependent rheologic processes in an effort to quantify their contribution independent of the other processes that are likely involved in vivo. We take advantage of an experimental system that, to our knowledge, uniquely enables the study of pressure-driven blood flow in physiologic-sized tubes at physiologic hematocrit under controlled oxygenation conditions, while excluding the effects of endothelium, leukocyte activation, adhesion, inflammation, and coagulation. We find that deoxygenation-dependent rheologic processes are sufficient to increase apparent viscosity significantly, slowing blood flow velocity at arterial oxygen tension even without additional contributions from inflammation, adhesion, and endothelial and leukocyte activation. We quantify the changes in apparent viscosity and define a set of functional regimes of sickle cell blood flow personalized for each patient that may be important in further dissecting mechanisms of in vivo vaso-occlusion as well as in assessing risk of patient complications, response to transfusion, and the optimization of experimental therapies in development., (Copyright © 2016 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2016

17. A biophysical indicator of vaso-occlusive risk in sickle cell disease.

Author

Wood DK, Soriano A, Mahadevan L, Higgins JM, and Bhatia SN

Subjects

Anemia, Sickle Cell blood, Anemia, Sickle Cell complications, Anemia, Sickle Cell physiopathology, Anemia, Sickle Cell therapy, Antisickling Agents therapeutic use, Blood Flow Velocity, Blood Transfusion, Blood Viscosity, Constriction, Pathologic, Equipment Design, Humans, Oxygen blood, Predictive Value of Tests, Prognosis, Risk Assessment, Risk Factors, Severity of Illness Index, Time Factors, Vascular Diseases blood, Vascular Diseases etiology, Vascular Diseases physiopathology, Vascular Resistance, Anemia, Sickle Cell diagnosis, Hemorheology, Microfluidic Analytical Techniques instrumentation, Vascular Diseases diagnosis

Abstract

The search for predictive indicators of disease has largely focused on molecular markers. However, biophysical markers, which can integrate multiple pathways, may provide a more global picture of pathophysiology. Sickle cell disease affects millions of people worldwide and has been studied intensely at the molecular, cellular, tissue, and organismal level for a century, but there are still few, if any, markers quantifying the severity of this disease. Because the complications of sickle cell disease are largely due to vaso-occlusive events, we hypothesized that a physical metric characterizing the vaso-occlusive process could serve as an indicator of disease severity. Here, we use a microfluidic device to characterize the dynamics of "jamming," or vaso-occlusion, in physiologically relevant conditions, by measuring a biophysical parameter that quantifies the rate of change of the resistance to flow after a sudden deoxygenation event. Our studies show that this single biophysical parameter could be used to distinguish patients with poor outcomes from those with good outcomes, unlike existing laboratory tests. This biophysical indicator could therefore be used to guide the timing of clinical interventions, to monitor the progression of the disease, and to measure the efficacy of drugs, transfusion, and novel small molecules in an ex vivo setting.

Published

2012