scholarly journals Visualizing Sickle Cell Disease Whole Blood Flow and Viscosity through Modifications to Hemoglobin Levels from a Simple Blood Transfusion

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 3244-3244
Author(s):  
Kirby S. Fibben ◽  
Wilbur A. Lam ◽  
Dan Y. Zhang ◽  
Melissa L. Kemp ◽  
David K. Wood ◽  
...  
Keyword(s):  
Blood Flow ◽  
Sickle Cell Disease ◽  
Velocity Profile ◽  
Sickle Cell ◽  
Whole Blood ◽  
Red Cells ◽  
Patient Specific ◽  
Red Cell ◽  
Cell Disease ◽  
Blood Samples

Abstract Red cell transfusions are an effective part of a clinical care regiment in the treatment of chronic sickle cell disease; however, the understanding of the target hemoglobin levels has not been investigated past the standard hematocrit/hemoglobin (HgB) of 10 g/dL. A simple transfusion of packed red cells can be a beneficial clinical treatment of acute pain crisis or even stroke. Along with other transfusion-based complications, when performing a simple transfusion, the changes in blood velocity as a result of increased blood viscosity from the additional red cells can lead to complications of their own. Because of this, clinical treatment has hesitated to transfuse sickle patients above a HgB of 10 g/dL. The complications of sickle cell disease tend to be more pronounced on the microvascular scale than then macrovascular. Along with this, the overall slower blood flow caused by the increase in viscosity from a simple blood transfusion is more probable to lead to complications on the microvascular level. Our device allows us to target the changes in whole blood on multiple scales including down to arteriole sizes. Here, we have begun to investigate how transfusion could be more patient-specific by identifying the velocity profile of whole blood flowing through a "microvasculature-on-a-chip" device that mimics the microvascular geometry (Figure 1A). The devices were microfabricated using polydimethylsiloxane (PDMS) and then coated with 0.1% bovine serum albumin (BSA) to help prevent red cell adhesion to channel walls. To simulate various HgB levels, healthy whole blood samples were centrifuged to separate red cells. To simulate a simple clinical transfusion of a sickle patient, isolated red cells were added to sickle whole blood samples. Similar to a clinical setting, sickle samples were only transfused up to higher HgB levels. HgB levels were then confirmed on a differential hematology analyzer (Sysmex XN 330). 3.2mm CA+ was added to various HgB samples to defeat the citrate anticoagulant. Samples were loaded into syringes then perfused into the BSA coated devices (Figure 1B). During perfusion, a 450 frame video of flow was captured at 40x resolution and 163 fps. Following capture, videos parameters such as frame rate and pixel distance were defined in a custom MATLAB (Mathworks, Natick, MA) script. The script segmented videos into cropped frames of the desired regions of interest then a Kanade-Lucas-Tomasi (KLT) tracking algorithm detected red cell features in each frame across 4 frames (Figure 1 B&C). 12 equal spaced bins were created across the width of the channel in the direction of flow; Tracked velocities were assigned to their corresponding bin and averaged to create a velocity profile of function as the distance from the center of the channel (Figure 1 D&E). To create a case study, two patient samples were received with the same starting HgB of 6.8 g/dL and were transfused upwards incrementally to a HgB of 12 g/dL. One patient is currently on a hydroxyurea regiment and the other patient is not. At each HgB level, the perfused whole blood was tracked through several different arteriole-sized vessels (30, 40 & 60 um) at two appropriate flow rates. To quantify the differences in the flow, the average cell velocity (um/s) through the channel and the peak velocity (um/s) through channels were charted against the various HgB levels (Figure 2). Continuing this series of experiments, 2 additional sickle whole blood on hydroxyurea samples were transfused upwards from their respective starting hemoglobin (9.7 & 10 g/dL). The flow was tracked and averages were quantified across the channel through its distance from the center of the channel. As transfused sickle HgB levels were increased, the bluntness of the velocity profile, or the difference between the average flow velocity in the center of the channel and at the walls of the channel, became less dramatic. This could be primarily attributed to the increase in the viscosity from the addition of the red cells (Figure 3). Our data shows that viscosity plays an important factor in whole blood flow. HgB of 10 g/dL is an important target for sickle transfusions; however, this target HgB may be more patient-specific than previously stated. Understanding patient viscosity may prove to be more important than hemoglobin levels. As patient blood increases in viscosity, blood slows down on the microvascular level the most. This may be critical in understanding the appropriate transfusion. Figure 1 Figure 1. Disclosures Lam: Sanguina, Inc.: Current holder of individual stocks in a privately-held company. Kemp: Parthenon Therapeutics: Membership on an entity's Board of Directors or advisory committees.

Whole Blood Tissue Factor Procoagulant Activity Is Elevated in Patients With Sickle Cell Disease

Blood ◽  
1998 ◽  
Vol 91 (11) ◽  
pp. 4216-4223 ◽  
Author(s):  
Nigel S. Key ◽  
Arne Slungaard ◽  
Luke Dandelet ◽  
Stephen C. Nelson ◽  
Christopher Moertel ◽  
...  
Keyword(s):  
Sickle Cell Disease ◽  
Tissue Factor ◽  
Mononuclear Cell ◽  
Sickle Cell ◽  
Whole Blood ◽  
Procoagulant Activity ◽  
Cell Disease ◽  
Blood Samples ◽  
Significant Difference ◽  
Whole Blood Samples

Abstract We developed a simple assay for the measurement of tissue factor procoagulant activity (TF PCA) in whole blood samples that avoids the need for mononuclear cell isolation. This method combines convenience of sample collection and processing with a high degree of sensitivity and specificity for TF. Using this method, we have determined that TF PCA is detectable in whole blood samples from normal individuals, which is itself a novel observation. Essentially all PCA could be shown to be localized in the mononuclear cell fraction of blood. Compared with controls, whole blood TF levels were significantly (P < .000001) elevated in patients with sickle cell disease (SCD), regardless of the subtype of hemoglobinopathy (SS or SC disease). No significant difference in TF PCA was observed between patients in pain crisis compared with those in steady-state disease. Because TF functions as cofactor in the proteolytic conversion of FVII to FVIIa in vitro, it was expected that an increase in circulating TF PCA would lead to an increased in vivo generation of FVIIa. On the contrary, FVIIa levels were actually decreased in the plasma of patients with SCD. Plasma TF pathway inhibitor (TFPI) antigen levels were normal in SCD patients, suggesting that accelerated clearance of FVIIa by the TFPI pathway was not responsible for the reduced FVIIa levels. We propose that elevated levels of circulating TF PCA may play an important role in triggering the activation of coagulation known to occur in patients with SCD. Because TF is the principal cellular ligand for FVIIa, it is possible that increased binding to TF accounts for the diminished plasma FVIIa levels.

Phenotype Matching of Donor Red Blood Cell Units for Nonalloimmunized Sickle Cell Disease Patients: A Survey of 1182 North American Laboratories

2005 ◽  
Vol 129 (2) ◽  
pp. 190-193 ◽  
Author(s):  
Melanie Osby ◽  
Ira A. Shulman
Keyword(s):  
Sickle Cell Disease ◽  
Blood Cell ◽  
Sickle Cell ◽  
North American ◽  
Red Cells ◽  
Red Cell ◽  
Cell Disease ◽  
Cell Antigen ◽  
Red Cell Antigens ◽  
Matched Donor

Abstract Context.—The transfusion of donor red blood cell units (RBCs) that lack certain red cell antigens (such as C, E, and K) when the corresponding antigens are absent from the recipient's red cells has been shown to reduce the risk of red cell alloimmunization in sickle cell disease patients. However, data are limited regarding the extent to which transfusion services routinely perform red cell antigen phenotype testing of nonalloimmunized sickle cell disease patients, and then use that information to select donor RBCs lacking 1 or more of the red cell antigens that the patient's red cells do not express. Objective.—To determine the extent to which transfusion services routinely perform red cell antigen phenotype testing of nonalloimmunized sickle cell disease patients, and then use that information to select donor RBCs lacking 1 or more of the red cell antigens that the patient's red cells do not express. Design.—An educational subsection of a College of American Pathologists Proficiency Testing Survey (J-C 2003) assessed transfusion service practices regarding performance of red cell antigen phenotype testing of nonalloimmunized sickle cell disease patients and how transfusion services use this information for the selection of donor RBCs. The data analysis of the survey included 1182 North American laboratories. Results.—Data from 1182 laboratories were included in the survey analysis, of which the majority (n = 743) reported that they did not routinely perform phenotype testing of sickle cell disease patients for antigens other than ABO and D. The other 439 laboratories reported that they did routinely perform phenotype testing of sickle cell disease patients for antigens in addition to ABO and D. The majority of these 439 laboratories (three fourths; n = 330) reported that they used these patient data for prophylactic matching with donor RBCs when sickle cell disease patients required transfusion. When phenotype-matched donor RBCs were used, the antigens most commonly matched (85% of the time) were C, E, and K. Conclusions.—The majority of North American hospital transfusion service laboratories do not determine the red cell antigen phenotype of nonalloimmunized sickle cell disease patients beyond ABO and D. Those laboratories that do determine the red cell phenotype of nonalloimmunized sickle cell disease patients beyond ABO and D most commonly match for C, E, and K antigens when phenotype-matched donor RBCs are used.

Clinical Effects of Chronic Red Blood Cell Exchange and Different Types of Red Cell Concentrates in Patients with Sickle Cell Disease

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 4823-4823
Author(s):  
Sergio Cabibbo ◽  
Agostino Antolino ◽  
Giovanni Garozzo ◽  
Carmelo Fidone ◽  
Pietro Bonomo
Keyword(s):  
Sickle Cell Disease ◽  
Blood Cell ◽  
Iron Overload ◽  
Sickle Cell ◽  
Red Blood Cell ◽  
Whole Blood ◽  
Clinical Effects ◽  
Red Cell ◽  
Blood Components ◽  
Cell Disease

Abstract For patients with severe SCD not eligible for hydroxyurea, two major therapeutic options are currently available: blood transfusion, and bone marrow transplantation. Either urgent or chronic red blood cell transfusion therapy, is widely used in the management of SCD but determines a progressive increase of ferritin level and is also limited by the development of antibodies to red cell antigens. The introduction of chronic red blood cell exchange and prestorage filtration to remove leucocytes and the use of techniques for multicomponent donation could be a good solutions. Thus, the aims of our studies were to evaluate the clinical effects of the different blood components in terms of annual transfusion needs and the intervals between transfusion, moreover we evaluated the efficacy of chronic red blood cell exchange (manual or automatic with cell separator) in preventing SCD complications and limiting iron overload. In our center we follow 78 patients affected by Sickle Cell Disease. We selected 36 patients occasionally treated with urgent red blood cell exchange because they had less than 2 complications/Year, and 42 patients regularly treated with chronic red blood cell exchange because they had more than 2 complications/Year with Hospital Admission. Moreover among these we selected 10 patients for fulfilling the criteria of continuous treatment at the Centre for at least 48 months with no interruptions, even sporadic and absolute transfusion dependency. All 10 patients were evaluated for a period of 4 years, during which two different systems of producing RCC were used. In the second two the patients were transfused with RCC obtained from filtering whole blood prestorage or with RCC from apheresis filtered prestorage. These products differed from those used in the preceding two years, during which the leucodepletion was obtained by bed-side filtration For all the patients we performed 782 automatic red blood cell exchanges and 4421 units of RCC were transfused. The exchange procedures were extremely well-tolerated by the patients and adverse effects were limited to symptoms of hypocalcaemia during automatic red blood cell exchange with cell separator. After every red blood cell exchange we obtained HbS level < 30%. The10 patients selected received respectively a mean of 6.9 and 6.1 units of RBCs exchanged per automatic procedure, in the first two years and in the second two years. Alloantibody developed in 14 patients but only 2 clinically significant and about the observed frequency of transfusion reactions it was very low. All patients treated with chronic red blood cell exchange had an improvement of the quality of life with a reduced number of complications/year (<2/year) and good compliance and moreover patients had limited iron overload making chelating therapy easier. In conclusion this study was focused on the most suitable characteristics of blood components for use in sickle cell disease patients and the choice of systematically adopting prestorage filtration of whole blood, enabled us to have RCC with a higher Hb concentration than standard. Moreover chronic manual or automatic red blood cell exchange as an alternative approach to simple long-term RBC transfusions give many advantages by being more rapid and tolerable as well as clinically safe and effective and minimize the development of iron overload especially when procedure was carried out with an automatic apparatus. To note that the clinical advantages for patients derived from good selection of the donor and good practices in the production of the blood components

scholarly journals Assessment of Average Hematocrit of Red Cell Units for Erythrocytapheresis Procedure in Sickle Cell Disease

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 4285-4285
Author(s):  
Veronica Cook ◽  
Teresa Munson ◽  
Elpidio Pena ◽  
Ashok Raj
Keyword(s):  
Sickle Cell Disease ◽  
Blood Cell ◽  
Sickle Cell ◽  
Red Blood Cell ◽  
Small Sample ◽  
Red Cells ◽  
Red Cell ◽  
Limited Data ◽  
Cell Disease ◽  
Consensus Report

Abstract Background: Erythrocytapheresis, or red blood cell exchange (RCE) is a non-invasive procedure in which a patient's erythrocytes are removed from the bloodstream while being replaced with erythrocytes from blood donors. RCE is commonly used as a transfusion technique in patients with sickle cell disease (SCD) to help treat and prevent complications associated with sickling of erythrocytes and iron overload. The AABB consensus report (1) outlines the procedural guidelines for RCE including appropriate indications and ideal forms of vascular access. However, the guidelines make no recommendation for determining the hematocrit (Hct) of the red cell bags for the procedure. Institutions take several different approaches to determine how many red cell units to exchange. The number of units needed depends on the volume and Hct of the individual units as well as the patient's pre-procedure Hct and HbS levels, height, weight, and the desired HbS and Hct targets. Red cell units are routinely labeled with volume, but are not generally labeled with Hct. The AABB consensus report (1) states that some institutions use an estimated Hct of 56% to 57% for each unit. The report rationalizes the use of an estimated Hct for input for the RCE, by citing the approximated Hct of bags of red cells (55% to 60%) with additive solution produced from whole blood donation, based on limited data. The goal of our study was to determine the average Hct on the red cell units used for RCE. Methods: This study used a retrospective chart review to investigate the Hct of red cell units during a RCE in a calendar year. Our institution uses pre-storage leuko-reduced red blood cells units in citrate phosphate dextrose adenine (CPDA-1) and adsol preservative (AS-1), which are 21 days old or less for RCE. The average Hct of the bags of red cells infused during the procedure was determined by accessing each bag for a small sample of blood to determine the Hct. Data was excluded if the patient did not meet standard weight requirements (> 30 kg) or required additional treatment protocols including the use of washed cells or machine priming. Results: A total of 297 encounters were recorded for 30 different patients. A total of 1953 bags (approximately 517 liters of red cell units in volume) were administered. Data from the encounters were used to calculate measures of central tendency. The average calculated Hct for each encounter was 63.3%, with a median and mode Hct being 63% and 62%. The range of Hct from the bags was 54.6% to 72.9%. The average Hct of the bags ranged from 60.6% (in March) to 64.8 % (in July). Conclusions: Our study suggests a higher average Hct of transfused red cell units than stated in the AABB consensus report (1), which was based on limited data. Our findings indicate that a standardized average of 63.3%, would be appropriate for our institution. Conversely, our findings also signify that the standardized average Hct must be determined in each institution prior to their application for RCE. However, our data also reveals that it is possible to subject patients to estimates as far as 9.7% above and 9.6 % below the true average Hct of the red cell bags used. The process of determination of Hct for each of the red cell units increases the time of pre-service activities, laboratory costs, and the overall infusion center time for the patients leading to higher costs per infusion. Consequently, using a standardized average of the Hct would result in cost savings. We have therefore adopted the practice of using the standardized average of Hct of 63.3% for RCE in our patients. Reference: 1. Biller E, Zhao Y, Berg M, Boggio L, Capocelli KE, Fang DC, Koepsell S, Music-Aplenc L, Pham HP, Treml A, Weiss J, Wool G, Baron BW. Red blood cell exchange in patients with sickle cell disease-indications and management: a review and consensus report by the therapeutic apheresis subsection of the AABB. 2018 Aug;58(8):1965-1972. doi: 10.1111/trf.14806 Disclosures Munson: Terumo Medical Corporation: Consultancy, Honoraria, Speakers Bureau. Raj: Terumo Medical Corporation: Honoraria, Speakers Bureau; Global biotherapeutics: Speakers Bureau; Forma therapeutics: Consultancy.

scholarly journals SOD3-Mimetic As a Complement for Genetic Therapy in Sickle Cell Disease

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 2355-2355
Author(s):  
Carleton JC Hsia ◽  
Li Ma
Keyword(s):  
Blood Flow ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Whole Blood ◽  
Dose Range ◽  
Breakdown Product ◽  
Cell Disease ◽  
Genetic Therapy ◽  
Shed Blood ◽  
Blood Exchange

Abstract Background and Objectives: Genetic therapy relieves transfusion-dependence in patients 12 years and older with ß-Thalassemia (1) There is an urgent need to develop a complementary approach to genetic therapy for children younger than 12 years of age. The objective of this report is to describe the potential development of an extracellular superoxide dismutase-mimetic (SOD3-mimetic) to relieve sickle cell disease (SCD) children susceptible to stroke from being transfusion-dependent in order to avoid stroke. SanFlow [aka polynitroxylated pegylated hemoglobin (PNPH)], a SOD3-mimetic has been evaluated and approved by the FDA for further development as drug for the treatment of traumatic brain injury (TBI) complicated by hemorrhagic shock (HS), stroke, and SCD. PK&PD studies demonstrated that SanFlow works as a macromolecular SOD3-mimetic by protecting the endogenous vascular nitric oxide (NO) leading to enhanced blood flow. SanFlow has been shown to protect against superoxide induced hypoxia and inflammation in transgenic SCD and rat model of ischemic stroke as well as a mouse model of TBI+HS. In a rat middle cerebral artery occlusion (MCAO) model of stroke the spreading of the hypoxic core of the ischemic brain as measured by Pial arterial diameter is maintained over 2 hours post onset of stroke with associated reduction in inflammatory markers and brain infraction (3). In a mouse TBI+SH model, SanFlow was shown to be superior to fresh shed whole blood. The safety and efficacy of SanFlow was tested over a 50 fold dose range (i.e. from 0.1 to 5 times the shed blood volume). SanFlow was shown to work at extremely low volume in conjunction with volume replacement crystalloid to substitute whole blood resuscitation (3). Experimental Results: Using Berkeley model of sickle mice (Hba0/0 Hbb0/0Tg (HuminiLCRα1GγAγδβS) we have measures the PK&PD of SanFlow as a complementary or a substitute for genetic therapy. We have non-invasively measured the blood flow and vasoconstriction using transgenic SS mice (N=7) against WT littermates (N=4) as control. A single bolus dose of SanFlow (20ml/kg at hemoglobin of 4g/dl) significantly corrected the aortic stiffness and pulmonary flow of the SS mice to that of WT littermates (P<0.05). This is also correlated with the decrease of superoxide level in the lung as measure by Luminol activity assays (which fluoresces in the presence of superoxide) (P<0.05). Plasma cGMP (downstream effector of NO and natriuretic peptide activity) and NOx (breakdown product of NO and a measure of NOS activity) concentrations were measured in plasma of mice after infusion of SanFlow. SanFlow infusion was shown to significantly increased plasma cGMP concentrations in plasma. SanFlow infusion also resulted in a significant increase in NOx in plasma after infusion (P<0.05). SanFlow resulted in an increase in plasma cGMP and NOx in SS mice. Thus, the pathophysiological defects or difference of SS mice and WT littermates are corrected by SanFlow infusion. Conclusions:The present results support development of SanFlow, delivered through continuous infusion, for anemic SCD children to prevent the development of blood transfusion dependency in order to avoid stroke and painful vaso-occlusive crisis (VOC). These results also demonstrated that SanFlow can be used safely and effectively in the elimination of serious painful vaso-occlusive crisis and protect silent and major strokes. Clinical trials of SanFlow in SCD children, prior to their transfusion dependence, as well as in transfusion-dependent teenagers and adults with SCD patients are warranted. By extension, ß-Thalassemia patients can also be treated like SCD patients using SanFlow to relieve them from dependence on life-long blood exchange transfusion. However, these patients would be treated with SOD3-mimetic while waiting for genetic therapy. References: Thompson AA., et.al. Eng. J. Med 2018; 398: 1479-1493 Brockman EC., et. al. 2017 Neurotrauma, 34(7):1337-50 Cao S., et. al. 2017 J. Am Heart Assoc., 6(9):e006505. Disclosures Hsia: AntiRadical Therapeutics LLC: Employment.

Immunohematologic Complications after Nonmyeloablative Hematopoietic Progenitor Cell Transplantation in Patients with Sickle Cell Disease

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 3404-3404
Author(s):  
Elizabeth S. Allen ◽  
Matthew M. Hsieh ◽  
Courtney D. Fitzhugh ◽  
Harvey G. Klein ◽  
John F. Tisdale ◽  
...  
Keyword(s):  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Progenitor Cell ◽  
Conditioning Regimen ◽  
Red Cells ◽  
Hematopoietic Progenitor Cell ◽  
Clinical Effects ◽  
Red Cell ◽  
Cell Disease ◽  
Hematopoietic Progenitor

Abstract Abstract Background: Hematopoietic progenitor cell (HPC) transplantation can cure sickle cell disease (SCD). Anonmyeloablative conditioning regimen has lower morbidity and mortality, and typically results in donor-derived erythrocytes and stable mixedchimerism of recipient- and donor-derived leukocytes. There is a risk ofimmunohematologic complications due to red cell antibodies induced by transfusions during theperi-transplantation period or exposure to donor antigens from the HPC graft. We described the incidence ofimmunohematologic complications in a cohort of patients with SCD undergoing HPC transplantation. Study design and methods: All patients with SCD (42 with HLA-matched and 19 withhaploidentical donors) enrolled in 3 clinical trials before March 31, 2015, were retrospectively evaluated for the formation of new red cell antibodies after transplantation or any red cell incompatibility between donor and recipient. Results: Of the 61 patients, 9 experienced immunohematologic complications. Before HPC transplantation, 3 patients had antibodies that were incompatible with their donors. After HPC transplantation, new antibodies were observed in 6 patients (11 allo-, 2 auto-), 3 of whom developed antibodies that were incompatible with donor or recipient red cells, while 3 developed antibodies that were compatible. The occurrence of new alloantibodies was not significantly associated with allo- or autoantibodies at enrollment, number of pre-enrollment transfusions, recipient sex, or ABO blood group. On average, the 3 patients with antibodies at enrollment that were incompatible with donor red cells received more red cell transfusions and depended on transfusion for longer time periods than comparison groups (51 vs. 13 units, p=0.015; 419 vs. 38 days, p=0.009). Among the 9 patients withimmunohematologic complications, the clinical course was highly variable: some had no significant effects attributable to the antibodies, while others experienced prolongedreticulocytopenia, severe anemia, or became almostuntransfusable. In the 47 patients who maintained their grafts long-term,immunohematologic complications did not negatively impact hemoglobin concentration or hemoglobin S expression after transfusion independence. There was no significant correlation betweenimmunohematologic complications and graft failure, rejection or death. Conclusions:Immunohematologic complications occurred in 15% of patients with SCD undergoingnonmyeloablative HPC transplantation. Clinical effects ranged from seemingly insignificant to potentially fatal. The formation of new antibodies was not predictable. In individuals with SCD, careful evaluation of donor and recipient phenotypes using red cell genotyping aids in preventing and managingimmunohematologic complications. Disclosures No relevant conflicts of interest to declare.

scholarly journals Cell-bound autologous immunoglobulin in erythrocyte subpopulations from patients with sickle cell disease

Blood ◽  
1985 ◽  
Vol 65 (5) ◽  
pp. 1127-1133 ◽  
Author(s):  
GA Green ◽  
MM Rehn ◽  
VK Kalra
Keyword(s):  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Red Cells ◽  
Cell Subpopulation ◽  
Red Cell ◽  
Cell Disease ◽  
Sickle Erythrocyte ◽  
Cell Subpopulations ◽  
Cell Fractions

Abstract Previously, we have demonstrated a parallel between most-dense (bouyant density) sickle erythrocyte subpopulations and most-dense aged normal red cells in the organization of membrane components in the intact cell. The present study has addressed the possibility that a corresponding similarity may exist between most-dense sickled red cell subpopulations and aged normal erythrocytes in the development of membrane protein components that function as receptors for autologous immunoglobulin (Ig). Autologous IgG retained by density-fractionated erythrocytes has been estimated by a nonequilibrium 125I-protein A (Staphylococcus aureus) binding assay. Results show that most-dense sickle cell fractions contain more (2.7-fold and 1.8-fold, P less than .005) cell-bound IgG in comparison to younger sickle erythrocyte fractions sedimenting at low density. Parallel findings were obtained after similar analyses of normal (homozygous-A) erythrocyte fractions. Detection of the presence of specific IgG was also carried out by direct binding of fluorescein isothiocyanate-conjugated anti-human IgG to density-separated red cell fractions followed by analyses of the fluorescent cell populations by flow cytometry. Results showed significantly higher levels of IgG bound to most-dense (12.1% +/- 2.5% and 8.8% +/- 0.5%-) sickle red cell subpopulations (P less than .005) in comparison to younger sickle erythrocyte fractions sedimenting at low densities (3.8% +/- 0.32% and 4.7% +/- 1.6% IgG-positive red cell subpopulation). These results indicate that some of the same membrane changes that occur at about 120 days in normal red cells are also apparent in the chronologically younger (life span in vivo, ten to 40 days) sickle erythrocyte. The increased retention of IgG by most-dense irreversibly sickled cell-enriched fractions in comparison to least- dense reversibly sickled cells or pre-irreversibly sickled erythrocyte fractions, suggests that alterations in the topography of the sickle cell membrane during the transformation in vivo to the most-dense irreversibly sickled cell morphology may produce the unmasking of cryptic antigenic sites. In addition, these findings may indicate that opsonization of specific erythrocyte subpopulations may play a role in the pathophysiology of sickle cell disease.

Polymerization and Three Dimensional Reconstruction of Deoxy-Sickle Cell Hemoglobin Fibers in High and Low Phosphate Buffers

2000 ◽  
Vol 6 (S2) ◽  
pp. 240-241
Author(s):  
Zhiping Wang ◽  
Gregory Kishchenko ◽  
Yimei Chen ◽  
Robert Josephs
Keyword(s):  
Blood Flow ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Three Dimensional ◽  
Polymerization Process ◽  
Red Cell ◽  
Cell Disease ◽  
Specific Therapy ◽  
Physiological Conditions ◽  
Dimensional Reconstruction

The amino acid substitution (B Glu → G6 Val) results in the conversion of Hemoglobin A (HbA) to sickle cell hemoglobin(HbS) which is responsible for sickle cell disease. Under physiological conditions this substitution causes a reduction of the solubility of HbA from about 340 mg/ml to 165 mg/ml (for HbS). One consequence of the reduction in solubility is that HbS polymerizes to form long fiber like structures about 240Å in diameter. The formation of these fibers causes sickle cell disease. The fibers fill the red cell and cause it to assume a characteristic sickle shape. More significantly the fibers cause the red cell to become rigid and, as a result, sickled cells can block blood flow in the capillaries. Understanding the polymerization process in detail is important for understanding the pathophysiology of sickle cell disease and for developing a specific therapy that could be used in its treatment.

scholarly journals MetAP2 Inhibition Modifies Hemoglobin S (HbS) to Delay Polymerization and Improve Blood Flow in Sickle Cell Disease

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2260-2260
Author(s):  
Melanie Demers ◽  
Sarah Sturtevant ◽  
Kevin Guertin ◽  
Dipti Gupta ◽  
Kunal Desai ◽  
...  
Keyword(s):  
Blood Flow ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Whole Blood ◽  
Research Funding ◽  
Oxygen Affinity ◽  
Enzyme Kinetic ◽  
Erythroid Cells ◽  
Cell Disease

Dilution of HbS with non-sickling hemoglobin or hemoglobin with increased oxygen affinity is clinically beneficial in sickle cell disease. Aldehydes, including 5-HMF, tucaresol or GBT440, modify the N-terminus of HbS by reversible covalent imine formation generating modified forms of HbS that resist polymerization under low oxygen concentrations. In contrast to reversible imine formation by aldehydes, we hypothesize that stable modification of HbS will result from N-terminal retention of the initiator methionine (iMet) and subsequent N-terminal acetylation of the iMet (acetyl-iMet). MetAP2 is the methionine aminopeptidase able to cleave iMet from Val1 on α-globin and βS-globin as the unfolded N-terminal peptides emerge from the ribosome. Enzyme kinetic studies with pure MetAP2 and N-terminal octapeptides showed that βS-globin peptide is a 5-fold better substrate than α-globin peptide. Lentiviral shRNA knock-down of MetAP2 in differentiating erythroid HUDEP cells in vitro confirmed that α-globin is more extensively modified than βS-globin, consistent with the enzyme kinetic data. Selective MetAP2 inhibitors used to treat cultured human erythroid cells (HUDEP and PBMC derived CD34+) and Townes SCD mice in vivo confirmed that both α-globin and βS-globin domains of HbS are extensively modified by N-terminal iMet and acetyl-iMet. N-terminal retention of iMet and subsequent acetylation creates a mixture of modified HbS tetramers with combined modifications on both globins. Cation exchange chromatography separated nine different modified HbS variants from unmodified HbS as identified by LCMS. Purified samples of HbS modified by N-terminal iMet and acetyl-iMet had increased oxygen affinity as measured by decreased P50. Modified HbS containing the acetyl-iMet-βS-globin were found to have delayed polymerization under complete hypoxia (sodium metabisulfite triggered hypoxia in 1.8 M phosphate). Two modified HbS variants were further purified for X-ray crystallography studies (βS-globin / iMet-α-globin and acetyl-iMet-βS-globin / iMet-α-globin). Oxyhemoglobin structures of both modified HbS variants were in the R2-state previously described in structures of aldehyde modified HbS. This R2-state stabilizes the oxygenated R-state of HbS from conversion to the deoxygenated T-state that initiates HbS polymerization in sickle RBC. Treatment by selective irreversible covalent or reversible MetAP2 inhibitors resulted in high levels of HbS modification (>75%) in cultured erythroid cells (HUDEP and CD34+ cells). Dose dependent modification of HbS was observed in Townes sickle cell mouse blood RBC in vivo with total modification of HbS approaching 50%. In whole blood ex vivo studies, modification of HbS decreased RBC sickling under hypoxia (4% O2) and significantly increased the affinity of RBC for oxygen (decreased P50). Blood samples from MetAP2 inhibitor treated mice were analyzed for single-cell O2 saturation of the RBC and for the fractional flow velocity drop in whole blood rheology under decreasing partial oxygen pressures. In blood from vehicle treated sickle mice, a low-saturation peak of deoxy-HbS was observed in 7.8% O2, in contrast to blood from MetAP2 inhibitor-treated mice where the low-saturation peak was only observed in 6.4% O2. Similarly, in an assay of O2 dependent blood flow rheology, the half-maximum fractional velocity drop occurred at 5% O2 in control blood decreasing to 2% O2 in MetAP2 inhibitor treated blood. Our studies show that MetAP2 inhibition results in retention of iMet on βS-globin and α-globin and allows further acetylation of the retained iMet to create a mixture of N-terminal modified HbS tetramers. These modified HbS variants resist polymerization and RBC sickling under conditions of low O2 by delaying HbS polymerization and increasing O2 affinity. Our data suggests that MetAP2 may warrant further study as a potential therapeutic target for sickle cell disease. Disclosures Demers: Sanofi: Employment. Sturtevant:Sanofi: Employment. Guertin:Sanofi: Employment. Gupta:Sanofi: Employment. Desai:Sanofi: Employment. Vieira:Sanofi: Employment. Hicks:Sanofi: Employment. Ismail:Sanofi: Employment. Safo:Sanofi: Consultancy, Research Funding; Virginia Commonwealth University: Patents & Royalties. Wood:Sanofi: Consultancy, Research Funding. Higgins:Sanofi: Consultancy, Research Funding. Light:Sanofi: Employment.

Type-2 Phosphatidylserine (PS)-Positive Erythrocytes and Their Association with Markers of Hemolysis and Hemostatic Activation in Children with Sickle Cell Disease (SCD)

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 943-943
Author(s):  
Yamaja B. Setty ◽  
Suhita Gayennebetal ◽  
Nigel S. Key ◽  
Marie Stuart
Keyword(s):  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Conflicts Of Interest ◽  
Red Cells ◽  
Red Cell ◽  
Cell Disease ◽  
Activation Markers ◽  
D Dimer

Abstract Introduction: Type-2 phosphatidylserine (PS)-positive red cells are a subpopulation of erythrocytes that are highly positive for PS, contain low levels of fetal hemoglobin, are specific for sickle cell disease (SCD) and have been identified in the dense red cell fraction. Studies have implicated PS-positive red cells in enhancing anemia due to phagocytosis and hemolysis. Shielding of red cell PS by diannexin, a synthetic homodimer of human annexin-V, has been demonstrated to provide protection against hemolysis and prevent activation of prothrombinase. Methods: Using flow cytometry, we measured the levels of type-1 (red cells with low PS positivity) and type-2 PS-positive red cells in 50 children with SCD (31 with HbSS and 19 with HbSC), and assessed their association with various markers of hemolysis and hemostatic activation. Markers of hemolysis evaluated included plasma lactate dehydrogenase (LDH), reticulocyte count, and hemoglobin. Whole blood tissue factor (WBTF), pro-thrombin fragment F1+2, and D-dimer were evaluated as markers of hemostatic activation. Results: We demonstrate that the levels of type-2 PS-positive red cells are significantly increased in HbSS patients (1.37 ± 0.97%, p<0.01) compared to children with HbSC disease (0.32 ± 0.21%) and age- and race-matched controls (0.15 ± 0.15%, n=19). WBTF and D-dimer showed significant associations with both type-1 and -2 red cells with no significant differences in the strength of their association. However, significantly greater correlations were noted between type-2 PS red cells and hemolytic markers compared to those noted with type-1 (Steiger's Z=3.05 to 4.59, p<0.01). In addition our in vitro studies demonstrate increased osmotic fragility of these red cells. Table 1. Association of PS-positive RBCs with markers of hemolysis and hemostatic activation Biomarker Type-1 PS-positive RBCs Type-2 PS-positive RBCs Markers of Hemolysis LDH r = 0.44, p<0.002 r = 0.63, p<0.00001 % Reticulocyte r = 0.43, p=0.002 r = 0.66, p<0.00001 Hemoglobin r =-0.35, p=0.014 r =-0.63, p<0.00001 Markers of Hemostatic Activation WBTF r = 0.41, p=0.008 r = 0.56, p<0.0002 F1+2 r = 0.26, p=0.07 r = 0.31, p<0.03 D-dimer r = 0.46, p<0.001 r = 0.56, p<0.0005 Conclusions: Type-2 PS-positive red cells are elevated in SCD and the number of these cells correlates significantly with both markers of hemolysis and hemostasis. These findings provide a patho-physiologic link between the intravascular hemolytic milieu of SCD and the hemostatic perturbations previously noted in this disease. Disclosures No relevant conflicts of interest to declare.

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