Background: Sickle hemoglobin (HbS) under conditions of deoxygenation polymerizes to cause sickling of red blood cells (RBCs) and other rheological abnormalities. Voxelotor has been previously shown in a preclinical model of sickle cell disease (SCD) to increase HbS affinity to oxygen, thus reducing its polymerization and sickling with subsequent increase in the half-life of RBCs. We hypothesized that given this mechanism of action, we would observe improvements in RBC physiology in patients receiving voxelotor. In the Phase 3 GBT HOPE trial, the use of voxelotor in patients with SCD caused a significant reduction in markers of hemolysis and anemia. Ektacytometry is considered the gold standard to study deformability of RBCs with membrane protein disorders. The deformability of RBCs can be assessed using a defined value of shear stress with an increasing osmotic gradient (osmoscan) as well as with a newer technology to subject these cells to gradual deoxygenation (oxygenscan). Both assays can be measured using the Laser Optical Rotational Red Cell Analyzer (LORRCA, RR Mechatronics, NL). In this pilot study, we analyzed samples from patients with SCD receiving voxelotor, before and 12 weeks after starting therapy to assess the benefits of voxelotor on RBC physiology. Methods: Our pilot study obtained whole blood from children ages 4-11 years with SCD, who were enrolled in the IRB approved GBT 440-007 clinical trial (NCT02850406; a study evaluating multiple doses of voxelotor at 1500 mg/day equivalent exposure to adults based on body weight) at Emory University/Children's Healthcare of Atlanta. All participants in this cohort continued their stable, optimal hydroxyurea dose during treatment with voxelotor. The below measurements were performed on the pre-dose and Week 12 visit samples. Deformability of RBCs was performed at a shear stress of 30 Pa and varying osmolality gradients (0-600 mOsm/Kg) for Osmoscan. Omin corresponds to the value of the hypotonic osmolality, where 50% of the cells hemolyze in an osmotic fragility assay and provides information on the initial surface area:volume ratio. Maximal deformability or Elongation Index (EImax) near isotonic osmolality informs us of the RBC cytoskeleton mechanics and Ohyper, the osmolality corresponding to 50% of the Elmax, provides information regarding the cytoplasmic viscosity. Oxygenscan was performed but under controlled deoxygenation using nitrogen. Point of Sickling (POS) is a point on the curve during deoxygenation when sickling begins, and EImin corresponds when sickle RBCs can least elongate. Oxygen dissociation curves were obtained using a HemOx Analyzer (TCS Scientific). Complete blood count parameters were determined on a clinical laboratory hematology analyzer (ADVIA, Siemens). Data was analyzed with Prism using a paired T-test. Results: Both pre-dose and Week 12 visit samples were available for 10 participants. Mean hemoglobin at baseline was 9.0 g/dL (7.6-10.0) and at 12 weeks, 10.3 g/dL (8.2-12.3). Six out of 10 participants had a hemoglobin response at Week 12 (defined as an increase in Hb from baseline by >1 g/dL), of which 5 had hemoglobin over 10 g/dL. Mean % change in percentage of reticulocytes was -17.0%. Significant improvement in EImax on osmoscan was noted at Week 12 (p=0.0147), suggesting RBCs were more deformable with improved cytoskeleton mechanics. In addition, oxygenscan curves shifted upwards towards normal with a significant increase in EImax (p=0.0347) and EImin (p=0.0079). These findings combined with a decrease in POS (p=0.0001) during deoxygenation suggests that at low oxygen tension, voxelotor treated RBCs were more deformable possibly from reduced HbS polymer inside these cells. Significant reductions in P50 (p=0.0011) and P20 (p=0.0001) with a left shift of the oxygen dissociation curve further demonstrates the effect of voxelotor on RBCs. Discussion: Voxelotor therapy in children with HbSS is associated with reductions in anemia and reticulocyte response, and recovery in RBC health as early as 12 weeks of treatment. Voxelotor's ability to inhibit HbS polymerization and RBC sickling is associated with specific modulation in red cell rheology at normoxic and deoxygenating conditions. Left shifted oxygen dissociation curves confirm voxelotor's ability to increase oxygen affinity. These findings suggest that voxelotor improves RBC deformability and anemia and delays the initiation of RBC sickling. Figure Disclosures Chonat: Alexion: Other: advisory board; Agios Pharmaceuticals, Inc.: Other: advisory board. Baratz:Prolong Pharmacuticals: Honoraria; Global Blood Therapeutics: Research Funding. Pochron:Global Blood Therapeutics: Employment, Equity Ownership. Dixon:Global Blood Therapeutics: Employment, Equity Ownership. Tonda:Global Blood Therapeutics: Employment, Equity Ownership. Lehrer-Graiwer:Global Blood Therapeutics: Employment, Equity Ownership. Brown:Pfizer: Research Funding; Novartis, Inc: Research Funding; Imara, Inc: Consultancy, Research Funding; Global Blood Therapeutics, Inc: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding. Archer:AstraZeneca: Research Funding; Prolong Pharmaceuticals: Consultancy; Global Blood Therapeutics: Consultancy, Research Funding.
Background: Amongst patients with sickle cell disease (SCD) the leading cause of death is the acute chest syndrome (ACS). This pneumonia-like complication frequently occurs during or shortly after a vaso-occlusive crisis (VOC). In pediatric patients hospitalized for VOC, incentive spirometry has demonstrated to prevent the development of ACS. Aims: This study was designed to determine if a comparable effect of incentive spirometry can be demonstrated in adult patients with SCD. Furthermore, we aimed to validate the ability of the Bartolucci score to identify patients at risk of ACS and assessed the value of procalcitonin as a potential biomarker for ACS. In addition, clinical characteristics and laboratory results were determined to identify potential risk factors. Methods: In this multicenter prospective randomized trial, we included consecutive adult patients (≥18 yr) admitted for VOC presenting with chest or back pain above the diaphragm. Patients were randomly assigned to spirometry or control group. Patients presenting with ACS were excluded. A chest radiograph was performed 5 days after admission, or sooner when clinically indicated, in order to diagnose pulmonary abnormalities. ACS was defined as a new infiltrate/atelectasis combined with pulmonary symptoms. At presentation, procalcitonin plasma levels were assessed and the Bartolucci risk score was calculated to determine to the risk of developing ACS for each patient. In addition, clinical and laboratory parameters were compared between patients with and without ACS during admission. Results: In total 66 episodes of hospitalization for VOC in 48 patients were included. Median age was 26 years and 46 of the hospitalizations concerned patients with a severe genotype (HbSS/HbSβ 0 thalassemia) versus 20 hospitalization with a mild genotype (HbSC/HbSβ + thalassemia). The overall incidence of ACS in this study cohort was 19.7%. In the spirometry group, ACS was diagnosed in 5/34 (14.7%) hospitalizations compared to 8/32 (25%) hospitalizations in the control group ]; P = .293). Twelve of the 13 ACS episodes occurred in patients with a severe genotype. The Bartolucci risk score could be calculated for 50 hospitalizations. The scores area under the curve (AUC) was 0.747 (P = .013), with a negative predictive value (NPV) of 94% and a positive predictive value (PPV) of 31%. No difference in procalcitonin plasma levels were found between patients with and patients without ACS (0.52 ± 1.56 µg/ml versus 0.56 ± 1.44 µg/ml, respectively). At baseline, hemoglobin levels were significantly lower while LDH plasma levels, leukocyte and platelet counts were significantly higher in ACS hospitalizations as compared to non-ACS hospitalizations. Patients who developed ACS showed significantly more documented fever during admission (61.5% vs 17.0%) and a longer length of hospital stay (median 10.0 days vs 4.5 days). Summary/Conclusion: Incentive spirometry did not significantly reduce the development of ACS in this prospective study in adult patients with SCD admitted with VOC and...
In sickle cell disease (SCD), higher whole blood viscosity is a risk factor for vaso-occlusive crisis, avascular necrosis, and proliferative retinopathy. Blood viscosity is strongly impacted by hemoglobin (Hb) levels and red blood cell (RBC) deformability. Voxelotor is a hemoglobin S (HbS) polymerization inhibitor with anti-sickling properties that increases the Hb affinity for oxygen, thereby reducing HbS polymerization. In clinical trials, voxelotor increased Hb by an average of 1g/dl, creating concern that this rise in Hb could increase viscosity, particularly when the drug was cleared. To investigate this potential rebound hyperviscosity effect, we treated SCD mice with GBT1118, a voxelotor analog, and stopped the treatment to determine the effect on blood viscosity and RBC deformability under a range of oxygen concentrations. GBT1118 treatment increased Hb, improved RBC deformability by increasing the elongation index under normoxic (EImax) and hypoxic conditions (EImin), and decreased the point of sickling (PoS) without increasing blood viscosity. The anti-sickling effects and improvement of RBC deformability balanced the effect of increased Hb such that there was no increase in blood viscosity. Forty-eight hours after ceasing GBT1118, Hb declined from the rise induced by treatment, viscosity did not increase, and EImin remained elevated compared to control animals. Hb and PoS were not different from control animals, suggesting a return to native oxygen affinity and clearance of the drug. RBC deformability did not return to baseline, suggesting some residual rheological improvement. These data suggest that concerns regarding viscosity rise above pre-treatment levels upon sudden cessation of voxelotor are not warranted.
The pathophysiologic mechanism of sickle cell disease (SCD) involves polymerization of sickle haemoglobin (HbS) following deoxygenation in the microvasculature, leading to red blood cell (RBC) sickling and decreased RBC health, deformability and survival. 1,2 These abnormalities drive haemolysis, anaemia, vascular inflammation and microvasculature occlusions, resulting in clinical complications, such as fatigue, painful vaso-occlusive crisis, reduced quality of life, considerable end-organ damage and premature death. 1,2 Voxelotor is a first-in-class polymerization inhibitor approved by the US Food and Drug Administration for the treatment of SCD in patients aged ≥4 years and in Great Britain, the European Union, the United Arab Emirates, Kuwait, and Oman in patients aged ≥12 years. Voxelotor is a reversible covalent modifier of Hb that allosterically increases Hb-O 2 affinity, thereby increasing the proportion of oxygenated Hb in all RBCs. 3,4 GBT021601 is a potent second-generation HbS polymerization inhibitor with the same mechanism of action as voxelotor. Herein, we present the in vitro characterization of GBT021601 using blood
Background: In sickle cell disease (SCD), elevated blood viscosity is a risk factor for vaso-occlusive crisis (VOC). Blood viscosity is influenced by hemoglobin (Hb) levels, red blood cell (RBC) deformability, density, and aggregation. Voxelotor is an HbS polymerization inhibitor that increases the Hb affinity for oxygen and reduces sickling. In human subjects, voxelotor significantly increases Hb levels. A rise in Hb due to voxelotor does not increase blood viscosity the way a similar increase in unmodified HbS would. However, voxelotor transiently modifies HbS, raising concern that if voxelotor was stopped suddenly, the drug induced extra HbS would revert to its unmodified state, causing a significant rise in blood viscosity and increasing the risk of VOC. This effect could continue until the drug induced Hb is eliminated by hemolysis. To investigate this, we treated a sickle mouse model with GBT1118, a voxelotor analog. We then stopped the treatment and determined the effect on whole blood viscosity, the hematocrit-to-viscosity ratio (HVR), a measure of oxygen carrying capacity, and RBC deformability. As GBT1118 has a half-life of 14 hours in SCD mouse, we measured the post-drug effect 48 hours after drug withdrawal. Methods: Ten Townes HbSS mice were fed control chow, 10 were fed chow containing GBT1118 for 7 days, 10 were fed GBT1118 chow for 7 days, and then returned to control chow for 48 hours. RBC deformability was measured by oxygen gradient ektacytometry (Lorrca with Oxygenscan, RR Mechatronics). Blood viscosity was measured with a cone and plate viscometer (Brookfield DVII+). Hb was measured via ADVIA (Siemens). Results: Treatment with GBT1118 significantly increased Hb without increasing blood viscosity. HVR was increased at both 45 s-1 and 225 s-1 shear rates (Figure 1). GBT1118 treatment also improved RBC deformability under both normoxic (EImax) and hypoxic conditions (EImin). Point of sickling (PoS) was reduced, indicating that treated RBC tolerated lower oxygen concentrations before sickling (Figure 2). When the drug was withdrawn for 48 hours, compared to control animals, 1) Hb declined rapidly (7.1 g/dL in control feed, 13.1 g/dL in treated mice compared to 9.0 g/dL after 48 hours off treatment, P<0.001); 2) viscosity did not increase compared to control feed (at shear rate 45 s-1, 12.8 cP after treatment compared to 11.4 cP in control cohort; at shear rate 225 s-1,10.8 cP after treatment compared to 10.3 cP in controls); 3) HVR returned to baseline (at shear rate 45 s-1, 4.5 after treatment compared to 3.6 in controls; at shear rate 225 s-1, 6.6 after treatment compared to 4 cP in controls), 4) EImin remained elevated (0.16 in controls compared to 0.32 after 48 hours off treatment, P<0.001); 5) Elmax and PoS were not significantly different. Conclusions: The GBT1118-treated sickle mouse had a significant rise in Hb and improvement in PoS and deformability. Forty-eight hours after removing the analog compound, Hb dropped markedly, and the PoS was not different from control animals, suggesting a return to native oxygen affinity and clearance of the drug. Interestingly, deformability (EImin) did not return to baseline, suggesting some residual rheological improvement occurred in the red cell population that did not dissipate when the drug was cleared. These data suggest that potential concerns regarding viscosity rising above pre-treatment levels upon sudden cessation of voxelotor are not warranted. This may be due to retained improvement in red cell rheology after voxelotor is stopped combined with rapid return to baseline Hb levels. Further study in patients treated with voxelotor may be needed to determine if voxelotor produces additional benefits, such as reduction in oxidative stress, that outlive its presence in the red cell. Disclosures Pochron: Global Blood Therapeutics: Current Employment, Current equity holder in publicly-traded company. Oksenberg:Global Blood Therapeutics: Current Employment, Current equity holder in publicly-traded company. Sheehan:Global Blood Therapeutics: Research Funding; Emmaus: Research Funding; Novartis: Research Funding.
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