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Treatment of sickle cell disease by increasing oxygen affinity of hemoglobin.

Eric R HenryBelhu MetaferiaQuan LiJulia HarperRobert B BestKristen E GlassTroy CellmerEmily B DunkelbergerAnna ConreySwee Lay Lay TheinH Franklin BunnWilliam A Eaton
Published in: Blood (2021)
The issue of treating sickle cell disease with drugs that increase hemoglobin oxygen affinity has come to the fore with the US Food and Drug Administration approval in 2019 of voxelotor, the only antisickling drug approved since hydroxyurea in 1998. Voxelotor reduces sickling by increasing the concentration of the nonpolymerizing, high oxygen affinity R (oxy) conformation of hemoglobin S (HbS). Treatment of sickle cell patients with voxelotor increases Hb levels and decreases indicators of hemolysis, but with no indication as yet that it reduces the frequency of pain episodes. In this study, we used the allosteric model of Monod, Wyman, and Changeux to simulate whole-blood oxygen dissociation curves and red cell sickling in the absence and presence of voxelotor under the in vivo conditions of rapid oxygen pressure decreases. Our modeling agrees with results of experiments using a new robust assay, which shows the large, expected decrease in sickling from the drug. The modeling indicates, however, that the increase in oxygen delivery from reduced sickling is largely offset by the increase in oxygen affinity. The net result is that the drug increases overall oxygen delivery only at the very lowest oxygen pressures. However, reduction of sickling mitigates red cell damage and explains the observed decrease in hemolysis. More importantly, our modeling of in vivo oxygen dissociation, sickling, and oxygen delivery suggests that drugs that increase fetal Hb or decrease mean corpuscular hemoglobin concentration (MCHC) should be more therapeutically effective than drugs that increase oxygen affinity.
Keyphrases
  • sickle cell disease
  • small molecule
  • single cell
  • radiation therapy
  • drug administration
  • drug induced
  • spinal cord injury
  • spinal cord
  • high throughput
  • molecular dynamics simulations
  • replacement therapy