Your search keyword '"Nathalie, Eymard"' showing total 2 results

1. Bone marrow infiltration by multiple myeloma causes anemia by reversible disruption of erythropoiesis

Author

Mark J. Koury, Nathalie Eymard, Anass Bouchnita, Vitaly Volpert, and Tamara K. Moyo

Subjects

0301 basic medicine, Pathology, medicine.medical_specialty, Chemotherapy, Anemia, business.industry, Bortezomib, medicine.medical_treatment, Hematology, medicine.disease, 3. Good health, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, hemic and lymphatic diseases, medicine, Erythropoiesis, Bone marrow, business, Infiltration (medical), Multiple myeloma, Lenalidomide, medicine.drug

Abstract

Multiple myeloma (MM) infiltrates bone marrow and causes anemia by disrupting erythropoiesis, but the effects of marrow infiltration on anemia are difficult to quantify. Marrow biopsies of newly diagnosed MM patients were analyzed before and after four 28-day cycles of non-erythrotoxic remission induction chemotherapy. Complete blood cell counts and serum paraprotein concentrations were measured at diagnosis and before each chemotherapy cycle. At diagnosis, marrow area infiltrated by myeloma correlated negatively with hemoglobin, erythrocytes, and marrow erythroid cells. After successful chemotherapy, patients with less than 30% myeloma infiltration at diagnosis had no change in these parameters, whereas patients with more than 30% myeloma infiltration at diagnosis increased all three parameters. Clinical data were used to develop mathematical models of the effects of myeloma infiltration on the marrow niches of terminal erythropoiesis, the erythroblastic islands (EBIs). A hybrid discrete-continuous model of erythropoiesis based on EBI structure/function was extended to sections of marrow containing multiple EBIs. In the model, myeloma cells can kill erythroid cells by physically destroying EBIs and by producing proapoptotic cytokines. Following chemotherapy, changes in serum paraproteins as measures of myeloma cells and changes in erythrocyte numbers as measures of marrow erythroid cells allowed modeling of myeloma cell death and erythroid cell recovery, respectively. Simulations of marrow infiltration by myeloma and treatment with non-erythrotoxic chemotherapy demonstrate that myeloma-mediated destruction and subsequent reestablishment of EBIs and expansion of erythroid cell populations in EBIs following chemotherapy provide explanations for anemia development and its therapy-mediated recovery in MM patients.

Published

2016

2. Bone marrow infiltration by multiple myeloma causes anemia by reversible disruption of erythropoiesis

Author

Anass, Bouchnita, Nathalie, Eymard, Tamara K, Moyo, Mark J, Koury, and Vitaly, Volpert

Subjects

Adult, Erythrocyte Indices, Male, Anemia, Middle Aged, Models, Theoretical, Dexamethasone, Thalidomide, Bortezomib, Treatment Outcome, Erythroid Cells, Bone Marrow, Antineoplastic Combined Chemotherapy Protocols, Humans, Erythropoiesis, Female, Multiple Myeloma, Lenalidomide, Biomarkers, Aged

Abstract

Multiple myeloma (MM) infiltrates bone marrow and causes anemia by disrupting erythropoiesis, but the effects of marrow infiltration on anemia are difficult to quantify. Marrow biopsies of newly diagnosed MM patients were analyzed before and after four 28-day cycles of non-erythrotoxic remission induction chemotherapy. Complete blood cell counts and serum paraprotein concentrations were measured at diagnosis and before each chemotherapy cycle. At diagnosis, marrow area infiltrated by myeloma correlated negatively with hemoglobin, erythrocytes, and marrow erythroid cells. After successful chemotherapy, patients with less than 30% myeloma infiltration at diagnosis had no change in these parameters, whereas patients with more than 30% myeloma infiltration at diagnosis increased all three parameters. Clinical data were used to develop mathematical models of the effects of myeloma infiltration on the marrow niches of terminal erythropoiesis, the erythroblastic islands (EBIs). A hybrid discrete-continuous model of erythropoiesis based on EBI structure/function was extended to sections of marrow containing multiple EBIs. In the model, myeloma cells can kill erythroid cells by physically destroying EBIs and by producing proapoptotic cytokines. Following chemotherapy, changes in serum paraproteins as measures of myeloma cells and changes in erythrocyte numbers as measures of marrow erythroid cells allowed modeling of myeloma cell death and erythroid cell recovery, respectively. Simulations of marrow infiltration by myeloma and treatment with non-erythrotoxic chemotherapy demonstrate that myeloma-mediated destruction and subsequent reestablishment of EBIs and expansion of erythroid cell populations in EBIs following chemotherapy provide explanations for anemia development and its therapy-mediated recovery in MM patients.

Published

2015