Platelet growth factors: potential impact on transfusion medicine

Cost of chemotherapy-induced thrombocytopenia among patients with lymphoma or solid tumors

BACKGROUND

The purpose of this study was to estimate the mean incremental cost of chemotherapy-induced thrombocytopenia and the drivers of cost. Another goal was to estimate the impact of depth and duration of thrombocytopenia on the cost of thrombocytopenia.

METHODS

A retrospective cohort, consisting of a random sample of 75 solid tumor or lymphoma patients who developed chemotherapy-induced thrombocytopenia (</= 50,000 platelets per microl), was chosen. The number of each type of resource used during 217 cycles with and 300 cycles without thrombocytopenia were multiplied by the cost of each resource and summed to yield the total cost of care (in 1999 dollars from the provider's perspective).

RESULTS

Compared with cycles without thrombocytopenia, the mean incremental cost of thrombocytopenia was $1037 per cycle. However, 60% of cycles were usual cost, with a mean cost of thrombocytopenia of $43 per cycle less than control cycles. Twelve percent of cycles were high cost (mean incremental cost = $612 per cycle); 28% were very high cost (mean incremental cost = $3519). The excess cost during high-cost cycles was due to high consumption of prophylactic platelet transfusions and during very high-cost cycles to both higher platelet transfusion consumption and to a high incidence of major bleeding episodes.

CONCLUSIONS

Although thrombocytopenia is a common complication of chemotherapy, only 40% of cycles with thrombocytopenia would be considered high or very high cost. Interventions targeted at this subset of cycles could significantly reduce the cost of thrombocytopenia provided they are initiated early enough in the chemotherapy experience to be effective.

Thrombopoietin therapy increases platelet yields in healthy platelet donors

The recombinant thrombopoietins have been shown to be effective stimulators of platelet production in cancer patients. It was therefore of interest to determine if one of these, pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF), could be used to increase platelet counts and consequently platelet yields from apheresis in healthy platelet donors. In a blinded, 2-cycle, crossover study, 59 platelet donors were randomized to receive a single subcutaneous injection of PEG-rHuMGDF (1 microg/kg or 3 microg/kg) or placebo and 15 days later undergo platelet apheresis. Donors treated with placebo had a median peak platelet count after PEG-rHuMGDF injection of 248 x 10(9)/L compared with 366 x 10(9)/L in donors treated with 1 microg/kg PEG-rHuMGDF and 602 x 10(9)/L in donors treated with 3 microg/kg PEG-rHuMGDF. The median maximum percentage that platelet counts increased from baseline was 10% in donors who received placebo compared with 70% in donors who received 1 microg/kg and 167% in donors who received 3 microg/kg PEG-rHuMGDF. There was a direct relationship between the platelet yield and the preapheresis platelet count: Placebo-treated donors provided 3.8 x 10(11) (range 1.3 x 10(11)-7.9 x 10(11)) platelets compared with 5.6 x 10(11) (range 2.6 x 10(11)-12.5 x 10(11)) or 11.0 x 10(11) (range 7.1 x 10(11)-18.3 x 10(11)) in donors treated with 1 microg/kg or 3 microg/kg PEG-rHuMGDF, respectively. Substandard collections (<3 x 10(11) platelets) were obtained from 26%, 4%, and 0% of the placebo, 1 microg/kg, and 3 microg/kg donors, respectively. No serious adverse events were reported; nor were there events that met the criteria for dose-limiting toxicity. Thrombopoietin therapy can increase platelet counts in healthy donors to provide a median 3-fold more apheresis platelets compared with untreated donors.

Influence of medium components on ex vivo megakaryocyte expansion

Reinfusion of ex vivo-expanded autologous megakaryocytes together with a stem cell transplantation may be useful to prevent or reduce the period of chemotherapy-induced thrombocytopenia. In this study, we analyzed several serum-containing and serum-free media to identify the most suitable medium for megakaryocyte expansion. Moreover, two thrombopoietin (Tpo)-mimetic peptides were tested to evaluate whether they could replace Tpo in an expansion protocol. To analyze the effects of different media on megakaryocyte expansion, we used an in vitro liquid culture system. For this purpose, CD34(+) cells were isolated from peripheral blood and cultured for 8 days in the presence of Tpo and interleukin-3 (IL-3). The presence of megakaryocytes was analyzed by flow cytometric analysis after staining for CD41 expression. For our standard culture procedure, megakaryocyte medium (MK medium) supplemented with 10% AB plasma was used. Addition of 5% or 2.5% AB plasma yielded higher numbers of megakaryocytes, implying the presence of inhibitory factors in plasma. However, some plasma components are required for optimal megakaryocyte expansion because addition of less than 1% AB plasma or addition of human serum albumin instead of AB plasma resulted in the formation of lower numbers of megakaryocytes. Two commercially available serum-free media were also tested: Cellgro and Stemspan. If CD34(+) cells were cultured in Cellgro medium similar numbers of megakaryocytes were obtained as when CD34(+) cells were cultured in MK medium supplemented with 10% AB plasma. In MK medium with 2.5% AB plasma, higher numbers of megakaryocytes were cultured than in MK medium supplemented with 10% AB plasma. Therefore, Cellgro medium is not the best alternative medium. In cultures with Stemspan medium, higher numbers of megakaryocytes were obtained compared to MK medium with 10% AB plasma. Stemspan is thus a good alternative for MK medium. Two Tpo-mimetic peptides, AF13948 and PK1M, were tested for their ability to replace Tpo. In cultures with AF13948, comparable numbers of megakaryocytes were obtained as in the presence of Tpo, but in cultures with PK1M the number of megakaryocytes was lower. This study shows that high concentrations of plasma in medium inhibits megakaryocyte formation, but some plasma components are required for optimal megakaryocyte expansion. For an ex vivo expansion protocol, it is worthwhile to test several media, because the number of megakaryocytes differs widely with the medium used.

Differences in megakaryocyte expansion potential between CD34(+) stem cells derived from cord blood, peripheral blood, and bone marrow from adults and children

OBJECTIVE

Reinfusion of ex vivo expanded autologous megakaryocytes together with stem cell transplantation may be useful to prevent or reduce the period of chemotherapy-induced thrombocytopenia. We compared the megakaryocyte expansion potential of CD34(+) stem cells derived from different sources: cord blood (CB), peripheral blood (PB), bone marrow from adults (ABM), and bone marrow from children (ChBM). Three different growth factor combinations were tested to identify the best combination for each of the sources.

MATERIALS AND METHODS

CD34(+) cells were isolated from CB, PB, ABM, or ChBM and cultured in an in vitro liquid culture system in the presence of thrombopoietin (Tpo), Tpo + interleukin (IL-1), or Tpo + IL-3. After 8 days, proliferation was determined and the cultured cells were identified with lineage-specific surface markers by flow cytometry.

RESULTS

Cultures with ChBM-derived CD34(+) cells showed the lowest level of expansion of megakaryocytes and gave rise to more profound formation of myeloid and monocytic cells. In cultures with BM- or PB-derived cells, presence of IL-3 reduced the number of immature megakaryocytes (CD34(+)CD41(+) cells). However, in CB cultures, the number of CD34(+)CD41(+) cells was highest in cultures with Tpo + IL-3. Overall, cultures with CB CD34(+) cells yielded the highest number of megakaryocytes, but these cells showed reduced ploidization and lower level of CD41 expression, suggesting less maturation.

CONCLUSIONS

Each of the different CD34(+) cell sources responded differently to cytokine stimulation. For PB and ABM, the cytokine combination Tpo + IL-1 is most suitable to obtain high numbers of both immature and mature megakaryocytes for transfusion purposes. For CB, Tpo + IL-3 is better.

Thrombopoietin and the TPO receptorduring platelet storage

BACKGROUND

For most cells, the addition of a specific growth factor has improved cellular viability by preventing programmed cell death (apoptosis). To determine whether the platelet-specific hematopoietic growth factor thrombopoietin (TPO) might improve platelet viability, endogenous TPO and the platelet TPO receptor were analyzed during storage, and the effect of recombinant TPO on platelet viability was assessed.

STUDY DESIGN AND METHODS

During platelet storage, TPO stability was assessed by SDS-PAGE, TPO receptor function was measured, and the platelet TPO receptor was characterized by a (125)I-rHuTPO competitive-binding assay. A recombinant TPO, pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF), was added to platelet concentrates during storage, and its effect on pH, LDH, and metabolic activity was determined.

RESULTS

During storage, the molecular weight and concentration of endogenous TPO (125 +/- 19 pg/mL) and exogenous TPO (5720 +/- 140 pg/mL) were constant for 12 days; the number (33 +/- 4), binding affinity (149 +/- 33 pM), and function of the platelet TPO receptors were constant for 7 days. Metabolic activity measured with the MTT and MTS assays closely correlated with changes in the pH and LDH. The addition of PEG-rHuMGDF did not alter the pH, LDH, or metabolic activity of platelets during storage, but it did increase by 65 percent the uptake of (35)S-methionine into platelets. Finally, platelet concentrates obtained from donors treated with PEG-rHuMGDF retained normal metabolic activity for 12 days, as compared with 5 to 6 days for normal platelet concentrates.

CONCLUSIONS

TPO and its platelet receptor are present in normal amounts and have normal function during platelet storage. The addition of recombinant TPO increased platelet methionine transport but did not alter platelet viability during storage. Other means to prevent apoptosis during platelet storage should be considered, and the measurement of platelet metabolic activity by MTT and MTS assays may assist this effort.

A double-blind, placebo-controlled trial of pegylated recombinant human megakaryocyte growth and development factor as an adjunct to induction and consolidation therapy for patients with acute myeloid leukemia

Newly diagnosed patients with acute myeloid leukemia (AML) were randomized to receive either 2.5 or 5 μg/kg/day of pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF) or a placebo administered subcutaneously after completion of chemotherapy. The study evaluated the toxicity of PEG-rHuMGDF and any effect on the duration of thrombocytopenia. Each of 35 patients under 60 years of age received the following therapy: 45 mg/m2 daunorubicin on days 1-3, 100 mg/m2cytarabine (ARA-C) for 7 days, and 2 gm/m2 high-dose ARA-C (HIDAC) for 6 doses on days 8-10. The 22 patients 60 years or older received standard daunorubicin and ARA-C without HIDAC. PEG-rHuMGDF was well tolerated, and no specific toxicities could be attributed to its use. There was no difference in the time to achieve a platelet count of at least 20 × 109/L among the 3 groups (median 28-30 days for patients less than 60 years old and 21-23 days for patients 60 years or older). Patients receiving PEG-rHuMGDF achieved higher platelet counts after remission. However there was no significant difference in the number of days on which platelet transfusions were administered among the 3 groups. The complete remission rate was 71% for patients less than 60 years and 64% for those 60 years or older, with no significant difference among the 3 groups. Postremission consolidation chemotherapy with either placebo or PEG-rHuMGDF was given to 28 patients beginning the day after completion of chemotherapy. There was no apparent difference in the time that was necessary to reach a platelet count of at least 20 or 50 × 109/L or more platelets or in the number of platelet transfusions received. In summary, PEG-rHuMGDF was well tolerated by patients receiving induction and consolidation therapy for AML; however, there was no effect on the duration of severe thrombocytopenia or the platelet transfusion requirement.

A double-blind, placebo-controlled trial of pegylated recombinant human megakaryocyte growth and development factor as an adjunct to induction and consolidation therapy for patients with acute myeloid leukemia

Newly diagnosed patients with acute myeloid leukemia (AML) were randomized to receive either 2.5 or 5 μg/kg/day of pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF) or a placebo administered subcutaneously after completion of chemotherapy. The study evaluated the toxicity of PEG-rHuMGDF and any effect on the duration of thrombocytopenia. Each of 35 patients under 60 years of age received the following therapy: 45 mg/m2 daunorubicin on days 1-3, 100 mg/m2cytarabine (ARA-C) for 7 days, and 2 gm/m2 high-dose ARA-C (HIDAC) for 6 doses on days 8-10. The 22 patients 60 years or older received standard daunorubicin and ARA-C without HIDAC. PEG-rHuMGDF was well tolerated, and no specific toxicities could be attributed to its use. There was no difference in the time to achieve a platelet count of at least 20 × 109/L among the 3 groups (median 28-30 days for patients less than 60 years old and 21-23 days for patients 60 years or older). Patients receiving PEG-rHuMGDF achieved higher platelet counts after remission. However there was no significant difference in the number of days on which platelet transfusions were administered among the 3 groups. The complete remission rate was 71% for patients less than 60 years and 64% for those 60 years or older, with no significant difference among the 3 groups. Postremission consolidation chemotherapy with either placebo or PEG-rHuMGDF was given to 28 patients beginning the day after completion of chemotherapy. There was no apparent difference in the time that was necessary to reach a platelet count of at least 20 or 50 × 109/L or more platelets or in the number of platelet transfusions received. In summary, PEG-rHuMGDF was well tolerated by patients receiving induction and consolidation therapy for AML; however, there was no effect on the duration of severe thrombocytopenia or the platelet transfusion requirement.

Current issues with platelet transfusion in patients with cancer

For the past 30 years, platelet transfusions have been used in the treatment of thrombocytopenia caused by decreased production, inadequate function, or increased destruction of platelets. The number of platelet transfusions has increased more than transfusions of other blood components, shifting from whole blood use for the platelet source to plateletpheresis. Hematology/oncology patients are among the largest group receiving platelet transfusions, primarily because the more aggressive chemotherapies produce more acute and prolonged thrombocytopenia. While platelet transfusions often rescue patients with very low platelet levels, they are associated with the risk of viral and bacterial infections, as well as alloimmunization. Platelet donor recruitment can also be difficult, and platelet transfusion can be very expensive depending on the source of platelets. As a result, prophylactic transfusions are less likely to be administered at higher platelet counts, reducing platelet use and cost of platelet transfusions. However, cancer patients receiving intensive chemotherapy or myeloablative regimens require multiple platelet transfusions. For these patients, alternate strategies are needed so that platelet transfusions can be significantly reduced or eliminated.

Alternatives to standard blood transfusion: availability and promise

Largely due to concerns over safety, a wide variety of alternatives to the conventional blood bank products of red cells, platelet concentrates, plasma and fractionated plasma products are under development. This review attempts to survey the alternative therapies that are being developed, whether they provide viable solutions and what impact they might have on transfusion practice.

The proportion of reticulated platelets is higher in bone marrow than in peripheral blood in haematological patients

Since the detection that platelets originate from megakaryocytes (MK), the site of megakaryocyte fragmentation has been disputed. Some authors have even postulated that platelets are solely produced in the lungs. Thus, we have directly measured platelet generation in the bone marrow (BM) by comparing the relative number of young RNA-containing, so-called reticulated platelets (%RP) in the BM and in the peripheral blood (PB). Two separate prospective, cross sectional trials have been conducted in patients routinely undergoing BM biopsies for diagnostic purposes. In the first part of the study 30 patients with stem cell or bone marrow transplantation were examined. The second part of the study was performed in 62 haematological patients visiting the outpatient's clinic. Median %RP were higher in BM than in PB (p <0.001). In the second part of the study the difference averaged 133% (interquartile range: 30-383%). There was a moderate correlation between %RP in BM and in PB (r = 0.67; p <0.001). The absolute number of RP in PB correlated weakly with the number of megakaryocytes (0.42; p = 0.001), which was due to a correlation between the platelet counts and the megakaryocyte counts (r = 0.55; p <0.001 in biopsies). Two patients with autoimmune antibodies against GPIIb/IIIa exhibited 10% and 16% RP in PB, and had 29% and 59% RP in BM, respectively. It is concluded that the relative number of RP is significantly higher in BM than in blood. This supports the notion that platelets are at least in part released from MK in the bone marrow, particularly in patients suffering from immune thrombocytopenia.