Anti-D alloimmunization after D-mismatched allogeneic hematopoietic stem cell transplantation in patients with hematologic diseases

BACKGROUND: The de novo development of anti-D after D-mismatched allogeneic hematopoietic stem cell transplantation (AHSCT) is a possibility that must be considered. The transfusion of D- blood components after AHSCT has been recommended but anti-D alloimmunization in this setting has been studied little. Thus, the aim of this study was to analyze anti-D formation after D-mismatched AHSCT. STUDY DESIGN AND METHODS: Thirty patients with a hematologic disease who underwent D-mismatched AHSCT were retrospectively studied. Support therapy included red blood cells (RBCs) and platelet (PLT) concentrates (PCs) from whole-blood donations and PLTs from apheresis. After AHSCT, patients received D+ PCs without administering Rh immunoglobulin (RhIG). An antibody screening to detect anti-D was performed by low-ionic-strength saline-indirect antiglobulin test with the tube test. RESULTS: Fifteen D+ patients received stem cells (SCs) of D- donors and 15 D- patients received SCs of D+ donors. After AHSCT, patients received a median of 11.5 (range, 0-32) D- RBC units. D+ patients received 682 (83%) of 825 PLT units from D+ donors, and D- patients received 573 (85%) of 678 PLT units from D+ donors. None of the 30 patients developed anti-D after a median follow-up of 32 weeks (range, 4-310 weeks). CONCLUSION: Anti-D alloimmunization after performing a D-mismatched AHSCT is infrequent in patients with hematologic diseases although patients receive D-mismatched PLT transfusions without RhIG administration.     

Absence of D alloimmunization in D- pediatric oncology patients receiving D-incompatible single-donor platelets

BACKGROUND: Guidelines are lacking for prophylaxis against D alloimmunization after D-incompatible platelet transfusion. A rational basis for the application of prophylaxis would be beneficial for institutions in which inventory constraints demand the administration of large numbers of D-incompatible platelets. STUDY DESIGN AND METHODS: A retrospective analysis was performed of all D-incompatible platelet transfusions administered at a pediatric research hospital over a 1.5-year period. Patients exclusively received single-donor WBC-reduced platelets and did not receive RhIg immunoprophylaxis. Numbers, source, ABO type, duration of serologic follow-up, and level of RBC contamination of D-incompatible transfusions were analyzed. All positive D serologies in the institution over a 3.5-year period were examined to determine cause and potential association with platelet transfusion. RESULTS: Thirty-five patients not receiving bone marrow transplant and seven bone marrow transplant patients received 490 and 255 D-incompatible transfusions, respectively, over 1.5 years. Patients had various diagnoses, predominantly malignancies. Seventy-nine percent of D-incompatible transfusions were ABO compatible. An estimated 2300 incompatible transfusions were performed over 3.5 years. No case of D alloimmunization was detected. CONCLUSIONS: D immunoprophylaxis is generally unnecessary in pediatric oncology patients receiving D-incompatible, WBC-reduced, single-donor platelets not visibly contaminated by RBCs. Further studies to validate these observations in the pediatric population and to extend them to other population groups are warranted.     

Transforming growth factor beta is increased in plasma of patients with hematologic malignancies after transfusion of platelet concentrates

BACKGROUND: Transforming growth factor beta 1 (TGF-beta 1) acts as a potent inhibitor of bone marrow proliferation. High concentrations were found in human platelets, which release this cytokine during storage. STUDY DESIGN AND METHODS: TGF-beta 1 levels during a storage period of 5 days were compared in the plasma of platelet concentrates prepared by apheresis or by the buffy coat method. In addition, TGF-beta 1 plasma levels were monitored in patients with hematologic malignancies before and after transfusion. RESULTS: TGF-beta 1 levels in the supernatant of platelet concentrates were found to be 55 times higher than those in the plasma of healthy volunteer donors. During storage, an additional increase was observed. Accordingly, the transfusion of platelet concentrates resulted in a significant increase of plasma TGF-beta 1 levels in patients with hematologic malignancies (before transfusion: 2.2 +/− 0.5 ng/mL; after transfusion: 2.9 +/− 0.6 ng/mL), and these higher levels persisted for at least 4 hours. CONCLUSION: Because TGF- beta 1 reduces the clonogenic capacity of hematopoetic progenitor cells, a myelosuppressive effect of platelet transfusions is suggested.     

Platelet transfusions from D+ donors to D- patients: a 10-year follow-up study of 1014 patients

BACKGROUND: Current guidelines recommend that platelets (PLTs) from D? donors should be given to D? patients. However, such evidence comes from studies with a limited number of included patients that reported an incidence of anti‐D alloimmunization to be up to 19%. We thus decided to extend these findings by examining anti‐D alloimmunization at our institution, where PLT transfusions from D+ donors are transfused to D? patients because of logistic constraints. STUDY DESIGN AND METHODS: From April 1999 to December 2009, we retrospectively reviewed the clinical and transfusion records of all D? patients who received PLT transfusions from D+ donors at our hospital. PLT concentrates (PCs) were obtained from apheresis and from whole blood donations. RhIG was not administered after the transfusion of PCs from D+ donors. The antibody screen test to detect anti‐D was performed by low‐ionic‐strength solution indirect antiglobulin test using the gel test. RESULTS: Our series comprises 1014 D? patients who received 5128 PLT transfusions from D+ donors (89% were pooled PCs). We had 315 (31.1%) patients who had a blood sample to analyze the presence of anti‐D 4 or more weeks after the first D+ PLT transfusion with a median follow‐up of 29 weeks (range, 4‐718 weeks). Anti‐D developed in 12 (3.8%) of these 315 patients. CONCLUSIONS: The frequency of anti‐D alloimmunization of D? patients after receiving pooled PCs from D+ donors is low. The transfusion of D‐incompatible pooled PCs without immunoprophylaxis to D? men or D? women without childbearing potential seems a reasonable and safe alternative.     

Low cytokine contamination in buffy coat-derived platelet concentrates without filtration

BACKGROUND: Cytokines (interleukin [IL]-1 beta, IL-6, and tumor necrosis factor [TNF]) generated by white cells during the storage of platelet concentrates can cause febrile nonhemolytic transfusion reactions. The high rate of febrile reactions reported in other studies was not observed in the patients in the authors' center. This discrepancy prompted the determination of cytokine levels in buffy coat- derived platelet concentrates. STUDY DESIGN AND METHODS: Platelet concentrates were produced from buffy coats by a standard large-scale production process. Buffy coats were separated from the red cell and plasma components, and then platelets were recovered from the buffy coats by a soft-spin procedure. Levels of cytokines (IL-1 beta, IL-6, IL-8, and TNF) were determined with commercial enzyme-linked immunosorbent assays. RESULTS: In platelet concentrates produced by the buffy coat method, IL-1 beta, IL-6, IL-8, and TNF were observed at or below the detection limit of current enzyme-linked immunosorbent assays after 5 days' storage at 22 +/− 2 degrees C. Therefore, prestorage filtration had no measurable effect on cytokine levels. In controls, IL- 1 beta, IL-6, IL-8, and TNF were quantitatively detected after exogenous addition of recombinant cytokines or exposure to lipopolysaccharide. CONCLUSION: Platelet concentrates prepared from buffy coats may be virtually free of cytokines (IL-1 beta, IL-6, IL-8, and TNF) during 5 days of storage. Filtration is not required to reduce the recipient's cytokine exposure via such platelet concentrates.     

Detection of anti-D in D- recipients transfused with D+ red blood cells

BACKGROUND: The D antigen is highly immunogenic, requiring only a small quantity of transfused red blood cells (RBCs) to cause alloimmunization in D- immunocompetent recipients. The relatively low sensitization rate in oncology patients transfused with D+ platelets is well documented. A study of the alloimmunization rate of primarily nononcology D- recipients transfused with D+ RBCs was undertaken. STUDY DESIGN AND METHODS: Transfusion service records were examined to identify D- recipients who were not alloimmunized to the D antigen and who had a follow-up antibody screen performed at least 10 days after the initial D+ RBC transfusion(s). The age and sex of the recipients, date and number of D+ RBC transfusion(s) and their leukoreduction status, all subsequent serologic investigations, and the hospital ward where the units were issued were recorded. RESULTS: There were 98 study-eligible recipients identified who received a total of 445 D+ RBC units. The mean follow-up length was 182 days. Most recipients (87%) had antibody screens performed more than 21 days after the initial D+ RBC transfusion. In total, 24 recipients made 44 new alloantibodies: 22 anti-D (22%), 11 anti-E, 5 anti-C, 2 anti-K, and 1 each of anti-Kp(a), anti-Jk(a), anti-Bg, and anti-Fy(b). The rate of anti-D alloimmunization among recipients of entirely leukoreduced D+ units was 13 percent (1/8). Reexposure to D+ RBCs after the initial bleeding episode did not increase the rate of alloimmunization. CONCLUSIONS: The 22 percent rate of anti-D alloimmunization in patients requiring urgent RBC transfusion was intermediate between the rates previously reported for D- oncology patients transfused with D+ RBCs and that in immunocompetent volunteer recipients.     

Alloimmunization to D antigen and HLA in D-negative immunosuppressed oncology patients

D-negative patients may be divided into responders and nonresponders when immunized with D-positive red cells (RBC). Forty-nine D-negative oncology patients who received D-positive RBCs via platelet and white cell transfusions were studied to determine if nonresponders to D were likely to form lymphocytotoxic antibody (LCA). Nine patients developed anti-D in 16 to 390 days (mean = 112) after 2.6 to 481 ml (mean = 106) of D-positive RBCs. Forty patients had no evidence of anti-D after 0.8 to 535 ml (mean = 98) of D-positive RBCs and were followed for 14 to 1275 days (mean = 192). The anti-D group had no prior D-positive RBC transfusions, and two of five women making anti-D had previous pregnancies but no record of anti-D. LCA was found in four of nine (44%) patients with anti-D and in 12 of 40 (30%) patients without anti-D (p less than 0.50). Since both D and antigens HLA are considered highly immunogenic, it is of interest that the ability to form anti-D or LCA does not correlate. In fact, more patients (16/49; 32%) made LCA than anti-D (9/49; 18%). Of the 21 alloimmunized patients, 4 made both antibodies, while 17 had selective alloimmunization. It would thus appear that alloimmunization to D and HLA are not strongly linked and may indeed be unrelated.     

A prospective, randomized study of the use of platelet concentrates irradiated with ultraviolet-B light in patients with hematologic malignancy

BACKGROUND: Irradiation of platelet concentrates (PCs) with ultraviolet- B (UVB) light inactivates the contaminating white cells and might be an alternative to filtration for the prevention of alloimmunization to HLA antigens and subsequent refractoriness to further platelet transfusions in multiply transfused patients with bone marrow failure. STUDY DESIGN AND METHODS: Patients with hematologic malignancy, mainly acute myeloid leukemia, were prospectively assigned in a random manner to receive either UVB-irradiated or control, nonirradiated PCs. All patients were given red cells that were white cell reduced by filtration. Transfusion efficacy and alloimmunization were assessed by means of corrected count increments, requirement for red cells and PCs, and measurement of lymphocyte-reactive antibodies. RESULTS: UVB-irradiated PCs had a clinical efficacy similar to controls as judged by corrected count increments at 1 to 6 and 12 to 24 hours and by the median requirement for red cell and platelet transfusions. Alloimmunization determined by measurements of lymphocyte-reactive antibodies using both conventional and antiglobulin-augmented lymphocytotoxicity techniques was not abolished in recipients of UVB-irradiated PCs (4/30, 13%) but was less than that in controls (5/20, 25%; p = NS). The mean number of platelet transfusion episodes prior to the occurrence of alloimmunization was greater in the control group (27 vs. 10; p = 0.017). CONCLUSION: In this trial, UVB irradiation did not diminish the clinical efficacy of platelet transfusions. There was a small but nonsignificant reduction alloimmunization, but no difference in refractoriness of the two groups was observed. Larger prospective randomized studies are required to confirm these findings and to compare UVB irradiation with white cell reduction.     

Platelet storage in Fresenius/NPBI polyolefin and BTHC-PVC bags: a direct comparison

SUMMARY: New platelet storage systems, such as changes in the plastic of the storage bags, require validation. In this study, pooled buffy coat platelets stored in Fresenius/NPBI polyolefin bags were compared with those stored in Fresenius/NPBI butyryl-trihexyl citrate (BTHC) plasticized polyvinyl chloride (PVC). The CompoSelect thrombocyte polishing filter system (1000 mL polyolefin bag) and the CompoStop F730 system (1300 mL BTHC-PVC bag) were used to prepare paired, plasma-suspended, buffy coat platelet concentrates. Samples were taken up to day 7 for in vitro analysis. In a separate experiment, 12 units were prepared using the CompoStop F730 system and samples taken after leucofiltration for FXIIa assay. By day 7, platelet concentrates stored in BTHC-PVC demonstrated significantly higher pH levels (7.32 +/- 0.05 vs. 7.26 +/- 0.05) and a greater degree of cell lysis as shown by increased lactate dehydrogenase levels (497 +/- 107 vs. 392 +/- 81 U L(-1)). The supernatants contained higher concentrations of soluble P-selectin and the chemokine 'regulated on activation, normal T-cell expressed and presumably secreted', which are released from the alpha-granules during activation. The ATP concentrations were significantly lower in BTHC-PVC. Platelet counts, mean platelet volume and hypotonic shock response were similar for both bags. FXIIa antigen concentrations were 0.6 +/- 0.2 ng mL(-1) indicating that activation of the contact factor pathway had not occurred. Although the CompoStop F730 leucoreduction filter did not activate the contact system, platelets stored in 100% plasma in BTHC-PVC bags demonstrated different in vitro characteristics from those stored in polyolefin. Further work is required to demonstrate whether these differences will affect in vivo recovery and survival.     

Possible implication of sterile connecting device in contamination of pooled platelet concentrates

Considering the possibility that a pooled random donor platelet concentrate could become contaminated by welding with a sterile connecting device, we undertook a study to determine the influence of pooling on the contamination rate. As a control group, apheresis platelets were examined. Bacteriological testing was done with a sensitive CO2 detecting culture system, the BacT/ Alert. Out of 1105 pooled platelet concentrates prepared by the buffy coat method, 15 (1.4%) were confirmed as contaminated, all with Staphylococcus epidermidis and two with a second bacterial species, i.e. Staphylococcus capitis and Propionibacterium acnes, respectively. Median detection time by the BacT/Alert was 23 h. Twelve pools of five units were contaminated, which is significantly more than the three contaminated pools of four units. On the other hand, the reuse of the welding wafers proved not be a risk factor for contamination. One welded tubing segment of a contaminated platelet concentrate failed the air leakage test, an incident which was 73 times more frequent than with the sterile platelet concentrates. We found five pooled platelet concentrates containing Staphylococci from which no bacteria could be grown from the individual buffy coats that had been pooled. We suggest the contamination here to have occurred after separation of the buffy coat from the whole blood, possibly during the welding process. Finally, none out of 378 apheresis platelet concentrates was contaminated. All our observations highlight the potential risk for contamination when making pooled platelet concentrates with a sterile connecting device. For this type of transfusion product, we advocate bacteriological screening of all units before release. The incubation time for the sterility test should, however, be limited to 36 h, if logistical problems with the availability of platelets are to be avoided.     

Screening for alloantibodies in the serum of patients receiving platelet transfusions: a comparison of the ELISA,lymphocytotoxicity, and the indirect immunofluorescence method

BACKGROUND: For screening of alloimmunization in patients repeatedly receiving platelet transfusions, different tests are used, none of which is the standard. Here we describe a comparison of four tests most commonly used for detection of alloimmunization in a group of nonselected patients receiving platelet transfusions. STUDY DESIGN AND METHODS: In 99 patients with hematologic malignancies who received platelet transfusions, 192 random serum samples were tested in the ELISA, the lymphocytotoxic test (LCT), the lymphocyte immunofluorescence test (LIFT), and the platelet immunofluorescence test (PIFT). Results of all tests were compared. RESULTS: The results of all tests were significantly correlated with each other (p < 0.005). ELISA and LIFT were more often positive than LCT and PIFT. ELISA and LIFT showed the best correlation (chi-square test = 63.7, p < 0.001). CONCLUSION: ELISA, the least time-consuming test, detects alloimmunization as often as LIFT and more often than LCT and PIFT.     

Leukocyte-depleted platelets prepared from pooled buffy coat post-transfusion increment and "in vitro bleeding time" using the Thrombostat 4000/2

A technique for preparation of platelet concentrate (PC) from pooled buffy coat (BC) is described in this study. The yield of platelets from 4 BCs was 310+/-48x10 9 per unit with a leukocyte content of 21+/-20x10 6 per unit. When a leukocyte removing filter was interconnected, Sepacell 5N and Pall PL-50 filters, no leukocytes could be found in 56 of 59 and in 36 of 37 PCs, with a maximum content of 2.3 and 0.54x10 6 leukocytes per PC, respectively. The platelet yield was 276+/-37 and 279+/-54x10 9 per unit, respectively. The in vitro bleeding time (IVBT), using the Thrombostat 4000/2, corresponded with the corrected count increment in most of 11 thrombocytopenic patients receiving platelet transfusions. However, in two transfusions no correction of IVBT was obtained. This technique offers a new possibility to investigate the functional capacity of transfused platelets.     

Circulation and distribution of 111-In-oxine-labeled autologous baboon platelet aggregates and buffy coat.

BACKGROUND: Although it is known that RBC concentrates may contain buffy coat and platelet concentrates may contain platelet aggregates, the circulation and distribution of these materials in the blood products have never been reported. STUDY DESIGN AND METHODS: Baboon platelets were labeled with 111-In-oxine, aggregated with ADP and autotransfused without a filter. Baboon buffy coat was stored at 4 degrees C, labeled with 111-In-oxine and autotransfused without a filter. The circulation of the radiolabeled platelets and buffy coat was measured and the distribution of the buffy coat and platelet aggregates was measured by external scanning of the baboon using a gamma camera. The effects of the infusion of aggregated platelets, buffy coat, and gelatin on the plasma fibronectin level also were evaluated. RESULTS: The 111-In-oxine labeled platelet aggregates were initially sequestered in the lungs and released into the peripheral blood during the next 3h, during which time the cell associated radioactivity increased by about 25%. Following the autotransfusion of 111-In-oxine labeled buffy coat, the 111-In-oxine radioactivity over the lungs increased, but decreased during the 60-min post-transfusion period as the radioactivity over the liver increased. Cell-associated radioactivity increased by about 10% over the 3-h post-transfusion period. Fibronectin levels decreased by 3% following the autotransfusion of platelet aggregates, by 10% after the autotransfusion of buffy coat and by 50% after the infusion of gelatin. CONCLUSIONS: 111-In-oxine radioactivity in the platelet aggregates and buffy coat was initially sequestered in the lungs, and 10-25% of the 111-In-oxine cell-associated radioactivity was released into the circulation during the 24-h post-transfusion period.     

Evaluation of platelet concentrates prepared from buffy coats and stored in a glucose-free crystalloid medium

Comparison was made between platelet concentrates prepared from pools of buffy coats removed from standard blood donations and stored in a glucose-free, commercially available crystalloid solution (BC-PCs) and standard platelet concentrates prepared from platelet-rich plasma (PRP-PCs). Platelet yield in BC-PCs and PRP-PCs was 59 and 75 percent of donated platelets, respectively. The number of total white cells in 1 BC-PC unit, prepared from a pool of 7 buffy coats, was 21 x 10(6), i.e., 50 times lower than that of 7 units of PRP-PCs. The in vitro values of adequate platelet quality were maintained for 10 days in BC-PCs stored in 1000-mL polyolefin bags. Prolonged bleeding times were reduced or corrected in three of three thrombocytopenic leukemic patients evaluated before and after transfusion of stored BC-PCs. Pretransfusion and 1- and 24-hour posttransfusion median platelet counts in 57 leukemic recipients during 4 months of routine transfusion of BC-PCs (n = 93) were 14, 35, and 27 x 10(9) per L, while those of PRP-PCs (n = 246) were 13, 37, and 31 x 10(9) per L, respectively. No reactions to BC-PCs were reported, but a 1.3 percent rate of reaction to PRP-PC transfusions was reported. This study indicates that BC-PCs are a good alternative to PRP-PCs for platelet support of thrombocytopenic patients.     

Reactions and platelet increments after transfusion of platelet concentrates in plasma or an additive solution: a prospective, randomized study

BACKGROUND: Reactions after platelet transfusions are rather common and frequently are caused by plasma constituents. In recent developments, the preparation and storage of platelet concentrates (PCs) in a platelet additive solution (PAS-2) have been shown to result in acceptable storage conditions. A major drawback of the use of these PCs is the progressive increase of P-selectin-positive platelets during storage. The clinical benefit of transfusions of PCs in PAS-2 was studied. STUDY DESIGN AND METHODS: PCs prepared from buffy coats were suspended in either plasma or PAS-2 and stored for up to 5 days. Clinical responses were evaluated in a prospective study in 21 patients treated with intensive chemotherapy for hematologic malignancies. Eligible patients were randomly assigned to receive prophylactic transfusions of PCs prepared in either plasma or PAS-2. Reactions and CCIs were recorded after each transfusion. RESULTS: The incidence of reactions in 12 patients given PCs in plasma (n = 192) was 12 percent. Transfusions to 9 patients of PCs in PAS-2 (n = 132) showed a reduction in the incidence of reactions to 5.3 percent (p<0.05). The average 1-hour and 20-hour CCIs after transfusion of PCs in plasma were 20.7 +/- 8. 5 and 11.5 +/- 8.0, respectively. CCIs after transfusion of PCs in PAS-2 were significantly lower: the average 1-hour CCI was 17.1 +/- 6.6 (p<0.001) and the average 20-hour CCI was 9.5 +/- 7.0 (p<0.05). Storage conditions of PCs were optimal: in each group, average 1-hour CCIs of both fresh and stored PCs were similar. The 20-hour CCIs after the transfusion of fresh and stored PCs in PAS-2 also were similar. CONCLUSION: Transfusion of PCs in PAS-2 significantly reduces the incidence of reactions. The 1-hour and 20-hour CCIs after transfusion of PCs in PAS-2 were significantly lower than the CCIs after transfusion of PCs in plasma. Because storage conditions of both PCs were found to be optimal, the decrease in CCIs after transfusion of PCs prepared in PAS-2 may be caused by rapid elimination of a subpopulation of P-selectin-positive platelets from the circulation.     

Buffy coat platelets stored in apyrase, aprotinin, and ascorbic acid in a suspended bag: combined strategies for reducing platelet activation during storage

BACKGROUND: Platelet activation is an important factor impeding the clinical effectiveness of platelet transfusions. In this study, platelet concentrates (PCs) were prepared by a novel suspended-bag buffy coat technique that was followed by the addition of a mixture of platelet activation inhibitors to the storage bag. STUDY DESIGN AND METHODS: In vitro platelet function was evaluated in PCs prepared by the suspended-bag buffy coat technique and stored at 22 degrees C for 5 days in the presence of (n = 12) or absence (n = 12) of apyrase, ascorbic acid, and aprotinin (AAA). RESULTS: Platelets from AAA- incubated PCs demonstrated mean ATP levels 17 percent (p < 0.004), 13 percent (p < 0.02), and 22 percent (p < 0.003) higher than those measured in parallel control PCs on Days 1, 3, and 5, respectively. Similarly, on Days 3 and 5 of storage, respectively, 45-percent (p < 0.001) and 50-percent (p < 0.001) greater ADP-induced maximum aggregation was observed in AAA-incubated PCs than was seen in control preparations. AAA-incubated PCs demonstrated alpha-granule membrane protein-140 expression 92 percent (p < 0.01), 133 percent (p < 0.003), and 104 percent (p < 0.001) below that in control PCs on Days 1, 3, and 5, respectively. At similar intervals, a significant increase in recovery from hypotonic shock also was observed in AAA-incubated PCs. Further, Day 5 AAA-PCs demonstrated significantly higher morphology scores and O2 consumption than did control preparations. CONCLUSION: Buffy coat platelets prepared in suspended bags and stored in the presence of AAA demonstrate significantly reduced activation and enhanced functional and metabolic activity.     

High-dose CD34+ cells are not clinically relevant in reducing cytopenia and blood component consumption following myeloablative therapy and peripheral blood progenitor cell transplantation as compared with standard dose

BACKGROUND: No agreement exists about the number of autologous peripheral blood progenitor cells (PBPCs) to transfuse for optimal hematologic recovery after high-dose chemotherapy. STUDY DESIGN AND METHODS: To determine CD34+ cell dosage following high-dose chemotherapy (in terms of hematologic recovery and blood component consumption), the effects of two schedules of CD34+ cell transfusions in a cohort of patients with myeloma or non-Hodgkin's lymphoma were examined. Forty patients (Group 1) received between 2.5 and 5 x 106 CD34+ cells per kg, with a median of 3.4 x 106 per kg following high-dose chemotherapy, and 40 patients (Group 2), selected to match Group 1 for age, diagnosis, prior therapies, and procedure for PBPC mobilization, received a dose of CD34+ cells >5 x 106 per kg, with a median of 8.4 x 106 per kg (5-33). RESULTS: The median number of days to achieve a neutrophil count of >0.5 x 109 per L and unsupported platelets of >20 x 109 per L was identical for the two groups, but the time required to reach 1.5 x 109 neutrophils per L and 50 x 109 platelets per L was greatly delayed in Group 1. No significant difference was observed for the median number of RBC and platelet transfusions, or for the proportion of patients in each group that did not require either platelet or RBC transfusions. CONCLUSION: Our data confirm a dose-response relationship between CD34+ cell dose transfused and time to hematologic recovery after high-dose chemotherapy. However, the minimal Hb and platelet counts for transfusion independence in the two groups are similar when the CD34+ cell dose is greater than 5 x 106 CD34+ cells per kg. Therefore, our data suggest that it is not necessary to go on with apheresis procedures after 5 x 106 CD34+ cells per kg are harvested to sustain one high-dose chemotherapy.     

The flow rate significantly influences the leukocyte depletion rate during prestorage in-line filtration of platelet concentrates

BACKGROUND: White cell reduction of blood products minimizes the risks of alloimmunization against HLA-antigens, the transmission of viral diseases and the incidence of platelet transfusion reactions. One modern strategy is leukocyte depletion with an integrated filter system immediately after preparation and prior to storage. STUDY DESIGN AND METHODS: We evaluated the efficiency of a novel in-line filter system Sepacell PLX-5 BPS for leukocyte reduction of platelet concentrates (PC) from pooled buffy-coats. A total of 44 PCs were investigated with regard to different filtration flow rates (25-110 ml/min) and leukocyte depletion and thrombocyte recovery rates were analysed. Furthermore, we studied the influence of filtration on PCs over a storage period of 6 days (n = 12) by investigation of pH, lactate and glucose. Platelet function was determined by means of hypotonic shock response, external shape change and expression of CD62p. RESULTS: The mean leukocyte depletion rate was > log 5. After filtration the mean leukocyte count was 0.12 +/- 0.21 x 10(6). In 60% of the PCs the leukocyte count lay below the detection level of the Nageotte chamber, which is < 0.3 x 10(5). The flow rate correlates significantly with the leukocyte count in the PCs (r = 0.325; p = 0.033) and therefore with the leukocyte depletion rate (r = -0.422; p = 0.01). Flow rates under 40 ml lead to a significantly lower leukocyte contamination. Only in one PC, at a flow rate of 84 ml/min, was the leukocyte threshold of 1 x 10(6) exceeded. We did not find a significant correlation between filtration flow rate and thrombocyte recovery (r = 0.315; p = 0.069). The mean platelet count in the PC was 2.88 +/- 0.47 x 10(11). Compared with the thrombocyte count in the pooled buffy coat, the recovery was 68.6%. We observed a decrease of pH, glucose, external shape change and hypotonic shock response over the storage period while lactate and the expression of CD62p increased. CONCLUSION: The filter system Sepacell PLX-5 BPS proved to be suitable for in-line filtration of platelet concentrates prior to storage. Filtration flow rates of up to 40 ml/min allowed efficient leukocyte depletion without significant loss in the quality of the platelet concentrates and the platelet function in vitro.     

Transfusion experience with platelet concentrates stored for 24 to 72 hours at 22 degrees C. Importance of storage time

We studied the transfusion response from random donor platelet concentrates in 15 stable multitransfused, thrombocytopenic patients by comparing the platelet counts measured before and 20 hours after transfusion. The observed platelet increments were corrected (corrected increment, C.I.) for the number of units of platelet concentrate transfused and the patient's body surface area in square meters (platelets/microliter per unit/m2). Using platelet concentrates stored for less than 24 hours, the patients achieved a median C.I. of 9500 (range: 5000–18,000). When platelet concentrates stored for 24 to 48 hours or 48 to 72 hours were given, the median C.I. markedly decreased to 1000 (range: 0–4800) and 0 (range: 0–5100), respectively (p less than 0.001). These differences could not be explained by further recipient alloimmunization. Transfusion with platelet concentrates less than 24 hours old on a second occasion, bracketing the transfusions of older platelet concentrates, resulted in a median C.I. of 7200 (range: 5400–14,500). Similar results were obtained in three patients when HLA- identical sibling platelet concentrates were employed. In vitro tests, including pH, morphology, and aggregation, demonstrated no statistically significant differences among the platelet concentrates stored for less than 24 hours, 24 to 48 hours, and 48 to 72 hours. These studies suggest that, although platelet concentrates can be stored for 72 hours without loss of in vitro function, the in vivo recovery is significantly diminished after 24 hours of storage, and preferably patients should not be transfused prophylactically with platelet concentrates greater than 24 hours old.     

Guidelines for platelet transfusions

Recommendations for the optimal transfusion support of patients likely to receive repeated platelet transfusions. 1. Determine policy for prophylactic platelet support, and select the platelet count below which platelet transfusions will be used. 2. Consider using leucocyte depletion of red cell and platelet concentrates to prevent HLA alloimmunization from the outset. 3. Type patients for HLA-A and B antigens at an early stage. 4. Use random donor platelet concentrates for initial platelet support (either single or multiple donor, depending on availability). 5. If refractoriness occurs, determine whether clinical factors, which may be associated with non-immune consumption of platelets, are present and test the patient's serum for HLA antibodies. 6. Use HLA-matched platelet transfusions if HLA alloimmunization is the most likely cause of refractoriness. 7. If there is no improvement with HLA-matched transfusions, platelet crossmatching may identify the cause of the problem and help with the selection of compatible donors. 8. Discontinue prophylactic platelet support if a compatible donor cannot be found. Use platelet transfusions from random donors to control bleeding and increase the dose, if necessary.