An in vitro system for testing leucocyte and leukaemic cell line adhesion to synthetic fibres

Leucocyte adhesion is an important phenomenon in antimicrobial defence, inflammation and immunological mechanisms and has been shown to be dependent upon specialized adhesion molecules. To prevent side-effects related to blood transfusion (e.g. anti-human leucocyte antigen immunization and transmission of infectious agents) leucocyte reduction of blood products is now systematically performed in various countries. The most common system used for leucoreduction is blood filtration. For further understanding of the mechanisms responsible for the interaction between leucocytes and the fibres present in filters we used a flow chamber to study the adhesion of leucocytes and leukaemic cell lines to different types of fibre. Adhesion was quantified using video-microscopy and computer image analysis. Our results demonstrate that adhesion to filter fibres was dependent on the expression of beta2-integrins CD11--CD18 and was inhibited by anti-CD18. The amount of fibres present, their spatial arrangement and the physicochemical characteristics of the fibres were important factors in leucocyte adhesion. Leucocyte adhesion was the highest to polyethylene terephthalate (PET) and polyimide fibres. Lymphocytes or lymphocytic cell lines were poorly adherent to PET fibres. The retaining capacity of leucocyte filters can be improved by taking into account the different parameters for the design of new filters

In vivo and in vitro characteristics of double units of RBCs collected by apheresis with a single in-line WBC-reduction filter

BACKGROUND

A novel apheresis procedure for a blood separator (MCS+, Haemonetics) enables the collection of 2 WBC-reduced RBC units in a single donation by using one disposable set with one in-line WBC-reduction filter (RC2H, Pall Corp.). The objective of this study was to evaluate the filtration performance in connection with different prefiltration RBC storage conditions and with the in vitro and in vivo storage quality of the filtered units.

STUDY DESIGN AND METHODS

Sixty-six 2-unit RBC collection and gravity-filtration procedures were completed at three sites, resulting in 132 RBC units. Filtration of the double RBC units was performed at room temperature (RT) within 8 hours of collection (n = 36) and under refrigeration (1-6 degrees C) for up to 24 hours (n = 10) and 72 hours (n = 20) before filtration. RBC quality was compared to that of nonfiltered apheresis RBC units (n = 10).

RESULTS

Median filtration time was 6.5 and 14 minutes for units stored at RT and under refrigeration, respectively. All 132 RBC units had residual WBC counts <0.4 x 10(6). The refrigerated units showed a greater mean log reduction in WBCs: 5.06 +/- 0.16 (24 hour) and 4.74 +/- 0.48 (72 hour), respectively, than did RT units: 4.47 +/- 0.28 (p<0.05). RBC loss was less than 12 percent in all cases (mean, 7.8 +/- 1.8%). Minimal differences in volume were observed between the paired RBC units. In vitro RBC storage characteristics of the filtered units were as expected and similar to those of the nonfiltered units. For RBC units held at RT (n = 24), the mean in vivo 24-hour recovery was 81.8 +/- 8.4 percent (double-label).

CONCLUSION

Satisfactory filter performance in terms of WBC removal and RBC loss was observed with all 66 procedures, irrespective of storage conditions before filtration.

Inverse relationship between patient peripheral blood CD34+ cell counts and collection efficiency for CD34+ cells in two automated leukapheresis systems

BACKGROUND

The purpose of this study was to analyze the CD34 cell collection efficiency (CE) of automated leukapheresis protocols of two blood cell separators (Spectra, COBE [AutoPBSC protocol] and AS104, Fresenius [PBSC-Lym, protocol]) for peripheral blood progenitor cell (PBPC) harvest in patients with malignant diseases.

STUDY DESIGN AND METHODS

PBPCs were collected by the Spectra AutoPBSC protocol in 95 patients (123 collections) and the AS104 PBSC-Lym protocol in 87 patients (115 harvests). Patients underwent a median of one (range, 1-4) conventional-volume apheresis procedure of 10.8 L (9.0-13.9) to obtain a target cell dose of > or =2.5 x 10(6) CD34+ cells per kg.

RESULTS

The median overall CD34 CE was significantly better on the AS104 than on the Spectra: 55.8 percent versus 42.4 percent (p = 0.000). This was also true below (59.2% vs. 50.1%; p = 0.022) and above (51.2% vs. 41.3%; p = 0.001) the preleukapheresis threshold of 40 CD34+ cells per microL needed to collect a single-apheresis autograft. However, at > or =40 circulating CD34+ cells per microL, both cell separators achieved the target of > or =2.5 x 10(6) CD34+ cells per kg. The CD34 CE dropped significantly, from 59.2 percent at <40 cells per microL to 51.2 percent at > or =40 cells per microL on the AS104 (p = 0.017) and from 50.1 percent to 41.3 percent on the Spectra (p = 0.033).

CONCLUSION

Whereas the CD34 CE was significantly different with the AS104 and the Spectra, the CD34 CE of both machines correlated inversely with peripheral blood CD34+ cell counts, showing a significant decline with increasing numbers of circulating CD34+ cells. Nevertheless, at > or 40 preapheresis CD34+ cells per microL, sufficient hematopoietic autografts of > or =2.5 x 10(6) CD34+ cells per kg were harvested by a single conventional-volume (11 L) leukapheresis on both cell separators.

Repopulating activities of human cord blood cells separated by a stem cell collection filter in NOD/SCID mice: a comparative study of filter method and HES method

BACKGROUND

Volume reduction and removal of RBCs are essential for cost-efficient cord blood (CB) banking. It has previously been shown that a newly developed device, a stem cell-collection filter (SCCF), can reduce the CB volume and remove RBCs efficiently, giving high recovery rates for CD34+ cells, colony-forming cells, and long-term culture-initiating cells with short operation time. The aim of this study was to compare the quality of CB cells separated by SCCF and HES by analyzing repopulation in NOD/SCID mice.

STUDY DESIGN AND METHODS

A total of 1 x 10(6) or 5 x 10(6) nucleated cells derived from SCCF- or HES-separated, cryopreserved, thawed, and washed CB were transplanted into NOD/SCID mice. Eight weeks after transplantation, bone marrow cells of the recipient mice were examined by flow cytometry and hematopoietic progenitor assay for the engraftment of human cells.

RESULTS

Mice given human CB cells, separated by SCCF, showed degrees of engraftment similar to those in mice given HES-separated CB cells. There was no significant difference in the lymphohematopoietic reconstitution pattern in the two groups of mice.

CONCLUSION

SCCF processing does not appear to reduce the number of repopulating cells in NOD/SCID mice or alter the number of HPCs. It is now shown that these cells can be captured by SCCF and removed, and that they will engraft.

Leukodepletion of platelet concentrates and plasma collected with haemonetics MCS+ apheresis system. Experience of EFS-Alsace

The prevention of transfusion reactions and transmission of infectious diseases partly relies on the systematic removal of leukocytes from blood products. Apheresis platelets and plasma collected on the Haemonetics MCS+ collection system require filtration to obtain low levels of residual leukocytes. This filtration step is automated for platelet concentrates, whereas plasma filtration requires sterile docking of a leukoreduction filter. Our experience shows residual leukocyte levels of approximately 10(5) for platelets (the French requirements are 10(6) per unit) and 10(2) for apheresis plasma (no existing standard in France). Leukocyte residuals in platelets are highly dependent on the filtration rate, which should be as slow as possible. Whereas the current method of filtration is convenient for platelets, the connection of an in-line filter for plasma causes some organizational problems and is also associated with a loss of plasma. Haemonetics' latest development, the use of a filtering core bowl, should avoid the requirement for the connection of an additional filter for plasma filtration and will ensure continuous filtration of platelets, reducing, even further, the residual leukocyte count in platelet concentrates.

Studies on the improvement of leucodepletion performance of the Haemonetics MCS+ for production of leucodepleted platelet concentrate

With the implementation of universal leucodepletion, an in-line, negatively charged LRF6H leucodepleting filter became an essential part of the Haemonetics MCS+ plateletpheresis system. A larger-scale (968) study using the standard protocol revealed a 2.79% leucodepletion failure rate (standard < 5 x 10(6) leucocytes per adult therapeutic dose). Factors influencing the efficacy of the filter were investigated. The pH of the filtrate was 7.0, the temperature 28 degrees C and filtration rate 80 ml/min. Reduction of the filtration rate to 30 ml/min (784 doses) reduced leucodepletion failure to 0.38%. Measurement of the leucocyte count, pre- and post-filtration of the platelet products, revealed that donations from 1% of donors contained substantially larger numbers of leucocytes in pre-filter samples (300-1500/microl) than in control samples (35-70/microl). This number tends to increase progressively with subsequent donations in these individuals, leading to leucodepletion failure, whilst peripheral leucocyte counts remain normal. The new continuous filtration protocol (version C) using a less impact filter LRF-XL and a lower (7 ml/min) head pressure was also effective but failure still occurred twice on one of the donors who persistently showed high pre-filter count. We conclude that leucodepletion failures in the Haemonetics system are related to both donor leucocyte (i.e., being light and non-adherent) and operational/filter performance.

Safety and efficacy of granulocyte and monocyte adsorption apheresis in patients with active ulcerative colitis: a multicenter study

Active ulcerative colitis (UC) is characterized by activation and infiltration of granulocytes and monocytes/macrophages into the colonic mucosa. The infiltrated leukocytes can cause mucosal damage by releasing degradative proteases, reactive oxygen derivatives, and proinflammatory cytokines. The aim of this trial (conducted in 14 specialist centers) was to assess safety and efficacy of granulocyte and monocyte adsorption apheresis in patients with active UC most of whom were refractory to conventional drug therapy. We used a new adsorptive type extracorporeal column (G-1 Adacolumn) filled with cellulose acetate beads (carriers) of 2 mm in diameter, which selectively adsorb granulocytes and monocytes/macrophages. Patients (n = 53) received five apheresis sessions, each of 60 minutes duration, flow rate 30 ml per minute for 5 consecutive weeks in combination with 24.4 +/- 3.60 mg prednisolone (mean +/- SE per patient per day, baseline dose). During 60 minutes apheresis, 26% of granulocytes, 19.5% of monocytes and 2% of lymphocytes adsorbed to the carriers. At week 7, 58.5% of patients had remission or improved, the dose of prednisolone was reduced to 14.2 +/- 2.25 mg (n = 37). The apheresis treatment was fairly safe, only eight non-severe side effects (in 5 patients) were reported. Based on our results, we believe that in patients with active severe UC, patients who are refractory to conventional drugs, granulocyte and monocyte adsorption apheresis is a useful adjunct to conventional therapy. This procedure should have the potential to allow tapering the dose of corticosteroids, shorten the time to remission and delay relapse.

Bradykinin-associated reactions in white cell-reduction filter

PURPOSE

The purpose of this study was to examine the effect of temperature on bradykinin generation during blood transfusion using positively charged (positive filter), negatively charged (negative filter), and neutral (neutral filter) filters.

MATERIALS AND METHODS

Whole blood collected from six volunteers at 4 degrees C or 37 degrees C was passed through the positive or negative filter. In six surgical patients during surgery, autologous blood transfusion at 37 degrees C was initiated through the positive filter, and the same transfusion was reintroduced through the negative filter. Whole blood from another six volunteers at 4 degrees or 37 degrees C was passed through the neutral filter.

RESULTS

The positive filter did not generate bradykinin at any temperature, whereas the negative filter generated bradykinin by approximately 4,000-fold when warm blood was used but did not at cool blood. Blood pressure decreased and heart rate increased during warm blood transfusion using the negative filter but did not change using the positive filter. Plasma bradykinin levels increased in patients with use of the negative filter. The neutral filter generated bradykinin when warm blood was used but at levels lower than for the negative filter.

CONCLUSIONS

Use of negative filter results in the temperature-dependent generation of bradykinin, which becomes a potential anaphylatoxin when warm blood is used.

Residual red cell and platelet content in WBC-reduced plasma measured by a novel flow cytometric method

BACKGROUND

The levels of residual red blood cells (RBC) and platelets (PLT) in WBC-reduced plasma are often below the lower detection limit of automated blood cell counters. This study established a novel flow cytometric method for the enumeration of residual RBC and PLT in plasma. Furthermore, their levels in WBC-reduced plasma prepared by using various filters were investigated.

MATERIALS AND METHODS

WBC-reduced plasma was prepared from two sources: (i) filtration of buffy-coat reduced plasma using dock-on Baxter, Pall and Maco Pharma plasma filters; (ii) filtered whole blood using integral Asahi RZ2000, Maco Pharma LST1, NPBI, and Pall WBF2 whole blood filters. Residual RBC and PLT counts were assessed by using a TruCount tube (Becton Dickinson) containing a known number of lyophilized fluorescent beads. RBC and PLT were labelled with dual monoclonal antibodies, anti-CD41-R-phycoerythrin and anti-glycophorin A-fluorescein isothiocyanide, and analyzed by flow cytometer.

RESULTS

The flow cytometric method used in this method can detect residual RBC, PLT as well as RBC-MV simultaneously. The sensitivity of the assay was 50 x 10(6) cells/l with the coefficient of variations < or = 10%. Baxter and Maco Pharma plasma filters consistently reduced both RBC, RBC-MV and PLT to below 50 x 10(6/)l. Plasma derived from day 1 RZ2000 filtered whole blood contained PLT below 50 x 10(6) cells/l, whereas day 0 NPBI filtered whole blood showed the highest level of residual PLT.

CONCLUSION

A sensitive and accurate method for the detection of low levels RBC, RBC-MV, and PLT was established to measure their levels in WBC-reduced plasma. The procedure is simple and practical for routine quality monitoring of plasma, as well as for setting a new specification for WBC-reduced plasma.

The MCS + revision A2 for highly efficient PBSC collection

Autologous PBSC transplantation is an integral component of the management of hemato-oncology patients. In order to reduce the number of sessions needed to collect the desired number of repopulating cells there has been significant research activity in developing progressively more and more effective technologies and techniques. Recently our group has been involved in the rejuvenation of the MCS + apparatus for both platelet and PBSC collection. The so called "version A2 protocol" is aimed at collecting PBSC in a very efficient way. This protocol is characterized by high blood flow rates both in the collection and reinfusion (80 ml/min) recirculation (56 ml/min) and collection phases (30 ml/min). Only one recirculation is carried out every 5 cycles and only from 5 to 7 are carried out for a single procedure. Twenty-seven collections were carried out of which 25 were evaluable in terms of PBSC efficiency. These averaged 68.8% in an average procedure time of 3.5-5 h for processing an average of 7,052 ml of blood. The RBC contamination was reduced to approximately 5.02 g of hemoglobin and the average volume of the product to 177 ml. If these results are confirmed, the gap between CFC and DFC PBSC is progressively closing.

Correlation of hematopoietic progenitor cell count determined by the SE-automated hematology analyzer with CD34(+) cell count by flow cytometry in leukapheresis products

The yield of stem cell collection after mobilization is crucial for autologous peripheral blood stem cell (PBSC) transplantation. Quantitative determinations of CD34(+) cells using flow cytometry or stem cell culture have been used, but these methods require much time, technical experience, and expensive reagents. The automated hematology analyzer (Sysmex SE-9000trade mark, TOA, Japan) equipped with the Immature Information (IMI) channel for immature myeloid cells can detect IMI(+) cells within 90 sec. Detection is made possible by the combination of a special reagent system and direct current/radiofrequency biosensors. We studied the relation of IMI(+) cells and variable cell counts with CD34(+) cell yield in autologous stem cell harvest. In a series of 32 patients (median age, 44 years; M:F = 11:21), 184 leukaphereses were performed after mobilization regimens with chemotherapy and G-CSF or G-CSF alone. Full blood cell counts were enumerated on peripheral blood (PB) samples taken prior to each leukapheresis. Mononuclear cell (MNC) and IMI(+) cell counts by automated hematology analyzer and flow cytometry based CD34(+) cell yield were measured on the harvested product. The relationship among PB white blood cells (WBC), PB monocytes, IMI(+) cells, MNC, and CD34(+) cell yield in a single leukapheresis was estimated by Pearson correlation analysis. PB WBC count showed no correlation with CD34(+) cell yield in a single leukapheresis (r = 0.02, P = 0.81). PB monocyte count showed a weak correlation (r = 0.21, P = 0.01) and MNC in harvest also showed a weak correlation (r = 0.36, P = 0.0001) with CD34(+) cell yield. In contrast, CD34(+) cell yield correlated well with IMI(+) cell count (r = 0.68, P = 0.0001), and data could be fitted by a linear regression equation, y = 0.330 + 0.974x. IMI(+) cell assay by the automated hematology analyzer correlated well with the CD34(+) cell yield in a mobilized autologous stem cell harvest. The IMI(+) cell count might be used as a simple and efficient indicator of blood stem cell mobilization and collection.

Prospective randomised concurrent comparison of the COBE spectra version 4.7, COBE spectra version 6 (Auto PBSCtrade mark), and haemonetics MCS+ cell separators for leucapheresis in patients with haematological and non haematological malignancies

A prospective study of three cell separators was undertaken to compare the mononuclear cell, CD34+ cell and CFU-GM yield. Twenty patients were entered in the study; all had received chemotherapy and daily G-CSF (5 microg/kg subcutaneously) up to and including the first day of leucapheresis. The first leucapheresis was performed on the first day the peripheral blood absolute CD34+ cell count was > or =20 cells/microl. All patients underwent two leucaphereses on consecutive days. The patients were randomised to undergo either the first or second leucapheresis using the COBE Spectra Version 4.7 and then randomised to either the COBE Spectra Version 6 or Haemonetics MCS+ for the other leucapheresis. The target durations of the procedure on the COBE Spectra Version 4.7 and Version 6 were 180 minutes or 2 total blood volumes (TBV), and for the Haemonetics MCS+ was 20 cycles with four recirculations. All machines were operated on the 1997 software supplied by the respective manufacturers. The time taken for the procedure was significantly longer with both the Haemonetics MCS+ and the COBE Spectra Version 6 than the COBE Spectra Version 4.7. Both COBE Spectra versions processed significantly larger volumes of blood than the Haemonetics MCS+. The absolute yield of mononuclear cells, CFU-GM and CD34+ cells were all significantly lower with the Haemonetics MCS+ compared with both COBE Spectra versions, as were the yields per unit volume of blood processed. The product volume was significantly higher with the COBE Spectra Version 4.7 compared to the other two machines. There was no significant difference in the reduction in the platelet count following leucapheresis with any of the machines. The COBE Spectra Version 6 is particularly useful for patients with potentially poor peripheral venous access because of its increased interface stability.

Automated collection of peripheral blood stem cells with the COBE spectra for autotransplantation

BACKGROUND

A convenient, effective and safe peripheral blood stem cell (PBSC) apheresis procedure is desirable to cope with the increasing requirements for PBSC collections. We performed PBSC harvesting with the novel COBE Spectra AutoPBSC(TM) system using the default software configuration recommended by the manufacturer. We analyzed collection parameters and clinical efficiency of harvested autografts following high-dose chemotherapy (HDCT).

PATIENTS AND METHODS

Eighty-one patients underwent 102 harvests after standard chemotherapy plus filgrastim (5-10 microg/kg/day) to obtain a target of >/=2.5 x 10(6) CD34+ cells/kg for autologous blood stem cell transplantation. Conventional-volume leukaphereses (median: 11 liters) were performed using the manufacturer's standard software default regarding inlet flow, harvest/chase volume (3/7 ml) and number of collection cycles. The ratio of ACD-A to whole blood was initially set at 1:12 (56 collections), later at 1:10 (46 aphereses).

RESULTS

With respect to preapheresis counts of 93 (9-876) CD34+ cells/microl, 69 patients (85.2%) achieved >/=2.5 x 10(6) CD34+ cells/kg by the first apheresis. PBSC products contained medians of 5.0 x 10(6) (0.7-77.3) CD34+ cells/kg and 13.8 x 10(4) (2.3-105.0) CFU-GM/kg. A preapheresis count of >/=40 CD34+ cells/microl predicted a single-apheresis yield of >/=2.5 x 10(6) CD34+ cells/kg. Apheresis products showed a high mononuclear cell (MNC) purity of >/=89%. The median overall collection efficiency of CD34+ cells (CD34-CE) was 42.6% (12.2-87.4). The CD34-CE decreased significantly with increasing numbers of circulating CD34+ cells: 52.5% at CD34+ cells <40/microl versus 41.0% at CD34+ cells >/=40/microl (p </= 0. 002). Coagulation problems occurred in 3 of 56 procedures at an ACD-A to whole blood ratio of 1:12, but in no case at 1:10. Patients who underwent HDCT and autologous blood stem cell transplantation (n = 40) engrafted in a median time of 9 (8-13) days for absolute neutrophil counts >0.5 x 10(3)/microl, 10 (8-13) days for WBC >1.0 x 10(3)/microl and 11 (8-17) days for platelets >20 x 10(3)/microl.

CONCLUSIONS

As a result of efficient PBSC mobilization, a single conventional-volume leukapheresis with the COBE Spectra AutoPBSC system resulted in hematopoietic autografts with >/=2.5 x 10(6) CD34+ cells/kg in 85% of patients. Following the standard PBSC apheresis recommendations of the manufacturer, the AutoPBSC system assures PBSC products with a high MNC purity and a moderate CD34-CE that declines significantly at increasing levels of circulating CD34+ cells. Leukaphereses performed at an ACD-A to whole blood ratio of 1:10 should run without coagulation problems.

A prospective randomised concurrent comparison of the COBE Spectra Version 4.7, COBE Spectra Version 6 (auto PBSC) and Haemonetics MCS+ cell separators for leucapheresis in patients with haematological and non-haematological malignancies

A prospective study of the CD34+ cell collection efficiency of three cell separators was undertaken comparing the mononuclear cell, CD34+ cell and CFU-GM yield. Twenty patients were entered in the study, all had received mobilising chemotherapy and daily G-CSF (5 microg/kg subcutaneously). The first leucapheresis was performed when the peripheral blood absolute CD34+ cell count was > or = 20 cells/microl. All patients underwent two leucaphereses on consecutive days. The patients were randomised to undergo either the first or second leucapheresis using the COBE Spectra Version 4.7 and then randomised to either the COBE Spectra Version 6 or Haemonetics MCS+ for the other leucapheresis. The target durations of the procedure on the COBE Spectra Version 4.7 and Version 6 were 180 min or two total blood volumes (TBV), and for the Haemonetics MCS+ was 20 cycles with four recirculations. All machines were operated on the 1997 software supplied by the respective manufacturers. The time taken for the procedure was significantly longer with both the Haemonetics MCS+ and the COBE Spectra Version 6 than the COBE Spectra Version 4.7. Both COBE Spectra versions processed significantly larger volumes of blood than the Haemonetics MCS+. The absolute yield of mononuclear cells, CFU-GM and CD34+ cells were all significantly lower with the Haemonetics MCS+ compared with both COBE Spectra Versions, as were the yields per unit volume of blood processed. There was no significant difference in the reduction in the platelet count following leucapheresis with any of the machines.

Evaluation of two types of leukocyte removal filters on transfusion dependent thalassaemics

The advent of leukocyte filters has enabled effective removal of leukocytes from certain blood products thus avoiding many adverse effects of blood transfusion. Many different materials have been incorporated into these filters to achieve >95% leukocyte removal. In this study we evaluated the efficacy of leukocyte removal of two different filters, using actual bedside transfusion settings involving patients with transfusion dependent thalassaemia. Fifty-one transfusion events were randomised to use either a polyurethane filter or a non-woven polyester filter. We found that the two filters achieved 98.4% and 96.2% leukocyte removal respectively (p = 0.022). We also found no significant correlation between pre-filtration white blood cell count and the volume transfused with the efficacy of leukodepletion. No untoward events or transfusion reactions were observed during the study.

[Novel extracorporeal granulocyte apheresis column inhibits myocardial reperfusion injury: future clinical applications]

OBJECTIVES

Leukocyte infiltration is very important in myocardial ischemia/reperfusion injury. A new extracorporeal circulation therapy using a granulocyte-apheresis column (G-1) has recently been proved to be effective and safe in patients with rheumatoid arthritis and with ulcerative colitis. This study investigated whether this therapy would reduce myocardial ischemia/reperfusion injury.

METHODS

Rabbits were subjected to 30 min ischemia followed by 180 min reperfusion with no treatment (control group: n = 12); or treated with extracorporeal blood circulation (2 ml/min) passing through the G-1 (G-1 group: n = 12), or sham column (sham group: n = 12). Infarct size was determined by tetrazolium staining and expressed as a percentage of the area at risk.

RESULTS

Infarct size in the G-1 group (15.9 +/- 3.4%) was significantly (p < 0.01) smaller than in the control (34.7 +/- 3.9%) and sham (35.2 +/- 4.1%) groups. Granulocyte emigration into the ischemic myocardium assessed by histopathological score was significantly (p < 0.01) less in the G-1 group (0.58 +/- 0.17) than in the sham group (1.42 +/- 0.26). There was a significant (r = 0.78, p < 0.0001) positive correlation between this score and infarct size. Flow cytometry showed alterations in the adhesion molecule expression on granulocytes during the passage through the G-1, but not sham, columns as a low L-selectin and high Mac-1 form, which is associated with the inability to home to the inflamed site.

CONCLUSIONS

Extracorporeal circulation with the G-1 column, a newly-developed clinically applicable therapy, appears to reduce infarct size at least in part by limiting the emigration capacity of granulocytes into the ischemic myocardium.

Stem cell collection using the dideco excel continuous flow blood cell separator: parameters for optimal stem cell collection timing

This study evaluates stem cell collection procedures performed with the Dideco Excel blood cell separator, with particular attention given to yields and separator collection efficiencies. Patients' blood precounts and yield parameters related to the harvest capacity of the collection system were investigated. Fifty-five collection procedures were analyzed in 32 patients suffering from hematological malignancies and solid tumors and mobilized with chemotherapy plus G-CSF. The median blood volume processed in each procedure was 15.8 liters (12-19.750), with a blood flow rate of 70 ml/min. Patients had the following median blood precount value: NC 7.81x10(9)/L, CD34+ cells 49.08x10(3)/ml. Leukapheresis procedures gave the following yields: NC 14.95x10(9), MNC 10.83x10(9), CD34+ cells 4.37x10(6); yields/kg, NC 0.21x10(9)kg, MNC 0. 15x10(9)/kg CD34+ cells 4.26x10(6)/kg. Procedures show the following collection efficiencies: NC 10.79%, MNC 29.06%, CD34+ 42.33%, PLT 26.5%. The RBC (red blood cell) contamination of the product was (median value) 20.9 ml for each procedure, and for platelets 1.76x10(11) per procedure. The CD34+ cell precounts strongly correlated with the CD34+ yields/kg (r=0.82. p=0.000). Furthermore the NC and MNC precounts correlated with the CD34+ yields/kg but only the MNC precount correlation is notable (r=0.57, p=0.000). The logistic regression analysis shows that CD34+ (p=0.008) but not NC (po=0.14), MNC (p=0.09), or PLT (p=0.53) precounts significantly influenced the collection of a sufficient dose of CD34+ cells for transplantation (> or =2.5x10(6)/kg). Eleven of the thirty-two patients have been transplanted till now, and all had a prompt and lasting trilineage engraftment NC >1x10(9)/L on day 12 (10-17). Our data show that the collection system analyzed in this report is able to collect large amounts of progenitor cells, harvesting >2.5x10(6)/kg CD34+ cells with a single procedure in 68.8% of patients and assuring complete recovery after stem cell transplantation.

Peripheral blood stem cell collection: the interaction of technology, procedure, and biological factors

Centrifugal technology, continuous flow and discontinuous flow, has served as the technology platform for extracting cell concentrates of interest from peripheral blood (PB) for patient therapy for the past 35-40 yr. Models for procedure outcome exist for collection of normal donor (ND) platelet and granulocyte concentrates that integrate: (1) biological variables (pre-procedure PB cell concentration, the total circulating quantity of cells, donor/patient blood volume (BV)), (2) device efficiency, and (3) procedure parameters such as total blood processed (TBP), and in the case of cytoreductions - the volume collected. (cf. Hester J, Kellogg R, Mulzet A, et al., Blood (54) (1979) 254; Hester J, Ventura G, J Clin Apheresis (4) (1988) 188.) To date, no predictive CD34+ yield algorithm integrating these three variables has been formulated that could be applied prospectively for individual ND or patients (PT). There are economic, toxicity and statistical comparison benefits to be derived from generating such an algorithm.A small pilot study is presented with a brief review of current publications that suggest the circulating quantity of CD34+ cells available to be collected and the quantity mobilized during leukapheresis are the major contributing factors to CD34+ yield, somewhat obscuring the role of the total blood processed (TBP). Intraprocedure CD34+ cell mobilization, incompletely characterized to date, appears to be a dynamic nonlinear process, as the harvested yield does not rise proportionally as the fraction of BV processed increases. And, like the pre-procedure PB CD34+ concentration and total circulating quantity, CD34+ mobilization during leukapheresis probably relates to prior treatment and the priming regimen. Studies that provide: (1) separate analyses of PT populations divided according to chemotherapy toxicity factors; (2) design and implementation of optimal priming regimens with respect to dose 'intensity' of both growth factors and chemotherapy; and (3) standardization of laboratory assays of CD34+ enumeration seem essential to generating a predictive algorithm.

Efficiency of leukocyte removal by filters made of superfine glass fiber membranes

BACKGROUND AND OBJECTIVES

To demonstrate the application of leukocyte removal filters made of a new type of filter material - superfine glass fiber - for depleting leukocytes in SAGM red cell suspensions and preventing nonhemolytic transfusion reactions.

MATERIALS AND METHODS

The extent of leukocyte depletion and red cell recovery was based on cell counts. Trace leukocytes were counted in a 50-microl Nageotte counting chamber or by using a flow cytometer. The chemical stability of the glass fiber membranes was studied by plasma emission spectrometer and by measuring the ion content and weighing nonvolatile matter in water extract. The structural stability of the glass fiber membranes was studied by a micropore-filter membrane method.

RESULTS

Leukocyte removal filters made of superfine glass fiber membranes removed more than 99.0% of leukocytes in SAGM red cell suspensions prepared from 400 ml whole blood. Red cell recovery exceeded 90%, and the total number of residual leukocytes was less than 5x10(6). A water extract of the glass fiber membranes contained only traces of Si4+ and Ca2+ and less than 2 mg/100 ml of nonvolatile matter. No broken or loose fibers were found in the filters. Scanning electron microscopy showed that the web structure of the glass fiber membranes was instrumental in trapping and holding leukocytes.

CONCLUSION

A filter made of glass fiber membranes is effective in leukocyte depletion.

Harvesting of peripheral blood progenitor cells with different programmes of discontinuous flow systems

BACKGROUND AND OBJECTIVES

From a technical point of view two problems arise during the collection of peripheral blood progenitor cells (PBPC): first, the volume of the apheresis product is often large, requiring volume reduction prior to cryopreservation. Second, the platelet (PLT) loss due to the harvesting of the buffy coat is an unwanted side effect. With respect to these problems, the present study was designed to compare programs for PBPC collection with discontinous-flow cell separators.

MATERIALS AND METHODS

Three different protocols for PBPC harvesting were investigated in 32 patients with malignancies. In the first protocol, the blood cell separator Haemonetics MCS 3p was used. In the second protocol using the same machine, the opening and closure of the stem cell valve was modified in combination with a centri surge to reduce the PLT loss. The MCS+ device with another configuration of the valves was used in the third protocol. PBPC were mobilised by chemotherapy plus cytokine administration or application of growth factor alone. Blood counts and CD34 antigen-expressing cells were determined before apheresis and in the PBPC product. Colony-forming unit granulocyte/macrophage (CFU-GM) were determined in the apheresis product.

RESULTS

55 PBPC collections were carried out with a median end product volume of 105 ml. The median counts for CD34+ antigen-expressing cells and CFU-GM were 1.5x10(6 )and 2.5x10(4)/kg body weight, respectively. PLT loss was significantly lower in protocol III.

CONCLUSION

The study reported here revealed that PBPC could be easily collected in a reduced product volume by the intermittent-flow cell separators. No additional centrifugation prior to cryopreservation was necessary to remove the plasma from the apheresis product. Patient's PLT loss was reduced by the centri surge technique but this still has to be improved.

Prospective, concurrent comparison of the Cobe Spectra and Haemonetics MCS-3P cell separators for leukapheresis after high-dose filgrastim in patients with hematologic malignancies

A prospective study was undertaken to compare the mononuclear cell, CD34+ cell, and CFU-GM yields of the Haemonetics MCS-3P and the Cobe Spectra cell separators in ten patients (nine multiple myeloma and one non-Hodgkin lymphoma) on two consecutive days after mobilization with high-dose filgrastim (12-16 micrograms/k) for 4 days. All patients were harvested once on each machine, five starting on each machine. The target duration of the procedure on the Spectra was 160 minutes, and the target blood volume processed on the MCS-3P was 60-70 ml/kg body weight. Both machines were operating on the 1995 software versions supplied by the respective manufacturers. The time taken for the procedure was significantly longer with the Haemonetics machine. The volumes of blood processed and the product collected were significantly higher with the Spectra, as were the absolute mononuclear and CD34+ cell yields, and yields per unit time. Mononuclear and CD34+ cell yields per unit volume of blood processed were comparable for both machines. The differences in CFU-GM yields were not significant, largely because of wide interpatient variations. The extent of platelet depletion as a result of the procedure was greater with the Spectra because of the higher blood volume being processed. We conclude that the Cobe Spectra is a significantly faster machine than the Haemonetics MCS-3P; and consequently, its use is associated with higher mononuclear and CD34+ cell yields.

Adjustment of the interface detector (location 71) to the absolute number of mononuclear cells in the peripheral blood: no improvement of the collection efficiency of the Fenwal CS3000 plus during progenitor cell harvests

Improvement of the collection efficiency (CE) of the Fenwal CS3000 plus in collecting circulating progenitor cells (CPC) might diminish the number of leukapheresis procedures (LP) required to obtain the CPC required to assure engraftment. We analyzed whether adjustment of the optical setting (location 71,L71) to the number of MNC present in the peripheral blood could enhance the CE of the MNC. Thirty-five patients underwent 121 LP with an adjusted L71. We compared the results retrospectively with 26 LP performed with a fixed L71 (1:100) in 12 patients. The CPC were mobilized with chemotherapy followed by subcutaneous administration of granulocyte colony-stimulating factor (G-CSF) in both groups. Adjustment of the L71 did neither improve the CE of the MNC, the estimated CE of CD34+ cells nor diminished granulocyte contamination. For the total 121 LP with an adjusted L71 and for the total 26 LP with a fixed L71 the mean CE of MNC were, respectively, 44.6 +/- 18.3% and 46.4 +/- 14%. The mean granulocyte contamination, determined by manual white blood cell differentiation, was 1.7 +/- 2.3% for the adjusted L71 group and 2.3 +/- 3 for the fixed L71 group. There was no difference in the median number of LP required to obtain 3 x 10(6) CD34+ cells/kg between both groups. We found a weak significant correlation between WBC and pre-LP MNC count and the CE of MNC (r = 0.36, P = 0.012, resp.r = 0.33, P = 0.023), but no correlation between the CE of MNC and the estimated CE of CD34+ cells (r = 0.24, P = 0.113). In conclusion, adjustment of the L71 to the MNC did not improve the CE of MNC of the Fenwal CS3000. The lack of correlation between the CE and MNC and the estimated CE of CD34+ cells should be further explored.

Comparison of COBE Spectra software version 4.7 PBSC and version 6.0 auto PBSC program

Until recently, the collection of peripheral blood progenitor cells (PBPC) has been semi-automated by using the COBE Spectra, with the operator manually maintaining the position of the white cells being collected. The COBE Spectra Version 6.0 apheresis device offers the user an automated program for the collection of PBPC. In this study, we compared the new software Version 6.0 to that of Version 4.7. Patients (n = 46) undergoing PBPC collection were allocated to cell processing with either Version 4.7 (n = 24) or Version 6.0 (n = 22). The CD34+ cell count, mononuclear cell (MNC) count, white cell count (WCC), hemoglobin (Hb), and platelet content in the autograft product by using the two versions were compared. We divided the analysis into three subsets according to peripheral blood (PB) CD34 content: <10x10(6)/L, 10-50x10(6)/L and >50x10(6)/L. Analysis of the three subsets showed no statistical difference between results obtained when the starting PB CD34+ cell count was 10-50x10(6)/L (P=0.08) or >50x10(6)/L (P=0.4065). At lower starting PB CD34+ cell counts of <10x10(6)/L, Version 4.7 was superior (P=0.0167). However, autograft platelet contamination of the autograft was significantly higher using Version 4.7 (P=<0.0001).