Quantitation of residual white cells in filtered blood components by polymerase chain reaction amplification of HLA DQ-A DNA

BACKGROUND: Over the past several years, blood filtration technology has improved dramatically, such that currently available experimental filters are capable of reducing white cells (WBCs) in blood components to less than 0.1 WBC per microL. These residual WBC concentrations are below the sensitivity of automated cell counters, as well as of large- volume (Nageotte) hemocytometers. STUDY DESIGN AND METHODS: A quantitative polymerase chain reaction (PCR) amplification assay directed at HLA DQ-A DNA sequences has been developed for the enumeration of WBCs in filtered blood. To ensure quantitative recovery of WBCs at very low residual cell concentrations, a direct red cell lysis and WBC concentration protocol using 0.5 mL of filtered blood was perfected. Amplified product is detected by oligomer hybridization using 32P-labeled probes, with quantitation by image analysis of autoradiographic signals relative to a standardized dilution series processed in parallel. RESULTS: Recovery of residual WBCs in filtrates was shown to be enhanced by the addition of xenogeneic WBCs or polystyrene beads, which served as "carrier" particles during red cell lysis and wash steps. A contribution of nuclear fragments in filtered blood to PCR signal in the range of 0.01 to 0.5 WBCs per microL was observed; a modified protocol was developed to minimize this effect. Parallel analysis of spiked dilution series and evaluations of 39 red cell components filtered through commercial filters indicated good correlation between PCR and standard Nageotte counts in the range of 0.1 to 10 WBCs per microL (r2 = 0.94); only PCR was able to detect residual WBCs in filtrates from prototype 6 log10 WBC-reduction filters. CONCLUSION: This assay should prove useful for the development and quality assurance of increasingly efficient WBC-reduction filters.     

Multicenter evaluation of two flow cytometric methods for counting low levels of white blood cells

BACKGROUND: Flow cytometric methods can be used to count residual white blood cells (WBCs) in WBC-reduced blood products, which should contain fewer than 1 x 10(6) WBCs per unit (approximately 3.3 WBCs/ microL). In this study two flow cytometric methods for counting WBCs under routine conditions in nine laboratories were evaluated. STUDY DESIGN AND METHODS: Panels of red blood cells (RBCs), platelets (PLTs), and plasma were prepared containing 33.3, 10.0, 3.3, 1.0, and 0.3 WBCs per microL and counted with flow cytometric methods (either LeucoCOUNT, BD Biosciences, four laboratories; or LeukoSure, Beckman Coulter, five laboratories). Requirements were that at the level of 3.3 WBCs per microL, coefficient of variation was < or =20 percent and accuracy was > or =80 percent. Routine flow cytometric quality control (QC) data of WBC-reduced blood products from two laboratories were analyzed. RESULTS: At the level of 3.3 WBCs per microL, none of the laboratories met the requirements for all three blood products. The LeucoCOUNT method met requirements at more laboratories than the LeukoSure method for RBCs and PLTs, but the opposite was true for plasma. Routine QC data showed that >99 percent of the flow cytometric measurements for WBC-reduced products was below the 95 percent prediction interval at 3.3 WBCs per microL. CONCLUSION: None of the laboratories met the requirements for accuracy and precision for all three blood products. Nevertheless, routine results showed that in >99 percent of the products, WBC counts were below guideline limits. Therefore, both flow cytometric methods are suitable for QC with pass-fail criterion.     

A flow cytometric method for counting very low levels of white cells in blood and blood components

Reduction of white cells (WBCs) in blood components may reduce the risk of virus transmission and HLA alloimmunization. Filtration provides a means by which to achieve high-efficiency WBC reduction. A method has been developed using flow cytometry to quantitate the number of WBCs in WBC-reduced packed red cells or platelet concentrates. This method uses a detergent and propidium iodide (PI) solution to label the WBC nuclei and incorporates a known amount of fluorescein isothiocyanate (FITC)- labeled chicken red cells (cRBCs) into the mixture as an indicator of the volume examined. The number of observed WBCs per mL is calculated as follows: Number of PI WBC nuclei events/Number of FITC cRBC events × Number of FITC cRBCs added to mixture/Volume of blood in mixture. The method may allow the detection of WBCs at a concentration as low as 0.01 per microliters (10/mL) in a blood sample. It is an efficient method of collecting data, as it requires less than 10 minutes per sample. This flow cytometric technique is suitable for research purposes and for quality control of WBC-reduced blood components, because it is precise and can be used to quantitate WBCs in large or small numbers in a sample.     

Routine quantitation of white cells as low as 0.001 per microL in platelet components

A method is described for routine quantitation of very low numbers of white cells (WBCs) in platelet components, using flow cytometry and dual nucleic acid stains. The WBC quantitation is based on the detection of nucleated cells labeled with propidium iodide and thiazole orange, with chicken red cells added as an internal counting standard. Platelet concentrates containing 0.001 to 1500 WBCs per microL (2 × 10(2)-3 × 10(8) WBCs/component) and 600 to 2800 × 10(3) platelets per microL were analyzed for the number of contaminating WBCs. The method was found to be linear throughout the 7 log10 range and to have sufficient reproducibility and sensitivity for routine analysis of WBC- reduced platelet concentrates.     

Flow cytometric determination of residual white blood cell levels in preserved samples from leukoreduced blood products

BACKGROUND: In preparation for a proposed consolidated testing service, Canadian Blood Services undertook the evaluation of a commercial test kit for the enumeration by flow cytometry of residual white blood cells (rWBCs) present in preserved samples recovered from leukoreduced (LR) blood and platelet products. STUDY DESIGN AND METHODS: The stability of preserved WBCs, the equivalency of WBCs used for spiking, test method precision, specificity, reliability, accuracy, and sensitivity were investigated. For comparative purposes, WBC counts were also determined by Nageotte as well as by flow cytometry. RESULTS: WBCs were stable up to 4 weeks at room temperature for all components by either method. Within methods, no differences were observed due to the source of WBC used for spiking purposes. By either method, test precision was acceptable (<20% coefficient of variation) and of similar reliability at a target value of 10 +/- 5 WBCs per microL. The flow cytometric method was shown to be more specific and accurate than the Nageotte method. Sensitivity by either method was 0.1 WBCs per microL. On average, Nageotte counts were lower than those observed by flow cytometry. CONCLUSIONS: These results demonstrate that WBCs in WBC stabilizing solution-treated samples from LR blood components were stabilized up to 4 weeks at room temperature and that rWBC determinations made with a WBC enumeration kit by flow cytometry have the required precision, specificity, reliability, and accuracy in the relevant test range. This validated WBC stabilization and flow cytometric counting method is considered acceptable as part of a quality control program for leukoreduced blood products.     

A general method for concentrating blood samples in preparation for counting very low numbers of white cells

BACKGROUND: To count extremely low levels of white cells (WBCs) in WBC- reduced blood components, a larger volume of sample must be processed. The goal was to develop an all-purpose method for concentrating the samples obtained from WBC-reduced red cells or platelets. The method was designed to be compatible with a variety of counting techniques. STUDY DESIGN AND METHODS: Coded samples of red cell concentrates with an expected WBC concentration of 200, 100, 50, and 10 per mL and of the diluent (undetectable WBCs/mL) were sent to three sites on five occasions and counted by the use of the concentration method, crystal violet stain, and a Nageotte counting chamber. Additional samples were tested by flow cytometry, polymerase chain reaction, and volumetric capillary cytometry. RESULTS: The results from the three test sites showed good linearity, with an overall r2 = 0.9994. The lower limit of accurate detection of the assay was 10 WBCs per mL. The results were biased toward underestimation, particularly at one of the test sites (Site A). There were no significantly different results in Sites B and C. The intra-assay CV was acceptable. Precision (reproducibility) at the three test sites varied. CONCLUSION: This method allows reliable determination of WBC concentrations as low as 0.01 per microL in blood. Despite the use of technologists trained in Nageotte chamber counting, validation testing demonstrated that one test site's performance was significantly different from that of the other two sites, because of both underestimation bias and variation in count results. The sample concentration method, when used in conjunction with an automated assay for WBC identification, should permit larger volume analysis with a greater degree of precision and a lower limit of detection than is found in assays that do not concentrate the sample before counting.     

Automatic volumetric capillary cytometry for counting white cells in white cell-reduced plateletpheresis components

BACKGROUND: As the benefits of white cell (WBC)-reduced blood components become increasingly apparent, the need has arisen for a simple, automated WBC-counting technique that is sensitive to low WBC concentrations. Automated volumetric capillary cytometry was evaluated for its ability to quantify residual WBCs in WBC-reduced plateletpheresis components. STUDY DESIGN AND METHODS: The volumetric capillary cytometry system evaluated uses a laser to excite fluorescent dye-labeled nucleated cells. The number of nucleated cells per microliter is reported. Four studies were performed: linearity, precision of results near the value of 5 × 10(6) WBCs per unit, the limit of detection, and correlation to the Nageotte manual counting method. RESULTS: Assay values correlated to expected values (range, 0- 125 WBC/microliter) with an r2 > 0.99. In the range of 5 × 10(5) WBCs per unit the CV was 8.5 percent, and concentration differences of 0.15 log10 were detectable. The limit of detection was 1.0 WBCs per microliter (95% upper confidence limit). The assay correlated to the Nageotte method with an r2 of 0.98, slope of 1.0, and y-intercept of 2.0 WBCs per microliter. Assay results were 10 to 15 percent higher than Nageotte results, in samples with values near 5 × 10(6) WBCs per unit. Technician time per sample was 2 to 3 minutes. CONCLUSION: Volumetric capillary cytometry is precise and sensitive to small differences in WBC concentration in the range of clinical interest. The device provides an efficient new method for quality assurance and control of WBC-reduced plateletpheresis products.     

Microdroplet fluorochromatic assay for the enumeration of white cells (WBCs) in WBC-reduced blood components: validation and application for evaluating newly developed WBC-reduction filters

BACKGROUND: Sensitive and accurate counting methods are required to assess the residual white cells (WBCs) in WBC-reduced blood components. The Nageotte hemocytometer, widely used for this purpose, is cumbersome, and its efficacy is dependent upon the skill of the operator. The performance of a simple fluorochromatic assay using tissue-typing microdroplet trays is presented here. STUDY DESIGN AND METHODS: Undiluted samples of blood components were mixed with a fluorochromatic dye in trays. WBCs were counted under an epifluorescence microscope. The accuracy and sensitivity of this method were compared with those of the reference Nageotte hemocytometer method by using serial dilution of samples of platelets and red cells containing known concentrations of WBCs and by calculating the standard curves. The Nageotte hemocytometer and the microdroplet fluorochromatic assay (MFA) were also compared in terms of count correlation and reproducibility in 320 paired counts of plateletpheresis samples. MFA was used to evaluate a newly developed WBC-reduction red cell filter. RESULTS: The MFA for platelets and red cells was linear to 0.1 and 0.03 WBCs per microL, respectively. The linear regression line of log10 MFA versus log10 Nageotte method had a slope of 0.963, intercept of -0.04, and r2 of 0.968. The Nageotte method gave an estimation of WBC content 12 to 20 percent greater than that of the MFA. The MFA, with a larger neat sample volume, showed precision comparable to that of the Nageotte method. The filters demonstrated a median WBC reduction of 4.8 log10. CONCLUSION: The MFA is a sensitive and accurate method for quality control processes to assess the residual WBCs in WBC-reduced blood components.     

Real-time amplification of HLA-DQA1 for counting residual white blood cells in filtered platelet concentrates

BACKGROUND A real-time polymerase chain reaction (PCR) assay based on amplification of a conserved region of the HLA-DQA1 locus was developed and validated to assess its suitability in quantitating low levels of white blood cells (WBCs) in filtered platelet (PLT) concentrates (PCs). STUDY DESIGN AND METHODS: To determine the detection limit, serial dilutions of nonfiltered PCs with known quantities of WBCs were prepared. The analytical sensitivity and accuracy of the assay was tested with WBC concentrations ranging from 300 to 0.03 per microL with real-time PCR and flow cytometry. In addition, 126 random PCs were investigated to assess the capacity of the PCR method to quantify residual WBCs in clinical specimens. RESULTS: A sensitivity of 0.2 WBC equivalent per micro L (1.5 x 10(4) WBC equivalents/unit) was achieved. The assay was shown to be accurate and the HLA-DQA1 gene was reproducibly and consistently amplified in all tested samples (coefficient of variance of < 5%). Overall, the results of the PCR assay correlated well with those of the flow cytometry. The PCR assay detected a concentration of 3 WBCs per micro L (approximately 1 x 10(6) WBCs/unit) with 100 percent accuracy. CONCLUSION: Real-time PCR is rapid, sensitive, accurate, and reproducible. Hence this approach may prove suitable in routine monitoring of residual WBCs in PCs.     

A rare-event analysis model for quantifying white cells in white cell- depleted blood

An analysis model to detect and quantify white cells (WBCs) in red cell concentrates (RBCC) drawn from units of blood that are highly depleted of WBCs is described. WBC detection is performed by fluorescence analysis of 50 microL of RBCC labeled with propidium iodide, a DNA/RNA fluorophore. Quantification is performed by regression analysis of standard dilutions of RBCC in substantially WBC-free red cells. This RBCC diluent is obtained by filtration of blood through a new medium. The method proves to be precise (CV = 7%), efficient (+/- 30 min/aliquot), and linear (r = 0.99) to 6 log10 WBC depletion of the native product. The current technique is preferable to those suggested previously, such as ficoll concentration, which requires the sacrifice of the unit of blood for counting purposes, and to earlier fluorescence analysis techniques that do not employ WBC-free red cell diluents. The latter do not monitor extremely low concentrations of WBCs because they lack adequate signal-to-noise discrimination. The sensitivity of the described method allows for monitoring of WBC depletion procedures with greater efficiency than is currently available commercially.     

Validation of a simple method to count very low white cell concentrations in filtered red cells or platelets

The increased performance of white cell (WBC) filters makes it difficult to count precisely the number of residual WBCs. Concentrations as low as 0.01 WBC per microL cannot be determined with electronic cell counters, conventional hemocytometers, or the flow cytometric techniques currently being used. This article describes a simple, manual method using a Nageotte hemocytometer with a large-volume chamber (50 microL) to count the number of WBCs contained in red cell (RBC) suspensions (preparations A, B, and C) and in platelet suspensions (preparation D) diluted 1 in 10 pure, or concentrated two fold. To validate the method, several reference ranges, prepared by successively adding mononuclear cells to a suspension of pure RBCs or platelets, were used. Among the different series, validation ranges varied from 0.2 to 12 to 0.01 to 0.5 WBCs per microL and correlation coefficients ranged from 0.929 to 0.996. To determine the limit of accurate detection, accuracy tests (n = 160) were carried out by two experienced operators on samples with WBC concentrations of about 5, 10, and 120 times the concentration at the theoretical limit of detection (1 WBC/chamber). No significant difference was observed in the various types of preparations (A, B, C, D) in the tests performed by the two operators. However, intra-assay coefficients of variation were 18, 9.5, and 2.2 percent, respectively, at WBC concentrations of 5, 10, and 120 times that at the theoretical limit of detection. These observations show that a limit of accurate detection (10%) seems to be reached when 10 cells are observed in a Nageotte hemocytometer.(ABSTRACT TRUNCATED AT 250 WORDS)     

A flow cytometric method for determination of white cell subpopulations in filtered red cells

A flow cytometric method for the detection of low amounts of lymphocytes, monocytes, and granulocytes in filtered red cells (RBCs) was evaluated. In this procedure, the RBCs in the samples were lysed by ammonium chloride treatment and the white cells (WBCs) were detected by flow cytometry according to their specific light-scattering properties. The identity of the WBC subpopulations was confirmed by immunofluorescence with monoclonal antibodies specific for each cell type. Flow cytometric determination of WBCs in filtered RBCs correlated with numbers obtained by both a hemocytometer (r = 0.76) and a radioimmunoassay (r = 0.79). Total numbers of WBCs in RBCs measured by flow cytometry were 59 +/- 13 percent (n = 7) of those measured by electronic particle counting, 32 +/- 6 percent (n = 25) by hemocytometer, and 48 +/- 11 percent (n = 29) by radioimmunoassay. Lymphocytes added to filtered RBCs in a concentration of 1.37 cells per microL were detected at an average of 0.56 +/- 0.22 cells per microL (n = 3). Results with monoclonal antibodies indicated an altered expression of membrane markers on granulocytes after RBC filtration, as seen with cell activation. The inefficiency of the flow cytometric method to detect the total number of WBCs calculated by other methods may reflect filtration-induced changes in light-scattering properties of the WBCs. Although the method described does not accurately quantitate the total numbers of WBCs present in filtered RBCs, it may provide useful information on qualitative aspects of WBC subpopulations.     

Quality control of white cell-reduced red cells: white cell preservation and simplified counting

BACKGROUND: White cell (WBC) degradation restricts the interval between the filtration process and the assay for residual WBCs. Maintaining WBC integrity would permit extended sample storage for batching and/or shipment to centralized laboratories. The usual quality control assay for WBC-reduced red cell units requires determining the number of WBCs in the entire counting area of a Nageotte hemocytometer, which consists of 40 rows. Reducing the counting area would simplify the quality control procedure. STUDY DESIGN AND METHODS: Adsol red cell units were prepared either on the day of collection (Day 0) or on Day 1 and WBC reduced by filtration on the same day. By using prefiltration and postfiltration red cells, samples containing WBC concentrations of 15, 10, and 3 WBCs per microL were prepared by serial dilution. Identical samples were treated with glutaraldehyde and stored at either 20 to 24 degrees C or 1 to 6 degrees C. All samples were assayed on the day of component preparation and on Days 7 and 14. The numbers of WBCs corresponding to 10- and 40-row areas of the Nageotte hemocytometer were determined. RESULTS: For the conditions and WBC concentration range studied, no significant changes in WBC concentrations were observed through Day 14 for glutaraldehyde-treated samples stored at either temperature, although there were substantial decreases in untreated samples. A 10-row measurement was determined to be sufficient for identifying WBC-reduced red cell units passing the present limit of 5 × 10(6) residual WBCs. CONCLUSION: Glutaraldehyde treatment can preserve WBCs in red cell samples at least up to Day 14, which provides increased efficiency in quality control for laboratories. Current red cell WBC-reduction filters produce components that, when assayed, contain fewer than 10 WBCs per full counting area. The simplified procedure would allow reduction of the counting area by 75 percent.     

Validation of use of the Nageotte hemocytometer to count low levels of white cells in white cell-reduced platelet components

BACKGROUND: Determination of the white cell (WBC) count in WBC-reduced platelet components requires methods that have a detection limit in the range of approximately 5.0 × 10(2) to 5.0 × 10(4) per mL. STUDY DESIGN AND METHODS: With a 50-microL Nageotte hemocytometer and bright-field microscopy (200x magnification), studies were conducted to develop and validate a method that could be used routinely with filtered and apheresis-harvested platelets. A 1-in-5 dilution of sample with a commercially available blood-diluting fluid was used because, with a lower (1-in-2) dilution, the observed number of WBCs was substantially less than the number expected at relatively high platelet counts (> 1.9 × 10(9)/mL). RESULTS: The observed and expected WBC counts in WBC- reduced platelet samples correlated well at levels between approximately 5 and 1100 WBCs per counting area (5.0 × 10(2)-1.1 × 10(5)/mL). At levels of more than 300 to 400 WBCs per counting area, accurate counts were obtained when 10 of the 40 rectangles were counted. CONCLUSION: These studies provide data to confirm that the 50- microL Nageotte hemocytometer can be used to accurately count low levels of WBCs in platelet components.     

Comparison of CD34+ cell collection on the CS-3000+ and Amicus blood cell separators

BACKGROUND: Mobilized PBPCs, detectable on the basis of CD34 expression, can be collected on various cell separators. The CD34+ cell collection efficiencies of two cell separators (CS-3000+ and Amicus, Baxter) were tested on two comparable groups of oncology patients. STUDY DESIGN AND METHODS: Leukapheresis assisted by the standard manufacturer's software and variables settings was performed in 37 (CS-3000+) and 34 (Amicus) patients (total of 83 and 67 collections, respectively) after chemotherapy plus G-CSF treatment. RESULTS: The total CD34+ cell count per leukapheresis components as well as per kg of patient's body weight were twofold higher by using the Amicus than the CS-3000+ device. Platelet contamination in Amicus components was twice as low compared to the CS3000+. Mean Amicus CD34+ collection efficiency (CD34+eff) (54.9 +/- 27.2%) was significantly higher (p < 0.015) than the CS-3000+ (46.4 +/- 16.7%) one. However, Amicus CD34+eff decreased progressively as the peripheral blood CD34+ concentrations increases over 200 CD34+ cells per microL. A parallel increase in the WBC counts in these cases seems to be the principal cause of decrease in CD34+eff (evident for WBCs >40 x 10(3)/microL and most pronounced for WBCs >60 x 10(3)/microL). CONCLUSIONS: Mean CD34+eff and CD34+ cell yields were better on Amicus than on CS-3000+. CD34+eff of Amicus, however, seems to be related to the initial WBC counts, decreasing progressively when WBC increased over 4 x 10(3) per microL that coincided with the increase in CD34+ cell concentrations. For these cases, the volume and duration of cycles should be adapted to optimize CD34+ collections by using Amicus separators.     

Sampling errors and the precision associated with counting very low numbers of white cells in blood components

Attention to the accurate and precise measurement of the white cell (WBC) content of transfused products has risen in response to awareness of the potential benefits of WBC-depleted components and the development of technical capabilities to produce these components. The techniques thus far reported have focused on the reliability of detecting a WBC, provided it is present in the test system. The likelihood of selecting a WBC from the product of interest for counting in the analytical system--that is, the sampling error--must also be considered. The occurrence of a WBC in a WBC-depleted component is a rare event and may be modeled with the binomial or the Poisson distribution. Several assay techniques were analyzed by using these distribution models to determine the confidence intervals of the WBC content. The 95-percent confidence intervals spanned more than 2 logs10 for some methods at 3 x 10(5) WBCs per product. It is concluded that the reporting of WBC content for research provides not only the estimate of the mean but also a confidence interval for this estimate. Quality control procedures should be designed to verify that the WBC content is less than the targeted amount and should provide an associated statement of confidence.     

Quantitation of white cell subpopulations by polymerase chain reaction using frozen whole-blood samples. Viral Activation Transfusion Study

BACKGROUND: Previous methods for processing whole blood (WB) for nucleic acid analyses of white cells (WBCs) required fresh blood samples. A simple protocol that involves the freezing of WB for quantitative polymerase chain reaction (PCR) analyses was evaluated. STUDY DESIGN AND METHODS: Controlled studies were conducted in which paired fresh and frozen WB preparations were analyzed. The integrity of WBCs in the frozen WB samples was first assessed by flow cytometry using CD45 fluorescence, and calibration beads to quantitate recovery of WBC subsets. PCR of an HLA-DQ-A sequence was used to quantitate residual WBCs in a double-filtered red cell (RBC) component spiked with serial dilutions of WBCs, as well as in 51 filtered RBCs and 19 filtered platelet concentrates. Y-chromosome-specific PCR was used to quantitate male WBCs in five female WB samples spiked with serial dilutions of male WBCs and in serially collected frozen WB samples from four females transfused with male blood components. RESULTS: By flow cytometry, all major WBC subpopulations in frozen-thawed WB were quantitatively recovered and immunologically intact, although they were nonviable. HLA-DQ-A PCR quantitation of a dilution series from 8 to 16,700 per mL of WBCs spiked into double-filtered RBCs showed linear correlation of the results with both fresh and frozen preparations of the expected WBC concentrations (r2 = 0.98, p<0.0001 for both), without significant difference between observed and expected values (p>0.05). Y- chromosome-specific PCR results in female WB samples spiked with male WBCs were not significantly different in fresh and frozen preparations over a 3 log10 range of male cells. The results of WBC survival studies on frozen WB samples were consistent with previous observations in fresh blood samples. CONCLUSION: Direct freezing of WB enables subsequent recovery of WBCs for quantitative PCR analyses, with results comparable to those of fresh preparations. This protocol should facilitate wider implementation of nucleic acid-based analyses for quality control of WBC-reduced components, as well as for prospective clinical studies of microchimerism in transfusion and transplant recipients.     

Preparation of white cell-reduced platelet concentrates from whole blood during component preparation

This article introduces a new method of component preparation that is capable of producing white cell (WBC)-reduced platelet concentrates (PCs) from whole blood. Whole blood is separated into packed red cells (RBCs) and platelet-rich plasma (PRP) by centrifugation, and the PRP is expressed through a newly designed WBC removal filter into the platelet storage bag. The filtered PRP is then centrifuged and yields WBC-reduced PCs and plasma for freezing as fresh-frozen plasma (FFP). The method uses standard triple-pack blood bags and centrifugation protocols. Fifteen WBC-reduced PCs prepared with this technique had an average volume of 56.7 mL, an average Day 5 platelet content of 8.6 x 10(10) per unit, and an average Day 5 WBC content of 0.83 +/- 0.7 x 10(4) per unit (0.14 WBCs/microL). This represents WBC removal equal to at least 99.9 percent (3 log10) of the WBCs found in standard PCs prepared in our laboratory by an identical centrifugation protocol. Paired studies documented a 4.5-percent platelet loss by filtration. Filtration had no effect on the plasma prepared for FFP as measured by prothrombin time; activated partial thromboplastin time; factors I, V, VIII:C, and VIII:von Willebrand factor; antithrombin-III; albumin; globulin; or total protein. This method holds promise as a simple and highly effective technique for the production of WBC-reduced PCs by filtration during component preparation.     

A multicenter study evaluating three methods for counting residual WBCs in WBC-reduced blood components: Nageotte hemocytometry, flow cytometry, and microfluorometry

BACKGROUND: A multicenter study was conducted to evaluate the performance characteristics of flow cytometry and microfluorimetry for counting low concentrations of WBCs and to compare the results with Nageotte hemocytometry. STUDY DESIGN AND METHODS: A two-phase study involving 10 centers located in the United States and in Europe was performed. Coded samples of RBCs and platelets were distributed by 24-hour (Phase 1) or 2-day (Phase 2) courier service to each test site for analysis. Samples were prepared to include concentrations of WBCs slightly above and below the concentration corresponding to the threshold standards for WBC-reduced RBCs and platelets. All centers tested samples by Nageotte hemocytometry plus one or both of two automated methods. RESULTS: Both flow cytometry and microfluorometry gave better results than Nageotte hemocytometry in testing freshly prepared samples. At WBC concentrations >5 per microL (RBCs) or >3 per microL (platelets), the intersite CV was <20 percent for the automated methods but >30 percent for the Nageotte hemocytometer method (p<0.001). Accuracy was greater for the automated methods than for the Nageotte hemocytometer method (p<0. 001). Nageotte hemocytometry showed a bias to underestimation relative to the results obtained with the automated methods. All methods had poorer performance in testing samples that required > or =2 days' shipment than in testing of those requiring overnight shipment. CONCLUSION: Automated methods for counting residual donor WBCs in WBC-reduced cellular components offer advantages of improved precision and greater accuracy than are seen with the Nageotte hemocytometer method. Automated methods are less labor-intensive but more costly than microscopic methods. Preparation and shipping methods will need further refinement for samples to be counted more than 24 hours after sample collection.