RAPID COMMUNICATION |
Standardization of the Immunocytochemical Detection of Neuroblastoma Cells in Bone Marrow
Department of Pediatric Hematology and Oncology, Ghent University Hospital, Ghent, Belgium (KS); Children's Cancer Research Institute, St. Anna Children's Hospital, Vienna, Austria (PFA,RL); Laboratory of Hematology, Institut Gustave Roussy, Villejuif, France (CB); Unidad de Oncología Pediátrica, Hospital Infantil La Fe, Valencia, Spain (JMFN); Pediatric Oncology Research, Pediatrics, University Hospital CHUV, Lausanne, Switzerland (NG); Histopathology Department, Great Ormond Street Hospital for Children, London, United Kingdom (DR); University of Cologne, Universitätskinderklinik, Cologne, Germany (RS-K); Servizio di Anatomia Patologica, Istituto G. Gaslini, Genoa, Italy (ARS); and Department of Pathology, Rikshospitalet, Oslo, Norway (KB)
Correspondence to: Katrien Swerts, Lab of Hematology (1P8 West), Ghent University Hospital, De Pintelaan 185, B-9000 Gent, Belgium. E-mail: Katrien.Swerts{at}UGent.be
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Summary |
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(J Histochem Cytochem 53:14331440, 2005)
Key Words: immunocytochemistry minimal residual disease neuroblastoma bone marrow
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Introduction |
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The demonstration of disseminated tumor cells in BM is important for clinical staging and risk assessment at diagnosis and for monitoring therapeutic response during treatment. In addition, screening of autologous stem cell preparations is crucial because the reinfusion of contaminated stem cell products could lead to systemic recurrence (Brenner et al. 1993; Deisseroth et al. 1994
; Rill et al. 1994
).
According to the International Neuroblastoma Staging System, conventional cytology of BM smears is still the only accepted technique for the detection of disseminated NB cells (Brodeur et al. 1988). However, the sensitivity of this approach is limited because a tumor cell number lower than 0.1% is virtually not detectable by conventional cytomorphology (Cheung et al. 1997
; Mehes et al. 2003
). Therefore, the development of more sensitive and specific detection methods is indispensable.
During the last few decades, several assays based on immunocytology (Cheung et al. 1986; Berthold et al. 1989
; Nagai et al. 1994
), automatic immunofluorescence plus fluorescence in situ hybridization (FISH) (AIPF) (Ambros et al. 2003
), RT-PCR (Burchill et al. 1995
; Miyajima et al. 1995
; Cheung et al. 1998
; Lo Piccolo et al. 2001
), or flow cytometry were evaluated (Komada et al. 1998
; Nagai et al. 2000
; Warzynski et al. 2002
; Swerts et al. 2004
). However, the reliability of tumor cell detection and quantification by these methods remains controversial.
A Neuroblastoma Bone Marrow Committee (NBMC) was established by the European Neuroblastoma Study Group to evaluate and standardize procedures for the detection of minimal residual disease (MRD) in NB patients. In connection with the evaluation of a new high-risk protocol by the SIOP European Neuroblastoma (SIOPEN) group, the NBMC developed, optimized, and standardized an immunocytochemical assay based on the detection of the neuroblastoma-specific GD2 disialoganglioside. In addition, morphological and immunocytological criteria for the interpretation of results were introduced and standardized. Four multicenter quality control (QC) rounds were organized among nine European research groups to evaluate the technique and assess the interobserver concordance. The latter improved markedly after the adoption of the standardized protocol.
This article describes a standardized immunocytochemical staining method and minimal morphological and immunocytological criteria for the evaluation of stained BM samples. The application of this protocol will lead to a more reproducible and reliable assessment of MRD in NB. We believe that a standardized method is needed to generate comparable results in multicenter studies evaluating the clinical significance of MRD.
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Materials and Methods |
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Control Samples
Slides containing cells from a NB cell line (e.g., IMR32) were included in every experiment as positive controls. For negative control, the primary anti-GD2 antibody was replaced with an antibody of the same IgG2a isotype (Dako Corporation; Glostrup, Denmark). This allowed us to evaluate the background staining caused by the interaction of the anti-GD2 antibody with Fc-receptorbearing leukocytes.
Isolation, Processing, and Storage of Mononuclear Cells
Mononuclear BM cells were isolated by density gradient centrifugation using Lymphoprep (Nycomed; Oslo, Norway) following the instructions of the manufacturer. Aspirates from different sites were processed separately. After separation, the mononuclear cells were collected from the interphase layer and washed twice in PBS (Gibco; Paisley, UK).
Large-diameter cytospins (17 mm) containing 5 x 105 mononuclear cells were prepared. These slides should not be overcrowded and the mononuclear cells must lie well separated from one another. This can be achieved by centrifuging no more than 7 x 105 cells down on precoated (e.g., poly-L-lysine) glass slides in a Hettich centrifuge (Hettich Zentrifugen; Tuttlingen, Germany).
The slides were air-dried overnight and stored in airtight plastic boxes or wrapped in aluminum foil at 24C until immunocytology was performed. Before staining, the slides were thawed in closed boxes to avoid formation of condensation water, because this could destroy the morphology of the cells.
Standardized Immunocytochemical Staining Protocol
The NBMC decided to standardize the fixation, the immunocytochemical staining procedure and the evaluation of immunocytological results to improve the sensitivity, specificity, and reproducibility of MRD detection in NB.
Fixation
The cytospins must be fixed in 4% buffered paraformaldehyde for 10 min. Commercially available formaldehyde can also be used, provided that it is free from methanol. To avoid artificial tumor cell contamination, slides must be incubated individually. After fixation, the cytospins were washed three times with PBS to remove remainders of the fixative.
Immunocytochemical Staining
The staining procedure comprised 10 subsequent steps. All incubations were performed in a humidifier at room temperature.
Evaluation of Immunocytochemically Stained Samples
The characteristics of GD2-positive disseminated NB cells and false-positive hematopoietic cells were examined in detail. The observations led to the following morphological and immunocytological guidelines for the identification of positive cells.
Morphological Criteria
Cells with a round nucleus, often, but not always, larger than that of small lymphocytes, displaying a granular chromatin structure and a scarce amount of cytoplasm were considered positive. Cells showing a low nuclear/cytoplasmic ratio or typical morphological features of hematopoietic cells were considered negative. Cells found outside or on the border of the cytospin field were excluded.
Immunocytological Criteria
Cells must display a strong, deep red staining localized to the entire cell membrane and cytoplasm. A weak staining and a staining restricted to a subcellular compartment or covering the nucleus was considered negative. In addition, cells surrounded by positively stained amorphous material were excluded.
Based on the morphological and immunocytological criteria, cells were classified into three groups:
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When evaluating or reporting immunocytochemical results, the work flow depicted in Figure 2 should be followed. No further review is needed when no GD2-positive cells or more than 10 CPCs are present. For samples with 110 CPCs or samples containing NCICs, central review by the members of the NBMC is obligatory. When no consensus is reached, the genetic profile of the doubtful cells should be checked by FISH to find out whether it corresponds to the cytogenetic aberrations found in the primary tumor. The sequential immunocytological staining and molecular cytogenetic characterization can be done using an automated scanning and relocation system (e.g., Metafer4/RCDetect; MetaSystems, Altlussheim, Germany) (Ambros et al. 2003). GD2-positive cells showing genetic aberrations (e.g., gain of whole chromosomes or 17q and MYCN amplification) are called FPCs (FISH-positive cells) (Figure 3).
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Results |
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Quality Control
Between 2001 and 2003, four multicenter QC rounds were organized among the nine members of the NBMC to develop and validate the staining protocol, the morphological and immunocytological criteria, and the work flow. A total of 111 QC samples were analyzed. Every research group sent preferably three slides from at least two different BM samples to every other member. The participants fixed and stained the cytospins independently of each other. They evaluated the samples unaware of any clinical information. Individual screening results were disclosed and the level of interobserver concordance was assessed during subsequent QC meetings. In addition, samples with discordant results were reviewed by all participants, resulting in an optimized staining protocol and refined morphological and immunocytological criteria. The results of quality control round 1 and 4 are shown in Table 1. Only samples analyzed by at least four participants were included in the study. Participants 18 used the immunocytochemical staining assay to evaluate the quality control samples. Participant 9 detected residual NB cells using automatic immunofluorescence plus FISH.
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Quality control round 4 was organized after the standardization of the staining method, the formulation of the criteria, and the design of the work flow. Thirteen samples were fixed, stained, and evaluated by each participant in a blinded way and, in accordance with the work flow, samples containing less than 10 CPCs or samples with NCICs were reviewed during a QC meeting. Because we noticed a remarkable improvement in the sensitivity and specificity of the method and in the reproducibility of the results after analyzing 13 samples, QC round 4 was terminated at that point. After central review, the results were concordant in 10 samples. Only in three samples (23%) were discordant results found. In these samples, the average difference between the highest and the lowest reported number of CPCs was 9. Discordant results were only found in samples with less than 10 CPCs per 1 x 106. The standardization of the assay led to a significant decrease in the number of discordant results (2 = 4.91, p=0.027, DF = 1). The range between the highest and the lowest reported number of positive cells decreased from 19 to 9.
The immunocytochemical results (participants 18) were also compared with those obtained with AIPF (participant 9). In QC round 1, 15 samples scored positive for the immunocytochemical assay, whereas no neuroblastoma cells were detected by AIPF. The discrepancies in four of these samples were probably from sample variability because only one or two immunocytochemistry positive cells were found. All other samples (11) were most likely false positive. In QC round 4, only one discordant result was found (8%). Participant 7 reported 8 CPCs, whereas no FPCs were detected by participant 9. These results prove that the standardization of the staining and evaluation procedures reduced the number of false positive results dramatically.
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Discussion |
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In connection with a phase III study organized by the SIOPEN group, the NBMC developed, optimized, and standardized an immunocytochemical assay based on the detection of the NB-specific GD2 disialoganglioside. This antigen is highly and consistently expressed in neuroectodermal tumors and is not found in normal BM or peripheral blood cells (Cheung et al. 1986; Wu et al. 1986
; Sariola et al. 1991
). Because all NB are believed to express GD2, the possibility of a false-negative result can usually be excluded. However, the uneven distribution of NB cells in the body may hamper the detection of disseminated tumor cells. To avoid false-negative results caused by sampling error, a sufficient number of cells must be analyzed. The Poisson distribution f(X) = µX x eµ/X! can be used to calculate the statistics of tumor cell detection (Cheung et al. 1986
). At least 3 x 106 cells must be analyzed to reach a 95% probability of detecting one tumor cell in 1 x 106 normal mononuclear cells.
Immunocytochemical results can also be obscured by false-positive events (Pantel et al. 1994; Borgen et al. 1998
; Mehes et al. 2001
). These can be caused by the active or passive uptake of the tumor cellderived GD2 ganglioside by hematopoietic cells. Furthermore, a very small subset of mature plasma cells producing antibodies against alkaline phosphatase can be false positive because they react directly with the enzyme (Borgen et al. 1998
). Finally, the illegitimate expression of the targeted antigen, the cross-reactivity of the applied monoclonal antibody, and interactions between antibodies and Fc-bearing leukocytes can give rise to false-positive results.
When the members of the NBMC stained their slides using different immunocytochemical staining methods and analyzed their results according to individual morphological criteria, considerable discrepancies were observed. The evaluation of stained samples by the whole group using a multiheaded microscope clearly demonstrated the urgent need for developing a standardized immunocytochemical staining protocol and introducing morphological and immunocytological criteria. Consequently, the NBMC agreed on one staining method and formulated morphological and immunocytological criteria for the interpretation of the results. Only cells with a round nucleus, often, but not always larger than that of small lymphocytes, a granular chromatin, and a limited amount of cytoplasm are considered positive. In addition, a strong, deep red staining localized to the entire cell membrane and cytoplasm must be present. To our knowledge, this is the first time that a standardized protocol including morphological and immunological criteria for the detection of NB cells in BM has been designed.
However, when applying these criteria, the NBMC discovered that a small proportion of immunocytochemically stained cells could not unequivocally be classified as positive (i.e., NB cells) because they did not fulfill all postulated morphological and immunocytological criteria. Therefore, it was decided to categorize all immunocytochemically stained cells into three groups: CPCs fulfilling all postulated criteria; NCICs displaying some but not all inclusion criteria; and NCs, which, in spite of their staining, were identified as nonmalignant hematopoietic cells.
Borgen et al. published a similar approach for the analysis of circulating carcinoma cells by applying the anti-cytokeratin antibodies AE1/AE3 and an alkaline phosphatasebased detection method on cytospins prepared from mononuclear BM cells (Borgen et al. 1999). They also categorized immunologically stained cells into three groups which they called tumor cells, probable tumor cells (?), and hematopoietic cells. To discriminate among these groups, they presented a catalog of pictures illustrating a large number of morphological and immunological variants of these categories. However, regarding the detection of NB cells using an anti-GD2 antibody, the members of the NBMC do not believe that it is feasible to cover all possible variants of immunocytochemically stained BM cells by means of illustrations. Therefore, the NBMC decided to introduce a workflow including two additional analytical steps (Figure 2). First, samples with 110 CPCs or samples containing NCICs are simultaneously reviewed by the members of the NBMC. Second, if no consensus is reached, the genetic profile of the doubtful cells is checked by automatic immunofluorescence plus FISH to disclose the identity of these cells. If the genetic aberrations in the doubtful cells correspond to those found in the primary tumor, the cells are called FPCs. Finally, the morphological and immunocytological features of these FPCs are carefully studied to refine the standardized evaluation criteria.
The standardized staining protocol, the morphological and immunocytological criteria, and the work flow were evaluated during four multicenter QC rounds, organized among the nine members of the NBMC. A total of 111 QC samples was analyzed. The concordance between the different observers, with regard to the staining and the evaluation of the immunocytochemical results, was assessed. After standardization, a significant decrease in the number of discordant results was reported. In addition, the range between the highest and the lowest reported result was reduced by half, and discordant results were only found in samples with less than 10 CPCs per 1 x 106 mononuclear cells.
Immunocytology has been used in the clinical practice of hematology and oncology for many years and has many advantages compared with flow cytometry or RT-PCR. In contrast to the latter, immunocytology allows the reliable quantification of tumor cells. This is important when the number of disseminated tumor cells appears to be prognostically important and not purely the presence or the absence of disease. The immunocytochemical technique is cost-effective and simple, and, because no expensive equipment is needed, immunocytological stainings can be performed in virtually every routine laboratory around the world.
This article describes the first international standardization of an immunocytochemical staining and evaluation method developed to detect and quantify small numbers of neuroblastoma cells in BM. The results of our QC rounds show that the standardization of the staining method, the formulation of morphological and immunocytological criteria and the design of the work flow resulted in a higher reproducibility, sensitivity, and specificity. Methodological standardization is indispensable and must be agreed on before multicenter studies, designed to assess the clinical importance of minimal residual disease, can be initiated.
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Acknowledgments |
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Footnotes |
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