Affiliations of authors: U. Guller, Dept. of Surgery, University of Basel, Basel, Switzerland and Department of Surgery, Duke University Medical Center, Durham, NC; E. Nitzsche, Department of Radiology, Institute of Nuclear Medicine, University of Basel, Basel, Switzerland; H. Moch, Institute of Pathology, University of Basel, Basel, Switzerland; M. Zuber, Department of Surgery, Kantonsspital Olten, Olten, Switzerland.
Correspondence to: Markus Zuber, M.D., Dept. of Surgery, Kantonsspital Olten, CH-4600 Olten, Switzerland (e-mail: mzuber_ol{at}spital.ktso.ch).
Breast cancer is the most common malignancy among women, leading to approximately 45 000 deaths per annum in the United States (1). The presence of axillary lymph node metastases has major prognostic implications in breast cancer patients (2,3), and it is an important criterion in determining the need for adjuvant chemotherapy (4). Sentinel lymph node (SLN) biopsy has become routine practice in the surgical treatment of patients with breast cancer because the disease status of the SLNs accurately reflects the status of the remaining axillary lymph nodes (57). Hence, patients who present with a negative SLN (no metastases) can be spared from having a more traumatic axillary lymph node dissection (ALND), which has been shown to be associated with substantial short- and long-term sequelae (8,9). Despite the enormous advantages of SLN biopsy over ALND in regard to post-operative complications in node-negative patients, it would be of great clinical benefit if a reliable non-invasive method to assess lymph node status in breast cancer patients could be found.
Positron emission tomography (PET) reflects the biochemical and physiologic processes occurring in the tissues being imaged and has been used in diagnosing a variety of malignancies (10, 11). The most frequently used positron emitting radiopharmaceutical is 18-fluor labeled 2-deoxy-D-glucose (18F-FDG), a radioactively labeled glucose analog. The clinical use of 18F-FDGPET is based on the premise that cancer cells exhibit a higher glycolytic rate than do non-neoplastic cells. Thus, 18F-FDG accumulates predominantly in the tumor tissue and can be visualized by a PET camera. Since the first reported visualization of lymph node metastases with 18F-FDGPET in a preclinical animal study in 1990 (12), several investigations (1319) have assessed the accuracy of PET in evaluating the nodal status of patients with breast cancer. These investigations have yielded conflicting results, with some investigators doubting that 18F-FDGPET is capable of accurately assessing the nodal status of breast cancer patients (1316) and others believing that a noninvasive PET scan could replace SLN biopsy at predicting the disease status of the axillary lymph nodes (1719).
In a recent investigation by an Italian group (18), pre-operative 18F-FDGPET was compared with the histologic findings of ALND in 167 clinically node-negative T1 (tumor size 2cm) and T2 (tumor size >2cm to
5cm) breast cancer patients, the largest patient collective published. 18F-FDGPET detected 68 of 72 patients with axillary metastases, resulting in an overall sensitivity for PET of 94%. In the subset of T2 patients, the sensitivity was even higher (98%; 48/49), with only one false-negative finding. Based on these results, the authors claimed that 18F-FDGPET can safely predict axillary lymph node status in patients with breast cancer and is a reliable and accurate method to identify patients who can avoid ALND. In the second largest published patient collective (19), pre-operative 18F-FDGPET was compared with the histologic findings of ALND in 124 pT1T3 (T3 tumor size >5cm) breast cancer patients. PET scanning correctly identified all 44 patients with axillary lymph node metastases, resulting in an overall sensitivity for PET of 100%. These findings led the investigators of that study to suggest that 18F-FDGPET should be considered as the initial test in evaluating axillary lymph nodes in breast cancer patients and that those patients without increased axillary 18F-FDG-uptake may not require ALND. Other investigations (17,2023) with smaller patient numbers have reported similar findings, with sensitivities of pre-operative 18F-FDGPET at detecting axillary lymph-node metastases ranging from 90% to 100%.
In contrast to the above-mentioned investigations, several studies have found that 18F-FDGPET has a low sensitivity at detecting SLN or axillary lymph node metastases. Indeed, Avril et al. (14) suggest that 18F-FDGPET scanning cannot substitute for histologic analyses of axillary lymph nodes. Their study compared the diagnostic potential of 18F-FDGPET with ALND in 41 breast cancer patients and reported an overall sensitivity for PET of 79% (19/24). PET sensitivity in the subset of patients with pT1 tumors was, however, only 33%; four of six patients had false-negative results, and the largest metastasis undetected by 18F-FDGPET measured 12 mm in diameter. Kelemen et al. (15) also found low PET sensitivity when they compared 18F-FDGPET scanning with the histolopathologic findings of SLN biopsies in clinically node-negative T1 and T2 breast cancer patients. If the SLN biopsies were negative by hematoxylin and eosin (H&E) staining, further biopsy sections were obtained for immunohistochemical (IHC) analyses using polyclonal anticytokeratin (CK) antibodies. Four of five patients with SLN metastases had false-negative 18F-FDGPET scans (i.e., 18F-FDGPET sensitivity was only 20%), and the missed metastases ranged from a micro-metastasis (defined as a cohesive cluster of malignant cells >0.2 mm to 2.0 mm in diameter), which was identified by IHC only, to macro-metastases up to 11 mm in diameter. Furthermore, a Canadian study (24) also found low PET sensitivity when evaluating the accuracy of 18F-FDGPET at detecting axillary lymph node metastases in 41 T13 breast cancer patients. All patients underwent pre-operative 18F-FDGPET scan, SLN biopsy, and ALND. The SLN was examined using serial sectioning and IHC using a monoclonal anti-CK antibody (CAM 5.2 clone) in addition to standard H&E staining. They reported that 18F-FDGPET was unable to identify SLNs that were found to be node positive by IHC only and that PET had a sensitivity of 27% at detecting axillary lymph node metastases.
We found similar PET sensitivity results in our own investigation (13), in which we compared pre-operative 18F-FDGPET with the histopathologic analysis of SLN biopsies in 31 clinically node-negative pT1 and pT2 breast cancer patients. SLNs were analyzed by standard H&E staining, IHC (anti-CK antibody cocktail CK22 and monoclonal anti-CK antibody Lu-5), and step sectioning. The step sectioning technique examines adjacent serial sections of the SLN, which are cut at different intervals, making them different thicknesses. Each SLN was analyzed intra-operatively, and lymph nodes that were more than or equal to 5 mm in diameter were bisected along their longitudinal axis into sections of 34 mm and snap frozen. The SLNs were intra-operatively examined at three levels with H&E stained sections (cutting interval of 150 µm). If no metastases were diagnosed in the frozen sections, the remaining tissue of the lymph node was formalin-fixed and embedded in paraffin for histologic analysis. This residual tissue was then examined using serial sectioning (cutting interval of 150 µm; at least six levels), and the permanent H&E stained slides were screened for tumor cells. Of the 14 patients with SLN metastases, eight had false-negative results by 18F-FDGPET scan, including three patients with macro-metastases (4 mm, 4 mm, and 13 mm, respectively), two patients with micro-metastases (0.8 mm and 1 mm, respectively), and three patients with sub-micro-metastases that remained unidentified. Hence, 18F-FDGPET had an overall sensitivity of detecting SLN metastases of 43% (6/14).
A study from The Netherlands (16) that evaluated 70 patients with predominantly early-stage breast cancer who underwent 18F-FDGPET followed by SLN biopsy and/or ALND has confirmed our finding of low PET sensitivity in detecting axillary lymph node metastases. If the first slice of the SLN was negative for the presence of metastases, an additional four to six sections were examined by H&E staining and IHC (using monoclonal anti-CK antibody CAM5.2). For patients undergoing ALND, up to two slices per lymph node were examined by IHC. The overall sensitivity of 18F-FDGPET at detecting lymph node metastases was 25% (8/32), and sensitivity was dependent on the tumor load in the axilla and the 18F-FDG avidity of the primary tumor. The authors also found that 18F-FDGPET was unreliable in the detection of axillary lymph node micro-metastases, regardless of the 18F-FDG avidity of the primary tumor.
Our investigation (13) as well as other studies (2,16,2527) indicate that the percentage of detected metastases in lymph nodes increases when using step sectioning and IHC as compared with standard pathology protocols. Most institutions make only one H&E-stained slice from each node obtained from an ALND, or they divide the node in half along its longitudinal axis and make one section from each tissue slice. In addition, serial or step sectioning of lymph nodes is usually not required as a standard procedure. In response to the false-negative rates associated with the SLN biopsy procedure, new pathology protocols have emerged, including intra-operative serial frozen sections, cytokeratin IHC, and molecular biology techniques such as reverse transcription polymerase chain reaction. IHC and step sectioning techniques are particularly useful in the detection of small tumor infiltrates (i.e., micro-metastases), which often remain undetected using standard histopathologic analyses. Although large retrospective studies (2) have shown disease-free and overall survival disadvantages for breast cancer patients with micro-metastases, therapeutic consequences and the prognostic importance of micro-metastases remain a matter of scientific debate. It should be emphasized, however, that both micro- and small macro-metastases cannot be identified by PET scanning, because their diameters (i.e., <3 mm) are below the current spatial resolution of PET imaging, which is currently reported to be between 3 mm and 10 mm (2830). Hence, investigations comparing pre-operative 18F-FDGPET with standard histologic analyses of ALND could miss micro-metastases and small macro-metastases by both histologic analysis and PET scanning. Thus, patients with small tumor infiltrates that are undetectable by PET scan (i.e., false-negatives) might be wrongly classified as "true-negatives" by histologic analysis, resulting in incorrectly high sensitivities for PET scanning.
Although step sectioning and IHC would increase the rate of detection of small tumor infiltrates in axillary lymph nodes, the systematic use of these techniques is not feasible in the assessment of ALND specimens because these procedures are prohibitively time consuming and costly (2). In contrast, SLN biopsy offers the advantage that these techniques can be applied on a small number of lymph nodes. Interestingly, all four reported studies (13,15,16,24) that compared 18F-FDGPET with histopathologic analyses of axillary lymph nodes yielded poor sensitivities for PET at detecting metastases (20%43%, Table 1). The use of step sectioning and IHC in our investigation (13) allowed the detection of sub-micro-metastases, all micro-metastases, and one macro-metastasis, all of which were undetected in the intra-operative frozen section analysis and in the initial H&E staining. The failure to detect tiny metastatic foci in large lymph nodes represents a limitation of the frozen section technique used in standard pathology protocols. Indeed, in our study (13), the sensitivity of 18F-FDGPET at detecting sentinel lymph node metastases, which was initially 88% using standard H&E staining only, dropped to 43% after step sectioning and IHC were also used. It should be emphasized that none of the studies (1719) that suggest that 18F-FDGPET is a reliable and non-invasive alternative to ALND/SLN biopsy used techniques that would allow the detection of small metastases. Therefore, it is reasonable to assume that the reported values for sensitivities of 18F-FDGPET in those studiesmost of them close to 100%are overly optimistic and do not accurately reflect the limitations of this diagnostic tool. Therefore, it might be misleading to report the diagnostic potential of 18F-FDGPET without systematically performing histologic analyses that allow the detection of small tumor infiltrates.
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In summary, based on the present literature (1416) and on own experience (13), we suggest that PET scanning does not currently have the adequate spatial resolution to detect both micro- and small macro-metastatic disease in axillary lymph nodes of patients with breast cancer. Therefore, PET scanning cannot serve at this time as a non-invasive alternative to SLN biopsy. It is possible, however, that with the advent of new detector materials in clinical practice (e.g., lithium, silicon, curved crystals), the sensitivity of 18F-FDGPET will further improve (35) and could eventually replace invasive procedures in the evaluation of the nodal status of patients with breast cancer.
NOTES
We thank the Swiss National Foundation, Bern/Switzerland, Krebsliga beider Basel, Basel/Switzerland, Freiwillige Akademische Gesellschaft, Basel/Switzerland, and Fondazione Gustav und Ruth Jacob, Aranno/Switzerland for their financial support of Dr. Gullers research fellowship. We also thank Mr. Jonathan McCall for carefully reading the manuscript and making many valuable suggestions.
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Manuscript received November 7, 2002; revised April 25, 2003; accepted May 12, 2003.
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