Reliability of sentinel node status in predicting axillary lymph node involvement in breast cancer

However, axillary lymph node dissection is not without morbidity: seroma formation, wound infection, damage to nerves, and reduced shoulder mobility. Of particular importance is lymphoedema, which occurs in 15% and 30% of women.^5-8 As a consequence, other, less invasive methods of assessing axillary node status have been investigated (eg, mammography, ultrasound and colour doppler imaging, magnetic resonance imaging [MRI] and positron emission tomography [PET] scanning), but have yet to achieve the accuracy of surgical staging.

Axillary node sampling -- removal of a small number of Level 1 nodes (those below the lower border of the pectoralis minor muscle) -- is associated with fewer complications, and has been proposed as an alternative to complete axillary dissection for staging of the axilla.^9,10 However, its efficacy has been questioned.¹¹

With the advent of population-based mammographic screening programs, there has been a dramatic decrease in tumour size and lymph node involvement in women diagnosed with early breast cancer.^12,13 Thus, an increasing proportion of women will undergo axillary dissection only to find that their lymph glands are free of disease. Ideally, there should be a method of providing accurate assessment of axillary lymph node status without the need for axillary dissection.

The sentinel lymph node (the first draining node within a lymph node basin) is the first to receive lymphatic drainage from a tumour site. Selective biopsy of this node allows the detection of metastases in clinically normal nodes with a low false negative rate, and has been used in patients with operable breast cancer by several groups.^14-19 Their findings indicate that the status of the sentinel node(s) can accurately predict that of the fully dissected axilla. We report our experience of lymphoscintigraphy, intraoperative sentinel node mapping and sentinel node biopsy in 117 women with primary operable breast cancer. Our aims were:

• To assess the success rate of lymphoscintigraphy and intraoperative lymph node mapping in identifying the sentinel node; and

• To assess the accuracy of sentinel node biopsy in staging the axillary nodes.

Eligibility criteria were:

• Operable primary breast cancer (tumour, < 5 cm in diameter), detected clinically and by imaging, and confirmed by cytology, core biopsy or open biopsy;

• Clinically impalpable axillary lymph nodes; and

• The usual surgical indications for axillary dissection (ie, invasive, operable cancer).

Patients were excluded if their condition did not fulfil these criteria; if they were pregnant or currently breastfeeding; if there was a high clinical suspicion or preoperative verification of axillary nodal involvement; or if they had metastatic breast carcinoma or a preoperative diagnosis of ductal carcinoma-in-situ.

The women's ages ranged from 31 to 82 years (median, 60 years). Their clinical characteristics are summarised in Table 1. During the period of study, no eligible women refused entry to the study.

The intraoperative probe (RMD CTC 4 with audible guidance system, Gammasonics, Melbourne) was calibrated in the Nuclear Medicine Department to the counts detected at the skin surface.

At operation, a 2-cm transverse axillary incision was made in accordance with the planned axillary lymph node dissection, but taking into account the preoperative skin markings indicating the location of the sentinel node at lymphoscintigraphy. An attempt was made to identify the node in vivo before commencement of axillary dissection. The node was identified by its blue colour (if dye was used) and/or by the hand-held gamma probe (in a sterile sheath). The probe enabled detection of individual nodes with radioactivity levels significantly greater than those of the axillary fat (Figure 2). Sometimes more than one sentinel node was identified. If both dye and radioisotope were used for lymphatic mapping, the blue node corresponded to the most radioactive node.

Once the sentinel node was removed, its activity was reassessed ex vivo and it was sent for histological examination separately from the main axillary nodal specimen. The axillary fat was then examined with the gamma probe in vivo to exclude any residual activity suggesting further sentinel nodes. The axillary skin incision was then lengthened and a level I and II axillary lymph node dissection was performed. The resected axillary tissue was examined ex vivo using the probe to identify any further radioactive or blue lymph nodes not identified during in-vivo examination.

The axillary fat was fixed in formalin and the nodes were later isolated from the fat after clearance in Carnoy's solution. Each node was placed in an individual cassette and larger nodes were sliced before being embedded in paraffin. At least one H&E-stained section of each node was examined.

Our results confirm that the status of the sentinel lymph node(s) predicts the overall axillary lymph node status with a high degree of accuracy, and can thus be used to limit the morbidity associated with axillary surgery. More importantly, the predictive value of a tumour-free sentinel node was 97%. As such, women identified with a sentinel node free of metastatic tumour can be reassured that further axillary lymph node involvement is highly unlikely. Other studies of sentinel node biopsy in breast cancer (using blue dye and radioactive isotope techniques) have shown sentinel node status to accurately determine axillary lymph node status in more than 95% of women.^14-19

We still need to deal with the problem that 3% of patients exhibited tumour-positive axillary nodes when the biopsied sentinel node was negative. The optimal method of pathological assessment of the sentinel node remains unresolved and was not addressed in our study. This issue was discussed at the Adelaide Workshop on Sentinel Node Biopsy in Breast Cancer²⁷ and is the subject of further studies by one of us (G F). Giuliano et al²⁸ have found that immunohistochemical studies of sentinel nodes showed micrometastases in an additional 11% of women whose sentinel node was tumour negative on light microscopy. However, similar assessment of two women with false negative results in our study did not reveal metastases.

The implications of micrometastases detected by sensitive immunohistochemical and polymerase chain reaction (PCR) techniques for multidisciplinary care are unknown. They are currently being investigated in trials in the United States (Merrick Ross, Associate Professor of Surgical Oncology, M D Anderson Hospital, Texas, USA, personal communication). Until the answers to this question are available, a large UK trial (ALMANAC) is assessing sentinel node status by conventional microscopy (R Mansell, Professor of Surgery, Cardiff University, UK, personal communication), as this is the current method on which treatment planning is based. These uncertainties emphasise the need for Australian studies to incorporate detailed protocols for pathology assessment of the sentinel node. The prognostic implications of a false negative sentinel node are uncertain, but should be compared with the considerable physical morbidity associated with axillary dissection in lymph node negative women. There is a definite error rate in routine pathological assessment of axillary dissection specimens which may underestimate metastatic disease by 11%-30%,^27,29 while unselective sampling of the axilla fails to remove involved nodes in many women.¹¹ The false negative rate must ultimately be minimised by maximal detection of the sentinel node by scintigraphy, careful operative technique and optimal pathological assessment, which requires an experienced multidisciplinary team.

The concomitant intraoperative use of both blue dye and radionuclide methods for lymphatic mapping was particularly useful for sentinel node biopsy. Preoperative lymphoscintigraphy permits identification of the sentinel node and subsequent planning of the site of skin incision. Several radiolabelled colloids are currently in use around the world, but the recent workshop in Adelaide²⁷ identified antimony colloids as having excellent properties for lymphoscintigraphy. This is the only agent available for this purpose in Australia and is able to visualise sentinel nodes in the internal mammary chain as well as in the axillary node group. The blue dye technique facilitated visualisation of the sentinel node at the time of surgery and was supplemented by the use of an intraoperative gamma probe. In all patients in whom both blue dye and radionuclide were used, the blue node corresponded to the "hot" node previously identified on lymphoscintigraphy and identified intraoperatively with the hand-held gamma probe. Furthermore, the identification of a sentinel node at preoperative lymphoscintigraphy was the only factor significantly associated with the intraoperative identification of the sentinel node. Lymphoscintigraphy also demonstrates the number and location of potential sentinel nodes requiring biopsy. The initial rate of preoperative identification of the sentinel node by lymphoscintigraphy in our series was lower than that in published reports. However, this was overcome by increasing the volume of the isotope injection and presumably increasing tissue oncotic pressure, lymphatic uptake and drainage. The importance of isotope volume in achieving successful scintigraphic identification of the sentinel node has also been suggested by others.³⁰

Sentinel lymph node mapping and biopsy are likely to be incorporated into clinical practice, provided they can be successfully performed in most patients, and it can be shown that women with negative sentinel nodes who undergo no further treatment to the axilla are not adversely compromised in terms of disease-free and overall survival. This will be best established by randomised controlled studies comparing sentinel node biopsy with standard axillary surgical management. In addition, these studies should address the implied assumption of lower short and long term morbidity associated with this procedure, the optimal methods of pathological assessment, and allow analysis and comparison with clinicopathological variables in predicting sentinel node status. Studies are currently being undertaken in Europe, the United Kingdom and the United States and it is hoped that Australian women can soon participate in similar trials in Australia.

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Department of Tissue Pathology, Institute of Medical and Veterinary Science, Adelaide, SA.
Gelareh Farshid, MB BS, FRCPA, Senior Lecturer, University of Adelaide.

Reprints will not be available from the authors.
Correspondence: Associate Professor P G Gill, Breast-Endocrine Surgical Oncology Unit, Royal Adelaide Hospital, North Terrace, Adelaide, SA 5000.
cbatesbrownswordATmedicine.adelaide.edu.au