Introduction
Perioperative therapy offers a number of potential benefits including the ability to counteract the possibly negative effects of surgery, the ability to give effective therapy early and a gain in prognostic and predictive information. There is evidence [Reference Tagliabue, Agresti and Carcangiu1] that surgery stimulates the growth of breast cancer cells and causes the release of cancer cells that may then be able to form metastases; perioperative therapy may inhibit these two processes. Secondly, trastuzumab is an effective therapy, which is often not given until after chemotherapy but could be used sooner, if given in the perioperative setting. Presurgical therapy also offers the opportunity to measure response to treatment in vivo, giving information on the effect of treatment on biomarkers such as proliferation, apoptosis and gene expression, yielding potentially valuable prognostic information. Short-term presurgical models have been advocated to evaluate endocrine resistance mechanisms [Reference Dowsett2] and are more generally applicable to other interventions. However, if they are used for this purpose, it is important to show that use of intervention does not disadvantage individual patients. Large randomised trials such as that carried out with neoadjuvant cytotoxic chemotherapy by National Surgical Adjuvant Breast and Bowel Project in trial B18 [Reference Bernard Fisher, Bryant and Wolmark3] are needed to address such issues. Resistance mechanisms can also be investigated by associating changes in biomarkers, which are responsive to the intervention, such as Ki67 or apoptosis, with the expression of putative determinants of resistance. For example, little change in Ki67 would be expected in ER (oestrogen receptor) negative patients in response to presurgical treatment with an aromatase inhibitor. The biology of novel treatments can therefore be studied using this method; a current example examines the biological effect of lapatinib in unselected patients in a presurgical randomised controlled trial known by the acronym MAPLE [Reference Johnston4].
A large, randomised, controlled trial of perioperative anti-HER2 therapy supported by Cancer Research UK is planned within the United Kingdom. EPHOS-B is a phase III, multicentred, three-arm, randomised controlled trial of perioperative anti-HER2 therapy in which HER2+ patients will be allocated in a 1 : 2 : 2 ratio to control, perioperative trastuzumab or perioperative lapatinib. Perioperative treatment will consist of 11 days (±1 day) preoperative treatment and a short course of postoperative treatment. It is anticipated that patients will receive further trastuzumab treatment after adjuvant chemotherapy. Centres may choose at their discretion whether to take into account that some patients have already received serveral weeks of peri-operative anti-HER2 therapy when prescribing their standard adjuvant trastuzumab. This is a trial with biological endpoints, undertaken to examine whether an 11-day treatment period is able to produce biological changes compatible with a treatment effect. EPHOS-B will determine the definitive design of the following larger clinical study, EPHOS-C, which will assess the therapeutic value of perioperative therapy. EPHOS is being coordinated by The Institute of Cancer Research Clinical Trials and Statistics Unit (ICR-CTSU) in collaboration with The University of Manchester. POETIC [Reference Smith5], a parallel trial of 2 weeks of aromatase inhibitor therapy in hormone receptor positive postmenopausal patients, is also being coordinated by ICR-CTSU. Evidence of the biological efficacy of short-term preoperative aromatase inhibitor treatment already exists; POETIC has therefore been initiated as a 4000-patient trial with both efficacy and the predictive/prognostic effects of biomarker changes as endpoints.
The importance of the effect of surgery on breast cancer cells is still a matter for debate. Evidence that surgery stimulates the growth of breast cancer cells has been provided by Tagliabue et al. [Reference Tagliabue, Agresti and Carcangiu1] who examined breast cancer cell proliferation (MIB-1) in paired primary and re-excision specimens removed within 48 days of surgery. They found that the latter showed a significant increase in proliferation if they were HER2+ but not if they were HER2− negative (Fig. 1). Forty-three tumours, comprising 86 samples, were retrieved from 32 patients, 24 of which were carcinoma in-situ and 19 invasive cancer. Overall, the median percentage change in MIB-1 was −2 (95% CI: −10 to 2) in HER2− tumours and 8 (95% CI: 4 to 16) in HER2+ tumours, P = 0.0007. In HER2+ tumours, the mean number of MIB-1-positive cells was found to increase from 16.2% (SD 11.7) to 26.3% (13.6), an increase in proliferation of approximately 50%. In addition, the difference between HER2− and HER2+ tumours was also individually significant in carcinoma in-situ and invasive cancer patients (P = 0.01 and P = 0.03 respectively). Fisher et al. [Reference Fisher, Saffer, Rudock, Coyle and Gunduz6,Reference Fisher and Mamounas7] demonstrated a similar phenomenon in a mouse model; implanted human cell proliferation was found to follow tumour removal, this proliferation was also prevented by preoperative therapy.
Figure 1 Changes in MIB-1 in 43 tumours from 32 patients obtained following re-excision for residual disease. The tumours were removed within 48 days of surgery. Adapted from Tagliabue et al., each line shows the MIB-1 change from baseline of a single patient.
The ability of disseminated cancer cells to establish metastases is also a matter of controversy. Choy and McCulloch [Reference Choy and McCulloch8] found that although tumour-cell shedding occurs during surgery on primary breast cancers, after surgery the released cells are cleared from the circulation. It has also been predicted by some authors that only one in every 10 000 cells succeeds in forming a metastasis [Reference Liotta and Stetler-Stevenson9]. Circulating tumour cells have to settle at a distant vascular bed, make their way through the vessel wall into the target organ parenchyma and then be able to grow. Whilst this is happening, the cells must evade the host immunological response and be able to survive possibly adverse metabolic conditions. Spread of tumours through the bloodstream is hence likely to be an inefficient process and most circulating cells may not possess the characteristics to establish metastatic disease, or are overcome by adverse host factors [Reference Ring, Smith and Dowsett10].
Perioperative anti-HER2 therapy
There are a number of outstanding questions regarding the use of anti-HER2 therapies in addition to the value of perioperative therapy. Little is known about the optimum use of lapatinib but more evidence exists about the use of trastuzumab from clinical trials. One issue concerning the use of trastuzumab that has not been resolved is the optimum duration of therapy. It was observed in the HERA trial [Reference Smith, Procter and Gelber11], for example, that 12 months of trastuzumab reduces the increased hazard rate seen in the untreated group during the first year, but has less effect beyond this point. A trial comparing observation with trastuzumab for 9 weeks found a 60% reduction in the event rate over a median follow-up of 36 months [Reference Joensuu, Kellokumpu-Lehtinen and Bono12]. The FinHer trial included 232 early breast cancer patients and a hazard ratio favouring trastuzumab of 0.42 (95% CI: 0.21 to 0.83; P = 0.01) was observed for recurrence or death in this study. A short duration perioperative course of trastuzumab may, therefore, offer a proportion of this benefit early in the primary treatment phase. There is also evidence [Reference Al-Hajj, Wicha, Benito-Hernandez, Morrison and Clarke13,Reference Spector, Xia and Burris14] that preoperative trastuzumab is effective in improving pathological complete response rates. A study designed to determine whether the addition of trastuzumab to neoadjuvant chemotherapy could increase pathologic complete response (pCR) rates in patients with HER2+ disease was terminated early due to an indication of a large benefit for the trastuzumab group [Reference Buzdar, Ibrahim and Francis15]. Patients were randomised to either four cycles of paclitaxel followed by four cycles of fluorouracil, epirubicin and cyclophosphamide or to the same chemotherapy with concurrent weekly trastuzumab for 24 weeks. The intended trial size was 164 patients but it was stopped when 42 patients had been entered, of which 26% in the chemotherapy arm achieved pCR compared with 65.2% in the trastuzumab plus chemotherapy arm (P = 0.016). A further unresolved issue regarding the use of trastuzumab is whether it should be started concurrently with taxane chemotherapy (NSABP B-31, NCCTG N831 [Reference Perez, Suman and Davidson16]) or is better started after completion of chemotherapy (HERA [Reference Smith, Procter and Gelber11]).
The hypothesis that systemic therapy should be given preoperatively, was first tested in a large randomised trial by the National Surgical Adjuvant Breast and Bowel Project in trial B18 [Reference Bernard Fisher, Bryant and Wolmark3], which evaluated the role of preoperative chemotherapy (AC × 4) compared with the same duration of chemotherapy given after surgery. Trials of short-duration chemotherapy given immediately after surgery, followed by conventional adjuvant chemotherapy after radiotherapy, have also been conducted [Reference van der Hage, van de Velde and Julien17]. Unfortunately, neither of these approaches has shown clear evidence of a significant reduction in the recurrence rate, which would support the use of these techniques in place of conventional adjuvant chemotherapy to improve long-term outcome [Reference Mieog, van der Hage and van de Velde18]. However, trials of short-duration chemotherapy given immediately after surgery have demonstrated that treatment in this period was effective; patients who received only postoperative perioperative chemotherapy and locoregional therapy in EORTC 10854 [Reference van der Hage, van de Velde and Julien17] had significantly better overall survival rates than patients who received locoregional therapy alone (P = 0.004). This suggests that effective therapy in the immediate postoperative period is unlikely to be harmful.
The potential gain of prognostic and predictive information
Breast cancer is a notoriously clinically heterogeneous disease. Categorisation based on gene expression classification using unsupervised analysis identifies five main subtypes, two of which contain two HER2 positive groups: ‘HER2+ like’ (ER−, HER2+) and ER+, HER2+ patients within the luminal B subgroup. However, even within these groups there is wide variability in outcome and treatment sensitivity. For example, after a median follow-up of 2 years in the HERA trial [Reference Smith, Procter and Gelber11], 19% of observation patients and 13% of trastuzumab-treated patients had experienced an event; thus targeted therapy had only reduced the event rate by approximately one-third. The use of preoperative treatment may offer the opportunity to obtain useful prognostic and predictive information that can be used as a basis for giving or withholding further treatment. If there is a relationship between the long-term outcome of patients and biological changes in the primary tumour in response to presurgical therapy, then these changes may accurately reflect the effect of therapy on micrometastases; however this hypothesis needs to be validated in controlled randomised trials. Biological changes in the blood, such as changes in angiogenic factors, may also offer useful information and their measurement can extend beyond the point of surgery.
An example of this phenomenon is provided by a biomarker substudy of the IMPACT study [Reference Dowsett, Smith and Ebbs19] (the substudy had a total of 25 events), which looked at the effect of biomarker changes induced by 2 weeks of treatment with tamoxifen and/or anastrazole in hormone receptor positive early breast cancer. Ki67 (P = 0.004) and ER scores (P = 0.04) measured after 2 weeks exposure to presurgical endocrine therapy were found to be superior prognostic factors to the same values measured before therapy. Tumour size measured at baseline was also found to be important, but it was not measured at 2 weeks when relatively little change would be expected. With regard to changes following anti-HER2 therapy, change in tumour size after 11 days of therapy may provide additional prognostic information that is not available from a pretreatment tumour specimen. Lapatinib has been reported [Reference Migliaccio, Gutierrez and Wu20] to shrink tumour size by 74% after 6 weeks which interpolates to a 36% shrinkage after 2 weeks. Moshin et al. [Reference Mohsin, Weiss and Gutierrez21] also found early tumour regression with a median decrease of 20% (0–60.4%) after 3 weeks of trastuzumab; changes in apoptosis were also observed over this period. A study [Reference Johnston, Trudeau and Kaufman22] of biomarker profiles that were predictive of response to lapatinib was undertaken in a phase II trial in 45 inflammatory breast cancer patients, out of which 30 were HER2+. In these patients, those with phosphorylated HER-3 showed a higher response rate than those without this characteristic (67% vs. 22%; n = 15 and 11, P = 0.02) and lack of p53 was also predictive of response.
Gene expression prognostic indices are receiving increasing attention in cancer prognostication. The potential of gene expression indices based on changes in gene expression can be illustrated by a study undertaken by Mackay et al. [Reference Mackay, Urruticoechea and Dixon23], who undertook expression profiling using cDNA arrays from pretreatment and post treatment biopsies in 34 sample pairs from ER+ breast cancer patients treated with anastrozole or letrozole for 2 weeks. Significant changes in gene expression were observed, particularly oestrogen-dependent and proliferation-related genes. The authors explored this further by combining gene changes into an overall score, described as the Global Index of Dependence on Estrogen (GIDE), which summed the genes changing by at least twofold with therapy. GIDE was found to be related significantly to pretreatment levels of HER2 and changes in immunohistochemically detected Ki67.
An important characteristic of perioperative therapy is that it offers the opportunity to combine information from both pre-therapy and post therapy samples. The pre-therapy expression of a particular biomarker can be viewed as offering information on the inherent prognosis of the patient and the post-therapy expression offers information on the response to treatment. It is therefore preferable to treat these two values as independent factors initially and only combine them into a single prognostic factor if this can be shown to be appropriate. As a simple example, gene expression changes from one to three and from two to six both have a fold change of three; however a patient with the former fold change may have inherently different prognosis because the overall expression levels are lower. Although it is tempting to view biomarker changes as surrogate endpoints, it is important to remember that to identify a surrogate endpoint it is not enough to simply show that the biomarker level correlates with outcome. It must also be shown that changes in the biomarker correlate with changes in outcome [Reference Collette, Burzykowski and Carroll24].
A note of caution is appropriate about the assumption that new prognostic information will be available from the use of perioperative therapy. In NSABP-18 [Reference Fisher, Bryant and Wolmark25] prediction of outcome was no better in the presurgical chemotherapy arm than in the postoperative arm despite the fact that the former was able to incorporate factors such as pathological tumour response and pathological nodal response which reflected response to chemotherapy. However, scientific advances since NSABP-18 was conducted have resulted in more biological information now being obtainable and it is important to test whether this additional biological readout adds critically useful prognostic and predictive information.
Evidence for the biological effect of anti-HER2 therapy
Evidence for the effect of anti-HER2 therapy gained from the re-excision of tumours has been presented above; evidence is also available from a number of other sources. It has been suggested that stem cells are resistant to chemotherapy and are the origin of resistant disease. Organ-specific markers that are expressed by stem cells can be identified from solid tumours, for example, the cell surface marker profile, CD44+ CD24–/lowLin– [Reference Dontu, Al-Hajj, Abdallah, Clarke and Wicha26], was found to identify a tumourigenic stem-cell population in samples from eight of nine human breast cancers. This profile was found to be enriched upto 100-fold with cells able to form tumours in mice. As expected of stem cells, the corresponding tumours in mice were found to possess similar phenotypic diversity to the original tumour population, encompassing subpopulations of both tumourigenic and non-tumourigenic cells. There is some evidence that anti-HER2 therapy, unlike chemotherapy, is effective against stem cells. Rodriguez et al. [Reference Migliaccio, Gutierrez and Wu20] carried out a presurgical study involving 45 patients which provided evidence suggesting that lapatinib decreases breast cancer stem cells in the primary breast cancers of women receiving presurgical lapatinib.
Short-term biomarker effects were also seen in a study by Spector et al. [Reference Spector, Xia and Burris14]. These authors studied the biological effects on selected tumour growth and survival pathways in patients with advanced ErbB1 and/or ErbB2-overexpressing solid malignancies after 21 days of different doses of lapatinib. Tumour response was assessed after 8 weeks and the series included 13 patients with advanced breast cancer, four of whom demonstrated a partial response. Despite the small number of breast cancer patients, evidence of a fall was shown in p-Erk1/2 (P < 0.01), TGF-α (P < 0.05) and p-ERB1 (P = 0.03). There were also non-statistically significant falls in Cyclin D (P = 0.065) and p-Akt (P = 0.13) (Wilcoxon signed rank test, analyses performed by RA on data extracted from Tables 2 and 3 [Reference Spector, Xia and Burris14]).
EGFR and HER2 may be involved in maintaining anueploidy in some cancers, which may therefore be responsive to anti-EGFR and anti-HER2 therapy. Cancer can be caused by aneuploidy (chromosomal gain, loss or rearrangement) and may not be attributable solely to gene mutations. Anueploidy was first suggested to play such a role in 1890 and is currently incorrectly commonly considered to be a late-stage effect rather than a cause of cancer development. Bjerkvig et al. [Reference Bjerkvig, Tysnes and Aboody27], for example, have pointed out that carcinogens such as asbestos and arsenic initially produce aneuploid lesions and not genetic mutations and that normal cells exposed to chemical carcinogens can become aneuploid some time before they show signs of being cancerous. Mutations and chromosomal instability may therefore both be important in the early stages of tumour development and involved in genesis of the cancer stem cell. In ovarian cancer, the coexpression of EGFR and c-erbB-2 is 47–68% [Reference Pack, Alper and Stromberg28]. Pack et al. examined the effects of antisense or immunosuppression of EGFR and c-erbB-2 expression on the invasive phenotype, aneuploidy and genotype of cultured human ovarian carcinoma cells. They found that the suppression of both EGFR and c-erbB-2 resulted in a decrease in aneuploidy and genomic imbalances, and restored a more normal phenotype and a more normal gene expression profile. Other evidence also supported the fact that the regression of aneuploidy was due to the selective apoptosis of double antisense transfected cells with a highly abnormal karyotype. EGFR and HER2 may therefore play a role in maintaining anueploidy within cancers, a condition that may be countered by the use of anti-EGFR and anti-HER2 therapy.
Conclusions
This paper has contrasted the use of perioperative anti-HER2 therapy with the use of preoperative and perioperative cytotoxic chemotherapy, both of the latter have been tested in randomised clinical trials but have not been found to offer a benefit in terms of long-term outcome or enhanced prognostication. However, it is important to evaluate the role of perioperative anti-HER2 therapy because of its distinct modes of action, and scientific advances have resulted in the greater availability of biological information that can be used to study prognostic and predictive effects. Controlled trials of perioperative therapy present the best opportunity to investigate these characteristics. Perioperative anti-HER2 therapy is of unproven benefit and safety, and it should therefore only be undertaken within the context of a randomised controlled trial such as EPHOS-B; however such a strategy requires both HER2 status assessment at or close to diagnosis and cardiac assessment, requiring pathological services that can provide rapid diagnosis and the availability of timely ECHO or MUGA scans.
Questions relating to the EPHOS-B study can be addressed to the EPHOS Trial Coordinator within ICR-CTSU, Email: ephos-icrctsu@icr.ac.uk
Acknowledgement
The EPHOS-B trial (ISRCTN: ISRCTN63882543) is funded by Cancer Research UK.
