Research ArticleClinical Investigations

18F-FDG PET/CT for Early Prediction of Response to Neoadjuvant Lapatinib, Trastuzumab, and Their Combination in HER2-Positive Breast Cancer: Results from Neo-ALTTO

Geraldine Gebhart, Cristina Gámez, Eileen Holmes, Javier Robles, Camilo Garcia, Montserrat Cortés, Evandro de Azambuja, Karine Fauria, Veerle Van Dooren, Gursel Aktan, Maria Antonia Coccia-Portugal, Sung-Bae Kim, Peter Vuylsteke, Hervé Cure, Holger Eidtmann, José Baselga, Martine Piccart, Patrick Flamen and Serena Di Cosimo
Journal of Nuclear Medicine November 2013, 54 (11) 1862-1868; DOI: https://doi.org/10.2967/jnumed.112.119271

Abstract

Molecular imaging receives increased attention for selecting patients who will benefit from targeted anticancer therapies. Neo-ALTTO (Neoadjuvant Lapatinib and/or Trastuzumab Treatment Optimisation) enrolled 455 women with invasive human epidermal growth factor receptor 2 (HER2)–positive breast cancer and compared rates of pathologic complete response (pCR) to neoadjuvant lapatinib, trastuzumab, and their combination. Each anti-HER2 therapy was given alone for 6 wk, followed by 12 wk of the same therapy plus weekly paclitaxel. The early metabolic effects of the anti-HER2 therapies on the primary tumors and their predictive values for pCR were assessed in a subset of patients. Methods: Eighty-six patients underwent 18F-FDG PET/CT at baseline and weeks 2 and 6 of anti-HER2 treatment. An imaging core laboratory provided central validation, and 2 independent reviewers, masked to assigned treatment arm and clinical outcomes, performed consensus 18F-FDG PET/CT readings. Maximum standardized uptake value (SUVmax) reductions from baseline were used to measure metabolic response. Results: Seventy-seven of the 86 enrolled patients presented an evaluable baseline 18F-FDG PET/CT scan; of these, 68 and 66 were evaluable at weeks 2 and 6, respectively. Metabolic responses in the primary tumors were evident after 2 wk of targeted therapy and correlated highly with metabolic responses at week 6 (R2 = 0.81). pCRs were associated with greater SUVmax reductions at both time points. Mean SUVmax reductions for pCR and non-pCR, respectively, were 54.3% versus 32.8% at week 2 (P = 0.02) and 61.5% versus 34.1% at week 6 (P = 0.02). 18F-FDG PET/CT metabolic response rates at weeks 2 and 6 were 71.6% and 60%, respectively using European Organization for Research and Treatment of Cancer criteria; pCR rates were twice as high for 18F-FDG PET/CT responders than nonresponders (week 2: 42% vs. 21%, P = 0.12; week 6: 44% vs. 19%, P = 0.05). Conclusion: Early metabolic assessment using 18F-FDG PET/CT can identify patients with an increased likelihood of pCR after neoadjuvant trastuzumab, lapatinib, or their combination when given with chemotherapy.

Approximately 20% of all breast cancers (BCs) overexpress or amplify the human epidermal growth factor receptor 2 (HER2), a characteristic associated with poor prognosis, increased proliferation, angiogenesis, and resistance to apoptosis (13).

In combination with chemotherapy, the monoclonal antibody trastuzumab (Herceptin; Genentech), which specifically targets the HER2 extracellular domain, has been shown to improve survival in both the adjuvant and the metastatic settings (48). In addition, lapatinib (Tykerb; GlaxoSmithKline), a small-molecule inhibitor that targets the intracellular domain of HER2, has established its benefit in treating HER2-positive metastatic BC when combined with capecitabine or letrozole (9,10).

Preclinical and clinical studies showing that lapatinib resensitizes tumors that have progressed on trastuzumab (1113) provided the first indication that combining the agents to create a dual anti-HER2 blockade may improve the current standard of care even further. Lapatinib and trastuzumab do have partly nonoverlapping mechanisms of action: trastuzumab inhibits ligand-independent HER2 and HER3 signaling (14) and triggers antibody-dependent cellular cytotoxicity (15). By contrast, lapatinib blocks ligand-induced heterodimer signaling and prevents signaling via a frequently expressed truncated version of HER2 that could render cells resistant to trastuzumab. Additionally, lapatinib leads to an accumulation of HER2 at the cell surface, enhancing trastuzumab-dependent antibody-dependent cellular cytotoxicity (12).

In the neoadjuvant setting, trastuzumab combined with chemotherapy has been shown to significantly increase pathologic complete response (pCR) (16). According to recent data, higher pCR rates are in turn associated with improved outcomes (17).

We previously reported that treatment with the lapatinib and trastuzumab combination in Neoadjuvant Lapatinib and/or Trastuzumab Treatment Optimisation (Neo-ALTTO) resulted in a significantly higher pCR rate (51.3%) than with either trastuzumab (29.5%) or lapatinib (24.7%) alone. Neo-ALTTO randomized 455 patients from 86 sites in 23 countries to receive either lapatinib alone (n = 154), trastuzumab alone (n = 149), or both drugs (n = 152) for 6 wk, followed by the same assigned targeted therapy combined with weekly paclitaxel for 12 wk (18).

One of the trial’s key features was the initial 6-wk biologic window, during which patients received only anti-HER2 drugs. This protocol enabled us to investigate the effect of anti-HER2 therapy alone and search for potential molecular and imaging biomarkers of response. Central to this were 3 serial PET/CT scans with 18F-FDG performed in a subset of patients at baseline, week 2, and week 6.

A preplanned secondary objective of Neo-ALTTO was to assess both the early metabolic effects of anti-HER2 blockade on the primary tumors and their predictive value for pCR at the time of surgery. There was also interest in exploring whether 18F-FDG PET imaging would capture a higher rate of metabolic response with the dual HER2 blockade as opposed to single blockade. Neo-ALTTO thus represents the first investigation, to our knowledge, of 18F-FDG PET/CT in patients treated with anti-HER2 therapies in the neoadjuvant setting.

MATERIALS AND METHODS

Study Design

Patients were randomized to 1 of 3 treatment arms: oral lapatinib, intravenous trastuzumab, or their combination administered for 6 wk, followed by 12 wk of the assigned anti-HER2 therapy plus weekly paclitaxel (Fig. 1). Within 4 wk of the last administration of paclitaxel, patients underwent definitive breast surgery and were evaluated for pCR, defined as the absence of invasive cancer in the breast (19). The ethics committee and relevant health authorities at each participating institution approved the study protocol (clinical trial registration number NCT00553358). All women gave written informed consent before study entry.

FIGURE 1.
FIGURE 1.

Neo-ALTTO study design. B = baseline; FEC = fluorouracil, epirubicin, cyclophosphamide; w2 = week 2; w6 = week 6.

Evaluation of HER2/Hormone Receptor (HR) Disease

HER2/HR disease is described in the original manuscript of the Neo-ALTTO (18): in brief, HER2 and HR status were determined according to local pathology department criteria. HER2 status was assessed locally at participating institutions that had been accredited by the certified laboratory, Vall d’Hebron Institute of Oncology, Barcelona.

Selection of 18F-FDG PET/CT Study Sites

A feasibility questionnaire was sent to all sites before patient enrollment to assess their 18F-FDG PET/CT capabilities. Thirty centers in 14 countries were ultimately selected. In these centers, the imaging substudy was proposed to all consecutive patients included in the Neo-ALTTO trial.

18F-FDG PET/CT Procedures

Three 18F-FDG PET/CT scans were obtained for each patient: 1 before initiation of neoadjuvant treatment (baseline) and 2 more during treatment (weeks 2 and 6). All patients were studied using a dedicated 18F-FDG PET/CT camera of the brand locally available (GE Healthcare, Philips, or Siemens). All 18F-FDG PET/CT images had to be taken using the same scanner and identical acquisition parameters. Patients were required to have fasted for at least 6 h before the scan and to have blood glucose levels less than 150 mg/dL before 18F-FDG injection. The injected activity was 3.7–7.4 MBq/kg, with the difference of net injected activity between the baseline and the 2 subsequent scans not to exceed 20%. For all scans, the delay between 18F-FDG injection and start of image acquisition had to be at least 50 min. For scans at weeks 2 and 6, the time interval between tracer injection and start of the PET/CT acquisition needed to fall within 20 min of the interval recorded for the baseline 18F-FDG PET/CT scan. Any 18F-FDG PET/CT scan showing a significant paravenous tracer injection defined as more than 10% of the injected dose was excluded from the analysis. In all 18F-FDG PET/CT centers, the same iterative reconstruction method was used for the 3 time points, such as ordered-subset expectation maximization or row-action maximum likelihood algorithm, with and without CT-based attenuation correction.

Two nuclear medicine reviewers (in Barcelona and Brussels) retrospectively assessed the quality of the 18F-FDG PET/CT scans and imaging analysis. They verified and cross-checked the dedicated PET/CT imaging case report form and the DICOM (Digital Imaging and Communications in Medicine) headers. Face-to-face meetings were held by the 2 PET/CT reviewers to reach a consensus on assessments.

Selection of Target Tumor Lesions

Lesions were divided according to their location: breast, nodal (axillary, subclavicular, and internal mammary), and distant.

At baseline, 18F-FDG PET/CT target lesions were defined as those with a maximum standardized uptake value (SUVmax) ≥ 2.5 and a CT based maximal transaxial diameter ≥ 1 cm. Lesions not fulfilling these 2 criteria were classified as nontarget. Only target lesions were included in the statistical analysis.

Assessment of Metabolic Response

SUVmax was obtained by drawing a volume of interest in the lesions using the commercial PET VCAR software on an Advantage Workstation (GE Healthcare), which allows a practical approach to comparative analysis (20).

Lesion-Based Metabolic Response Assessment

SUV is a widely used 18F-FDG PET/CT quantifier, calculated as the ratio of the concentration of the measured tissue radioactivity and the injected radioactivity normalized for patient body weight. SUVmax represents the highest pixel SUV within a tumor and is a continuous variable. For each target lesion, metabolic response was calculated as the percentage decrease of the baseline value according to the following formula: (SUV baseline – SUV response)/SUV baseline. PET responses were classified according to criteria of the European Organization for Research and Treatment of Cancer (EORTC) (21).

For the 18F-FDG PET/CT scan performed at week 2, the selected threshold was 15%, meaning that target lesions showing at least a 15% reduction of the SUVmax were considered responding. For the 18F-FDG PET/CT for week 6, the selected threshold was 25%, meaning that target lesions showing at least a 25% reduction of the SUVmax were considered responding. For both time points, lesions showing an increased activity of 25% were classified as progressive lesions. Finally, also for both time points, if a lesion’s metabolic activity became visually identical to the local background activity, the response was classified as a complete metabolic response.

For this analysis, patients whose lesions showed either partial or complete metabolic responses were classified as responders, whereas metabolically stable or progressive cases were considered nonresponders.

Region- and Patient-Based Metabolic Response Assessment

The least responding target lesion was used to categorize region- and patient-based response. Responses were assessed separately for the primary breast tumor, lymph nodes, and distant lesions. We also distinguished primary tumor response from overall response, the latter including the primary tumor and the nodes. Of note, the few distant lesions identified were considered as nodal lesions in the analysis.

Statistical Analysis

We hypothesized that with roughly 30 patients per arm undergoing an early 18F-FDG PET/CT evaluation and by correlating early metabolic changes with pCR at surgery, we would be able to differentiate patients with HER2-addicted tumors from those with tumors less dependent on HER2 signaling. Because the optimal timing of 18F-FDG PET/CT in this context was unknown, we decided to perform 18F-FDG PET/CT imaging at weeks 2 and 6. No formal statistical hypothesis was planned for this first exploratory analysis.

Metabolic response was first described as the change in SUVmax from baseline to weeks 2 and 6. The correlation between these changes was assessed, and the changes in SUVmax were then summarized by means and box plots.

Although most of the analyses of metabolic response based on EORTC criteria were descriptive, logistic regression models were fitted to assess the relationship between metabolic response, pCR, and stratification factors.

RESULTS

Evaluable Population

According to the predefined eligibility criteria, 77 of the 86 patients enrolled in Neo-ALTTO presented an evaluable baseline 18F-FDG PET/CT scan and were included; 68 and 66 of those patients had an evaluable 18F-FDG PET/CT scan at week 2 and week 6, respectively. Ultimately, 62 patients were fully evaluable for all 3 time points (Fig. 2).

FIGURE 2.
FIGURE 2.

Patients included in 18F-FDG PET/CT analysis.

The main reason for exclusion was failure to comply with timing for one or more of the 3 assessments (n = 12). Other reasons included 18F-FDG PET/CT not performed or lost (n = 9), insufficient image quality (n = 2), and scans obtained with different 18F-FDG PET/CT cameras (n = 1).

Among the 77 evaluable patients, 52 (67.5%) presented metabolic lymph node involvement, and 9 (11.7%) presented both metabolic lymph node involvement and clinically unsuspected distant lesions.

Table 1 shows that the 18F-FDG PET/CT cohort (77 patients) is representative of the overall Neo-ALTTO population (455 patients), except for tumor size, which was found to be slightly larger in the imaging subgroup (54.5%) than in the general study population (39.8%).

View this table:
TABLE 1

Patient Characteristics According to Stratification Factors in 18F-FDG PET/CT Population and in General Neo-ALTTO Population

Biologic Window

Correlation Between Week-2 and Week-6 18F-FDG PET/CT Results

A significant correlation (R2 = 0.81) was found between the changes of primary tumor SUVmax at weeks 2 and 6 (Fig. 3).

FIGURE 3.
FIGURE 3.

Correlation between relative changes in SUVmax at week 2 and week 6.

Metabolic Response Rates at Weeks 2 and 6 According to EORTC Criteria

18F-FDG PET/CT metabolic response rates in the primary tumor were 71.6% at week 2 and 60% at week 6. Similar results were found for overall response (primary tumor and nodes), with rates of 69% and 56%, respectively.

Absence of response in the primary tumor at week 2 was predictive of nonresponse at week 6, with a negative predictive value of 90% (18/20 patients). The presence of response at week 2 was predictive of response at week 6, with a positive predictive value of 78.5% (33/42 patients). Figure 4 illustrates 2 examples.

FIGURE 4.
FIGURE 4.

Representative examples of metabolic responder and nonresponder included in our study. (A) Metabolic responder achieving pCR: baseline axial fused PET/CT slice showing right breast tumor (left), week 2 PET/CT metabolic complete response (middle), and week 6 PET/CT metabolic complete response (right). (B) Metabolic nonresponder not achieving pCR: baseline axial fused PET/PT slice showing left breast tumor (left), week 2 PET/CT metabolic stable disease (middle), and week 6 PET/CT metabolic stable disease (right).

Analysis of metabolic responses in the primary tumor according to treatment arm revealed the following: at week 2, responses were 66.7%, 56.5%, and 95% for the lapatinib, trastuzumab, and combination arms, respectively (P = 0.016); at week 6, responses were 60.9%, 43.5%, and 78.9%, respectively (P = 0.065). Comparison of the metabolic responses for single- versus dual-treatment arms showed 61.7% and 95% at week 2 (P = 0.013) and 52.2% and 78.9% at week 6 (P = 0.08), respectively.

Metabolic response rates were higher in patients with HR-negative tumors than in patients with HR-positive tumors: 82.1% versus 64.1% at week 2 (P = 0.18) and 78.5% versus 45.9% at week 6 (P = 0.016), respectively.

Of note, 5 (7%) patients (all with HR-negative tumors) showed complete metabolic response in their primary tumors at week 2, and 14 (21%) patients did so (10 with HR-negative tumors) at week 6.

Correlation Between Metabolic Response and pCR

Of the 77 patients included in this analysis, 27 (35.1%) achieved pCR at surgery.

Relative Changes in SUVmax in Primary Tumor at Weeks 2 and 6 According to pCR

Patients with pCR at surgery had significantly greater reductions in SUVmax at weeks 2 and 6 (P = 0.02 for both time points) than those without a pCR. Mean SUVmax reductions were 54.3% versus 32.8% at week 2 and 61.5% versus 34.1% at week 6 for pCR and non-pCR, respectively. Box plots of the changes in SUVmax are shown in Figure 5.

FIGURE 5.
FIGURE 5.

Box plots of changes in SUVmax: relative SUV max changes and pCR at week 2 (A) and week 6 (B).

pCR by Metabolic Response in Primary Tumor and Overall Response Using EORTC Criteria

Higher rates of pCR were observed in responders than nonresponders, independently of the selection of the target lesion: primary tumor (week 2: 41.6% vs. 21.1%, P = 0.12; week 6: 43.6% vs. 19.2%, P = 0.05, respectively) with or without node involvement (Table 2). However, when adjustments were made for stratification factors and treatment arm in multivariate logistic regression models, the odds ratio for metabolic response was reduced and no longer statistically significant (P = 0.19 and 0.24 at weeks 2 and 6, respectively). This appeared predominantly to be due to the adjustment for HR status, which was the strongest predictor of pCR.

View this table:
TABLE 2

pCR and Metabolic Response

pCR by Metabolic Response in Primary Tumor According to HR Status Using EORTC Criteria

HR-positive tumors had a lower rate of pCR than HR-negative ones: 8 of 43 (18.6%) versus 19 of 34 (55.9%). In addition, HR-positive tumors with metabolic responses classified as nonresponders had much lower pCR rates than those classified as responders (1/20 [5%] vs. 4/17 [23.5%] at week 6). This was not the case for HR-negative tumors: the pCR rates were comparable for the responders and the nonresponders, both for the primary tumor and for overall (13/22 [59.1%] vs. 4/6 [66.7%] at week 6) (Table 3).

View this table:
TABLE 3

pCR Rate by Primary Tumor Metabolic Response and HR Status

Complete Metabolic Responses and pCR

Of the patients with HER2-positive/HR-negative BC, 10 showed a complete metabolic response at week 6; of these, 9 presented a pCR at the time of surgery. Of the patients with HER2-positive/HR-positive BC, only 4 showed complete metabolic response, of which 1 presented a pCR at surgery.

DISCUSSION

Although trastuzumab’s use both in advanced and in early disease is associated with improved clinical outcomes, so far not a single biomarker beyond HER2 has been validated to help us identify the women most likely to benefit from it. More recent research into anti-HER2 therapies indicates that using 2 anti-HER2 agents to create a dual blockade offers further significant clinical advantages (22,23), but here also biomarker research has been unsuccessful (24).

Although PET/CT imaging has been established as a useful staging and prognostic instrument, the interest in functional imaging as a tool to predict pCR to neoadjuvant therapy emerged only a few years ago (2529), with promising results shown particularly in triple-negative BC (30). Neo-ALTTO is the first trial to test whether early 18F-FDG PET/CT–based metabolic response assessment could be a clinically useful pharmacodynamic biomarker to select patients with a high versus low probability of response to a HER2-based therapy combined with chemotherapy. Because of Neo-ALTTO’s 6-wk biologic window of anti-HER2 treatment alone, we could use 18F-FDG PET/CT to assess the effect of anti-HER2 treatments without the interference of chemotherapy.

Our primary observation was the rapidity with which metabolic changes occurred in the tumors after exposure to the anti-HER2 blockade. Metabolic responses were seen at 2 wk in more than two thirds (71.6%) of the patients, including 5 with a complete metabolic shut-down. Metabolic responses (21) were more frequent in the dual HER2 blockade arm (95% at week 2) than in the single-agent arms (66.7% for lapatinib, 56.5% for trastuzumab at week 2), which is consistent with Neo-ALTTO’s overall results for 455 patients: twice the pCR rate was observed with trastuzumab plus lapatinib than with either agent used alone (18). Lapatinib and trastuzumab do have different mechanisms of action, possibly explaining the synergy of metabolic response seen in the combination arm.

Moreover, the correlation between SUVmax changes at 2 and 6 wk is encouraging. These data clearly show that most of the decreased 18F-FDG uptake is seen early during treatment. This is vital both to individualize treatment and to optimize future drug development.

Equally encouraging is the correlation between early metabolic response and the likelihood of achieving pCR, the main objective of the 18F-FDG PET/CT analysis (19). The pCR rate was twice as high in patients showing an 18F-FDG PET/CT response than it was in nonresponders. However, 18F-FDG PET/CT nonresponders still showed a 20% pCR rate, which is clinically meaningful and may reflect the salvage activity of paclitaxel in some tumors that are not HER2-addicted. Interestingly, 20% is in line with the pCR rate of 22% observed in patients with HER2-positive tumors receiving only chemotherapy in the neoadjuvant setting (31).

Excellent concordance was also found between imaging results of the primary tumor alone and those of the primary tumor plus its adjacent lymph nodes, suggesting that further imaging studies of early response to preoperative anti-HER2 therapies may be based solely on primary tumor evaluation.

An unexpected observation was the marked heterogeneity of the 18F-FDG PET/CT response according to HR status. This unplanned analysis was conducted because of the growing evidence that HER2-positive/HR-positive disease is different from HER2-positive/HR-negative disease, with the former showing less dramatic responses to chemotherapy plus anti-HER2 therapy.

In our study, 18F-FDG PET/CT responses to HER2-therapy occurred less frequently in HR-positive tumors. This pattern also extended to metabolic complete responses, which were observed in only 4 HR-positive tumors but in 10 HR-negative tumors, and correlated less well to the achievement of pCR (1/4 pCRs for HR-positive tumors contrasting with 9/10 pCRs for HR-negative ones). Surprisingly, 18F-FDG PET/CT response turned out to be a weaker predictor of pCR than HR status, with HR-negative tumors being more likely than HR-positive ones to reach a pCR. Also notable is the apparent greater salvage effect of chemotherapy in patients with HR-negative BC classified as nonresponders than in nonresponders with HR-positive BC. This may explain the much better negative predictive value of the early 18F-FDG PET/CT in the latter group.

The potential weakness of the preoperative portion of Neo-ALTTO is that it lacked a blockade of the estrogen receptor pathway, which is a well-described escape mechanism in HER2-positive/HR-positive tumors (32,33). Our study corroborates these laboratory findings and suggests that HER2 blockade in the absence of endocrine therapy has limited efficacy.

In future trials, we recommend the systematic stratification or even separation of the 2 distinct biologic subsets, HER2-positive/HR-negative and HER2-positive/HR-positive. For the latter patient group, a HER2 blockade combined with endocrine therapy should be explored. This has already been done by Chang et al., who reported a pCR of 21% when using trastuzumab plus lapatinib in combination with letrozole (34).

Our study was not powered to investigate the predictive value of the early metabolic complete response that occurred in 21% (14/66) of the patients at week 6, mostly patients with HR-negative tumors. However, 10 of 14 of these early complete 18F-FDG PET/CT responders showed pCR at surgery. Because pCR is a surrogate of long-term outcome in this patient subset, independent validation of the apparently high correlation between an early metabolic complete response in HER2-positive/HR-negative disease and pCR is required. Early metabolic complete response could become an innovative way to separate patients well-served by existing anti-HER2 therapies from those who need additional or alternative ones.

Further work is required, however, and it includes determining a better 18F-FDG PET/CT response threshold to distinguish responding from nonresponding patients. In our study, we opted to use the EORTC threshold (15% at 2 wk), which is relatively low. However, threshold choice should depend on a study’s particular objective, with a high threshold most suited to identify the best responders and a low threshold to identify nonresponders.

The strength of this imaging trial is the multicentric effort. However, because of a lack of prior PET harmonization program, absolute baseline values of SUVmax were not comparable among cameras. Therefore, SUVs could not be pooled to study their predictive value but only their relative changes.

CONCLUSION

Our study is the first, to our knowledge, to demonstrate that early metabolic assessment using 18F-FDG PET/CT in patients with HER2-positive BC is informative and can identify patients with an increased likelihood of achieving pCR after anti-HER2 therapy combined with chemotherapy in the neoadjuvant setting.

DISCLOSURE

The costs of publication of this article were defrayed in part by the payment of page charges. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 USC section 1734. This trial was funded by GlaxoSmithKline. No other potential conflict of interest relevant to this article was reported.

Acknowledgments

We thank Lorena de la Peña (SOLTI Breast Cancer Research group) for her assistance in reviewing this manuscript and Carolyn Straehle for her editorial assistance. The Breast International Group, the Breast European Adjuvant Study Team, and SOLTI Breast Cancer Study Group were responsible for the design and coordination of the study, collection and management of data, medical review, analysis of the data, and reporting of the results. The members of the trial steering committee reviewed the report and were responsible for the decision to submit it for publication. The report was prepared by the members of the writing committee, who had unrestricted access to study data and made the final decisions about content. All authors and members of the Executive Committee (including a minority representation from GlaxoSmithKline) reviewed the article and suggested changes. The data were analyzed by statisticians at Frontier Science Scotland.

Footnotes

  • * Contributed equally to this work.

  • Published online Oct. 3, 2013.

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  • Received for publication January 10, 2013.
  • Accepted for publication May 14, 2013.
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