NIH Public Access Author Manuscript Published in final edited form as: Cancer Epidemiol Biomarkers Prev. 2010 January ; 19(1): 144 147. doi:10.1158/1055-9965.epi-09-0807. Feasibility Study for Collection of HER2 Data by NCI Surveillance, Epidemiology and End Results (SEER) Program Central Cancer Registries Marsha E. Reichman 1, Sean Altekruse 1, Christopher I. Li 2, Vivien W. Chen 3, Dennis Deapen 4, Mary Potts 2, Xiao-Cheng Wu 3, Donna Morrell 4, Jennifer Hafterson 2, Amanda I Phipps 2, Linda C. Harlan 5, Lynn G. Ries 1, and Brenda K. Edwards 1 1 Surveillance Research Program, DCCPS, NCI 2 Division of Public Health Sciences, Fred Hutchinson Cancer Research Center, Seattle, WA 3 Louisiana Tumor Registry 4 Los Angeles SEER Cancer Registry 5 Applied Research Program, DCCPS, NCI Abstract The clinical importance of human epidermal growth factor receptor-2 (HER2) in breast cancer is now clearly established given that expression of this tumor marker is used to guide therapy and as a prognostic indicator. Despite its now routine evaluation in breast cancer patients, population-based data are lacking because information on HER2 status is not routinely collected in the majority of population-based cancer registries. We assessed feasibility of collecting HER2 data and its completeness in three registries in the Surveillance, Epidemiology and End Result (SEER) Program. Among a sample of invasive first primary breast cancer patients diagnosed between June and December 2007, HER2 tests had been performed on 96.5% (N=522), and test results were available for 95.2% (N=515) of patients. The majority of HER2 tests were performed by immunohistochemistry (IHC) alone (50.9%), 35.3% by both IHC and fluorescence in situ hybridization (FISH) and 11.8% of tests by FISH alone. As a result of these findings SEER registries will collect HER2 data on all invasive breast cancer patients as an optional data element for those diagnosed in 2009 and HER2 will likely be a required data element for these patients in 2010. Introduction Over the past several years, the prognostic and clinical importance of human epidermal growth factor receptor-2 (HER2) has increased considerably. Guidelines from the American Society of Clinical Oncology now recommend that all primary invasive breast cancers be evaluated for HER2 overexpression and/or amplification (1). This stems primarily from the fact that HER2 status will not only determine whether or not trastuzumab, a targeted adjuvant therapy, is a treatment option, but also reflects growing evidence that HER2 status is an independent prognostic indicator (2) and a marker of sensitivity to anthracycline-based chemotherapy regimens (3). While the importance of HER2 testing is widely agreed upon, there are few population based studies of the frequency of HER2 testing in clinical settings, types of tests being used, results of these tests and how they vary across factors such as age, race/ethnicity, Corresponding Author: Marsha E. Reichman, Division of Cancer Control and Population Sciences, NCI; 6130 Executive Blvd., Suite 6138; Rockville, Maryland, 20852; ReichmaM@mail.nih.gov.
Reichman et al. Page 2 Methods and treatment facilities (4,5). Contributing to these gaps in knowledge is the fact that few population-based cancer registries routinely collect HER2 data. Such data collection would add greatly to information on HER2 testing and resultant patient treatment. Ultimately, availability of population-based data on HER2 testing will be critical for determining dissemination of treatment protocols in the community and comparative effectiveness of various protocols. A feasibility study was conducted to assess the ability of cancer registries in the SEER Program to collect HER2 data and to identify barriers to data collection. The overall availability of HER2 data, as well as characteristics associated with data availability are described. Three SEER registries (Los Angeles, Louisiana, and Seattle-Puget Sound) participated in this feasibility study focused on invasive first primary breast cancer patients diagnosed between June and December 2007. At each registry facilities diagnosing breast cancer cases were divided into tertiles of facility size (large, medium and small) based on the number of new cancer cases submitted to each registry in the last complete year of ascertainment. Numbers of cancer cases seen at large, medium and small facilities may differ by registry. Facilities were selected at random from each tertile. A target number of patients for each registry was set at 30 from each of 4 large facilities, 30 from each of 4 medium facilities, and 10 from each of 5 small facilities for a total of 290 cases. A run-in phase was established to test data collection procedures. The accrual goal for the run-in period was 50 cases from each registry, with 20 from a total of at least 3 large, 20 from a total of at least 3 medium and 10 from at least 3 small facilities. After the run-in period, the Los Angeles registry experienced a drastic change in resources necessitating modification of some registry processes. The registry ceased further study participation during this transition period. Certified tumor registrars from the registry s staff utilized a standard data collection form to extract the HER2 data from pathology reports and medical records. These forms, which included a generated number for patient identification, were submitted to the SEER Program at the NCI. Data were collected on the type of HER2 test performed (i.e. immunohistochemistry (IHC), fluorescence in situ hybridization (FISH), and/or other/unknown), quantitative results of test(s) performed, interpretation of test(s) performed, and the source of data for each data item (i.e. pathology report, addendum to pathology report, lab report in chart, other electronic data, other). In addition, the type of FISH test performed (ratio or copy number) and the cut point of the FISH test for positivity was obtained. We defined HER2 positivity based on current clinical practice for interpreting the results of IHC and/or FISH testing, the two most commonly used approaches for evaluating HER2 status. FISH is generally considered the gold-standard assay and is less susceptible to adverse effects of tissue handling than IHC. However, FISH is also more expensive and time-consuming, and requires equipment and training that may not be available in all clinical settings. FISH testing can be reported in two ways: as a ratio of HER2 gene copy number to an internal control probe; or as the number of gene copies per nucleus when an internal probe is not used. CEP17, a centromeric probe for chromosome 17, on which the HER2 gene is located, is used as an internal control. ASCO/CAP guidelines (1) suggest a FISH test be deemed negative for a ratio of <1.8 or HER2 gene copy number <4.0, positive for a ratio >2.2 or a copy number >6.0, and equivocal for a ratio between 1.8 and 2.2 or a copy number of 4.0 to 6.0. This is estimated to result in an equivocal group of not more than 3%. Because studies have documented close to 95% concordance between IHC scores of 0/1+ and FISH non-amplification (i.e., HER2 ) and greater than 90% concordance between IHC scores of 3+ and FISH amplification (i.e., HER2 +) (6,7), a common clinical protocol calls for the use of FISH testing only when IHC results
Reichman et al. Page 3 Results Discussion are equivocal (i.e., 2+). Previous studies have shown that approximately 17 23% of breast tumors scored as 2+ by IHC are classified as positive by FISH (6 8). Thus, HER2 testing in individual cases may be performed by IHC alone, FISH alone, or a combination of IHC and FISH. In this study HER2 status was derived by giving priority to FISH results over IHC, and to IHC results over a test of unknown type. Cases with a 2+ IHC result and no FISH testing were categorized as equivocal. Information regarding patient age at diagnosis, race/ethnicity, tumor stage and grade were obtained from registries as available. Data were collected for this study much closer to date of diagnosis than is standard for the SEER Program; thus items, such as race and ethnicity, that would be complete when the case is officially reported to SEER, may not have been complete at the time of this study. Deidentified data from all three registries was combined in a database for analysis using the SAS statistical package. Percents of cases with HER2 related data items were calculated by various characteristics and statistical associations determined by chi square tests. Among 541 observations obtained for analysis, HER2 data were either missing or it was unknown if a HER2 test was performed for 3.5% (N=19); an additional 1.3% (N=7) of records indicated that HER2 testing had been performed but results were unknown. Thus a HER2 test was known to be performed on 96.5% (N= 522) of observations in this feasibility study, and HER2 results were available for 95.2% (N= 515). The completeness of these data varied somewhat by registry, with results from a HER2 test available for 95.9%, 95.5%, and 89.8% of cases from the Seattle-Puget Sound, Louisiana, and Los Angeles registries, respectively (Table 1). The proportion of women with available HER2 data only varied somewhat by age, with data available from 96.5% of women <50 years of age at diagnosis and available for 92.9% of women 70 years of age at diagnosis. This proportion also did not vary much by either disease stage or race/ethnicity. In contrast, HER2 data were available from 97.7% of women treated at large facilities compared to only 88.6% of those treated in small facilities. The only statistically significant association with percent of breast cancer cases with known HER2 results was for facility size (Table 1). Overall, 17.7% (N=91) of cases were HER2-positive, 2.5% (N=13) were equivocal, and 79.8% (N=411) were HER2-negative (Table 2). The majority of cases with available HER2 data were tested by IHC alone (50.9%), 35.3% were tested by both IHC and FISH, and 11.8% of cases were tested by FISH only (for 7 cases the type of test performed was unknown, and for 3 cases a test of unknown type was performed along with IHC and/or FISH). For cases tested by FISH, the vast majority (88.2%) was reported as a ratio test, 3.3% reported copy number results, and the test type for the remaining 8.5% was unknown. For 77.3% of cases with data, HER2 data were obtained from either the pathology report or an addendum to the pathology report. This increases to 93.2% if lab reports in the medical chart are also included. These percentages include the conservative requirement that if both IHC and FISH tests are performed the results of both test types needed to be in the path report, addendum, or lab report. This feasibility study shows that SEER central cancer registries can, with limited additional resources (i.e. using only documents currently obtained by registries), collect information on whether a HER2 test was performed, the type of test methodology used, and the result of that test for approximately 95% of the population, based on a sample of breast cancer cases
Reichman et al. Page 4 References diagnosed in 2007. If sources of information are limited to pathology reports, their addenda and lab reports in chart, this percentage drops to 88.7% and to 73.6% if only pathology report and addenda are used. The distribution of HER2 testing practices (i.e., IHC alone, FISH alone, FISH and IHC) are likely to vary both on an institutional level, due to differences in institutional protocols, and according to patient population characteristics. While FISH is generally considered the gold-standard assay, the use of the more costly and involved FISH testing is likely to be lower in resource-limited facilities and in patient populations that are most likely to be HER2-negative on IHC (e.g., non-hispanic white women, women diagnosed at an advanced age). Further work is needed to fully evaluate these potential associations. The data source was collected since central cancer registry resources are limited and unlikely to increase in the near future making it very important to assess the level of completeness that can be reached without excessive effort. The source of information on the HER2 test is critical to the ability of central cancer registries to collect this data since it determines the resources that need to be allocated. Sources not routinely accessed, including other laboratory reports, physician offices, additional electronic data, or obtaining the data via telephone calls, are much more labor intensive and would require increased resources. Thus it is quite important that this feasibility study indicates that SEER central cancer registries can obtain fairly complete information on HER2 without expanding data sources. In addition, abstraction of HER2 data will also be facilitated by applications that highlight these items in pathology reports. These analyses found that the only statistically significant association with percent of breast cancer cases with known HER2 results was facility size (Table 1). Further investigation is needed to determine the reasons behind this difference. It is important to note that this feasibility study was not designed or powered to assess differences in HER2 status by patient, tumor, facility or registry characteristics. Larger scale population-based data collection is needed to better describe how the distribution of HER2 status varies with these factors. Expanded collection of HER2 data by SEER Program registries should be able to address these important issues. As a result of the findings in this study, the majority of SEER central cancer registries will be collecting HER2 data for breast cancer cases diagnosed in 2009 on an optional basis with the intent to require these data for cases diagnosed in 2010. This will enable analyses to be performed that examine variation in HER2 results by patient and tumor characteristics and associations with survival outcome in population-based samples. Examination of associations between HER2 test results and treatment may require treatment data beyond that currently found in the SEER limited-use data file. In general, it is difficult to determine when a biomarker matures to the point where it should be collected as part of population-based surveillance. The degree to which testing for that biomarker is part of standard medical practice, and to which assay methodology is stable contribute to this decision. HER2 likely represents a marker where its routine collection by population-based cancer registries is warranted given the frequency of its testing, the stability of assay methodology, and its proven clinical and prognostic utility. 1. Wolff AC, Hammond ME, Schwartz JN, et al. American Society of Clinical Oncology/College of American Pathologists guideline recommendations for human epidermal growth factor receptor 2 testing in breast cancer. J Clin Oncol 2007;25:118 45. [PubMed: 17159189] 2. Andrulis IL, Bull SB, Blackstein ME, et al. neu/erbb-2 amplification identifies a poor-prognosis group of women with node-negative breast cancer. Toronto Breast Cancer Study Group. J Clin Oncol 1998;16:1340 9. [PubMed: 9552035]
Reichman et al. Page 5 3. Pritchard KI, Shepherd LE, O Malley FP, et al. HER2 and responsiveness of breast cancer to adjuvant chemotherapy. N Engl J Med 2006;354:2103 11. [PubMed: 16707747] 4. Bauer KR, Brown M, Cress RD, Parise CA, Caggiano V. Descriptive analysis of estrogen receptor (ER)-negative, progesterone receptor (PR)-negative, and HER2-negative invasive breast cancer, the so-called triple-negative phenotype: a population-based study from the California cancer Registry. Cancer 2007;109:1721 8. [PubMed: 17387718] 5. Brown M, Tsodikov A, Bauer KR, Parise CA, Caggiano V. The role of human epidermal growth factor receptor 2 in the survival of women with estrogen and progesterone receptor-negative, invasive breast cancer: the California Cancer Registry, 1999 2004. Cancer 2008;112:737 47. [PubMed: 18189290] 6. Barrett C, Magee H, O Toole D, Daly S, Jeffers M. Amplification of the HER2 gene in breast cancers testing 2+ weak positive by HercepTest immunohistochemistry: false-positive or false-negative immunohistochemistry? J Clin Pathol 2007;60:690 3. [PubMed: 16822876] 7. Paik S, Bryant J, Tan-Chiu E, et al. Real-world performance of HER2 testing--national Surgical Adjuvant Breast and Bowel Project experience. J Natl Cancer Inst 2002;94:852 4. [PubMed: 12048273] 8. Press MF, Sauter G, Bernstein L, et al. Diagnostic evaluation of HER-2 as a molecular target: an assessment of accuracy and reproducibility of laboratory testing in large, prospective, randomized clinical trials. Clin Cancer Res 2005;11:6598 607. [PubMed: 16166438]
Reichman et al. Page 6 Table 1 HER2 Testing in Three SEER Registries: Percent of Breast Cancer Cases with Known HER2 Results by Selected Characteristics Characteristic N % With Known HER2 Result P-value, Chi-square test All Cases 541 95.2 0.17 Los Angeles 49 89.8 Louisiana 221 95.5 Seattle 271 95.9 Age at Diagnosis 0.39 <50 172 96.5 50 59 121 96.7 60 69 122 94.3 70+ 126 92.9 Stage at Diagnosis 0.36 I 220 93.2 II 143 97.2 III 56 98.2 IV 24 95.8 Unknown 98 94.9 Race 0.59 White 360 94.4 Black 75 96.0 Asian/Pacific Islander 22 100.0 Other/Unknown 84 96.4 Facility Size Small 79 88.6 0.003 Medium 198 94.4 Large 264 97.7
Reichman et al. Page 7 Table 2 Characteristics and Results of HER2 Testing Characteristic N % Result of HER2 Testing Negative 411 79.8 Equivocal 13 2.5 Positive 91 17.7 Type of HER2 Test Performed IHC only 262 50.9 FISH only 61 11.8 IHC and FISH 182 35.3 Other 10 2.0 Source of HER2 Data * Pathology Report 176 34.2 Addenda to Pathology Report 222 43.1 Laboratory Report in Chart 82 15.9 Other Electronic Data 34 6.6 Other 1 0.2 * If multiple HER2 tests were performed all results were required to be in the specified source