Diagnostic Accuracy of ^99mTc-Sestamibi Breast Imaging: Multicenter Trial Results

Subjects

Six hundred seventy-three women were enrolled at 42 institutions in the United States and Canada. Enrollment occurred from April 1994 through May 1995. For enrollment in the trial, the subjects were to be already scheduled for an excisional biopsy (or mastectomy) on the basis of the presence of a nonpalpable mammographically detected breast abnormality or a palpable breast abnormality; 387 women with nonpalpable abnormalities and 286 women with palpable abnormalities were enrolled. As in clinical practice, women with palpable abnormalities did not necessarily have mammographic abnormalities. Because preliminary pilot work had suggested that trauma could lead to false-positive ^99mTc-sestamibi images, subjects could not have undergone fine-needle aspiration or core needle biopsy within 1 wk before the ^99mTc-sestamibi imaging study. To be evaluable, subjects had to have an abnormality identified by palpation or mammography (or both), ^99mTc-sestamibi scintigraphy, and excisional biopsy (or mastectomy) in that sequence; 563 women met evaluability criteria (315 with nonpalpable abnormalities and 248 with palpable abnormalities). The investigational protocol was approved by the institutional review board at each participating center, and each subject provided written informed consent.

Mammography

Mammography was performed using standard craniocaudal and mediolateral oblique views with additional views obtained as clinically indicated. Each participating site in the United States was accredited by the American College of Radiology Mammography Accreditation Program. The Canadian site had full accreditation in medical imaging by the Diagnostic Accreditation Program in British Columbia. Additionally, phantom images and representative mammograms from each site were evaluated by the mammography core center. Deficiencies noted by the core center were corrected before enrolling patients. Collection of mammography results was based on the American College of Radiology Breast Imaging Reporting and Data System (21). Although it is not a common practice, for this trial the mammographer at each site assigned a mammographic probability of malignancy to each lesion (palpable or nonpalpable) that was to be biopsied. The parenchymal patterns “heterogeneously dense” and “extremely dense” were defined to represent dense breasts, whereas “almost entirely fat” and “numerous vague densities” were defined to represent fatty breasts.

Scintigraphy

Planar imaging with high-resolution collimation was performed using the gamma cameras available in the investigators' departments. Subjects received a 740- to 1110-MBq (20–30 mCi) bolus intravenous injection of ^99mTc-sestamibi in the arm contralateral to the suspicious breast abnormality; subjects with bilateral abnormalities were injected in a dorsalis pedis vein. Five minutes after injection, a 10-min lateral view of the breast scheduled for biopsy was obtained with the subject positioned prone on an imaging table overlay (Bodfish Research and Design, Inc., Bodfish, CA) so that the breast being imaged was pendent (11). The subject was then repositioned to obtain a lateral view of the contralateral breast followed by a supine anterior view. Lateral views were repeated 1 h after injection.

Scintigraphic images were read at the sites by the investigators (institutional results). Because most investigators in the trial had minimal experience interpreting ^99mTc-sestamibi breast images, a set of 18 images, scored on a 5-point scale (0 = normal; 1 = equivocal; 2 = focal uptake, low intensity; 3 = focal uptake, medium intensity; and 4 = focal uptake, high intensity) but without histopathologic correlation, was provided for image scoring training.

For the calculation of diagnostic statistics, scores of 2–4 were considered positive, scores of 0 were considered negative, and scores of 1 were considered uninterpretable and were not analyzed. Overall, institutional readers scored 6.4% of biopsied scintigraphic abnormalities as 1. In addition to the image interpretation by the investigators, two groups of three independent nuclear medicine physicians who had no knowledge of the subjects' clinical history, institutional scintigraphic results, or other test results (blinded readers) interpreted the images. Thus, the blinded readers were not told whether they were reading images from subjects with nonpalpable abnormalities or with palpable abnormalities. One group of blinded readers read the images from subjects with nonpalpable abnormalities, and the other group read the images from subjects with palpable abnormalities. For the blinded reading, digital data were converted to a common image display format, and images were randomized and read from the computer display.

Lesion Correlation

Because breast tissue is highly mobile and because mammographic and scintigraphic imaging used different views and techniques (compressed versus noncompressed), it was necessary to review the scintigraphic findings to establish lesion correlation. Thus, a radiologist not associated with the trial reviewed the scintigraphic images and mammograms in conjunction with the blinded readers' image interpretations and the investigational sites' mammographic data reporting to determine whether the scintigraphic abnormality corresponded to the same tissue as the mammographic finding. Similarly, a breast surgeon not associated with the trial reviewed the scintigraphic images, blinded readers' image interpretation, and the investigational sites' physical finding reporting to determine whether the scintigraphic abnormality corresponded to the same tissue as the palpable abnormality. All calculations of diagnostic statistics were based on histopathologically determined malignancy or benignity of biopsied tissue. Because a scintigraphic abnormality that did not correspond to a mammographic abnormality or physical finding was not biopsied, such abnormalities could not be assigned as malignant or benign and thus were excluded from analysis. Characterization of these scintigraphic abnormalities as either false-positive or true-positive findings is the objective of a follow-up study.

Biopsy and Histopathology

Biopsy decisions were based on clinical presentation independent of scintigraphic findings. After needle localization, excision of nonpalpable mammographically detected abnormalities was confirmed by specimen radiography. The institutional histopathologists determined tumor size from excised tissue specimens. Histopathologic diagnosis by the core laboratory was based solely on excisional biopsy or mastectomy specimens. Evaluation was performed on original slides or recuts of the tissue blocks if originals were unavailable. Ductal carcinoma in situ (DCIS), infiltrating ductal carcinoma, and infiltrating lobular carcinoma were classified as malignant. Cases of lobular carcinoma in situ were classified as nonmalignant.

Statistical Analysis

The primary analysis in evaluating ^99mTc-sestamibi for detecting the presence of malignancy compared the blinded reader's image interpretation with the histopathologic diagnosis. Sensitivity, specificity, positive and negative predictive values, and accuracy were calculated. Comparisons between two groups were performed using a two-sample test of proportions. Group differences were considered significant at P < 0.05. Inter-reader agreement was assessed using the κ statistic. κ < 0.40 indicates poor agreement, whereas κ = 0.40–0.75 and κ > 0.75 indicate fair-to-good and strong agreement, respectively (22).

To further investigate factors influencing diagnostic results, a multivariable regression analysis was performed. Variables entered into the model included patient age dichotomized as ≤50 or >50 y, mammographers' likelihood of malignancy, mammographic finding categorized as mass or calcification, lesion palpability, and tumor size dichotomized as <1 or ≥1 cm.

Age

The group of women who were ≤50 y old with nonpalpable abnormalities had a disease prevalence of 21.2%, whereas the group of younger women with palpable abnormalities had a prevalence of malignancy of 34.0%. The overall diagnostic sensitivity for ^99mTc-sestamibi breast imaging was comparable in women ≤50 y old and women ≥50 y old (75.3% and 75.5%, respectively; P = not significant). When the results were considered separately for women with palpable abnormalities and for women with nonpalpable abnormalities, there was a trend for higher sensitivity in older women, although these differences were not statistically significant (Table 2). Imaging specificity was higher in the older population, although this difference was not statistically significant for institutional results for women with palpable abnormalities.

Tumor Size

Diagnostic sensitivity of any imaging procedure is affected by limitations inherent in the procedure (e.g., scintillation camera resolution). Consequently, we assessed sensitivity for the detection of nonpalpable abnormalities as a function of the largest tumor dimension measured on the excised specimen. Institutional sensitivity was significantly higher for tumors ≥1 cm than for tumors <1 cm (74.2% and 48.2%, respectively; P < 0.05). Similar results were observed for the blinded readers.

Likelihood of Malignancy

The prevalence of histopathologically determined disease was well tracked by the mammographers' estimate of a lesion's likelihood of being malignant (r = 0.98; P < 0.005). The institutional sensitivity and specificity of ^99mTc-sestamibi imaging were similar in women with all likelihoods of disease, 64%–82% and 73%–87%, respectively (Table 3). Consequently, in women with ≤40% mammographic likelihood of malignancy, the negative predictive value for ^99mTc-sestamibi imaging was 94%.

Invasive Cancer Versus DCIS

Although our primary analysis classified DCIS as malignant, cognizant of the controversy over whether all DCIS progresses to invasive cancer, we also analyzed the sensitivity for invasive cancer and for DCIS separately. Overall institutional sensitivity was 82.0% for invasive cancer and 45.9% for DCIS (P < 0.001). For women with palpable abnormalities, sensitivity was 90.5% for invasive cancer and 57.1% for DCIS (P = 0.002). For women with nonpalpable abnormalities, sensitivity was 69.2% for invasive cancer and 39.1% for DCIS (P = 0.02).

Time of Imaging

We were interested in evaluating the impact of time of imaging after ^99mTc-sestamibi injection on diagnostic accuracy because ^99mTc-sestamibi tumor efflux could lead to decreased diagnostic sensitivity for delayed imaging. Overall institutional results showed a modest decrease in sensitivity for delayed imaging and a corresponding increase in specificity. However, diagnostic accuracy (Table 4) and area under the receiver operating characteristic curve were comparable for early and delayed imaging. Consequently, to ensure highest sensitivity for the identification of malignant abnormalities, we recommend early scintigraphic imaging only.

Inter-Reader Agreement

Reproducibility for the detection of malignancy among the blinded readers was very high. Inter-reader agreement among the three blinded readers who read scintigraphic images from subjects with palpable abnormalities ranged from 96% to 100% (κ = 0.93–0.99). Inter-reader agreement for evaluation of nonpalpable abnormalities ranged from 95% to 96% (κ = 0.82–0.89).

Multivariable Regression Analysis

The only independent predictors of a true-positive ^99mTc-sestamibi image in the multivariable regression analysis were lesion palpability and tumor size (global χ² = 37.7). The analysis was also conducted excluding tumor size, as would occur for abnormalities detected solely as microcalcifications. Lesion palpability became the only predictive variable in that model.