¹⁸F-Fluoroestradiol PET: Current Status and Potential Future Clinical Applications

¹⁸F-FES STRUCTURE, SYNTHESIS, PHARMACOKINETICS, AND SAFETY

Early efforts to develop an ER-targeting radiotracer involved labeling steroid and nonsteroid compounds with iodine and bromine (9). However, the subsequent advent of PET imaging and ¹⁸F—a small halogen that displayed uptake in target tissue, elimination in nontarget tissue, substitution at several positions in various estrogen analogs, and a half-life long enough to allow for multistep synthesis (10,11)—encouraged the development of ¹⁸F-labeled compounds.

In 1984, Kiesewetter et al. found that ¹⁸F-FES exhibited the highest uptake selectivity and target-to-background ratio among several ¹⁸F-labeled estrogens (10). Newer compounds such ¹⁸F-moxestrol and 4-fluoro-11β-methoxy-16α-¹⁸F-FES demonstrated increased ER binding, with ¹⁸F-moxestrol also displaying decreased metabolism (12,13). However, ¹⁸F-moxestrol displays suboptimal uptake in humans, which likely arises from modest binding to sex-hormone–binding globulin (SHBG), the main plasma protein estradiol transporter, compared with ¹⁸F-FES (12). Although adequate uptake in humans has been demonstrated by 4-fluoro-11β-methoxy-16α-¹⁸F-FES, tumor uptake comparison studies and further testing are needed. To date, ¹⁸F-FES remains the most widely studied ER PET imaging compound.

¹⁸F-FES is highly extracted and metabolized by the liver, resulting in rapid early blood clearance and steady total blood activity by 10–15 min after injection (11). By 20 min after injection, only 20% of the total activity is attributable to unmetabolized ¹⁸F-FES; by 120 min, only 10%. Like estradiol, unmetabolized ¹⁸F-FES is heavily protein-bound in blood. Although ¹⁸F-FES has much higher affinity for SHBG than for albumin, the higher concentration of albumin in blood results in an approximately 1:1 distribution of ¹⁸F-FES between SHBG and albumin (14). Its non-SHBG–bound metabolites, comprised of glucuronide and sulfate conjugation products (11), are secreted in bile, resorbed via enterohepatic circulation, and renally excreted. The rate of decline in total liver activity is similar to the rate of increase in total bladder activity, suggesting that ¹⁸F-FES metabolites are cleared by the kidneys at nearly the same rate as they are released into the circulation by the liver (11). At the highest recommended dose, 2.22 × 10⁸ Bq, the effective dose equivalent is 0.002 mSv/MBq, with the critical organ being the liver, at 0.13 mSv/MBq (15). Cumulative experience in published human studies has yet to demonstrate any associated toxicities or adverse events. Collectively, these characteristics make ¹⁸F-FES a favorable ER PET imaging tracer.

¹⁸F-FES has been studied as an investigational diagnostic agent in Canada, Europe, and Asia. Although it is currently considered an investigational drug in the United States, several American academic centers hold Investigational New Drug approvals that support studies involving ¹⁸F-FES PET and ¹⁸F-FES PET/CT. The National Cancer Institute also holds an Investigational New Drug approval (79,005)—enabled by a University of Washington study (16)—that can support multicenter trials in National Cancer Institute–supported clinical trial networks. There has been discussion in Europe and the United States of seeking regulatory approval for ¹⁸F-FES on the basis of published studies and accruing data from prospective multicenter trials.

CORRELATION OF ¹⁸F-FES UPTAKE AND TUMOR ER EXPRESSION

Multiple studies have demonstrated a correlation between ¹⁸F-FES uptake and tumor ER expression as measured by conventional in vitro assays (Supplemental Table 2). In 1988, Mintun et al. verified the association between ¹⁸F-FES uptake and in vitro tumor ER concentration as measured by radioligand binding among patients with primary breast masses (17). Subsequent studies established the correlation between ¹⁸F-FES uptake and immunohistochemical assay results. Peterson et al. used an SUV threshold of 1.1 to characterize tumors as ER-positive or ER-negative, reporting a correlation coefficient of 0.73 between ¹⁸F-FES uptake and immunohistochemical index results (18) consistent with correlations from studies comparing in vitro radioligand binding assays to immunohistochemical assays (19).

Peterson et al. also studied the correlation between immunohistochemical assays and other ¹⁸F-FES uptake quantification methods, finding that those that accounted for variable blood clearance and the presence of labeled ¹⁸F-FES metabolites provided no definite advantages over simpler SUV measurements (18). More recently, ¹⁸F-FES uptake and immunohistochemical ER expression have been demonstrated in early-stage breast cancers, though with a lower sensitivity than found in prior studies (20).

Other factors that can affect tumor ¹⁸F-FES uptake have also been evaluated. Prior analyses posited that competition with higher circulating estrogen levels in premenopausal women may contribute to false-negative ¹⁸F-FES PET results (21). However, Peterson et al. subsequently demonstrated no significant difference in average ¹⁸F-FES uptake based on a plasma estradiol threshold of 30 pg/mL, a level typically used to indicate menopausal status (22). In this same study, F-FES uptake was inversely associated with plasma SHBG levels but not with testosterone levels, patient age, or disease stage at time of imaging—discrepancies suggesting that although a certain amount of binding to SHBG may be necessary to protect F-FES from metabolism, protein-bound ¹⁸F-FES may be less available to tissue ER receptors and result in decreased ¹⁸F-FES uptake. Thus, measurement of SHBG levels in patients could be considered, especially in clinical scenarios such as the postpartum period, when SHBG levels might be expected to be outside the typical range.

This study also revealed only a modest effect of lower injected specific activities on ¹⁸F-FES uptake, suggesting that cold ¹⁸F-FES would not significantly saturate tissue ERs at specific activities of greater than approximately 11.1 GBq/mol. However, since a small (∼10%) negative effect on ¹⁸F-FES uptake was noted for injected ¹⁸F-FES masses greater than 0.2 nmol/kg, injected mass should aim to be below this value (22).

BASELINE ¹⁸F-FES UPTAKE AS A PREDICTOR OF RESPONSE TO ENDOCRINE THERAPY

For patients with ER-positive breast cancer, endocrine therapy can potentially provide effective treatment with fewer side effects and lower morbidity than chemotherapy (6). However, ER positivity correctly predicts response in only 50%–60% of treatment-naïve patients (5) as measured by in vitro immunohistochemical assays, which require biopsies and are thus limited by sampling error and disease heterogeneity. In contrast, ¹⁸F-FES PET can evaluate ER expression across all tumor sites and present a more complete picture of a patient’s overall ER status.

Studies have demonstrated a correlation between response to endocrine therapy and baseline pretreatment ¹⁸F-FES uptake (Supplemental Table 3). Both Dehdashti et al. and Mortimer et al. investigated baseline ¹⁸F-FES uptake in ER-positive patients beginning tamoxifen therapy (23,24). Using a threshold SUV of 2.0 for baseline ¹⁸F-FES uptake, they reported a positive predictive value of 79%–87% and negative predictive value of 88%–100% for response.

The utility of baseline ¹⁸F-FES PET imaging has also been demonstrated in patients undergoing salvage therapy with aromatase inhibitors (AIs) and fulvestrant. In a study of patients with heavily pretreated metastatic breast cancer, Linden et al. established a threshold ¹⁸F-FES SUV of 1.5 for baseline ¹⁸F-FES uptake, below which no patient responded (Supplemental Fig. 1) (25). Using a higher SUV threshold of 2.0, Dehdashti et al. demonstrated a negative predictive value of 81% for response (26). Both studies demonstrated a poor positive predictive value of 34%–50%, a finding consistent with known decreased objective response rates to endocrine therapy among those with recurrent and previously treated disease (27).

Taken together, these studies demonstrate the value of ¹⁸F-FES PET in predicting endocrine responsiveness or unresponsiveness. Data from 4 studies evaluating response to tamoxifen, AIs, and fulvestrant (23–26) reveal that of the 159 patients who underwent pretreatment ¹⁸F-FES PET imaging, only 1 with a baseline ¹⁸F-FES SUV of less than 1.5 responded to endocrine therapy by demonstrating disease stabilization (Supplemental Fig. 2) (26).

Applying an SUV threshold of 1.5 to these data, van Kruchten et al. studied the relationship between baseline ¹⁸F-FES PET and response to low-dose oral estradiol as salvage therapy (28). It is thought that long-term antiestrogen therapy may induce hypersensitivity to estrogens, whereby estrogen exposure activates apoptosis rather than growth pathways (29). In this scenario, the presence of ER, which could be measured by ¹⁸F-FES PET, is necessary to induce these apoptotic pathways. The threshold SUV of 1.5 demonstrated a positive predictive value of 60% and negative predictive value of 80% for response to low-dose estradiol (28).

An alternative approach to predicting response uses ¹⁸F-FDG PET imaging, which has been established as a predictive biomarker in cancers such as lymphoma (30). In breast cancer, a clinical flare can occasionally be seen with therapeutic agents possessing ER-agonist properties, where symptom exacerbation upon therapy initiation predicts subsequent response (31). Studies have shown that ¹⁸F-FDG PET can also detect subclinical metabolic flares in patients who subsequently respond to therapy (23,24). ¹⁸F-FDG PET can manifest transient agonist activity early after initiation of tamoxifen therapy. Comparison of ¹⁸F-FDG PET findings before and 7–10 d after initiation of tamoxifen showed increased ¹⁸F-FDG uptake in patients who subsequently responded but no significant change in uptake in nonresponders. Metabolic flare induced by an estradiol challenge was also predictive of response to AIs and fulvestrant as well as improved survival (26).

Studies supporting both pretherapy ¹⁸F-FES PET and early serial ¹⁸F-FDG PET to predict endocrine responsiveness have generated debate about which approach is more clinically applicable. Both radiotracers show a high negative predictive value for endocrine responsiveness, but serial ¹⁸F-FDG PET possesses a higher positive predictive value for response than does pretherapy ¹⁸F-FES PET (23,24). Some also argue that ¹⁸F-FDG PET is more widely available and applied in the setting of metastatic breast cancer. However, serial ¹⁸F-FDG PET requires 2 PET scans and exposure to a therapy with ER-agonist properties. In contrast, a single baseline ¹⁸F-FES PET study is able to predict response for various endocrine therapies before any exposure to therapy, directing patients without ER expression away from likely unbeneficial endocrine treatments. In addition, the increasing use of therapeutic strategies combining endocrine and other targeted therapy increases the need to determine ER expression and suitability for combined treatment. One potential framework for combining both approaches would be to first use ¹⁸F-FES to confirm target expression in patients whose tumors express ER and then use serial ¹⁸F-FDG PET or another standard modality to predict responsiveness by assessing the pharmacodynamic response to a specific type of therapy (Supplemental Fig. 3) (32).

ABILITY OF ¹⁸F-FES PET TO ASSESS WHOLE-BODY TUMOR BURDEN AND HETEROGENEITY OF DISEASE

One major advantage of ¹⁸F-FES PET is its ability to noninvasively assess the in vivo ER status of several tumor lesions across the whole body simultaneously. Evaluating for lesions with discordant ¹⁸F-FDG and ¹⁸F-FES uptake can determine the heterogeneity of a patient’s disease (Supplemental Fig. 4) (16,25,33,34).

Studies correlating ¹⁸F-FES uptake with in vitro ER expression and response to hormone therapies have demonstrated the ability of ¹⁸F-FES PET to image metastatic disease in vivo (Supplemental Table 4) (17,21,33). Among multiple metastatic sites in individual patients, ¹⁸F-FES uptake was concordant with in vitro ER expression (33). Patients with discordant in vitro ER expression and ¹⁸F-FES uptake (i.e., ER-positive but ¹⁸F-FES–negative) tended to have a decreased response to hormone therapy, suggesting that ¹⁸F-FES PET may identify tumor sites that are ER-positive by in vitro assay but functionally hormone therapy–resistant (16,33,34).

Kurland et al. specifically studied the within-patient and between-patient concordance of ¹⁸F-FES uptake and a previously documented ER-positive biopsy (35). Although ¹⁸F-FES uptake and the ratio of ¹⁸F-FES to ¹⁸F-FDG uptake were generally consistent across a single patient, these values varied greatly between patients despite the fact that all but one originally had ER-positive primary tumors. Thirty-four of the 91 patients, many of whom had already undergone treatment with one or more antiestrogen therapies, had an average ¹⁸F-FES SUV below 1.0, suggesting that exposure to endocrine therapy may impose selective pressure for tumor phenotypes with low or nonfunctional ER expression.

There was also a small number of patients who demonstrated highly discordant ¹⁸F-FES uptake across sites (i.e., ¹⁸F-FES–positive and ¹⁸F-FES–negative lesions), a finding that possibly reflects an emerging loss of ER expression in only some lesions. In another study evaluating within-patient concordance of ¹⁸F-FES uptake, discordant ¹⁸F-FES uptake was seen only in patients pretreated with endocrine therapy (36).

Potential discrepancies in tumor ER status and ¹⁸F-FES uptake are particularly important for women with recurrent or metastatic disease. Several studies have demonstrated that although a primary tumor may have been ER-positive, its metastatic lesions may no longer express ER or may express only nonfunctional ERs (16,33,34). Because it is clinically infeasible to biopsy all sites of disease to determine overall ER expression, or to make a patient undergo repeated biopsies to evaluate tumor phenotype evolution, ¹⁸F-FES PET imaging could represent an important adjunct for monitoring ER expression at the time of disease progression or throughout a treatment course.

UTILITY OF ¹⁸F-FES PET IN ASSESSING IN VIVO PHARMACODYNAMICS

Several investigators have used ¹⁸F-FES PET to study the in vivo pharmacodynamics of standard endocrine therapies (23,24,37,38) and validate new investigational ER antagonists (Supplemental Table 5) (39,40). McGuire et al. used repeated ¹⁸F-FES PET imaging to demonstrate a change in ¹⁸F-FES uptake after initiation of endocrine therapy. Compared with the baseline ¹⁸F-FES PET scan, decreased ¹⁸F-FES uptake at known metastatic lesions 7–10 d after initiation of tamoxifen provided evidence of receptor-mediated tumor uptake of ¹⁸F-FES (41). Mortimer et al. demonstrated similar decreases in ¹⁸F-FES uptake in patients receiving tamoxifen (24) and showed that the mean percentage decrease in ¹⁸F-FES uptake after initiation of therapy was significantly higher in responders (54.8% ± 14.2%) than in nonresponders (19.4% ± 17.3%; P = 0.0003).

Linden et al. evaluated changes in ¹⁸F-FES uptake in patients receiving tamoxifen, AIs, or fulvestrant (37). As expected, treatment with tamoxifen, a selective ER modulator, and fulvestrant, a selective ER downregulator, was associated with a greater decrease in ¹⁸F-FES uptake than treatment with AIs, which decrease the amount of circulating estrogen and do not act directly on ER. Van Kruchten et al. also used ¹⁸F-FES PET to study the effects of fulvestrant on ¹⁸F-FES uptake (38). Thirty-eight percent of patients demonstrated incomplete reduction of ¹⁸F-FES uptake (defined as less than a 75% decrease in median tumor SUV), which was significantly associated with shorter progression-free survival. There was also wide variance in the median change in ¹⁸F-FES SUV before and after initiation of therapy (−99% to +60%), with significantly larger decreases in patients with clinical response than in those with disease progression (median change in SUV, −88% vs. −58%). Neither clinical response nor degree of change in ¹⁸F-FES uptake correlated with plasma drug levels of fulvestrant, pointing to the unique potential of ¹⁸F-FES PET in evaluating the effects of fulvestrant at the receptor level.

In a related preclinical study, Heidari et al. demonstrated that increasing fulvestrant doses in murine xenografts led to parallel decreases in ¹⁸F-FES uptake and ER expression by immunohistochemical assay and that these did not correlate with ¹⁸F-FDG uptake (42). These findings suggest that changes in ER availability occur before detectable changes in tumor metabolism and growth. Since higher doses (750 mg vs. 500 mg) of fulvestrant have been studied with minimal increase in side effects (43), serial ¹⁸F-FES PET imaging could conceivably be used to measure early blockade of ER to guide individualized ER-antagonist dosing. However, this approach would require further testing to determine its accuracy and impact.

These concepts could also be applied to new investigational endocrine therapies, both to demonstrate effective ER blockade and to identify optimal dosing for complete ER downregulation. Wang et al. described a new ERα antagonist, ARN-810, and used ¹⁸F-FES PET to validate ER target engagement (39). Dickler et al. then evaluated ARN-810, also known as GDC-0810, in a phase I study and used ¹⁸F-FES PET to assess pharmacodynamic activity and demonstrated greater than 90% suppression of estradiol binding to ER in 90% of patients (40).

NON–BREAST CANCER USES OF ¹⁸F-FES

POTENTIAL CLINICAL USES

As described in this review, ¹⁸F-FES PET has the ability to quantify regional ER expression in breast cancer and preliminarily in other cancers. As with ER assays of sampled tissue, the key value of ¹⁸F-FES PET is in identifying patients whose tumors do not express ER, indicating a lack of endocrine responsiveness. Studies have also demonstrated the utility of ¹⁸F-FES as a pharmacodynamic marker for endocrine therapy, especially to assess the degree of blockade by ER antagonists. Below, we review possible clinical applications in which ¹⁸F-FES PET might be applicable to current and future practice.