Prognosis Related to Metastatic Burden Measured by ¹⁸F-Fluorocholine PET/CT in Castration-Resistant Prostate Cancer

DISCUSSION

Metastatic prostate cancer most commonly manifests in the bones and lymph nodes. ¹⁸F-fluorocholine PET/CT can readily interrogate these areas to delineate the route and extent of metastatic progression (9–11). In this study, metabolic tumor volume analysis succeeded in quantifying metastatic disease found on ¹⁸F-fluorocholine PET/CT in a manner that relates with prognosis. Specifically, whole-body tumor burden indices based on quantifying net MATV and net TLA on ¹⁸F-fluorocholine PET/CT were found to be predictive of OS in univariate and individually adjusted Cox regression analyses. This association between metastatic burden and prognosis is well supported by other lines of research linking a heavy tumor load with increased risks of hematologic and skeleton-related complications as well as higher mortality in metastatic prostate cancer (7,8,16–18).

Increased choline metabolism by tumors is associated with increases in phospholipid membrane synthesis and cell proliferation (19,20), as well as upregulated second-messenger activity along mitogenic pathways (21,22). Clinical and experimental observations have also linked increased choline metabolism to biologic aggressiveness in prostate cancer (23,24). The results of this study also support a role for choline metabolism in promoting prostate cancer progression through the observation that the highest tumor SUV_max from each scan was a significant predictor of OS. Although adjustments for tumor volume abrogated the statistical significance of SUV_max, the biologic significance of choline metabolism cannot be entirely dismissed since lesion MATV is also defined on the basis of tumor ¹⁸F-fluorocholine avidity. The biologic and prognostic implications of upregulated choline metabolism in prostate cancer should be better understood with more research.

TLA as defined in this study was based on the concept of total lesion glycolysis borrowed from ¹⁸F-FDG PET studies (12). TLA and total lesion glycolysis build on the concept of MATV by further integrating the metabolic information with volume data. In this study, net MATV and net TLA were the only parameters found to have preserved significance after adjustment by another significant univariate. Although multivariate analyses in this study were limited to only singular adjustments because of the relatively small sample size, this preliminary observation does support metabolic volume measurements on ¹⁸F-fluorocholine PET as prognostic factors that may be independent of PSA.

In this study, net MATV and net TLA measurements proved strongly colinear, suggesting that these parameters may have similar behavior in characterizing prognosis. In contrast, studies using ¹⁸F-FDG PET have reported significant differences in the predictive ability of MATV and total lesion glycolysis (25,26). Thus, the relative predictive value of ¹⁸F-fluorocholine–derived MATV and TLA in other clinical contexts, such as the measurement of therapeutic response, remains open to further study.

Patients were enrolled to this study after developing resistance to complete androgen blockade as evidenced by their rising PSA levels. All patients subsequently underwent chemotherapy or further manipulation of their androgen hormonal axis, as these were the most common treatment interventions for CRPC at the time of the study (3,4,27). Because treatments were selected on a clinical basis, they were not uniform in the study and therefore constitute potential confounders. However, the type of treatment received by patients did not demonstrate a significant effect on OS on Cox regression analysis, and there were no significant differences in PSA level, SUV_max, net MATV, or net TLA across different treatments. It is possible that any effect of treatment on survival was relatively small (e.g., docetaxel improves median survival by less than 2.5 mo (2,3)) or not significantly different between the types of treatment. Although it may have been possible to assess progression-free survival, OS was the only endpoint used in this study because of recognized inconsistencies in measuring progression-free survival in CRPC (5,28). As novel treatments for CRPC continue to emerge, their effects may warrant characterization on the basis of ¹⁸F-fluorocholine PET/CT in consideration of further developing ¹⁸F-fluorocholine PET/CT as a predictive biomarker for prostate cancer.

No survival differences were found related to the distribution of metastatic lesions (i.e., skeletal vs. nodal). However, the number of cases of nonskeletal metastases in this study was too small to afford a statistical conclusion. Previous studies have measured prognosis with imaging of just skeletal tumor burden (16–18). One study also linked poor survival with visceral disease (8). Further research is needed to clarify the impact of lesion distribution on prognosis in metastatic CRPC.

The process of defining MATV was automated in this study to provide reproducible PET measurements with little effort. However, only one specific method of image segmentation was used, and the optimal method for defining MATVs on ¹⁸F-fluorocholine PET/CT has yet to be determined. Although there are multiple approaches to PET volume segmentation (14), the high contrast achieved by metastases on ¹⁸F-fluorocholine PET/CT made it feasible to use a relatively simple threshold-based method. Unlike with ¹⁸F-FDG, the rapid clearance of ¹⁸F-fluorocholine from the vascular pool allowed PET images to be acquired shortly after tracer injection while still achieving good image quality and background contrast for automated MATV segmentation. Nonetheless, it may be worthwhile to further develop MATV segmentation methods specifically for ¹⁸F-fluorocholine PET/CT based on the potential clinical applications for such a technique.

The main limitations of this study were its sample size and single-institution setting. Both SUV_max and MATV are nonabsolute measures that are influenced by factors such as PET scanner calibration and image reconstruction method. The timing of tracer administration and image acquisition may also affect measurement reproducibility. Further research is required to characterize these effects and their impact on tumor volume segmentation on ¹⁸F-fluorocholine PET/CT. Consequently, parameters from this study may not necessarily be optimal for other institutions, and further work will be required to validate and generalize this technique for the clinical setting.

Because biopsies to confirm metastatic prostate cancer are often not clinically warranted, histopathologic diagnoses were not used to confirm the tumor origin of lesions detected by ¹⁸F-fluorocholine PET/CT. Thus, an assumption that the lesions quantified in this study were indeed prostate cancer metastases was applied. Hopefully, the study eligibility criteria minimized the possibility that another disease process produced ¹⁸F-fluorocholine–avid lesions, and given that all patients met the criteria for advanced prostate cancer at enrollment, this limitation should not significantly detract from the study conclusions.

Baseline prognostic markers are important in clinical trials to establish cohorts of uniform prognosis before randomization. They are also crucial in clinical practice to help in tailoring treatments to overall risk. Previous efforts in prostate cancer risk assessment have so far led to the development of clinical predictive nomograms (7,8). Although such nomograms tell little about the tumors directly, their incorporation of hemoglobin, lactate dehydrogenase, and alkaline phosphatase levels does serve to reflect the degree of skeletal and marrow compromise resulting from metastatic disease. Because PET can provide more direct information about the tumor, this imaging technique could complement existing prognostic markers, or at least provide unique information to enhance future predictive nomograms. Thus, further validation of ¹⁸F-fluorocholine PET/CT as a prognostic marker should ideally be pursued in the context of existing prognostic tools.

Although the diagnostic sensitivity and specificity of ¹⁸F-fluorocholine PET/CT for detecting CRPC is reportedly superior to that of conventional imaging (29), it is possible that some metastases may not be detected solely on the basis of increased ¹⁸F-fluorocholine uptake. With regard to disease detectability, the results of the current study suggest that having only a small volume of disease found on ¹⁸F-fluorocholine PET/CT can impart a favorable prognosis even in patients with CRPC. The natural history of prostate cancer progression is complex, and the diagnostic sensitivity of ¹⁸F-fluorocholine PET/CT may vary depending on prior treatments and clinical circumstance (9). The prognostic significance of a “negative” result on ¹⁸F-fluorocholine PET/CT is unknown in clinical states such as biochemical recurrence, evolving hormone resistance, or even initially when deciding on the primary treatment. Because treatment decisions throughout the course of prostate cancer are often predicated on considerations of competing mortality risks, it may be worthwhile to further explore the prognostic value of ¹⁸F-fluorocholine PET/CT in clinical situations in which this technique has already been applied for disease detection.