Changes in tumor-to-blood ratio as a prognostic marker for progression-free survival and overall survival in neuroendocrine tumor patients undergoing PRRT

The institutional database of the University Clinic Essen was screened for NET patients, who have undergone at least two cycles of [¹⁷⁷Lu]Lu-DOTA-TOC treatment and DOTATOC-PET/CT for baseline and follow-up imaging. The study was performed in accordance with the principles of the Declaration of Helsinki. The local ethics committee (University of Duisburg-Essen, Medical Faculty; protocol number: 22–10,737-BO) approved the analysis of available patient data; the requirement to obtain informed consent was waived.

In-house synthesis of ⁶⁸ Ga peptides followed the procedure outlined by Zhernosekov et al. [15]. ⁶⁸ Ga was obtained from a ⁶⁸Ge/⁶⁸ Ga radionuclide generator (GalliaPharm), and the peptide was supplied by Bachem (until 2016, thereafter by ABX GmBH). The preparation time took approximately 60 min until 2016 and 20 min after; the radiochemical yield ranged from 60 to 70%. Radiochemical yield was not assessed after 2016, but typically, activities ranging from 600 to 1300 MBq were obtained. Quality control assessments, conducted using two thin-layer chromatography (and additionally high-performance liquid chromatography after 2016) systems, confirmed a radiochemical purity exceeding 98%.

[⁶⁸ Ga]Ga-DOTA-TOC-PET/CT was performed after administration of mean (± standard deviation (SD)) 75.1 (± 13.8) MBq [⁶⁸ Ga]Ga-DOTA-TOC (equivalent to 1.0 ± 0.3 MBq/kg_bodyweight) with a mean (± SD) uptake interval of 56.0 (± 25.5) min. In the majority of patients, all follow-up imaging was performed by the use of [⁶⁸ Ga]Ga-DOTA-TOC-PET/CT as well. Until 2019, patients were encouraged to withhold long-acting somatostatin analogs (SSA) in the 4 weeks leading up to SSTR-PET. With the advent of prospective data showing no detrimental effect of SSA administration shortly before SSTR-PET, this practice was not upheld anymore [16].

Image analysis was performed by two readers (MW, OP) using OsiriX MD (Pixmeo SARL) and Carestream Picture Archiving and Communication System (PACS) for image analysis. The readers were blinded for all clinical and imaging information except that the Ga-[⁶⁸ Ga]Ga-DOTA-TOC examinations had been performed in NET patients undergoing PRRT.

The PET/CT assessment was performed as follows: Reference organ uptake was assessed by measuring SUVmax and SUVmean in a volume of interest with a 1 cm (left ventricle, kidney, spleen), 2 cm (liver), or adaptive (abdominal aorta) radius; an additional 50% threshold was employed for SUVmean measurements of the abdominal aorta.

Tumor uptake was categorized as high (≥ 2 × kidney uptake), intermediate (≥ kidney uptake, but < 2 × kidney uptake), and low (< kidney uptake, but ≥ liver uptake). SUVmax and SUVmean (using a 50% threshold) were measured on baseline, follow-up scans for up to three lesions of each uptake category, i.e., up to nine lesions per examination.

The ratios between SUVmean of the tumor were divided by the SUVmean of the left ventricle (TBR) and were subsequently calculated for each lesion. Based on the high deviation of abdominal aorta uptake values and a high congruence of left ventricle uptake measurements, among readers in a prior exploratory blinded reading of 30 patients, SUVmean of the left ventricle was chosen for TBR calculation over SUVmean of the abdominal aorta.

Repeat blinded readings were then carried out by both readers for all patients with conflicting results, i.e., increasing TBR reported by one reader and decreasing TBR by the other or description of new lesions by one reader but not the other. The remaining conflicting results were settled in a joint consensus session. Lastly, the average per patient baseline to follow-up change of TBR across all individual lesional TBRs was calculated.

TBR at baseline as well as changes in TBR from baseline to follow-up imaging were correlated with PFS and OS. Herein, OS was defined as the interval from the first treatment cycle until death/last follow-up. PFS was defined as the interval from treatment start until at least one of the following progression criteria was met:

Treatment was performed in accordance with European Association of Nuclear Medicine guidelines on PRRT and more specifically, according to the NETTER-1 treatment protocol starting in 2017. Co-infusion of 25 g lysine and 25 g arginine was used for nephroprotection. In the pre-NETTER-1 era, patients routinely underwent PRRT with two cycles, with additional cycles being performed in cases of insufficient treatment response. In the recent decade, the PRRT protocol has shifted towards increasing use of four cycles of [¹⁷⁷Lu]Lu-DOTA-TOC.

The 139 patients underwent a total (mean) of 470 (3.4) PRRT cycles. The mean cumulative activity per patient was 23.1 GBq [¹⁷⁷Lu]Lu-DOTA-TOC.

Statistical analysis was performed using SPSS version 27.0 (IBM Corp. Released 2020; IBM SPSS Statistics for Mac, version 27.0, Armonk, NY; IBM Corp).

The impact of mean TBR at baseline as well as changes in TBR and SUVmean on PFS and OS was tested using a univariate and multivariate Cox regression model. PFS and OS of patients with decreasing vs. stable/increasing TBR from baseline to follow-up imaging were compared by use of log-rank test and plotted using Kaplan–Meier curves. Based on a previously published test–retest study, in which unspecific fluctuations in lesional SUVmax of up to 25% were observed, the category of stable TBR (increase/decrease < 25%) was introduced, and additional log-rank tests carried out [18]. A one-way ANOVA with Bonferroni correction was performed to assess differences in TBR for patients with complete/partial remission, stable disease, and PD on first response assessment after PRRT. Pearson’s correlation coefficient was calculated to assess a potential association between SUVmean of the blood pool on the one hand and time post-injection and body weight on the other hand. A p < 0.05 was considered statistically significant.

In total, 139 patients were eligible for evaluation; 78/139 (56%) were male and 61/139 (44%) were female. Mean patient age was 62.1 (27.8–84.4) years. The primary NET was located in the pancreas, midgut, and lungs in 47/139 (34%), 40/139 (29%), and 12/139 (9%) patients, respectively. Histopathological grade was G1, G2, and G3 in 35/139 (25%), 75/139 (54%), and 9/139 (6%) patients, respectively, and unknown/not standard practice in the remainder. The patient selection process is shown in Supplemental Fig. 1. An overview of the patient baseline characteristics is provided in Table 1.

Mean TBR at baseline across all lesions and patients was 22.4. New lesions were observed in 27/139 patients. Increases in TBR were observed in 28/139 patients, 19 of those by > 25%. Decreases in TBR were observed in 84/139 patients, 63 of those by > 25%.

Body weight (p = 0.27; R² = 0.1) and time post-injection (p < 0.001; R² =  − 0.36) showed a weak correlation with SUVmean of the blood pool at best.

RECIST 1.1 response at first imaging, within 3–6 months after the last PRRT cycle, was as follows: complete remission 1/139 (1%), partial remission 10/139 (7%), stable disease 83/139 (60%), and progressive disease (PD) in 42/139 (30%) patients. In 3/139 (2%) patients, full diagnostic cross-sectional imaging was missing. Mean TBR for patients with PD was 22.1, for stable disease 22.4, and for partial/complete remission 25.6 (p = 0.88). An overview of patient follow-up characteristics is provided in Table 2.

Mean imaging follow-up until disease progression, or last patient visit without progression, was 22.3 months (range, 2.6–91.1 months). Disease progression was observed in 107/139 (77%) patients.

Median PFS did not differ significantly between patients with baseline TBR below the median (17.0 months) vs. above the median (23.7 months; p = 0.06). Quartile-wise comparison of baseline TBR revealed significantly shorter median PFS for patients in the 1st quartile (14.4 months) vs. the 3rd (23.7 months; p = 0.03) and 4th quartile (24.1 months; p = 0.02) but not vs. the 2nd quartile (22.3 months; p = 0.14). Any line of systemic treatment other than SSA was significantly associated with shorter PFS (HR, 1.72 [95%CI, 1.16–2.54]; p = 0.006). No other group differences were observed. PFS dependent on baseline TBR is shown in Fig. 1.

After exclusion of patients with PD according to RECIST 1.1 at first follow-up imaging (n = 42), the univariate Cox regression model showed a significantly shorter PFS for increasing TBR under PRRT (HR = 2.13 [95%CI = 1.18–3.85]; p = 0.01). PFS among patients with RECIST 1.1 complete/partial response vs. stable disease on first follow-up imaging after PRRT was similar (p = 0.43).

A further multivariate analysis including tumor grade, as a known prognostic marker [2], confirmed increasing TBR during PRRT as an independent risk factor for early PD (HR = 2.91 [95%CI = 1.54–5.50]; p = 0.01). Results of the uni- and multivariate Cox regression model are presented in Table 3; results of a sub-cohort with small-intestine and pancreatic NETs are presented in Supplemental Table 1.

Log-rank test revealed a similar PFS in patients with new lesions (20.0 months) vs. decreasing (27.6 months; p = 0.34) or increasing TBR (21.1 months; p = 0.89). Patients with increasing TBR showed shorter PFS than those with decreasing TBR (p = 0.04). No statistically significant changes were observed for changes in SUVmean (0.41–0.64).

When introducing the category of stable TBR for increases/decreases < 25%, a significantly shorter PFS was observed in patients with increasing TBR (19.4 months) vs. those with decreasing (25.1 months; p < 0.01) or stable (30.6 months; p = 0.001) TBR. No statistically significant differences with regard to median OS were observed between patients with new lesions vs. any of the other groups (20.0 months; p = 0.13–0.64). Figure 2 shows PFS dependent on changes in TBR.

Mean follow-up time until death or the last documented date of the patient being alive was 37.9 (range, 4.3–130.1) months. 77/139 (55%) patients died during follow-up.

Baseline TBR (p = 0.35) was not statistically associated with OS in a univariate Cox regression model. OS was similar in patients with TBR above vs. below median (median OS, 36.0 vs. 55.4 months; p = 0.03). Quartile-wise comparison of baseline TBR revealed significantly shorter median OS for patients in the 1st quartile (32.5 months) vs. the 2nd (41.8 months; p = 0.03), 3rd (69.2 months; p < 0.01), and 4th (42.7 months; p = 0.03) quartile. Any line of systemic treatment besides SSA did not bear impact on OS (p = 0.10). No other group differences were observed. Comparison of TBR regarding OS is shown in Fig. 3.

A univariate Cox regression model showed that increasing TBR is a significant risk factor for short OS (HR = 1.87 [95%CI = 1.22–2.86]; p < 0.01). The absence of progressive disease according to RECIST 1.1 criteria on the first imaging after PRRT was associated with longer OS as well (HR = 0.43 [95%CI = 0.27–0.69; p < 0.001). A significant association between OS and changes in SUVmean could not be established (p = 0.29).

A multivariate Cox regression model including the parameters tumor grade, PD during PRRT and increases in TBR, confirmed increases in TBR as an independent predictor of short OS (HR = 1.64 [95%CI = 1.03–2.62]; p = 0.02). The absence of RECIST 1.1 PD on the first follow-up imaging after PRRT was significantly associated with longer OS (HR = 0.47 [95%CI = 0.28–0.81]; p < 0.01). Results of the uni- and multivariate Cox regression model are presented in Table 4; a subcohort analysis on patients with small intestine and pancreas NET is presented in Supplemental Table 2.

Log-rank test showed significantly shorter median OS for patients with new lesions (24.2 months) than for those with decreasing TBR (67.3 months; p < 0.001). Median OS was longer for patients with decreasing vs. increasing TBR (34.8 months; p = 0.04). Median OS did not differ significantly between patients with new lesions vs. those with increasing TBR (34.8 months; p = 0.11).

There were statistically significant differences with regard to median OS in patients with new lesions (24.2 months) vs. those with decreasing (28.2 months; p < 0.001) or increasing (24.5 months; p < 0.01) SUVmean. However, median OS did not differ significantly between patients with increasing vs. decreasing SUVmean (p = 0.55).

When classifying patients with minor (< 25%) changes in TBR as stable disease, significantly shorter median OS was observed for patients with new lesions (24.2 months) than for those with stable (54.7 months; p < 0.01) or decreasing TBR (69.2 months; p < 0.001).

The mean OS was shorter in patients with increasing TBR (33.1 months) than in those with decreasing (p < 0.01) or stable TBR (p = 0.04). OS did not differ significantly in patients with stable vs. decreasing TBR (p = 0.82). Comparison of OS based on changes in TBR is shown in Fig. 4.

No statistically significant association was observed for median OS and increasing vs. stable (p = 0.35), increasing vs. decreasing (p = 0.29), and stable vs. decreasing SUVmean (p = 0.63).