Abstract
Purpose
Novel biomarkers to better predict outcome and select the best therapeutic strategy for the individual patient are necessary for pancreatic ductal adenocarcinoma (PDAC).
Methods
Using a panel assay, multiple biomarkers (IFN-γ, IL-10, IL-6, IL-8, TNF-α, CEA, CA 19–9, CYFRA 21–1, HE4, PD-1 and PD-L1 levels) were measured in serum samples of 162 patients with resected, locally advanced and metastatic PDAC in this retrospective single-center study. Optimal cut-off values to differentiate prognostic subgroups with significantly different overall survival (OS) were determined by receiver operator characteristics and Youden Index analysis. Marker levels were assessed before the start of chemotherapy and correlated with OS by univariate and multivariate Cox analysis.
Results
Median OS for resected patients was 28.2 months, for locally advanced patients 17.9 months and for patients with metastatic disease 8.6 months. CYFRA 21–1 and IL-8 discriminated metastatic from locally advanced patients best (AUC 0.85 and AUC 0.81, respectively). In univariate analyses, multiple markers showed prognostic relevance in the various subgroups. However, multivariate Cox models comprised only CYFRA 21–1 in the resected group (HR 1.37, p = 0.015), IL-10 in locally advanced PDAC (HR 10.01, p = 0.014), as well as CYFRA 21–1 and CA 19–9 in metastatic PDAC (p = 0.008 and p = 0.010) as an independent prognostic marker for overall survival.
Conclusion
IL-10 levels may have independent prognostic value in locally advanced PDAC, whereas CYFRA 21–1 levels are prognostic after PDAC surgery. CYFRA 21–1 and IL-8 have been identified to best discriminate metastatic from locally advanced patients.
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Introduction
Pancreatic ductal adenocarcinoma (PDAC) remains one of the most common and deadliest cancers. A 5-year overall survival rate of 10% (Siegel et al. 2021) and increasing incidence rates (Rahib et al. 2014) emphasize the unmet clinical need for more impactful therapeutic and diagnostic options. While combination chemotherapies have prolonged progression-free survival and overall survival (OS), they are often accompanied by significant side effects (Conroy et al. 2011; Von Hoff et al. 2013). Biomarkers to better stratify which patients benefit from a certain therapy, to allow early response assessment, or to identify patients with better or worse prognosis, are subject to ongoing research. So far, the biomarker best established as part of routine PDAC care is carbohydrate antigen 19–9 (CA 19–9) (Boeck et al. 2006). It has been shown that baseline CA 19–9 levels as well as CA 19–9 kinetics under treatment are significant prognostic factors in patients with advanced PDAC (Boeck et al. 2010; Haas et al. 2013; Chiorean et al. 2016). In patients with resectable PDAC, a preoperative constellation of high CA 19–9 combined with CEA (carcinoembryonic antigen) and CA 125 (carbohydrate antigen 125) elevation is associated with poor surgical outcome (Liu et al. 2015). The diagnostic value of CEA alone as a predictor of advanced PDAC could be demonstrated as well and diagnostical cut-off values have been determined (van Manen et al. 2020). However, optimal cut-off values for common biomarkers to predict the prognosis within a pancreatic cancer stage are yet to be defined. Although used to a lesser extent in clinical routine, CYFRA 21–1 (cytokeratin 19 fragment 21–1) has been identified as an independent predictor for OS in advanced PDAC while also being a significant marker for objective treatment response during the course of treatment (Boeck et al. 2013). Besides diagnostic and prognostic value, another important aspect of the establishment of biomarkers is accessibility, making blood-based biomarkers more attractive than tissue-based markers, as it allows for convenient evaluation of multiple time points without relevant additional risk to the patient. The development of various panel diagnostics has opened new possibilities to assess multiple biomarkers in one run, requiring only a small amount of sample material (Song et al. 2019).
In this retrospective, single-center biomarker study, multiple investigational biomarkers were measured in serum samples from 162 patients with resected, locally advanced or metastatic PDAC. The aims of the study were to identify novel diagnostic and prognostic biomarkers as well as cut-off values thereof, to correlate the biomarker serum levels with each other, and to investigate differences in biomarker serum levels and their discriminatory power between resected, locally advanced, and metastatic PDAC patients. Besides the already well-established biomarkers CA 19–9, CEA and CYFRA-21, we chose to investigate protein markers such as HE4, soluble PD-1 and PD-L1. Furthermore, we evaluated a panel of proinflammatory cytokines that have not been extensively examined in PDAC patients receiving chemotherapy yet but are thought to play an important role in the biology of PDAC, a disease associated with a pronounced inflammatory tumor microenvironment (Padoan et al. 2019).
Patients and methods
Patient population and treatment
Patients with histologically confirmed resected, locally advanced and metastatic PDAC treated at the LMU outpatient clinic between 2011 and 2020 were considered eligible for this study (figure S1). Patients with secondary neoplasia or who had received previous systemic treatment for PDAC were excluded. Commencement of neoadjuvant, adjuvant or palliative chemotherapy within 30 days after study inclusion, as well as the availability of pre-therapeutic serum samples were mandatory. The study has been approved by the local ethics committee of the Ludwig-Maximilians-University Munich (approval number 284–10); all patients had given written informed consent before any study-specific procedure was performed.
Sample collection and assays
Venous blood samples were collected in gel-separation tubes (Sarstedt, Nümbrecht, Germany) before initiation of chemotherapy (either in adjuvant, neoadjuvant or palliative intent). The samples were centrifuged at 3000 rounds per minute (rpm) for 10 min at room temperature; afterwards the serum was separated, aliquoted and frozen at – 80 °C. Samples were only thawed prior to analysis. CA 19–9, CEA, CYFRA 21–1 and HE4 were measured by the electrochemiluminescence immunoassay Elecsys® and the Cobas e 411 Analzyer (Roche Diagnostics, Penzberg, Germany) as described previously (Boeck et al. 2013). For measurement of the serum cytokines IFN-γ, IL-1β, IL-2, IL-4, IL-6, IL-8, IL-10, IL-12p70, IL-13, and TNF-α the commercially available Multi-Spot Assay V-PLEX Plus Proinflammatory Panel 1 Human Kit and the Mesoscale Quickplex SQ 120 (both obtained from Meso Scale Diagnostics, LLC, Rockville, USA) were used. The measurements were performed according to the manufacturer’s instructions.
Soluble PD-1 and PD-L1 were measured by Sandwich-ELISA using the Human PD-1 and Human PD-L1 DuoSet ELISA Development Kits (R&D Systems, Minneapolis, USA) and the Mesoscale Quickplex SQ 120 platform In brief, quickplex 96-well standard plates were incubated with 25 µl/well capture antibodies (concentration 2 µg/ml for PD-1 and 4 µg/ml for PD-L1), sealed and incubated overnight. On the following day, the plates were washed three times (200 µl/well 0.05% Tween®20). Next, 150 µl PBS with 5% BSA were added as a blocking agent, the plate was then sealed and shaken at 500 rpm for 1 h. After another washing step, 25 µl of calibrators or patient samples were added and incubated for 2 h while being shaken at 500 rpm. The calibration curve consisted of 1:4 dilutions of the standard ranging from 30 ng/ml to 7 pg/ml. For the PD-1 assay, diluent 2 was used for dilution, and for the PD-L1 assay PBS with 1% BSA was used. The samples were added undiluted. After a further washing step as described above, 25 µl/well of unlabeled detection antibodies were added (concentration 400 ng/ml for PD-1 and 100 ng/ml for PD-L1). The plates were sealed and incubated for 2 h under shaking conditions. Afterwards, the plates were washed once more, and 25 µl streptavidin-sulfo-tag antibodies were added and incubated for 2 h. After another washing step, 150 µl/well MSD Gold Read Buffer A was added and chemiluminescent measurement was conducted by the Mesoscale Quickplex SQ 120 reader. Acquired data were analysed with the software Discovery Workbench 4.0.12.
Study design and statistical analysis
The primary goal of this retrospective biomarker study was to evaluate the prognostic value of 16 serological biomarkers with regard to OS in patients with resected, locally advanced and metastatic PDAC. OS was defined as the time interval between study inclusion until death from any cause. Median follow-up was 52.1 months; the observations were censored for patients alive at a pre-defined time point (January 31st, 2020). Secondary study endpoints included the quantification limits and distribution of biomarkers, correlation of the biomarker serum levels with each other, evaluation of differences and discriminatory power in biomarker serum levels between the three study groups regarding the stage of disease and definition of relevant cut-offs.
The correlation between biomarker serum levels and patient age was estimated by Spearman’s rank-order correlation. Correlation of the biomarker serum levels with each other were also calculated with Spearman’s rank-order correlation and visualized in a heatmap. The differences in biomarker serum levels between the three study groups were tested by Kruskal–Wallis test and in regard to the ability to differentiate between the study groups by the area under the receiver operator characteristics (ROC) curve. A higher area under the curve (AUC) marks a higher discriminatory power. A 95% confidence interval (CI) not including the value 0.5 was considered a significant result.
By univariate Cox regression analysis, interval scaled biomarker serum levels were examined for prognostic relevance. Optimal biomarker serum level cut-off values that differentiate between a better or poorer outcome than group-specific median OS were calculated by ROC and Youden Index. Based on these cut-off values the study groups were divided into two groups and OS was estimated by the Kaplan–Meier method; differences in the survival curves were calculated by log-rank test (with a p-value of < 0.05 regarded as statistically significant). Parameters with statistical significance in the univariate analysis were included in multivariate Cox regression models.
Results
Patient characteristics
Ninety-five male and 67 female patients with pancreatic cancer from our high-volume comprehensive cancer center were included in this study. Baseline characteristics are summarized in Table 1: the majority of included patients (n = 103, 64%) presented with metastatic disease, while 20 patients (12%) had locally advanced PDAC, and 39 patients (24%) had undergone curative-intent surgical tumor resection before inclusion in this biomarker study (figure S2). The median time interval between tumor resection and measurement of serum markers was 54 days; all patients with resected PDAC received adjuvant chemotherapy, in most cases (92%) single-agent gemcitabine. Out of 20 patients with locally advanced PDAC, 9 were treated with palliative chemotherapy, and 11 received neoadjuvant chemotherapy, followed by secondary tumor resection in 8 patients. Systemic treatment for locally advanced PDAC most frequently consisted of 5-FU-based regimens (75%). The majority of patients with stage IV PDAC had synchronous metastatic disease (87%) and most received palliative chemotherapy (97%). 5-FU-based regimens were most common (44%), followed by gemcitabine-based regimens (32%) and gemcitabine monotherapy (24%). Only three patients with metastatic PDAC received ‘neoadjuvant’ chemotherapy and palliative resection of the primary tumor as an individualized therapeutic concept. Median follow-up after inclusion in this study was 52.1 months. Patients with resected PDAC had a median OS of 28.2 months, while median OS in locally advanced and metastatic PDAC patients were estimated at 17.9 and 8.6 months, respectively.
Quantification limits and distribution of biomarkers
Of the serological biomarkers investigated in this study, the interleukins IL-1β, IL-2, IL-4, IL-12p70 and IL-13 were not included in the further analysis due to more than 95% of measured values lying below the lower level of quantification of the assay used (for details see table S1). The boxplot distribution of the biomarker serum levels of IFN-γ, IL-10, IL-6, IL-8, TNF-α, CEA, CA 19–9, CYFRA 21–1, HE4, PD-1 and PD-L1 is illustrated within figure S3. The right skewness is reduced by logarithmic transformation, however, there is still considerable deviance from a normal distribution.
Correlation of serological biomarkers and group differences
Among the biomarkers that were evaluated further, a Spearman's correlation analysis revealed a correlation between CYFRA 21–1 and IL-8, IL-6 and IL-8, as well as TNF-α and HE4 (R = 0.60, 0.57, and 0.55, respectively, p < 0.001 for all, Fig. 1). Furthermore, a significant correlation between age and TNF-α, as well as age and HE4 was observed (R = 0.17, p = 0.03 and R = 0.25, p = 0.001, respectively, figure S4). As expected, Kruskal–Wallis test and Dunn's test showed a significant difference in median serum levels of the more established PDAC biomarkers CA 19–9 and CEA between the group of metastatic disease and the post-resection levels after PDAC surgery (data not shown, p < 0.001 for both biomarkers). While there was no substantial difference in median CYFRA 21–1 serum levels between the locally advanced group and the resected group, a significant difference was observed between the pre-therapeutic CYFRA 21–1 serum levels of patients with metastatic and locally advanced PDAC, as well as the metastatic and resected group (p < 0.001 for both comparisons, Fig. 2a). Further, IL-8 serum levels differed between metastatic PDAC patients compared to locally advanced and resected patients (p < 0.001 for both comparisons, Fig. 2d), while IL-6 and HE4 serum levels only differed significantly when comparing the metastatic group with the resected group (p < 0.001 for both comparisons, Fig. 2b, c). The differences in median PD-1 and PD-L1 serum levels were not different across all three groups (data not shown).
The biomarkers were also analyzed for their ability to differentiate between the patient groups by ROC analysis. Based on the AUC, CYFRA 21–1, CEA, CA 19–9, HE4, IL-6, and IL-8 discriminated between metastatic and resected patients, as well as metastatic and locally advanced patients (Fig. 3). Especially CYFRA 21–1 and IL-8 both discriminated the metastatic group from the locally advanced group well (AUC 0.85, 95% CI 0.76–0.93 and AUC 0.81, 95% CI 0.72–0.9, respectively, Fig. 3).
Univariate analysis for a correlation of serological biomarkers with prognosis
In the group of resected PDAC patients, univariate Cox regression revealed a significant correlation between higher IL-10 and CYFRA 21–1 serum levels and poorer OS (HR 1.43, 95% CI 1.09–1.87, p = 0.010 and HR 1.49, 95% CI 1.17–1.89, p = 0.001, respectively, Table 2). In contrast, neither CEA nor CA 19–9 (measured before the start of adjuvant chemotherapy) correlated with OS in the group of resected PDAC patients. Optimal cut-off values of CA 19–9 (40.0 U/ml), CYFRA 21–1 (3.2 ng/ml), IL-6 (2.05 pg/ml), IL-10 (0.49 pg/ml), and TNF-α (2.95 pg/ml) could be determined by ROC curve and Youden Index analysis which allowed subdivision into two groups with a significant difference in OS as determined by Kaplan–Meier method and log rank test (for details see figure S5).
In the group of locally advanced patients, higher IL-10 and higher CA 19–9 baseline levels correlated with poorer OS (HR 7.74, 95% CI 1.43–41.84, p = 0.017 and HR 1.001, 95% CI 1.0002–1.002, p = 0.017, respectively, Table 2). In this group, the cut-off values for CYFRA 21–1 (3.6 ng/ml), IL-8 (19.55 pg/ml), IL-10 (0.58 pg/ml), and IFN-γ (2.90 pg/ml) could determine two prognostic groups with a significant difference in OS (figure S6).
As expected, the most established PDAC biomarkers CEA, CA 19–9 and CYFRA 21–1 correlated with poorer prognosis in metastatic disease (HR 1.002, 95% CI 1.0004–1.004, p = 0.019, HR 1.00001, 95% CI 1.00001–1.00002, p = 0.0001 and HR 1.004, 95% CI 1.001–1.006, p = 0.003, respectively, Table 2). IL-10 did not seem to harbor any prognostic value in this patient group. We determined optimal cut-off values for CA 19–9 (1067 U/ml), CEA (8.4 ng/ml), CYFRA 21–1 (12.5 ng/ml), HE4 (82.2 pmol/l), IFNγ (3.3 pg/ml), IL-6 (3.3 pg/ml), IL-8 (29.65 pg/ml) and PD-L1 (0.008 ng/ml) levels in the metastatic group via ROC curve and Youden Index analysis. The cut-offs each allowed for division into two prognostic groups with significantly different OS (figure S7).
Multivariate analysis of correlation of serological biomarkers with prognosis
When univariately significant parameters were included in multivariate Cox models for the endpoint OS, only CYFRA 21–1 remained an independent prognostic marker in the resected group (HR 1.37, 95% CI 1.06–1.77, p = 0.015) and only IL-10 in the locally advanced group (HR 10.01, 95% CI 1.58–63.19, p = 0.014). In the subgroup of patients with metastatic disease, CA 19–9 and CYFRA 21–1 harbored independent prognostic value (HR 1.00001, 95% CI 1.000003–100,002, p = 0.008 and HR 1.004, 95% CI 1.0008–1.006, p = 0.010, respectively) in the multivariate model.
Discussion
In this analysis of biomarker serum levels from 162 PDAC patients treated at our comprehensive cancer center, we were able to investigate the prognostic role of various serological biomarkers across different stages of PDAC. In a first step, IL-1β, IL-2, IL-4, IL-12p70 and IL-13 were excluded from further analysis in this study, because more than 95% of measured values were below the lower level of quantification. These interleukins might have a role in PDAC biology nonetheless, however, pre-analytics, as well as the sensitivity of the diagnostic assay may have influenced the results. Previous reports have shown that IL-1β is produced by tumor cells and contributes to the immunosuppressive microenvironment in PDAC (Das et al. 2020). High IL-1β serum levels have been described to be associated with shorter OS (Mitsunaga et al. 2013; Piro et al. 2017). Furthermore, higher IL-4 serum levels have been found to be an independent prognostic factor for disease-free survival and significantly associated with shorter OS (Piro et al. 2017). Gabitass and co-workers demonstrated a significant increase in IL-13 levels in PDAC patients compared to healthy controls, and a positive correlation between IL-13 and myeloid-derived suppressor cell (MDSC) levels was found. Possibly due to their immunosuppressive potential, MDSC numbers were identified as an independent prognostic factor in PDAC patients (Gabitass et al. 2011). To further evaluate the prognostic role of the cytokines excluded in our study, protocol adaptation or use of an alternate, more sensitive assay may prove necessary.
HE4 is a protein better known as a relevant biomarker in ovarian cancer. We observed a significant correlation between age and HE4 serum levels which is in accordance with previous reports. HE4 levels have been described not only to increase with age in women and men (Hertlein et al. 2012; Moore et al. 2012; Cheng et al. 2020), but also correlate with renal function, inflammation, and hormonal levels (Qu et al. 2016). In our study, a cut-off value for HE4 serum levels that distinguished two prognostic groups could be determined for metastatic patients. While high expression levels of HE4 on PDAC cells have been associated with chemoresistance and poor prognosis (Ohkuma et al. 2021), to our knowledge, this has not yet been shown for HE4 serum levels. However, it must be noted that due to the correlation of HE4 serum levels with age, renal function and inflammation the prognostic value might be biased.
As expected, there were group differences in serum levels of most biomarkers between the resected and the metastatic patient subgroup. Interestingly, median CYFRA 21–1 and IL-8 serum levels significantly differed between the locally advanced and the metastatic subgroup, while not significantly differing between the resected and the locally advanced population. Both biomarkers each discriminated the locally advanced group from the metastatic group well as evaluated by area under the ROC curve. With CYFRA 21–1 and IL-8 serum levels apparently increased in metastatic disease, this information can complement imaging results in order to facilitate therapeutic decisions. IL-8 has been found to be produced by pancreatic cancer cells and correlate with metastatic potential and epithelial-mesenchymal transition (Chen et al. 2014; Matsuo et al. 2004), which may explain the significant difference in IL-8 serum levels between locally advanced and metastatic patients observed in this study.
The biomarkers evaluated in PDAC in clinical routine do not depend on the stage of the patient’s disease. In this study, univariate analysis revealed a significant correlation of (post-resection) IL-10 and CYFRA 21–1 with poorer outcome in patients with resected PDAC, a significant correlation of IL-10 and CA 19–9 with poorer outcome in locally advanced PDAC, as well as a significant correlation of CEA, CA 19–9, and CYFRA 21–1 with poorer outcome in metastatic disease. Therefore, the same biomarkers might have different prognostic values depending on the stage of the disease. When interpreting the results, it needs to be kept in mind that the HR is calculated for continuous variables, leading to HRs close to 1.0 but not including 1.0 when evaluating biomarkers with a broad variance. Interestingly, CA 19–9, the most established biomarker in PDAC, did not correlate with survival in the resected patient group, whereas IL-10 did. A small variance of IL-10 in this group resulted in a notably high HR of 10.01. Of note, the serum collection was performed before the start of adjuvant chemotherapy in our patient cohort and not before surgery; thus, the pancreatic tumor had already been removed when blood for the serum analyses was drawn. However, a similar observation could be demonstrated in the locally advanced group in this study, for which the independent prognostic role of IL-10 could be confirmed in the multivariate analysis. Higher levels of IL-10 have been described to be associated with poor survival before (Feng et al. 2018). This observation could possibly be explained by the known immunosuppressive effect of IL-10 in cancer (Sideras et al. 2014). The significant association of CYFRA 21–1 with OS in the resected and the metastatic group was maintained in multivariate analysis. Our group has previously described CYFRA 21–1 to significantly correlate with OS in advanced pancreatic cancer (Boeck et al. 2013).
In the current study, we did not only evaluate the prognostic value of different biomarkers, but we also determined cut-off values of the serum levels, which allowed the division of the patients into two prognostic groups. Cut-off values can be easily applied in clinical routine and support decision-making based on estimated prognosis. For most biomarkers, serum levels above the cut-off value marked belonging to the group with a shorter OS. However, for IFN-γ and PD-L1 in the metastatic setting, the group with a better prognosis had serum levels above the cut-off value. IFN-γ has been described to inhibit the proliferation and migration of PDAC (Lange et al. 2011; Zhang et al. 2018), however, high PD-L1 expression on pancreatic cancer cells has been associated with a poor prognosis in multiple previous studies (Nomi et al. 2007; Gao et al. 2018; Hu et al. 2019; Zhao and Cao 2020). But the same might not hold true for serum levels of PD-L1. We have previously reported that PD-L1 serum levels do not correlate with tumoral PD-L1 expression, and we did not find high serum PD-L1 levels to be an adverse prognostic marker (Kruger et al. 2017), which again was verified in this study.
With this study being monocentric and retrospective, a prospective validation of the data is recommended. The small number of patients in the locally advanced group is a limitation of this study and especially the findings related to this group call for further validation in a larger patient cohort. When interpreting the presented data, it should be noted that in contrast to the locally advanced and metastatic PDAC group, the resected patient group has already undergone resection of the tumor at the time point of the blood draw. This way, the tumoral burden is significantly lower, while there might still be some postoperative cytokine changes obscuring the measurements. Furthermore, a potential selection bias could have occurred because only patients treated at our comprehensive cancer center who also consented to the study were included. However, with patient outcomes matching what is to be expected from the literature, the patient population seems to be representative in this regard. Due to limited amounts of serum samples, we chose one commercially available panel diagnostic kit that included a variety of inflammatory biomarkers of interest, however, this way, other potentially relevant biomarkers had to be omitted and may be included in further studies. Despite the mentioned limitations, this study provides an important understanding of the role of an extensive biomarker panel in PDAC.
In conclusion, this study demonstrated that depending on the stage of pancreatic cancer, other biomarkers than CA 19–9 might provide helpful prognostic information and support patient stratification. CYFRA 21–1 and IL-8 have been identified to discriminate metastatic patients well from locally advanced patients, potentially adding information to imaging results and facilitating decisions in clinical routine. Furthermore, useful cut-off values have been calculated for various biomarker serum levels to easily determine prognostic groups with significantly different OS.
Data availability
The datasets generated and analysed during the current study are available from the corresponding author on reasonable request.
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Contributions
All authors contributed to the study’s conception and design. Sample and data collection were performed by MG, SK, CBW, and MH. Assays were performed by MG, KK, ZM, AR, and SH. Analysis was performed by KD, MG, SK, KK, ZM, AR, FK, SB and SH. The first draft of the manuscript was written by KD and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
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Conflict of interest
KD has received travel/accommodation/conference expenses from Servier and GSK. SK ist employed at MSD. DZ has received travel/accommodation/conference expenses from AMGEN. LW has received honoraria from Roche and Taiho. CBW has received honoraria from Bayer, Celgene, Janssen, Ipsen, F. Hoffmann-La Roche Ltd, Servier and Taiho, served in a consulting/advisory role for BMS, Celgene, Janssen, Merck, Shire/Baxalta, Rafael Pharmaceuticals, RedHill BioPharma and F. Hoffmann-La Roche Ltd, has received travel/accommodation expenses from Bayer, Celgene, Janssen, RedHill BioPharma, F. Hoffmann-La Roche Ltd, Servier, Taiho, and has received research funding from F. Hoffmann-La Roche Ltd. MvB reports receiving honoraria, research funding and reports being part of the speakers bureau from/of MSD Sharp & Dohme, Novartis, Roche, KITE/Gilead, Bristol-Myers Squibb, Astellas, Mologen and Miltenyi. VH has received honoraria from Merck, Roche, Celgene, AMGEN, Sanofi, Lilly, SIRTEX, Boehringer-Ingelheim, Taiho and Servier, served in a consulting/advisory role for Merck, Roche, AMGEN, Sanofi, SIRTEX, Servier, Celgene, Boehringer-Ingelheim, Halozyme, MSD and BMS, has received research funding from MERCK, Roche, AMGEN, SIRTEX, Servier, Celgene, Boehringer-Ingelheim and Shire, and has received travel/accommodation expenses from MERCK, Roche, AMGEN, SIRTEX, Servier, Shire, MSD, BMS. SB served in a consulting/advisory role for Celgene, Baxalta, Incyte, Fresenius, AstraZeneca, has received honoraria from Celgene and Servier, and has received research funding (institution) from Celgene, Clovis Oncology and Roche. SH served in a consulting/advisory role for VolitionSPRL and Roche, has received honoraria from VolitionSPRL, Roche, Merck, HISS, Streck, BMS, and has received research funding (institution) from VolitionSPRL, Roche, Promega and Mikrogen. The other authors have not declared any competing interests.
Ethical approval
This study was performed in line with the principles of the Declaration of Helsinki. The study has been approved by the local ethics committee of the Ludwig-Maximilians-University Munich (approval number 284–10); all patients had given written informed consent before any study-specific procedure was performed.
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This work is part of the doctoral thesis of M. Gerckens.
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Fig. S3 Distribution of measured serum biomarker levels logarithmized to base 10 and normalized to the median Supplementary file3 (TIF 1343 KB)
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Fig. S5 Post tumor resection with curative intention: Receiver operator characteristics (ROC) curves and Youden index for determination of a serum biomarker level threshold differentiating patients with a longer or shorter survival time compared to the subgroup-specific median. The ROC curves show the true-positive rates versus the false-positive rates assuming different threshold values. Thresholds with maximal sensitivity and specificity determined by the maximal Youden index are marked by a red dot. Kaplan-Meier curves and the associated p-value determined by log-rank test for any difference in the survival rates are given. Supplementary file6 (TIF 5569 KB)
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Fig. S6 Locally advanced pancreatic cancer: Receiver operator characteristics (ROC) curves and Youden index for determination of a serum biomarker level threshold differentiating patients with a longer or shorter survival time compared to the subgroup-specific median. The ROC curves show the true-positive rates versus the false-positive rates assuming different threshold values. Thresholds with maximal sensitivity and specificity determined by the maximal Youden index are marked by a red dot. Kaplan-Meier curves and the associated p-value determined by log-rank test for any difference in the survival rates are given. Supplementary file7 (TIF 4491 KB)
432_2022_4112_MOESM8_ESM.tif
Fig. S7 Metastatic pancreatic cancer: Receiver operator characteristics (ROC) curves and Youden index for determination of a serum biomarker level threshold differentiating patients with a longer or shorter survival time compared to the subgroup-specific median. The ROC curves show the true-positive rates versus the false-positive rates assuming different threshold values. Thresholds with maximal sensitivity and specificity determined by the maximal Youden index are marked by a red dot. Kaplan-Meier curves and the associated p-value determined by log-rank test for any difference in the survival rates are given. Supplementary file8 (TIF 4739 KB)
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Dorman, K., Gerckens, M., Kruger, S. et al. Serum biomarker panel diagnostics in pancreatic ductal adenocarcinoma: the clinical utility of soluble interleukins, IFN-γ, TNF-α and PD-1/PD-L1 in comparison to established serum tumor markers. J Cancer Res Clin Oncol 149, 2463–2474 (2023). https://doi.org/10.1007/s00432-022-04112-z
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DOI: https://doi.org/10.1007/s00432-022-04112-z