Intact SMAD-4 is a predictor of increased locoregional recurrence in upfront resected pancreas cancer receiving adjuvant therapy
Introduction
With an estimated 57,600 new cases in the United States and the lowest 5-year survival rate of major cancers, pancreas cancer has become the third leading cause of cancer mortality responsible for an estimated 47,050 deaths in 2020 (1-7). Approximately 20% of patients with clinically localized tumors are surgical candidates, and R1 resection occurs 20–60% of the time with survival similar to patients with unresectable tumors (8-10). Locoregional recurrence (LRR) is a known independent predictor of overall survival (OS) and the sole cause of death in up to 25% of patients (11,12). Despite use of adjuvant chemotherapy and/or chemoradiotherapy (CRT) to mitigate recurrence risk, prospective clinical trials still show high rates of LRR and distant recurrence (DR) of 20–53% and 46–86%, respectively (9,13-18).
Mothers Against Decapentaplegic homolog 4 (SMAD4), also known as deleted in pancreatic cancer 4 (DPC4), functions in the transforming growth factor beta (TGF-β) pathway to induce growth suppressive effects in normal development and tumorigenesis (19-25). Inactivation or loss of SMAD4 promotes pancreatic tumor growth through the loss of TGF-β/SMAD4-dependent cell cycle arrest and apoptosis, and mutations in SMAD4 are found in the majority of pancreatic adenocarcinomas (20,26). SMAD4 immunohistochemical (IHC) staining can be used to assess tumor SMAD4 expression, which is concordant with gene status in pancreas cancer (27,28).
As a biomarker, SMAD4 expression may predict individual LRR or DR risk to stratify patients into selective treatment paradigms, ultimately with the potential to improve survival (11,27,29-38). Past reports suggest loss of SMAD4 expression is associated with a distant metastatic predominant phenotype (11,28,30) and worse prognosis (27,31-38), while intact SMAD4 expression is associated with a locally aggressive tumor phenotype (11,29). For example, in a study of 65 pancreas cancer specimens analyzed on rapid autopsy, 78% of patients without metastases had intact SMAD4 expression compared to 33% of patients with metastatic disease (11). In another study, 11 (73%) of 15 patients with intact SMAD4 expression had a locally aggressive pattern of progression compared to four (29%) of 14 patients with SMAD4 loss (29). Previous studies reveal a range of SMAD4 loss in 15–82% of resected pancreas tumors (23,27,30-38). The wide range of frequency of SMAD4 loss may reflect differences in patient selection (localized vs. metastatic), specimen size, tumor heterogeneity, and IHC staining technique (30,31,36-38).
This work aims to determine the frequency of intact SMAD4 expression in a single-institution cohort of patients with treatment naïve, resected pancreas cancer and to evaluate the association of SMAD4 status with patterns of recurrence and survival. The following article is presented in accordance with the REMARK reporting checklist (39) (available at http://dx.doi.org/10.21037/jgo-21-55).
Methods
Patient selection
The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). The study was approved by the institutional review board of Mayo Clinic (No.: 17-003122), and informed consent was taken from all the patients. From 2000 to 2010, 778 patients with clinically non-metastatic pancreas cancer who underwent curative intent surgery were screened for enrollment in a prospective single-institution clinical registry (Biospecimen Resource for Pancreas Research, Mayo Clinic IRB#354-06, supported in part by the Mayo Clinic SPORE in Pancreatic Cancer) (40). Of these, 579 patients consented for prospective patient registry enrollment providing access to their medical records and archived tumor tissues. As part of a subsequent retrospective institutional review board-approved study (No.: 17-003122), the pathology biorepository was queried for surgical pathology specimens with sufficient available tissue for tissue microarray (TMA) construction for tumor biomarker analysis. Eligible patients were those who underwent upfront surgery without neoadjuvant therapy and received at least one cycle of postoperative adjuvant gemcitabine.
Tissue microarray generation
Treatment-naïve tumor biospecimens from 146 patients with formalin-fixed paraffin-embedded tissue available were included in TMA construction. In consideration of immense tumor heterogeneity, up to three viable tumor locations were marked by a pathologist from H&E stained slides. The identified locations were then core punched (2.0 mm diameter) and used to construct a set of TMA blocks (41). Each TMA slide consisted of 60 cores with four cores of non-pancreas tissue samples placed to enable TMA orientation as well as serve as internal controls. IHC staining for SMAD4 was performed using murine B-8 monoclonal Santa Cruz antibody (catalog number SC-7966). TMAs were assessed for staining quality and scored by the study pathologist, who was otherwise blinded to patient clinicopathologic features and clinical outcomes. Scoring based on two measures: percentage of tumor cell staining, ranged 0–100% in increments of 10%, and staining intensity, scored as 0, 1, 2 or 3 (none, weak, moderate, or strong, respectively). A histoscore ranging from 0–300 was created by the product of the percentage of cell staining and tumor intensity. A histoscore greater than zero was considered to have intact SMAD4 expression.
Clinical data collection
All 127 patients with SMAD4 IHC staining were included in the final analysis. Clinicopathologic features and clinical outcomes of the patients (OS, LRR, and DR) were collected retrospectively from the electronic medical record. LRR was defined by radiographic recurrence within the surgical bed, remnant pancreas, or draining lymph node regions such as superior mesenteric or celiac. DR included recurrences in the lung, liver, and other less common sites. LRR and DR events were tracked independently, and thus patients could be characterized as having one or both types of recurrence, whether identified concurrently or sequentially. The end of the follow up period was 1 January 2020, and median follow-up was 5.7 years (IQR, 4.6–7.6 years).
Statistical analysis
Descriptive statistics were reported using the number (percentage) for discrete variables and the median and interquartile range (IQR) for continuous variables. The Kaplan Meier method was used to estimate OS. Cumulative incidence estimates were calculated for LRR and DR considering death as a competing risk. Univariate associations of clinicopathologic parameters as variables (SMAD4 expression, resection margins (R0, R1, R2), tumor diameter dichotomized at median, tumor stage dichotomized as T1/T2 versus T3/T4, nodal stage, grade dichotomized at grade 2 versus grade 3/4, lymphovascular invasion, perineural invasion, carbohydrate antigen (CA) 19-9 dichotomized at median, and use of adjuvant CRT) and OS were made using a Cox model. Associations with both LRR and DR were made using the Fine and Gray extension of the Cox model. For the outcomes with significant univariate associations, multivariable models were examined including as candidate variables those with a univariate significance of P≤0.25. Variables were retained for the final model using the backward selection method. An alpha level of 0.05 was used for statistical significance.
Results
Clinicopathologic features of the 127 patients included in the final analysis are summarized in Table 1. All patients received adjuvant gemcitabine with a median number of cycles of 6 (range, 1–6). Seventy-nine percent (n=99) of patients received adjuvant CRT with a median dose fractionation of 5,040 cGy (range, 4,500–5,940 cGy) in 28 fractions (range, 25–33 fractions).
Table 1
All patients, % [n] (n=127) | SMAD4 intact, % [n] (n=10) | SMAD4 lost, % [n] (n=117) | P value | |
---|---|---|---|---|
Sex | 0.81 | |||
Female | 46.5 [59] | 50.0 [5] | 46.2 [54] | |
Male | 53.5 [68] | 50.0 [5] | 53.8 [63] | |
Age | 0.61 | |||
Median (years) | 64 | 69.5 | 64 | |
Interquartile range (years) | 55–73 | 56–74 | 55–73 | |
ECOG | 0.42 | |||
0 | 84.3 [107] | 100.0 [10] | 82.3 [97] | |
1 | 12.6 [16] | 0.0 [0] | 13.7 [16] | |
2 | 0.8 [1] | 0.0 [0] | 0.9 [1] | |
Missing | 2.4 [3] | 0.0 [0] | 2.6 [3] | |
Charlson comorbidity index | 0.62 | |||
0–2 | 19.7 [25] | 20.0 [2] | 19.7 [23] | |
3–5 | 56.7 [72] | 70.0 [7] | 55.6 [65] | |
>5 | 21.3 [27] | 10.0 [1] | 22.2 [26] | |
Missing | 2.4 [3] | 0.0 [0] | 2.6 [3] | |
Histology | 0.69 | |||
Adenocarcinoma | 93.7 [119] | 100.0 [10] | 93.2 [109] | |
Mucinous carcinoma | 3.9 [5] | 0.0 [0] | 4.3 [5] | |
Adenosquamous carcinoma | 2.4 [3] | 0.0 [0] | 2.6 [3] | |
Tumor site | 0.55 | |||
Head | 77.2 [98] | 90.0 [9] | 76.1 [89] | |
Body | 2.4 [3] | 0.0 [0] | 2.6 [3] | |
Tail | 11.8 [15] | 0.0 [0] | 12.8 [15] | |
Overlap/not specified | 8.7 [11] | 10.0 [1] | 8.5 [10] | |
Resection margin | 0.72 | |||
R0 | 81.9 [104] | 80.0 [8] | 82.1 [96] | |
R1 | 16.5 [21] | 20.0 [2] | 16.2 [19] | |
R2 | 1.6 [2] | 0.0 [0] | 1.7 [2] | |
Median tumor size | 0.55 | |||
Median (mm) | 35.0 | 30.5 | 35.0 | |
Interquartile range (mm) | 26.0–45.0 | 27.0–36.0 | 26.0–45.0 | |
Pathologic T stage | 1.00 | |||
T1/T2 | 25.2 [32] | 20.0 [2] | 25.6 [30] | |
T3/T4 | 74.8 [95] | 80.0 [8] | 74.4 [87] | |
Pathologic N stage | ||||
N0 | 32.3 [41] | 20.0 [2] | 33.3 [39] | 0.50 |
N1 | 67.7 [86] | 80.0 [8] | 66.7 [78] | |
Grade | 0.05 | |||
2 | 9.4 [12] | 30.0 [3] | 7.7 [9] | |
3 | 76.4 [97] | 50.0 [5] | 78.6 [92] | |
4 | 14.2 [18] | 20.0 [2] | 13.7 [16] | |
Lymphovascular invasion | 0.62 | |||
Absent | 86.6 [110] | 80.0 [8] | 87.2 [102] | |
Present | 13.4 [17] | 20.0 [2] | 12.8 [15] | |
Perineural invasion | 0.50 | |||
Absent | 31.5 [40] | 80.0 [8] | 68.5 [87] | |
Present | 68.5 [87] | 20.0 [2] | 31.5 [40] | |
Preoperative CA 19-9 | 0.17 | |||
Median (U/mL) | 195 | 63 | 219 | |
Interquartile range (U/mL) | 49–573 | 26–601 | 52–553 | |
Adjuvant chemoradiotherapy | 0.69 | |||
No | 21.4 [27] | 10.0 [1] | 22.4 [26] | |
Yes | 78.6 [99] | 90.0 [9] | 77.6 [90] | |
Missing | 0.8 [1] | 0.8 [1] |
A total of 10 (8%) patients had intact SMAD4 expression and were more likely to have grade 2 tumors (25% expression) relative to grade 3 or 4 (6% expression) (P=0.05). No other clinicopathologic parameters were associated with SMAD4 expression. The median OS for all patients was 2.1 years (IQR, 1.3–3.8 years). Eighty-eight patients experienced any type of recurrence, and of those, 12 patients experienced both LRR and DR. Allowing for recurrences to be assessed independently, LRR and DR events occurred in 20 and 80 patients, respectively (Table 2).
Table 2
Total events (n=127) | 3-year cumulative incidence, SMAD4 intact (95% CI), % | 3-year cumulative incidence, SMAD4 lost (95% CI), % | |
---|---|---|---|
Any recurrence | 88 | 90.0 (73.2–100.0) | 61.9 (53.6–71.4) |
Locoregional recurrence | 20 | 60.0 (36.2–99.5) | 10.3 (6.1–17.7) |
Distant recurrence | 80 | 80.0 (58.7–100.0) | 56.7 (48.3–66.5) |
CI, confidence interval.
On univariate analysis, intact SMAD4 expression was associated with a higher rate of LRR (HR =7.0, P<0.01, 95% CI: 2.8–18.0) (Table 3 and Figure 1). SMAD4 expression, use of CRT (P=0.07), and grade (P=0.08) were included as candidate variables in the multivariable model for LRR. On multivariable analysis, intact SMAD4 expression was associated with a higher rate of LRR (HR 9.6, P≤0.01, 95% CI: 3.7–24.8), use of adjuvant CRT was associated with a lower rate of LRR (HR =0.3, P=0.01, 95% CI: 0.1–0.8), and grade was not retained (Table 4). SMAD4 expression was not associated with DR (HR =1.8, P=0.06, 95% CI: 1.0–3.2) or OS (HR =1.1, P=0.73, 95% CI: 0.6–2.3) on univariate analyses (Table 3 and Figure 1). As no clinicopathologic parameters were associated significantly with DR or OS on univariate analyses, multivariable analyses were not performed for DR or OS.
Table 3
Univariate analysis for locoregional recurrence | Univariate analysis for distant recurrence | Univariate analysis for overall survival | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
P value | HR | 95% CI | P value | HR | 95% CI | P value | HR | 95% CI | |||
SMAD4 expression | |||||||||||
Lost | 1.00 | 1.00 | 1.00 | ||||||||
Intact | <0.01 | 7.02 | 2.75–17.92 | 0.06 | 1.76 | 0.97–3.19 | 0.73 | 1.13 | 0.57–2.25 | ||
Resection | |||||||||||
R0 | 1.00 | 1.00 | 1.00 | ||||||||
R1 | 0.53 | 0.62 | 0.15–2.69 | 0.91 | 1.04 | 0.56–1.92 | 0.12 | 1.48 | 0.90–2.44 | ||
R2 | 0.43 | 0.42 | 0.17–65.05 | 0.68 | 0.55 | 0.03–9.21 | 0.06 | 3.82 | 0.93–15.72 | ||
Tumor diameter | |||||||||||
≤35 mm | 1.00 | 1.00 | 1.00 | ||||||||
>35 mm | 0.56 | 1.30 | 0.54–3.15 | 0.13 | 1.41 | 0.9–2.19 | 0.14 | 1.34 | 0.91–1.99 | ||
T stage | |||||||||||
1/2 | 1.00 | 1.00 | 1.00 | ||||||||
3/4 | 0.80 | 1.14 | 0.41–3.16 | 0.96 | 1.01 | 0.62–1.67 | 0.27 | 1.30 | 0.82–2.05 | ||
N stage | |||||||||||
N0 | 1.00 | 1.00 | 1.00 | ||||||||
N1 | 0.54 | 1.37 | 0.50–3.78 | 0.77 | 0.93 | 0.58–1.49 | 0.52 | 0.87 | 0.58–1.32 | ||
Grade | |||||||||||
2 | 1.00 | 1.00 | 1.00 | ||||||||
3/4 | 0.08 | 0.38 | 0.13–1.11 | 0.12 | 1.76 | 0.86–3.58 | 0.17 | 1.49 | 0.84–2.65 | ||
Lymphovascular invasion | |||||||||||
No | 1.00 | 1.00 | 1.00 | ||||||||
Yes | 0.39 | 0.41 | 0.06–3.10 | 0.01 | 2.13 | 1.19–3.81 | 0.25 | 1.38 | 0.79–2.40 | ||
Perineural invasion | |||||||||||
No | 1.00 | 1.00 | 1.00 | ||||||||
Yes | 0.30 | 0.56 | 0.19–1.67 | 0.56 | 1.16 | 0.71–1.87 | 0.42 | 1.19 | 0.78–1.81 | ||
Preoperative CA 19-9 | |||||||||||
≤195 | 1.00 | 1.00 | 1.00 | ||||||||
>195 | 0.89 | 1.07 | 0.44–2.64 | 0.34 | 1.25 | 0.79–1.95 | 0.28 | 1.25 | 0.83–1.86 | ||
Adjuvant chemoradiotherapy | |||||||||||
No | 1.00 | 1.00 | 1.00 | ||||||||
Yes | 0.07 | 0.43 | 0.17–1.08 | 0.75 | 0.92 | 0.54–1.56 | 0.48 | 0.85 | 0.53–1.35 |
HR, hazard ratio; CI, confidence interval.
Table 4
Multivariate analysis for locoregional recurrence | |||
---|---|---|---|
P value | HR | 95% CI | |
SMAD4 expression | |||
Lost | 1.00 | ||
Intact | <0.01 | 9.60 | 3.72–24.79 |
Adjuvant chemoradiotherapy | |||
No | 1.00 | ||
Yes | 0.01 | 0.31 | 0.12–0.78 |
Grade was not retained in the parsimonious model including variables, P<0.05. HR, hazard ratio; CI, confidence interval.
Discussion
Pancreas cancer exhibits immense tumor and phenotypic heterogeneity with different treatment responses and patterns of recurrence (42-48). This is likely due to heterogeneous biologic subtypes as a result rapid clonal evolution and selection response (49,50). To date, limited information is available for identification and prognostic evaluation of subtypes for risk stratification. In the postoperative setting, adverse pathologic features and CA 19-9 are correlated retrospectively with LRR and DR (12,51). Unfortunately, these indicators alone are inadequate to predict patterns of recurrence prospectively for guidance of appropriate adjuvant therapies tailored specifically to individual patients. Further, as recent clinical trials provide supportive evidence for neoadjuvant therapy (52-54), historical pathologic predictors used to guide post-operative therapy are not available for use in selection of neoadjuvant therapy. Therefore, understanding tumor biology and easily assessable predictive biomarkers would be valuable in order to move toward individualized cancer therapy for pancreas cancer.
The present study adds to the existing body of work by suggesting intact SMAD4 as an independent risk factor for LRR in pancreas cancer. In the present study, 127 patients with resected pancreas cancer treated with adjuvant gemcitabine and in the majority of cases adjuvant CRT were evaluated, and SMAD4 was observed to be intact in 8% of specimens. This subset of patients treated at the study institution was chosen to isolate better the potential association of SMAD4 status and patterns of recurrence within a historical standard of care. The 3-year cumulative incidences of LRR were 60% in patients with SMAD4 intact and 10% in patients with SMAD4 lost. Intact SMAD4 was predictive of a seven-fold increased risk of LRR on univariate analysis and a ten-fold increased risk of LRR on multivariable analysis, although SMAD4 expression was not associated significantly with DR. Clinicopathologic features were similar between patients with intact or lost SMAD4 with the exception of histopathologic grade, which was not associated with LRR on univariate or multivariable analysis. These data support the hypothesis that intact SMAD4 expression may be an independent predictor of a pancreas cancer subset with a predilection for LRR and may be used in risk stratification to identify patients who may be most likely to benefit from aggressive locoregional therapy.
Recent clinical trials provide evidence for shifting the standard treatment paradigm of non-metastatic pancreas cancer to upfront neoadjuvant chemotherapy and CRT prior to an attempt at surgical resection (52-57). Two randomized trials demonstrated the benefits of neoadjuvant CRT prior to resection compared to upfront resection with adjuvant chemotherapy or CRT (52,54,58). While neoadjuvant CRT led to improvements in locoregional failure and disease-free interval, an additional benefit was the ability to detect the manifestation of occult metastatic disease during and after CRT but before surgery, thus improving the selection of surgical cases (54,58). For example, in the PREOPANC clinical trial, approximately 14% of the patients who were randomized to and received neoadjuvant CRT did not undergo resection due to manifestation of metastatic disease (54,58). In a predefined subgroup analysis, patients who underwent tumor resection and started adjuvant therapy had a median OS of 35.2 vs. 19.8 months in the immediate surgery group. Despite these advantages, the rates of distant metastasis were similar between groups. These findings indicate that current clinical tools are inadequate to determine individual biology and to predict patterns of progression. Thus, a major challenge in treatment of pancreas cancer, with or without a neoadjuvant approach, is selecting appropriate patients for whom aggressive locoregional therapy may prolong survival.
Most studies have evaluated SMAD4 expression in the context of treatment-naïve, resected pancreas cancer. It is uncertain as to what impact SMAD4 expression may have in patients who undergo neoadjuvant treatment. In one study, the frequency of SMAD4 expression of resected specimens was similar between patients who did and did not receive neoadjuvant treatment (20% vs. 13%, respectively), and SMAD4 loss was associated with a shorter time to DR in the combined cohort (P=0.02) (30). As SMAD4 staining may be performed on fine needle aspiration samples with accuracy (34,59,60), it is feasible to assess SMAD4 status at diagnosis prior to neoadjuvant treatment as well as at possible resection after neoadjuvant treatment. It remains unclear whether neoadjuvant chemotherapy or CRT may change the expression of, or patterns of recurrence predicted by, SMAD4 and thus its relevance in a neoadjuvant treatment paradigm.
Beyond SMAD4, other molecular markers of loss of tumor suppression or oncogene activation have been explored for predictive utility of patterns of recurrence. Examples of significant correlations include inactivating mutations in TP53 with a distant metastatic predominant phenotype (11), high CXCR4 expression with a DR pattern (61), loss of p16 with DR as first recurrence and dominant pattern of progression (34), and high c-MET with shortened time to DR (30). While each of these markers are of interest, a synergistic combination potentially could be used to enhance their clinical utility (41). A panel of predictive and prognostic biomarkers may provide a unique signature that could be used to guide the treatment sequences of different combinatorial therapies to improve survival among various pancreas cancer subtypes.
While the results of this study are hypothesis generating and encouraging, several limitations are present. First, this is a selected cohort of patients from a single medical institution, and all inherent biases of a retrospective study may be present. The frequency of intact SMAD4 expression (8%) was lower than those of previously published studies, which may reflect an institution-based selection effect of treating patients with more advanced pancreas cancer and may limit the generalizability of the findings (30,31,36-38). The low detected frequency of intact SMAD4 also could reflect sampling error caused by tumor heterogeneity and the relatively small samples utilized for TMA construction (41). To attempt to mitigate this, up to three separate cores were taken per tumor. Further, this study was performed without a validation cohort, and validation of these results with an independent cohort is crucial. While lacking a true validation cohort, the observations of this study fit within the context of previously published literature and suggest a relationship between intact SMAD4 expression and LRR. Ultimately the findings are correlational and prospective evaluation is warranted.
In conclusion, in a cohort of patients with resected pancreas cancer, intact SMAD4 expression was associated with a locally aggressive phenotype with a markedly increased risk of LRR. Multivariable analysis demonstrated intact SMAD4 and no adjuvant CRT were associated with increased risk of LRR. This work contributes to a growing body of knowledge that attempts to identify and differentiate molecular signatures in pancreas cancer and stratify patients who are more likely to benefit from aggressive locoregional therapy, including CRT. Future directions include prospective evaluation of the frequency of intact SMAD4, validation of its predictive utility including in both the adjuvant and neoadjuvant settings, and investigation into other biomarkers that could be combined with SMAD4 for improved prognostication.
Acknowledgments
We thank the pancreas cancer patients for contributing to this project at the Mayo Clinic as well as our colleagues in the Department of Radiation Oncology and the Mayo Clinic Pancreatic Cancer SPORE for their expert guidance and generous support.
Funding: This work was supported by National Cancer Institute (Mayo Clinic SPORE in Pancreatic Cancer P50CA102701 to GMP, CA140550 to AHT); 2010 AACR-PanCAN Innovative Grant (AACR-PanCan #169458 to AHT); 2005 Lutsgarten Foundation for Pancreatic Cancer Research (RFA05-046 to AHT); National Institute of General Medical Sciences (GM069922-06S1 to AHT); Dorothy G. Hoefer Foundation (to AHT); and the Mayo Pancreatic Cancer SPORE Pilot Grant Award (to AHT).
Footnote
Reporting Checklist: The authors have completed the REMARK reporting checklist available at http://dx.doi.org/10.21037/jgo-21-55
Data Sharing Statement: Available at http://dx.doi.org/10.21037/jgo-21-55
Peer Review File: Available at http://dx.doi.org/10.21037/jgo-21-55
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/jgo-21-55). SPC declares Olympus consulting and Ethicon educational events. ROK declares his wife is a senior technical product manager for GE Healthcare. KWM declares ongoing grant support for clinical trial and global medical education programs. None of these grants are relevant to the manuscript. DO declares grants for clinical trial operations and protocol delivery from Mayo Clinic and Astra Zeneca. No direct financial relationship. TTS declares that he provides strategic and scientific recommendations as a member of the Advisory Board and speaker for Novocure, Inc., which is not in any way associated with the content or disease site as presented in this manuscript. AHT declares grants from AACR-PanCAN, Lutsgarten Foundation for Pancreatic Cancer Research, National Institute of General Medical Sciences, National Cancer Institute, and Dorothy G. Hoefer Foundation for Pancreatic Cancer Research, is a grant reviewer at National Institute of Health, National Cancer Institute, Department of Defense, and PanCAN, and is a Vice Chair at PanCAN Career Development Award Scientific Review Committee. The other authors have no conflicts of interest to declare.
Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). The study was approved by the institutional review board of Mayo Clinic (No.: 17-003122), and informed consent was taken from all the patients. All figures and tables in this manuscript are original and are not adapted from published ones.
Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.
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