Model to Determine Risk of Pancreatic Cancer in Patients With New-Onset Diabetes

Ayush Sharma, Harika Kandlakunta, Sajan Jiv Singh Nagpal, Ziding Feng, William Hoos, Gloria M Petersen, Suresh T Chari, Ayush Sharma, Harika Kandlakunta, Sajan Jiv Singh Nagpal, Ziding Feng, William Hoos, Gloria M Petersen, Suresh T Chari

Abstract

Background & aims: Of patients with new-onset diabetes (NOD; based on glycemic status) older than 50 years, approximately 1% are diagnosed with pancreatic cancer (PC) within 3 years. We aimed to develop and validate a model to determine risk of PC in patients with NOD.

Methods: We retrospectively collected data from 4 independent and nonoverlapping cohorts of patients (N = 1,561) with NOD (based on glycemic status; data collected at date of diagnosis and 12 months previously) in the Rochester Epidemiology Project from January 1, 2000 through December 31, 2015 to create our model. The model weighed scores for 3 factors identified in the discovery cohort to be most strongly associated with PC (64 patients with PC and 192 with type 2 diabetes): change in weight, change in blood glucose, and age at onset of diabetes. We called our model Enriching New-Onset Diabetes for Pancreatic Cancer (ENDPAC). We validated the locked-down model and cutoff score in an independent population-based cohort of 1,096 patients with diabetes; of these, 9 patients (82%) had PC within 3 years of meeting the criteria for NOD.

Results: In the discovery cohort, the END-PAC model identified patients who developed PC within 3 years of diabetes onset (area under receiver operating characteristic curve 0.87); a score of at least 3 identified patients who developed PC with 80% sensitivity and specificity. In the validation cohort, a score of at least 3 identified 7 of 9 patients with PC (78%) with 85% specificity; the prevalence of PC in patients with a score of at least 3 (3.6%) was 4.4-fold greater than in patients with NOD. A high END-PAC score in patients who did not have PC (false positives) was often due to such factors as recent steroid use or different malignancy. An ENDPAC score no higher than 0 (in 49% of patients) meant that patients had an extremely low risk for PC. An END-PAC score of at least 3 identified 75% of patients in the discovery cohort more than 6 months before a diagnosis of PC.

Conclusions: Based on change in weight, change in blood glucose, and age at onset of diabetes, we developed and validated a model to determine risk of PC in patients with NOD based on glycemic status (END-PAC model). An independent prospective study is needed to further validate this model, which could contribute to early detection of PC.

Keywords: Biomarker; Enriching New-Onset Diabetes for Pancreatic Cancer; Pancreas; Screening.

Conflict of interest statement

Conflict of interest: No conflict of interest declared

Copyright © 2018 AGA Institute. Published by Elsevier Inc. All rights reserved.

Figures

Figure 1
Figure 1
Predictiveness curve and sensitivity of END-PAC model In Figure 1 at 80% on the x-axis [risk percentile] the pancreatic cancer risk value is 4.0% indicating that, after the END-PAC score, 80% of subjects in the cohort have a calculated risk below 4.0% and only 20% have risk at or above 4.0. The line intersecting at the 80th percentile on the lower half of the graph gives the sensitivity (80%) and specificity (80%) of the END-PAC score at the corresponding risk percentage. Abbreviations: NOD, new-onset diabetes; PC, pancreatic cancer;
Figure 2
Figure 2
A. Distribution of score in all patients; B. Sensitivity of END-PAC score in PC-NOD based on lead time Abbreviations: PC-NOD, pancreatic cancer new-onset diabetes; T2-NOD, type 2 new-onset diabetes
Figure 3
Figure 3
Guidelines for clinical workup on new-onset diabetes for pancreatic cancer Abbreviations: CT, computerized tomography; EUS, endoscopic ultrasound; FBG, fasting blood glucose, RBG, random blood glucose;
Figure 4
Figure 4
Comparison of predictiveness curves of new-onset diabetes + weight loss vs. END-PAC model Abbreviations: NOD, new-onset diabetes; PC, pancreatic cancer

References

    1. Rahib L, Smith BD, Aizenberg R, et al. Projecting cancer incidence and deaths to 2030: the unexpected burden of thyroid, liver, and pancreas cancers in the United States. Cancer research. 2014;74:2913–2921.
    1. Chari ST, Leibson CL, Rabe KG, et al. Probability of pancreatic cancer following diabetes: a population-based study. Gastroenterology. 2005;129:504–511.
    1. SEER. [Accessed on January 17, 2018];Fast Facts: Pancreatic Cancer. Available at: .
    1. Chari ST. Detecting early pancreatic cancer: Problems and prospects. Seminars in Oncology. 2007;34:284–294.
    1. Ogawa Y, Tanaka M, Inoue K, et al. A prospective pancreatographic study of the prevalence of pancreatic carcinoma in patients with diabetes mellitus. Cancer. 2002;94:2344–9.
    1. Damiano J, Bordier L, Le Berre JP, et al. Should pancreas imaging be recommended in patients over 50 years when diabetes is discovered because of acute symptoms? Diabetes Metab. 2004;30:203–7.
    1. Illes D, Terzin V, Holzinger G, et al. New-onset type 2 diabetes mellitus--A high-risk group suitable for the screening of pancreatic cancer? Pancreatology. 2016;16:266–71.
    1. Munigala S, Singh A, Gelrud A, et al. Predictors for Pancreatic Cancer Diagnosis Following New-Onset Diabetes Mellitus. Clin Transl Gastroenterol. 2015;6:e118.
    1. Boursi B, Finkelman B, Giantonio BJ, et al. A clinical prediction model to assess risk for pancreatic cancer among patients with new-onset diabetes. Gastroenterology. 2017;152:840–850. e3.
    1. Gupta S, Vittinghoff E, Bertenthal D, et al. New-onset diabetes and pancreatic cancer. Clinical Gastroenterology and Hepatology. 2006;4:1366–1372.
    1. Aggarwal G, Rabe KG, Petersen GM, et al. New-onset diabetes in pancreatic cancer: a study in the primary care setting. Pancreatology. 2012;12:156–61.
    1. Fraser LA, Twombly J, Zhu M, et al. Delay in diagnosis of diabetes is not the patient’s fault. Diabetes Care. 2010;33:e10.
    1. Harris MI, Klein R, Welborn TA, et al. Onset of NIDDM occurs at least 4–7 yr before clinical diagnosis. Diabetes Care. 1992;15:815–9.
    1. Porta M, Curletto G, Cipullo D, et al. Estimating the delay between onset and diagnosis of type 2 diabetes from the time course of retinopathy prevalence. Diabetes Care. 2014;37:1668–74.
    1. Ford ES, Williamson DF, Liu S. Weight change and diabetes incidence: findings from a national cohort of US adults. Am J Epidemiol. 1997;146:214–22.
    1. Sah RP, Nagpal SJS, Mukhopadhyay D, et al. New insights into pancreatic cancer-induced paraneoplastic diabetes. Nature Reviews Gastroenterology and Hepatology. 2013;10:423–433.
    1. Hart PA, Kamada P, Rabe KG, et al. Weight loss precedes cancer-specific symptoms in pancreatic cancer-associated diabetes mellitus. Pancreas. 2011;40:768–72.
    1. DeJesus RS, Breitkopf CR, Rutten LJ, et al. Incidence Rate of Prediabetes Progression to Diabetes: Modeling an Optimum Target Group for Intervention. Popul Health Manag. 2017;20:216–223.
    1. Nichols GA, Hillier TA, Brown JB. Normal fasting plasma glucose and risk of type 2 diabetes diagnosis. American Journal of Medicine. 2008;121:519–524.
    1. Pannala R, Leirness JB, Bamlet WR, et al. Prevalence and clinical profile of pancreatic cancer–associated diabetes mellitus. Gastroenterology. 2008;134:981–987.
    1. CenterforDiseaseControl. [accessed on January 17, 2018]; .
    1. [Accessed on January 17, 2018]; .
    1. Melton LJ. History of the Rochester epidemiology project. Mayo Clinic Proceedings; Elsevier; 1996.
    1. Rocca WA, Yawn BP, Sauver JLS, et al. History of the Rochester Epidemiology Project: half a century of medical records linkage in a US population. Mayo Clinic proceedings; Elsevier; 2012.
    1. Chari ST, Klee GG, Miller LJ, et al. Islet amyloid polypeptide is not a satisfactory marker for detecting pancreatic cancer. Gastroenterology. 2001;121:640–5.
    1. Aggarwal G, Ramachandran V, Javeed N, et al. Adrenomedullin is up-regulated in patients with pancreatic cancer and causes insulin resistance in β cells and mice. Gastroenterology. 2012;143:1510–1517. e1.
    1. Pannala R, Leibson CL, Rabe KG, et al. Temporal association of changes in fasting blood glucose and body mass index with diagnosis of pancreatic cancer. The American journal of gastroenterology. 2009;104:2318.
    1. Chari ST, Leibson CL, Rabe KG, et al. Pancreatic cancer–associated diabetes mellitus: prevalence and temporal association with diagnosis of cancer. Gastroenterology. 2008;134:95–101.
    1. Cohen JD, Li L, Wang Y, et al. Detection and localization of surgically resectable cancers with a multi-analyte blood test. Science. 2018
    1. Pepe MS, Feng Z, Huang Y, et al. Integrating the predictiveness of a marker with its performance as a classifier. Am J Epidemiol. 2008;167:362–8.
    1. Pepe MS, Janes H, Li CI, et al. Early-Phase Studies of Biomarkers: What Target Sensitivity and Specificity Values Might Confer Clinical Utility? Clin Chem. 2016;62:737–42.
    1. Pelaez-Luna M, Takahashi N, Fletcher JG, et al. Resectability of presymptomatic pancreatic cancer and its relationship to onset of diabetes: a retrospective review of CT scans and fasting glucose values prior to diagnosis. Am J Gastroenterol. 2007;102:2157–63.
    1. Bruenderman E, Martin RC., 2nd A cost analysis of a pancreatic cancer screening protocol in high-risk populations. Am J Surg. 2015;210:409–16.

Source: PubMed

Sponsors et collaborateurs

Les conditions médicales

Interventions en matière de drogue

3
S'abonner