Grant Details
Grant Number: |
6R01CA206279-05 Interpret this number |
Primary Investigator: |
Peters, Ulrike |
Organization: |
Fred Hutchinson Cancer Center |
Project Title: |
Comprehensive Colorectal Cancer Risk Prediction to Inform Personalized Screening |
Fiscal Year: |
2020 |
Abstract
PROJECT SUMMARY
The guidelines for initiation of colorectal cancer (CRC) screening are currently based on two risk factors:
attained age and family history of CRC. Using the principles of precision medicine, we will individually tailor
CRC screening recommendations based on the enormous knowledge we now have on genetic and non-
genetic factors that predict risk for this disease. This strategy will reduce under and over-utilization of CRC
screening, because individual risks vary substantially in the population, and over 80% of all CRC cases occur
in those without a positive family history. In Aim 1 we will develop predictive models for CRC, based on
genetic (~30M common and rare genotyped or imputed genetic variants) and clinico-epidemiologic variables
(over 70 harmonized characteristics), derived from over 40,000 colorectal tumor cases and 46,000 controls.
We will identify key predictors, and derive efficient personalized risk-prediction models for early detection of
more treatable CRCs as well for CRC prevention, through the identification of advanced colorectal adenomas.
In Aim 2 we will calibrate and validate these models in two prospective cohorts of >120,000 participants,
including 40,000 minority members, diversity representing racially/ethnically and socioeconomically. These two
cohorts (Research Program on Genes, Environment and Health and the Women's Health Initiative Minority
cohort) contain genome-wide genotype array and comprehensive risk factor data coupled to data on screening
and outcome data, allowing us to test the model's ability to predict risk for CRC and advanced colorectal
adenoma across a broadly defined community-based population, and to personalize decision on starting age of
screening based on individually specific genetic and environmental risk factors. In Aim 3 we will estimate the
population benefit of our risk-stratified screening strategy, based on our risk prediction methods, compared
with the current screening recommendations. This comparison will employ the well-tested decision model
currently used to inform the United States Preventive Services Task Force CRC screening guidelines.
Accomplishing these three aims, our research has the potential to accelerate the translation of a large amount of
genetic and epidemiologic research to patient care by predicting advanced adenoma risk, for cancer prevention,
and predicting cancer risk, for early cancer detection. Genetic testing is becoming part of routine care and
genetic data will increasingly become part of an individual's medical record. Using genetic and non-genetic
risk-factor information in clinical and preventive settings is a critical step towards developing precision
medicine. Our models will provide recommendations for individually tailored CRC screening and interventions
and, because they are personalized, may also increase adherence, maximize the appropriate use of invasive
technologies, and guide important next steps towards public health policy development and clinical translation.
Publications
Epidemiologic factors in relation to colorectal cancer risk and survival by genotoxic colibactin mutational signature.
Authors: Thomas C.E.
, Georgeson P.
, Qu C.
, Steinfelder R.S.
, Buchanan D.D.
, Song M.
, Harrison T.A.
, Um C.Y.
, Hullar M.A.
, Jenkins M.A.
, et al.
.
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2024-01-22 00:00:00.0; , .
EPub date: 2024-01-22 00:00:00.0.
PMID: 38252034
Related Citations
Combining Asian and European genome-wide association studies of colorectal cancer improves risk prediction across racial and ethnic populations.
Authors: Thomas M.
, Su Y.R.
, Rosenthal E.A.
, Sakoda L.C.
, Schmit S.L.
, Timofeeva M.N.
, Chen Z.
, Fernandez-Rozadilla C.
, Law P.J.
, Murphy N.
, et al.
.
Source: Nature Communications, 2023-10-02 00:00:00.0; 14(1), p. 6147.
EPub date: 2023-10-02 00:00:00.0.
PMID: 37783704
Related Citations
Elucidating the Risk of Colorectal Cancer for Variants in Hereditary Colorectal Cancer Genes.
Authors: Mahmood K.
, Thomas M.
, Qu C.
, Gecco-Ccfr Consortium
, Hsu L.
, Buchanan D.D.
, Peters U.
.
Source: Gastroenterology, 2023 Oct; 165(4), p. 1070-1076.e3.
EPub date: 2023-07-14 00:00:00.0.
PMID: 37453563
Related Citations
Probing the diabetes and colorectal cancer relationship using gene - environment interaction analyses.
Authors: Dimou N.
, Kim A.E.
, Flanagan O.
, Murphy N.
, Diez-Obrero V.
, Shcherbina A.
, Aglago E.K.
, Bouras E.
, Campbell P.T.
, Casey G.
, et al.
.
Source: British Journal Of Cancer, 2023-06-26 00:00:00.0; , .
EPub date: 2023-06-26 00:00:00.0.
PMID: 37365285
Related Citations
Risk-stratified screening for colorectal cancer using genetic and environmental risk factors: A cost-effectiveness analysis based on real-world data.
Authors: van den Puttelaar R.
, Meester R.G.S.
, Peterse E.E.P.
, Zauber A.G.
, Zheng J.
, Hayes R.B.
, Su Y.R.
, Lee J.K.
, Thomas M.
, Sakoda L.C.
, et al.
.
Source: Clinical Gastroenterology And Hepatology : The Official Clinical Practice Journal Of The American Gastroenterological Association, 2023-03-09 00:00:00.0; , .
EPub date: 2023-03-09 00:00:00.0.
PMID: 36906080
Related Citations
Validation of a genetic-enhanced risk prediction model for colorectal cancer in a large community-based cohort.
Authors: Su Y.R.
, Sakoda L.C.
, Jeon J.
, Thomas M.
, Lin Y.
, Schneider J.L.
, Udaltsova N.
, Lee J.K.
, Lansdorp-Vogelaar I.
, Peterse E.F.P.
, et al.
.
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2023-01-09 00:00:00.0; , .
EPub date: 2023-01-09 00:00:00.0.
PMID: 36622766
Related Citations
Deciphering colorectal cancer genetics through multi-omic analysis of 100,204 cases and 154,587 controls of European and east Asian ancestries.
Authors: Fernandez-Rozadilla C.
, Timofeeva M.
, Chen Z.
, Law P.
, Thomas M.
, Schmit S.
, Díez-Obrero V.
, Hsu L.
, Fernandez-Tajes J.
, Palles C.
, et al.
.
Source: Nature Genetics, 2023 Jan; 55(1), p. 89-99.
EPub date: 2022-12-20 00:00:00.0.
PMID: 36539618
Related Citations
Beyond GWAS of Colorectal Cancer: Evidence of Interaction with Alcohol Consumption and Putative Causal Variant for the 10q24.2 Region.
Authors: Jordahl K.M.
, Shcherbina A.
, Kim A.E.
, Su Y.R.
, Lin Y.
, Wang J.
, Qu C.
, Albanes D.
, Arndt V.
, Baurley J.W.
, et al.
.
Source: Cancer Epidemiology, Biomarkers & Prevention : A Publication Of The American Association For Cancer Research, Cosponsored By The American Society Of Preventive Oncology, 2022-05-04 00:00:00.0; 31(5), p. 1077-1089.
PMID: 35438744
Related Citations
Risk Stratification for Early-Onset Colorectal Cancer Using a Combination of Genetic and Environmental Risk Scores: An International Multi-Center Study.
Authors: Archambault A.N.
, Jeon J.
, Lin Y.
, Thomas M.
, Harrison T.A.
, Bishop D.T.
, Brenner H.
, Casey G.
, Chan A.T.
, Chang-Claude J.
, et al.
.
Source: Journal Of The National Cancer Institute, 2022-04-11 00:00:00.0; 114(4), p. 528-539.
PMID: 35026030
Related Citations
Risk Stratification for Early-Onset Colorectal Cancer Using a Combination of Genetic and Environmental Risk Scores: An International Multi-Center Study.
Authors: Archambault A.N.
, Jeon J.
, Lin Y.
, Thomas M.
, Harrison T.A.
, Bishop D.T.
, Brenner H.
, Casey G.
, Chan A.T.
, Chang-Claude J.
, et al.
.
Source: Journal Of The National Cancer Institute, 2022-04-11 00:00:00.0; 114(4), p. 528-539.
PMID: 35026030
Related Citations
Rising Early-Onset Colorectal Cancer Incidence is Not an Artifact of Increased Screening Colonoscopy Use in a Large, Diverse Healthcare System.
Authors: Lee J.K.
, Merchant S.A.
, Jensen C.D.
, Murphy C.C.
, Udaltsova N.
, Corley D.A.
.
Source: Gastroenterology, 2021-09-20 00:00:00.0; , .
EPub date: 2021-09-20 00:00:00.0.
PMID: 34555382
Related Citations
Nongenetic Determinants of Risk for Early-Onset Colorectal Cancer.
Authors: Archambault A.N.
, Lin Y.
, Jeon J.
, Harrison T.A.
, Bishop D.T.
, Brenner H.
, Casey G.
, Chan A.T.
, Chang-Claude J.
, Figueiredo J.C.
, et al.
.
Source: Jnci Cancer Spectrum, 2021 Jun; 5(3), p. pkab029.
EPub date: 2021-05-20 00:00:00.0.
PMID: 34041438
Related Citations
Genome-wide Modeling of Polygenic Risk Score in Colorectal Cancer Risk.
Authors: Thomas M.
, Sakoda L.C.
, Hoffmeister M.
, Rosenthal E.A.
, Lee J.K.
, van Duijnhoven F.J.B.
, Platz E.A.
, Wu A.H.
, Dampier C.H.
, de la Chapelle A.
, et al.
.
Source: American Journal Of Human Genetics, 2020-09-03 00:00:00.0; 107(3), p. 432-444.
EPub date: 2020-08-05 00:00:00.0.
PMID: 32758450
Related Citations
Incorporating Participant and Clinical Feedback into a Community-Based Participatory Research Study of Colorectal Cancer Among Alaska Native People.
Authors: Nash S.H.
, Greenley R.
, Dietz-Chavez D.
, Vindigni S.
, Harrison T.
, Peters U.
, Redwood D.
.
Source: Journal Of Community Health, 2020-03-06 00:00:00.0; , .
EPub date: 2020-03-06 00:00:00.0.
PMID: 32144608
Related Citations
Cumulative Burden of Colorectal Cancer-Associated Genetic Variants is More Strongly Associated With Early-onset vs Late-onset Cancer.
Authors: Archambault A.N.
, Su Y.R.
, Jeon J.
, Thomas M.
, Lin Y.
, Conti D.V.
, Win A.K.
, Sakoda L.C.
, Lansdorp-Vogelaar I.
, Peterse E.F.
, et al.
.
Source: Gastroenterology, 2019-12-19 00:00:00.0; , .
EPub date: 2019-12-19 00:00:00.0.
PMID: 31866242
Related Citations
Meta-analysis of 16 studies of the association of alcohol with colorectal cancer.
Authors: McNabb S.
, Harrison T.A.
, Albanes D.
, Berndt S.I.
, Brenner H.
, Caan B.J.
, Campbell P.T.
, Cao Y.
, Chang-Claude J.
, Chan A.
, et al.
.
Source: International Journal Of Cancer, 2019-04-29 00:00:00.0; , .
EPub date: 2019-04-29 00:00:00.0.
PMID: 31037736
Related Citations
When Should Guidelines Change? A Clarion Call for Evidence Regarding the Benefits and Risks of Screening for Colorectal Cancer at Earlier Ages.
Authors: Corley D.A.
, Peek R.M.
.
Source: Gastroenterology, 2018 10; 155(4), p. 947-949.
EPub date: 2018-09-04 00:00:00.0.
PMID: 30193780
Related Citations
Determining Risk of Colorectal Cancer and Starting Age of Screening Based on Lifestyle, Environmental, and Genetic Factors.
Authors: Jeon J.
, Du M.
, Schoen R.E.
, Hoffmeister M.
, Newcomb P.A.
, Berndt S.I.
, Caan B.
, Campbell P.T.
, Chan A.T.
, Chang-Claude J.
, et al.
.
Source: Gastroenterology, 2018-02-16 00:00:00.0; , .
EPub date: 2018-02-16 00:00:00.0.
PMID: 29458155
Related Citations
Developing an Epidemiologic Study to Investigate Risk Factors for Colorectal Cancer Among Alaska Native People.
Authors: Nash S.H.
, Peters U.
, Redwood D.
.
Source: Journal Of Public Health Management And Practice : Jphmp, 2019 Sep/Oct; 25 Suppl 5, Tribal Epidemiology Centers: Advancing Public Health in Indian Country for Over 20 Years, p. S54-S60.
PMID: 31348191
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