State health departments in Michigan, Minnesota, Oregon, and Utah explored the use of genomic information, including family health history, in chronic disease prevention programs. To support these explorations, the Office of Public Health Genomics at the Centers for Disease Control and Prevention provided cooperative agreement funds from 2003 through 2008. The 4 states’ chronic disease programs identified advocates, formed partnerships, and assessed public data; they integrated genomics into existing state plans for genetics and chronic disease prevention; they developed projects focused on prevention of asthma, cancer, cardiovascular disease, diabetes, and other chronic conditions; and they created educational curricula and materials for health workers, policymakers, and the public. Each state’s program was different because of the need to adapt to existing culture, infrastructure, and resources, yet all were able to enhance their chronic disease prevention programs with the use of family health history, a low-tech “genomic tool.” Additional states are drawing on the experience of these 4 states to develop their own approaches.
The Human Genome Project concluded in 2003, attracting attention to genomic research as a source for health information and applications (
To explore the potential use of genomic information in chronic disease prevention, the Centers for Disease Control and Prevention supported pilot programs in 4 states from 2003 through 2008. We describe the strategies, successes, challenges, and consequences of these programs, which offer potential models for using genomic information — particularly family health history — for public health action.
The Chronic Disease Directors’ Summit in 2002 called on CDC to help states respond to knowledge and applications emerging from the Human Genome Project (
Develop or expand leadership capacity in public health genomics.
Develop and implement population-based assessments and incorporate genomics into disease-specific data collection through surveillance and registries.
Implement or expand the use of genomics in program activities.
Educate the health care workforce, policy makers, and the public about the importance and role of family health history and genetic risk factors in disease etiology and prevention.
Prepare the chronic disease workforce for using genomic tools to reduce the burden of specific diseases, and teach them the benefits and limitations of genetic tests.
From 2003 through 2008, four states — Michigan, Minnesota, Oregon, and Utah — received cooperative agreement funds for public health genomics. Annual awards between $150,000 and $250,000 allowed each state to support 1 full-time staff member. Additional staff were hired part-time or as student interns; health departments also contributed staff time in kind (eg, for health education or web development support). States submitted annual progress reports to CDC.
Michigan, Oregon, and Utah chose to expand their existing state genetics plans, developed in 2002 with support from the Health Resources and Services Administration. They enhanced these plans with specific goals and activities that emphasized the role of genomics in chronic disease prevention programs (
All 4 states integrated genomic information — particularly family health history — into prevention plans for 1 or more chronic diseases, including asthma, obesity and diabetes, heart disease, and stroke. The most detailed plans focused on cancer. Oregon’s comprehensive cancer control plan added an objective to increase awareness of cancer family history as a factor in individual cancer risk (
Some key accomplishments are summarized in the following sections, corresponding with the categories in
Project staff in the 4 funded states identified “champions,” leaders within the health department who helped to develop partnerships and advisory groups. These groups varied in composition and scope, with members coming from various types of organizations: government agencies, academic and research institutions, health care plans, community groups, private businesses, genealogy organizations, and other entities. Oregon convened a broad Genetic Advisory Committee with clinical, public health, and academic members to gather input for Oregon’s Strategic Plan for Genetics and Public Health (
All 4 states had access to population-based data collected by state surveillance systems. Michigan, Oregon, and Utah added state-specific questions to the BRFSS (topics covered are listed in
| Information Category | 2003 | 2004 | 2005 | 2006 | 2007 | 2008 | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| OR | MI | MN | OR | MI | OR | UT | MI | OR | UT | MI | OR | UT | MI | OR | UT | |
|
| ||||||||||||||||
| Asthma | — | — | — | — | — | — | — | — | — | X | — | — | — | — | — | — |
| Breast or ovarian cancer | — | — | — | — | — | — | — | X | — | — | — | — | — | X | — | — |
| Cardiovascular disease | — | — | — | — | — | — | — | — | — | — | X | X | — | — | — | — |
| Colorectal cancer | — | — | — | — | X | — | — | — | — | — | — | — | — | — | X | — |
| Diabetes | X | — | X | X | — | X | — | — | X | — | — | — | X | — | — | X |
| Chronic disease (general) | — | — | — | — | — | — | X | — | — | X | — | — | X | — | — | X |
|
| — | X | — | — | X | — | X | — | — | X | — | X | X | — | — | X |
|
| — | — | — | — | — | — | — | X | — | X | — | X | X | — | X | X |
|
| — | — | — | — | — | — | — | — | — | — | — | — | — | X | — | — |
Abbreviations: OR, Oregon; MI, Michigan; MN, Minnesota; UT, Utah; —, data not collected; DTC, direct-to-consumer.
State participation in BRFSS and survey questions varied by year.
The Michigan public health genomics program collaborated with the Michigan Cancer Surveillance Program (MCSP), the state’s cancer registry, to assess completeness of cancer family history in oncology patients’ charts. They found that more than 80% of 853 charts documented the presence or absence of a family history of cancer and the tumor site; however, fewer than 10% included age at cancer diagnosis, a key indicator for assessing potential genetic risk (
Michigan also developed a novel, population-based surveillance system for sudden cardiac death among the young (SCDY). Michigan used these data to bring attention to SCDY as a public health problem, identifying an underlying genetic cause in a large proportion of cases (
State programs used population-based data to inform educational activities, policies, and standards for using family health history to enhance early disease detection and prevention (
| Topic Area | Michigan | Minnesota | Oregon | Utah |
|---|---|---|---|---|
| Disease-specific prevention plans and programs |
Asthma Cancer CVD Obesity |
Asthma Cancer CVD Diabetes Disabilities |
Cancer CVD Diabetes Nutrition and physical fitness |
Asthma Cancer CVD |
| Policies, guidelines, and standards |
Cancer registry Electronic health record WISEWOMAN |
WISEWOMAN |
Privacy Health plan Birth defects registry |
Medical family history |
| Education and training |
Public health workers Secondary teachers Health professionals |
Public health workers Graduate students Health professionals |
Public health workers Health professionals |
Public health workers Underserved communities Health professionals |
Abbreviations: CVD, cardiovascular disease; WISEWOMAN, Well-Integrated Screening and Evaluation for Women Across the Nation.
Michigan integrated family history questions into the baseline participant survey of its Healthy Homes University program. This program is funded by the US Department of Housing and Urban Development (DHUD) to reduce asthma triggers in low- to moderate-income households that include a child with asthma. Sixty-five percent of children with diagnosed asthma in Michigan’s survey had at least 1 first-degree relative with asthma. By identifying affected relatives, Michigan’s program was able to offer education and products to reduce asthma triggers to 150 additional persons with asthma in 92 of the first 162 households enrolled in the project (
From 2006 through 2009, the Michigan Colorectal Cancer Screening Program offered colorectal cancer screening to asymptomatic low-income, uninsured, and underinsured persons in 3 counties with high colorectal cancer mortality rates. The program linked local health departments with genetics services and provided data for use in communicating with program participants. Of the approximately 1,500 adults screened, 177 were referred to a genetic counselor. In Minnesota, the Department of Health integrated family history educational materials into the Sage Screening Program for breast and cervical cancer among underserved women aged 40 or older (
The Oregon public health genomics program focused on policy development, supporting the legislatively established Advisory Committee on Genetic Privacy and Research and facilitating a new Genetics Advisory Committee that served the Oregon Health Services Commission and Oregon’s Medicaid program. In 2007, the commission approved all of the committee’s recommendations on coverage of genetic services under Oregon’s Medicaid program. These services included testing for the
To increase awareness and understanding of the use of genomics — particularly family health history — in disease prevention, the states provided courses, seminars, and lectures and developed educational materials for public health practitioners, health care providers, policy makers, teachers, students, and the public (
Michigan developed continuing education modules on genomics, family history, and diabetes, which were accessed by more than 300 health care providers. Michigan also helped create a core lecture for first-year medical students at Wayne State University and collaborated with a regional health care network in southeastern Michigan to establish an annual grand rounds lecture on genomics for physicians and medical residents. Oregon explained how to use family history to identify patients at high risk for diabetes, colorectal cancer, breast cancer, and hyperlipidemia in
Michigan developed the Genetics to Genomics Workshop, which enrolled approximately 200 secondary school teachers in 2005 through 2006. Utah partnered with the University of Utah’s Genetic Science Learning Center to establish the Community Genetics Education Network, which provides genetic education to underserved and underrepresented minority communities. Utah developed and field tested the curriculum Using Family History to Improve Your Health to teach high school students about hereditary, lifestyle, and environmental components of chronic disease and to help them understand disease risk. The curriculum met national and state health education and biology standards and was made available in Spanish.
For health care providers and the public, Minnesota developed and broadly disseminated fact sheets on family history of chronic diseases. Utah developed the Family History Toolkit to help people collect and interpret their family health history (
Four state health departments developed pilot programs that integrated human genomics into core public health functions and programs. They were encouraged to explore local opportunities and build on existing resources, an approach that yielded novel projects that were difficult to evaluate as a whole. Nevertheless, they achieved important successes in 3 major areas: 1) conducting population-based assessments and surveillance to develop evidence for the use of genomic information and family history in state disease prevention efforts; 2) demonstrating the integration of this information into existing disease prevention programs, such as WISEWOMAN and Healthy Homes University; and 3) developing, disseminating, and documenting the uptake of educational materials for the health workforce, policy makers, and the public.
The pilot programs also delivered some useful lessons on strategies and challenges for integrating genomics into public health programs for chronic disease prevention (
Obtain support of health department leadership and decision makers.
Seek partnership with early adopters of genomics among disease prevention programs.
Meet programs at their level of interest in a way that is flexible, responsive, and open to ideas.
Engage local public health departments; they are an important setting for integrating genomic information into practice.
Develop external partnerships; consider nontraditional partners, such as genealogists, private businesses, community members, information technology experts, pharmaceutical companies, and the news media.
Develop communications and educational materials that are easy to understand, practical, relevant, and accessible to their intended audiences.
Focus on activities that are relevant to existing programs, require only incremental changes, demonstrate value and impact, and are likely to be sustained.
Evidence-based guidelines and professional standards for integrating family health history, genetic testing, and genetic risk factors into disease prevention programs are limited.
Disease prevention programs have many competing priorities and are reluctant to integrate genomics into their activities without a mandate from their funding source.
Minimal financial support for public health genomics is available from state health departments and federal agencies.
Cooperative agreements that exclude research and clinical services limit the ability of health departments to advance the field of public health genomics.
Funds are limited or lacking to cover clinical genetic services and testing for persons who are uninsured, underinsured, or insured through Medicaid.
No model or best practices exist for the organizational structure of state public health genomics programs.
Most health departments have few staff members with training in genetics.
Lack of a common vocabulary and other barriers hinder communication between public health practitioners and genetics experts.
Although the pilot programs did not set out to measure health outcomes, they created a foundation for successes in subsequent years. Michigan and Oregon sustained their public health genomics programs with limited state funding and in 2008 received new, 3-year cooperative agreements for implementing evidence-based recommendations on hereditary cancer through education, surveillance, and policy development. The new programs built on infrastructure developed during the pilot programs to carry out targeted interventions. Michigan used cancer registry data from 2006 through 2007 to identify more than 15,000 people needing evaluation for
The experiences of Michigan, Minnesota, Oregon, and Utah are useful to a growing number of states — including Connecticut, Ohio, and Georgia — that are developing their own approaches (
CDC’s Office of Public Health Genomics website offers materials for implementing interventions that proceed from evidence-based recommendations (
Timothy Baker and Jean Chabut convened the 2002 Chronic Disease Directors’ Summit, which inspired the work described here. It was supported by a CDC cooperative agreement.
The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention. None of the authors have any conflict of interest relevant to the information presented.
The opinions expressed by authors contributing to this journal do not necessarily reflect the opinions of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions.