Advancing Chronic Disease Practice Through the CDC Data Modernization Initiative

Timothy Jay Carney, PhD, MPH, MBA¹; Jennifer L. Wiltz, MD, MPH^1,2; Kailah Davis, PhD¹; Peter A. Briss, MD, MPH¹; Karen Hacker, MD, MPH¹ (View author affiliations)

Suggested citation for this article: Carney TJ, Wiltz JL, Davis K, Briss PA, Hacker K. Advancing Chronic Disease Practice Through the CDC Data Modernization Initiative. Prev Chronic Dis 2023;20:230120. DOI: http://dx.doi.org/10.5888/pcd20.230120.

PEER REVIEWED

Chronic disease affects 6 in 10 adults in the US, while 4 in 10 adults live with multiple chronic diseases (1). Chronic diseases represent one of the nation’s leading causes of disability and drivers of the nation’s $4.1 trillion in annual health care spending (1). Chronic conditions including heart disease, cancer, stroke, diabetes, and chronic kidney disease dominate the leading causes of death. Furthermore, leading lifestyle risk factors in the US include tobacco use, poor nutrition, physical inactivity, and excessive alcohol use (1).

Chronic disease prevention and control necessitates a comprehensive strategy to prevent disease (2–4), which is needed now more than ever (5). Information systems innovations are needed to advance health activities and outcomes and to allow decision makers and practitioners to act (4,6–8). Chronic disease data are a foundation that can inform interventions to promote healthy communities, support healthy behaviors and lifestyles, and facilitate effective and coordinated chronic disease prevention and health promotion (5,9). The benefits of an improved chronic disease data landscape include improved management of chronic disease programs, enhanced communication, data exchange, and coordination between federal, state, tribal, local, and territorial health departments and their partners. Additionally, efforts aimed at enhancing chronic disease surveillance practices will better enable a learning health system, precision public health, and improved situational awareness that will ultimately allow people across the US to live longer, healthier lives (10–12).

Despite the tremendous need for chronic disease data across all disease categories, gaps remain in the ability to rapidly translate data into action (7,8,13,14). Antiquated data systems need updating and modernization. This was particularly apparent during the COVID-19 pandemic when data flow between states and CDC was challenging (15,16). The lag time from initial chronic disease data capture to the availability of actionable information can be 2 years or more (17,18). Data are also often not available at the local level.

Data modernization efforts (19) are critical to building the capacity of the public health system to effectively monitor and address chronic disease. At the National Center for Chronic Disease Prevention and Health Promotion (NCCDPHP) within the Centers for Disease Control and Prevention (CDC), we aim to encourage better use of data and better meet the needs of our partners, more importantly ensuring the inclusion of those in health care, social services, and public health. The modernization activities as described in this manuscript have the goal of meeting the needs of the field and we hope that they are helpful. While we recognize that modernization will reflect a diverse portfolio of national, state, and local efforts crossing multiple sectors, this brief discussion will primarily focus on the federal response to chronic disease data challenges and how these efforts may represent and build support for greater, more comprehensive actions at all levels of public health.

Top

Understanding the Chronic Disease Data Challenges

To improve chronic disease data and address modernization efforts, we must account for the complexity in the chronic disease landscape and address the needs of 3 main partners: health care, social services, and public health. Each of these primary partners are essential to understanding chronic disease, each has unique data needs, and each possess their own chronic disease data. Challenges exist across these large-scale domains.

Public health system

Public health collects population-based data as well as data on reportable conditions. It requires accurate, locally relevant, and timely data to provide comprehensive and pertinent information for decision-making. However, accessing these data is an ongoing challenge. Currently, much of this information comes from large population-based surveillance systems. These should be complemented with pipelines into clinical (eg, electronic health information), social service, jurisdictional health department (eg, population registries), community (eg, local community profiles), and other data sources that will allow improved evaluation of local risks and disease burden. Much of the data in these systems is publicly available but seldom connected to either the health care or the social service systems. Challenges, needs, and thus opportunity exist at the level of data (eg, population sampling, information missingness, data quality standards), information systems (eg, systems infrastructure, data management, information linkages, privacy protection), and contextual factors (eg, the policy landscape, payments, tools packaged for application) across the process of data capture, integration, and use (20).

Health care system

Health care generates an enormous amount of individual-level chronic disease data necessary for care provision, billing, quality measures, and coordination of services. However, there continue to be barriers to accessing data and challenges to synthesizing data, in part because of fragmented systems. For those outside the health care system that could benefit from health care data, issues including privacy concerns, interoperability, and data quality all pose significant hurdles. While efforts are under way to improve access to health care data for public health use, to date no universal strategies exist to extract data from the health care system for public health uses.

Social services system

Social services also collect data on clients and consumers but would benefit from better standardization and linkages to both health care and public health data sources. For example, social services may require data from the health care system for effective referral and follow up including information on the client’s social needs and support mechanisms. However, there is a lack of consistent case management systems that are interoperable with electronic health records. Information on measurable progress needs to be communicated to ensure quality management, but variability in systems leads to inconsistent definitions, quality control, and reporting. In addition, the social service system could benefit from data about upstream community conditions that contribute to population risk, but there are few examples of public health and social service data sharing that would meet this need. Major data gaps also exist in identifying populations with greatest needs, including populations who have lower socioeconomic status or education levels, persons living in sparsely populated rural areas, and those from racial and ethnic minority groups. Addressing data gaps in these areas should help detect, monitor, and manage chronic conditions and promote healthy populations.

Across the chronic disease landscape

There is considerable data fragmentation within as well as between these silos. For example, the public health system at the national level maintains chronic disease data in multiple places. Some resources, like the Behavioral Risk Factor Surveillance System, cover a variety of chronic conditions. Others focus on a single chronic disease such as the Diabetes Surveillance System, the Paul Coverdell Stroke Registry, or the National Program of Cancer Registries. Similarly, within the health care system, there are countless registries and clinical data warehouses, health information exchanges, and claims databases that house and track data. Each data repository is typically managed by a different owner such as health care services, private companies, higher educational institutions, and government agencies. Some data are publicly available while others have limited access. All these disparate efforts result in fragmented views of the overall burden of chronic disease in the US within and across jurisdictions. They also result in challenges to generating up-to-date estimates of progress and shortfalls. While some progress has been made, there is no one model at the local or national level for chronic disease data modernization to adopt.

Addressing the challenges across these disparate systems will require solutions across the public health ecosystem. The CDC Moving Forward strategic initiative aims to modernize CDC to consistently deliver public health information in real time (21). The CDC Data Modernization Initiative (DMI) (22) intends to address many longstanding challenges of managing data and technology to support public health outcomes. While CDC activities will not apply seamlessly for all partners and will not address all challenges, we present the NCCDPHP portfolio of data modernization programs as good examples that might be more broadly reused or adapted.

Top

Highlighted Successes in Chronic Disease Modernization

CDC’s NCCDPHP is dedicated to improving the health and wellness of Americans by preventing and managing chronic disease. Data are a critical component of this mission. Modernizing approaches to generating and using chronic disease data will yield information to CDC, our partners, and the public in a timely, efficient, and accessible manner. NCCDPHP has launched efforts to modernize the chronic disease data landscape and now has a portfolio of over 27 projects. These projects touch various existing and new surveillance initiatives across all NCCDPHP operational units.

To better organize and coordinate the NCCDPHP data modernization effort, an NCCDPHP DMI strategic coordination plan was put in place. The activities were divided into 6 main areas that allowed for ease of tracking progress, reporting program updates, and promoting the value-added benefits to NCCDPHP program objectives. NCCDPHP data modernization priorities and activity areas (Table) include the following:

1. Modernizing legacy information technology and surveillance systems — NCCDPHP hosts close to 80 data systems and over 25 surveillance systems. Modernizing these systems is ongoing to increase data samples, connectivity, and usability.
2. Using electronic health record (EHR) platforms — Health care data largely stored in EHRs can be a source for health monitoring and quality of care improvements. Clean, accurate, timely, and complete EHR data could complement NCCDPHP surveillance efforts and support program activities.
3. Integrating data — Understanding and reducing chronic disease will require data across silos, bridges between disease data systems, and improvements in the flow of data. This will require large-scale data integration that can keep pace with modern query demands, produce integrated and dynamic analytics, support predictive capabilities, and produce efficiencies and economies of scale in design that provide better data for better results.
4. Leveraging cloud technologies — Cloud computing is a technological step forward that will allow enhanced data security, increased scalability, faster integration of data, automated reporting, and the promise of artificial intelligence computing that will enable dynamic processing of complex data queries and machine learning.
5. Using data to address health equity and social determinants of health (SDOH) challenges — Reducing health inequities and managing risk and vulnerabilities related to adverse SDOH is essential to improving chronic disease outcomes. Better data are needed to highlight areas of need, demonstrate what works, and allow for rapid strategy and intervention design to meet challenges as they arise.
6. Building informatics planning and reporting capacity — Strategic planning itself is a core practice supporting large-scale data modernization efforts. It allows planning for spending and investment in areas such as analytics reporting, dashboards, and related tools that are essential to see that desired results are being achieved.

The NCCDPHP modernization portfolio includes activities that impact the data lifecycle across the 6 priorities and address multiple chronic disease topical areas (Table). Select examples illustrate changes that might be useful:

• New information is being generated such as Population Level Analysis and Community Estimates (24) (PLACES; priority 4 in Table), that provides multiple health measures at local levels across the US. PLACES provides model-based estimates that can enhance understanding for localities, regardless of population size and rurality, of the burden and geographic distribution of health measures in their areas and assist them in planning public health interventions. In summer of 2024, a new SDOH module will also be available.
• Data are being linked across multiple sectors such as in the state-wide Clinical and Community Data Initiative (25) (priority 5 in Table). This project is linking data in North Carolina and Colorado across health care–based and community-based programs, and administrative data sets using common technology. Being able to link data on health behaviors, interventions, and outcomes to SDOH and other community services and factors provides more holistic views that are being used to reduce chronic diseases and achieve health equity (25).
• Complex data partnerships have been developed by the Multi-State EHR-Based Network for Disease Surveillance (23) (MENDS; priority 2 in Table). This network is helping to determine whether data routinely stored in EHRs can provide clinically detailed, efficient, and timely information from diverse populations both to answer pressing health questions and to yield reliable chronic disease estimates for public health surveillance. One example is from Washington, where MENDS data visualization tools are used to understand the distribution of hypertension and diabetes at a zip-code level (26).
• Data are being moved and stored securely, faster, and more flexibly through the use of new technologies. The National Program of Cancer Registries is transitioning to a newly designed cloud-based platform, the Cancer Surveillance Cloud-based Computing Platform (CS-CBCP; priority 4 in Table) (12). This move will automate cancer case collection processes, which will in turn make cancer data available in near real time. Similarly, a cloud data platform is being developed that improves data access and dissemination of the Pregnancy Risk Assessment Monitoring System (27) (PRAMS; priority 4 in Table) analytics research file. Expected benefits include lessening data access burden on partners and reducing data dissemination turnaround time (from 6 to 8 weeks to 2 or 3 days), ultimately reducing the time from data to action for mothers and children.
• Data are being translated into actionable information. One example is the National Diabetes Prevention Program (National DPP) Operations Center (28) (priority 3 in Table), which is a central data hub that provides critical and timely information and tools to CDC staff and organizations offering the National DPP lifestyle change program. These end users are now able to answer critical questions, solve programmatic challenges, and make data-driven decisions that can improve the delivery of and referral to the National DPP lifestyle change program. The use of the National DPP Operations Center may help scale and spread the National DPP to reach even more at-risk individuals (28).

Top

The Road Ahead for Chronic Disease Data Modernization

While examples of data modernization for chronic disease surveillance are under way nationally, more work is needed to use data resources to realize measurable impact on chronic disease outcomes. A comprehensive strategy for chronic disease modernization would address the inherent uniqueness of chronic disease surveillance across data types, collection methods, and systems at every level of public health. This must include activities such as improving data capture and quality for SDOH and demographic data, including race and ethnicity, to advance understanding of the drivers of health and equity; incorporating chronic disease within data flow pipelines; better supporting granular assessments of small segments of the population normally excluded in large aggregated estimates; reducing burden on partners engaged in surveillance activities; and building a skilled workforce to leverage advanced data practices and workflows. As we bolster the public health infrastructure after the pandemic, access to timely, accurate chronic disease data is foundational. Exemplars are already occurring in the field, and leaders in chronic disease can forge the path forward to better use data and information to improve the health of people across the US.

Top

Acknowledgments

Timothy Jay Carney and Jennifer L. Wiltz are co-first authors of this article.

We would like to acknowledge all the NCCDPHP programs for the data modernization activities as well as all our state, tribal, local, and territorial health partners participating in the work described here.

Top

Author Information

Corresponding author: Timothy Jay Carney, PhD, MPH, MBA, National Center for Chronic Disease Prevention and Health Promotion, Centers for Disease Control and Prevention, 4770 Buford Hwy NE, MS S107-8, Atlanta, GA 30341 (thc8@cdc.gov).

Author Affiliations: ¹National Center for Chronic Disease Prevention and Health Promotion, Centers for Disease Control and Prevention, Atlanta, Georgia. ²US Public Health Service, Atlanta, Georgia.

Top

References

1. Centers for Disease Control and Prevention, National Center for Chronic Disease Prevention and Health Promotion. Chronic diseases in America. Reviewed December 13, 2022. Accessed February 11, 2023. https://www.cdc.gov/chronicdisease/resources/infographic/chronic-diseases.htm
2. Bauer UE, Briss PA, Goodman RA, Bowman BA. Prevention of chronic disease in the 21st century: elimination of the leading preventable causes of premature death and disability in the USA. Lancet. 2014;384(9937):45–52. PubMed doi:10.1016/S0140-6736(14)60648-6
3. Thacker SB, Stroup DF, Rothenberg RB, Brownson RC. Public health surveillance for chronic conditions: a scientific basis for decisions. Stat Med. 1995;14(5-7):629–641. PubMed doi:10.1002/sim.4780140520
4. Beaglehole R, Ebrahim S, Reddy S, Voûte J, Leeder S; Chronic Disease Action Group. Prevention of chronic diseases: a call to action. Lancet. 2007;370(9605):2152–2157. PubMed doi:10.1016/S0140-6736(07)61700-0
5. Hacker KA, Briss PA, Richardson L, Wright J, Petersen R. COVID-19 and chronic disease: the impact now and in the future. Prev Chronic Dis. 2021;18:E62. PubMed doi:10.5888/pcd18.210086
6. Richards CL, Iademarco MF, Atkinson D, Pinner RW, Yoon P, Mac Kenzie WR, et al. . Advances in public health surveillance and information dissemination at the Centers for Disease Control and Prevention. Public Health Rep. 2017;132(4):403–410. PubMed doi:10.1177/0033354917709542
7. Balasuriya L, Briss PA, Twentyman E, Wiltz JL, Richardson LC, Bigman ET, et al. . Impacts of the COVID-19 pandemic on nationwide chronic disease prevention and health promotion activities. Am J Prev Med. 2023;64(3):452–458. PubMed doi:10.1016/j.amepre.2022.09.012
8. Calanan RM, Sandoval-Rosario M, Price JD, Samanic CM, Lu H, Barbour KE. Achieving excellence in the practice of chronic disease epidemiology. Prev Chronic Dis. 2018;15(11):E146. PubMed doi:10.5888/pcd15.180526
9. National Center for Chronic Disease Prevention and Health Promotion. Chronic disease data. Reviewed April 28, 2021. Accessed July 12, 2023. https://www.cdc.gov/chronicdisease/data/index.htm
10. Epping-Jordan JE, Pruitt SD, Bengoa R, Wagner EH. Improving the quality of health care for chronic conditions. Qual Saf Health Care. 2004;13(4):299–305. PubMed doi:10.1136/qshc.2004.010744
11. Canfell OJ, Davidson K, Woods L, Sullivan C, Cocoros NM, Klompas M, et al. . Precision public health for non-communicable diseases: an emerging strategic roadmap and multinational use cases. Front Public Health. 2022;10:854525. PubMed doi:10.3389/fpubh.2022.854525
12. Jones DE, Alimi TO, Pordell P, Tangka FK, Blumenthal W, Jones SF, et al. . Pursuing data modernization in cancer surveillance by developing a cloud-based computing platform: real-time cancer case collection. JCO Clin Cancer Inform. 2021;5(5):24–29. PubMed doi:10.1200/CCI.20.00082
13. Assistant Secretary for Planning and Evaluation. Improving data for decision making: HHS data collection strategies for a transformed health system: implementation update and accomplishments. 2011. Accessed July 12, 2023. https://aspe.hhs.gov/reports/improving-data-decision-making-hhs-data-collection-strategies-transformed-health-system
14. Li P, Ma L, Liu J, Zhang L. Surveillance of noncommunicable diseases: opportunities in the era of big data. Health Data Sci. 2022;2022:9893703.
15. McKillop M, Lieberman DA. The impact of chronic underfunding on America’s public health system: trends, risks, and recommendations, 2022. 2022. Accessed July 12, ­­­­­2023. https://www.tfah.org/wp-content/uploads/2022/07/2022PublicHealthFundingFINAL.pdf
16. Health Information Technology Advisory Committee. Public Health Data Systems Task Force 2021. Report to the Health Information Technology Advisory Committee. 2021. Accessed July 12, 2023. https://www.healthit.gov/sites/default/files/facas/2021-07-14_PHDS_TF_2021_Recommendations_Report_0.pdf
17. National Center for Chronic Disease Prevention and Health Promotion, Division for Heart Disease and Stroke Prevention. Interactive web applications and data. Reviewed June 9, 2020. Accessed July 12, 2023. https://www.cdc.gov/gis/interactive-applications.htm
18. Centers for Disease Control and Prevention. Data sets. Accessed June 13, 2023. https://data.cdc.gov/
19. Centers for Disease Control and Prevention. Public health data strategy. Public health data goals and 2-year milestones. 2023. Accessed April 22, 2023. https://www.cdc.gov/ophdst/public-health-data-strategy/public_health_data_strategy-final-p.pdf
20. Wiltz JL, Blanck HM, Lee B, Kocot SL, Seeff L, McGuire LC, et al. . Electronic information standards to support obesity prevention and bridge services across systems, 2010–2015. Prev Chronic Dis. 2017;14:E103. PubMed doi:10.5888/pcd14.160299
21. Centers for Disease Control and Prevention. CDC Moving Forward. Reviewed August 17, 2022. Accessed April 10, 2023. https://www.cdc.gov/about/organization/cdc-moving-forward.html
22. Centers for Disease Control and Prevention. Data Modernization Initiative. Reviewed December 15, 2022. Accessed February 13, 2023. https://www.cdc.gov/surveillance/data-modernization/index.html
23. Hohman KH, Martinez AK, Klompas M, Kraus EM, Li W, Carton TW, et al. . Leveraging electronic health record data for timely chronic disease surveillance: the Multi-State EHR-Based Network for Disease Surveillance. J Public Health Manag Pract. 2023;29(2):162–173. PubMed doi:10.1097/PHH.0000000000001693
24. Centers for Disease Control and Prevention, National Center for Chronic Disease Prevention and Health Promotion. PLACES: local data for better health. Reviewed December 9, 2022. Accessed March 6, 2023. https://www.cdc.gov/places/index.html
25. Centers for Disease Control and Prevention, National Center for Chronic Disease Prevention and Health Promotion, Division of Nutrition, Physical Activity, and Obesity. CODI. Clinical and Community Data Initiative. Reviewed October 21, 2021. Accessed October 18, 2023. https://www.cdc.gov/obesity/initiatives/codi/community-and-clinical-data-initiative.html
26. Raths D. Piloting EHR-based chronic disease surveillance in Washington State. Published August 26, 2021. Accessed March 14, 2023. https://www.hcinnovationgroup.com/policy-value-based-care/public-health/article/21235951/piloting-ehrbased-chronic-disease-surveillance-in-washington-state
27. Centers for Disease Control and Prevention, National Center for Chronic Disease Prevention and Health Promotion, Division of Reproductive Health. Pregnancy Risk Assessment Monitoring System. Published May 23, 2022. Accessed March 6, 2023. https://www.cdc.gov/prams/index.htm
28. Holliday C. How CDC Is Using Technology to Enhance its Diabetes Prevention and Management Efforts. Streaming video. National Committee for Quality Assurance (NCQA). 2022. Accessed July 12, 2023. https://www.ncqa.org/videos/how-cdc-is-using-technology-to-enhance-its-diabetes-prevention-and-management-efforts/

Top

Top

Table

Abbreviation: CDC, Centers for Disease Control and Prevention.
^a This table provides only a snapshot of NCCDPHP data modernization efforts across the Center’s divisions and offices; it is not a comprehensive list of data modernization activities.
^b Division of Population Health.
^c Division of Reproductive Health.
^d NCCDPHP Office of the Director.
^e Division of Diabetes Translation.
^f Division for Heart Disease and Stroke Prevention.
^g Division of Oral Health.
^h Office on Smoking and Health.
ⁱ Division of Cancer Prevention and Control.
^j Division of Nutrition, Physical Activity, and Obesity.

Top