Age-adjusted incidence per 100 000, adjusted for reporting delay, of thyroid cancer in the US Surveillance, Epidemiology, and End Results 13 registry from 1992 to 2016. The data markers indicate the observed incidence at each year. The lines represent trends based on segmented regression (Table). In the most recent periods, the annual percentage change in incidence rates for all thyroid cancers was −2.4%; for cancers greater than 1 cm, +2.0%; for subcentimeter cancers, −3.7%.
Customize your JAMA Network experience by selecting one or more topics from the list below.
Powers AE, Marcadis AR, Lee M, Morris LGT, Marti JL. Changes in Trends in Thyroid Cancer Incidence in the United States, 1992 to 2016. JAMA. 2019;322(24):2440–2441. doi:10.1001/jama.2019.18528
The incidence of thyroid cancer in the United States tripled between 1974 and 2013, increasing from 4.5 to 14.4 per 100 000 population.1,2 This increase has primarily been attributed to increasing detection of a subclinical reservoir of small thyroid cancers, although a concurrent increase in the true incidence of disease has not been ruled out. Autopsy studies reveal that many persons without known thyroid disease (4%-11%) harbor clinically occult thyroid cancers, suggesting that increasing health care utilization and imaging technologies have led to the detection of increasing numbers of cancers, without a change in the actual occurrence of thyroid cancer.1,3
In parallel, the incidence of thyroid cancer in South Korea increased to a level 15 times greater in 2011 than in 1993, attributed to a widespread practice of screening healthy persons with thyroid ultrasound.4 As awareness of this phenomenon emerged among physicians and the public, and screening practices were curtailed, the incidence of thyroid cancer in South Korea reversed, first declining in 2014.4
Our objective was to determine whether trends in US thyroid cancer incidence have changed in recent years.
Trends in the age-adjusted incidence of thyroid cancer from 1992 to 2016 (all histologies, stratified by size, with reporting delay adjustment) were analyzed in the Surveillance, Epidemiology, and End Results (SEER) 13 registry, a population-based cancer surveillance registry from 13 geographic regions representing 14% of the US population, using SEER*Stat version 8.3.6 (National Cancer Institute). Segmented log-linear regression was used to determine break points and annual percentage change (APC). Changes in time series trends were assessed by examining differences in slope between segments with a 1-tailed t test (Joinpoint 4.7; https://surveillance.cancer.gov/joinpoint/). The threshold for significance was P < .05. The Weill Cornell Medicine institutional review board deemed this study exempt from review and patient consent. A data use agreement was signed with the SEER program.
Age-adjusted thyroid cancer incidence in the United States increased from 5.7 to 13.8 per 100 000 between 1992 and 2009, with the greatest APC (6.6% [95% CI, 6.2%-7.0%]) from 1998 to 2009. The rate of increase significantly slowed from 2009 to 2014 (incidence, 13.8 to 14.7 per 100 000; APC, 2.0% [95% CI, 0.3%-3.7%]; change in slope, t = −5.4; P < .001). Since 2014, the incidence of thyroid cancer has been stable (from 14.7 to 14.1 per 100 000; APC, −2.4% [95% CI, −7.5% to 3.1%]; change in slope, t = −1.7; P = .06) (Figure and Table).
The incidence of subcentimeter thyroid cancers steadily increased from 1992 to 2009, from 1.2 to 4.7 per 100 000, with the greatest APC (9.1% [95% CI, 8.4%-9.8%]) from 1996 to 2009. The trend stabilized from 2009 to 2013 (incidence, 4.7 to 5.3 per 100 000; APC, 2.9% [95% CI, −2.5% to 8.6%]; change in slope, t = −2.3; P = .02), and then declined from 2013 to 2016 (incidence, 5.3 to 4.7 per 100 000; APC, −3.7% [95% CI, −8.7% to 1.7%]; change in slope, t = −1.9; P = .04) (Figure and Table).
Between 2009 and 2016, after 3 decades of rapid increase,1 the incidence of thyroid cancer incidence in the United States reached a plateau and possibly started to decline. Increasing trends in the incidence of subcentimeter thyroid cancers, most prone to increasing detection, began to reverse direction between 2013 and 2016. Limitations of this study include the nature of observational analyses, which cannot prove causality, and that the trends may not generalize to other areas of the United States beyond the SEER 13 geographic regions.
Although a true decline in the occurrence of thyroid cancer is a possible explanation for these changing trends, less intensive workup of thyroid nodules is more likely. These changes have occurred during a time of evolving understanding of overdiagnosis and the indolent nature of many small thyroid cancers, reflected in changing clinical practice guidelines, including recommendations against screening for thyroid cancer by the US Preventive Services Task Force in 2017.5 Recently, several US professional societies have developed radiographic classification systems for thyroid nodules and introduced risk-stratified recommendations against routine biopsy of nodules more likely to be benign or represent indolent cancers. For example, in 2009 and 2015, American Thyroid Association guidelines introduced size and appearance-based criteria, recommending observation rather than immediate biopsy for many smaller, lower-risk nodules.6
Accepted for Publication: October 22, 2019.
Corresponding Author: Jennifer L. Marti, MD, Department of Surgery, Weill Cornell Medicine, 420 E 70th St, New York, NY 10065 (firstname.lastname@example.org).
Author Contributions: Drs Morris and Marti, who jointly supervised the work and share senior authorship, had full access to the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.
Concept and design: All authors.
Acquisition, analysis, or interpretation of data: Powers, Marcadis, Lee, Morris.
Drafting of the manuscript: Powers, Marcadis, Lee, Morris.
Critical revision of the manuscript for important intellectual content: All authors.
Statistical analysis: Powers, Marcadis, Lee, Morris.
Administrative, technical, or material support: Marcadis, Morris.
Supervision: Morris, Marti.
Conflict of Interest Disclosures: Dr Morris reported receipt of personal fees from Rakuten Aspyrian; in addition, the Morris laboratory receives research funding from Illumina Inc and AstraZeneca for laboratory research. No other disclosures were reported.
Additional Contributions: We acknowledge Jill Gregory, CMI, and Ni-ka Ford, MS, Icahn School of Medicine at Mount Sinai, for their uncompensated assistance with the Figure.
Create a personal account or sign in to: