Differentiated thyroid cancer is increasing in incidence. The Surveillance, Epidemiology, and End Results (SEER) program database estimates that there will be 62,450 new cases of thyroid cancer in 2015, representing 3.8 % of all new cancers, and there will be 1950 deaths resulting from thyroid cancer. The incidence has been rising at about 5 % per year [1]. Thyroid cancer affects women more than men resulting in 47,230 of the 62,450 estimated cases to be in women. Deaths estimated in 2015 will occur in 1080 women and 870 men [2]. The yearly incidence has nearly tripled from 4.9 per 100,000 in 1979 to 14.3 per 100,000 in 2009 [3]. Nearly two out of three thyroid cancers will be detected in patients under 55 [3]. Overall, the 5-year survival for differentiated thyroid cancer is 97.9 % [1]. Many investigators feel the rise in incidence is due to detection earlier of small thyroid cancers with radiologic intensity; however, some studies have shown a rise in larger tumors being diagnosed as well [4]. Several authors including Vigneri et al. feel that thyroid cancer incidence is increasing due to two processes: (1) increased detection and (2) increased incidence due to thyroid-specific carcinogens that are not fully recognized nor studied; this latter point is the focus of ongoing investigations [5]. Almost the entire increase in incidence can be attributed to papillary thyroid cancers. Additionally, 25 % of the new thyroid cancers diagnosed in 1988–1989 were <1 cm compared to 39 % in 2008–2009 [3].

Approximately 88 % of all differentiated thyroid cancers (DTC) are papillary thyroid cancer (PTC) (and its various subtypes), while 8 % are follicular thyroid cancer [6]. DTC can occur at any age, but has a median age of diagnosis of 49 years, with approximately 39 % of new cases diagnosed prior to the age of 45 years. Women are about three times more likely to develop DTC [1]. By the year 2019, one study predicts that papillary thyroid cancer will be the third most common cancer in women at a healthcare cost of $19–21 billion in the United States alone, representing a major growing healthcare concern [7].

Overall prognosis for DTC is quite good. The goals of initial therapy (specifically surgery) are to (1) remove the primary tumor and any disease that has extended beyond the thyroid capsule including nodal metastases that are clinically significant; (2) minimize the risk of disease recurrence; (3) facilitate radioactive iodine ablation, adjuvant, or therapeutic, when appropriate; (4) permit accurate staging and risk stratification of the disease and prognostication; (5) permit accurate long-term surveillance for disease recurrence; and (6) minimize treatment-related morbidity [8].

In patients who have PTC tumors >1 cm with no extrathyroidal extension or vascular invasion, their risk of death is nearly 0 % and risk of recurrence on average is 2 % [9]. Patients with clinical N1 disease will have an overall risk of recurrence of 13–42 %, whereas those with pathological N1 disease will have a 7–14 % risk of recurrence [10]. Those with larger metastases and extra-nodal extension are at the highest risk for recurrence [10]. In terms of survival, stage I and II patients have a near 96–99.7 % relative 5-year survival rate vs. 91 % for stage III and 50 % for stage IV [11, 12].

Although most patients with DTC have a favorable long-term survival, up to 30 % of patients may experience a recurrence overall, but this is very dependent on initial staging and clinical findings [13]. Clinically evident disease recurrence has been reported up to 30 or 40 years after initial therapy, but large retrospective studies consistently show that the vast majority of recurrences are detected within 10–15 years after initial therapy [14].

Short-term and long-term surveillance strategies continue to evolve based on ongoing scientific investigations. Typically, current surveillance regimens for most patients with DTC include serial thyroglobulin measurements coupled with cervical ultrasound at a minimum to identify residual or recurrent disease, which commonly occurs within the thyroidectomy bed or lateral cervical lymph node chains [15]. In order to recommend how best to provide surveillance for a patient with treated thyroid cancer in the postoperative setting, it is important to use all of the available clinical data to individually risk-stratify patients [12]. This would include the original pathology report; pre- or postoperative neck imaging, which is typically in the form of an ultrasound; and postoperative serum thyroglobulin levels. A careful analysis of these data points can provide initial estimates for risk of recurrence, risk of having persistent disease, disease-specific mortality, and TSH suppression goals; it can guide providers in choosing the best imaging modalities for surveillance [16]. Tailoring a risk-stratified approach to individual patient care could lead to a more cost-effective approach, and possibly higher quality of life by reducing the burden of adverse treatment effects, and the stress and costs of ongoing surveillance. Providers are encouraged to stage patients postoperatively to provide prognostic information that is of value when considering disease surveillance and therapeutic strategies. In addition, this allows tracking of patients for communication among other healthcare professionals, tracking by various cancer registries and for research purposes [8].

The first-line therapy in nearly all patients is surgery, followed by radioactive iodine in some intermediate- and high-risk patients. The ATA has developed risk categories to help guide clinicians in initial treatment and subsequent surveillance as defined below.

ATA low-risk patients include papillary thyroid cancer with all of the following:

ATA intermediate-risk patients include:

ATA high–risk patients include:

[Adapted from the new American Thyroid Association guidelines, reference [8]]

Although most DTCs have a very favorable long-term prognosis, the disease can recur many years after initial diagnosis leading the provider to decide on a long-term plan for how best to provide surveillance for these treated thyroid cancer patients. No evidence of disease (NED) is defined as stimulated thyroglobulin <1 ng/ml with no other radiological or clinical evidence of disease. Studies looking at estimates of patients in each risk category who subsequently were characterized as no evidence of disease (NED) after total thyroidectomy and RAI remnant ablation found that 78–91 % of low-risk patients were NED; intermediate-risk patients, 52–64 % NED; and high risk, 31–32 % NED [8, 17–20]. Over a follow-up period of 5–10 years, structural disease recurrence was found in less than 1–2 % of ATA low-risk patients and 8 % of intermediate-risk patients who underwent thyroid surgery without RAI ablation as initial therapy [21–23].

It is also important to consider the clinical significance of “persistent disease.” In ATA low-risk patients, 70–80 % of persistent disease is manifest by abnormal serum thyroglobulin levels (suppressed or stimulated thyroglobulin >1 ng/ml) without identifiable structural disease, whereas in intermediate-risk patients, this ranges from 29 to 51 % and in high-risk patients 19–21 % [17, 20]. When counseling patients on risk of recurrence and tailoring surveillance strategies, the original pathology provides critical data. For example, patients with unifocal intrathyroidal papillary microcarcinomas experience structural disease recurrence of 1–2 % [24, 25] which increases to 5–6 % in 2–4 cm intrathyroidal PTCs [26] and 8–10 % in intrathyroidal PTCs >4 cm [26]. Intermediate-risk patients with locoregional lymph node involvement can have a risk of structural disease recurrence of 4 % in patients with fewer than five metastatic lymph nodes, 5 % if all lymph nodes involved are <0.2 cm, 19 % if more than five lymph nodes are involved, 21 % if >10 lymph nodes, 22 % if macroscopic lymph nodes are clinically evident (CN1 disease), and 27–32 % if any metastatic nodes are greater than 3 cm [10, 27].

Ultimately, all imaging (including structural and functional), biochemical, and cytopathological data should be used for a dynamic, ongoing redefinition of clinical status to assess the individual response to therapy at each follow-up visit over time. This re-evaluation should direct intensity of surveillance and follow-up.