**3. Papillary thyroid cancer and liquid biopsy**

is estimated to be about 53,070 new cases (40,260 in men and 37,810 in woman), and more than 2000 people will die from the disease [3]. As well as in the rest of the world, the incidence of thyroid cancer has increased threefold over the past 30 years and is expected to increase by 50–60% between 2010 and 2020 [3–5]. The increase in thyroid cancer incidence rates could be explained by thyroid ultrasound screening with improved technical performance of the

Although, there are no significant rise in thyroid cancer mortality rates, growing detection of indolent forms may lead to overtreatment of the patients by performing unnecessary thyroidectomies [7]. General postoperative complications, such as fever, hemorrhages, infection, or cardiopulmonary and thromboembolic events, as well as specific complicationssuch as hypoparathyroidism/hypocalcemia and vocal cord/fold paralysis can be seen. In large population-based study, 27,912 patients were included and analyzed. General postoperative complications were observed in 6.5% of the patients and surgery-specific complications in 12.3% [8]. The diagnostic gold standard for thyroid cancer is the evaluation of histological features, although there still are some differential diagnostic difficulties. To avoid complications, a new, more precise diagnostic tool is necessary to diagnose and manage thyroid cancer

Liquid biopsy is a usual blood sampling method, referred to as a noninvasive procedure to detect components of the tumor which circulates in the bloodstream, for example, circulating tumor cells (CTCs), cell-free nucleic acids, exosomes, or tumor-educated platelets (TEPs); thus it can be a promising method in tumor diagnostics prior to surgery, as well as in monitoring

As previously mentioned, in liquid biopsy, circulating tumor cells (CTC), cell-free nucleic acids, exosomes, or tumor-educated platelets (TEPs) can be acquired and studied for different

Circulating tumor cells are cells which detaches from primary tumor and deposits in a patient's blood. The described ability of CTC is particularly important to fully understand metastatic process; therefore a large scientific research field on this topic has evolved. It is believed that CTC can survive in the bloodstream because of the undergoing epithelial-mesenchymal transition (EMT). In this process tumor cells gain plasticity and motility which allows to extravasate from primary tumor into blood and intravasate into distant tissues as well. Detection of CTC can give valuable clinical information about patient's medical status—CTC can be used as a prognostic marker in different carcinomas including malignant thyroid tumors. Analysis of these cells can serve in treatment process as well—response to different pharmaceutical

Circulating cell-free nucleic acids (cfDNA, cfRNA, and cfmiRNA) discharge from apoptotic and necrotic tumor cells into the bloodstream. cfDNA originates not only form tumor cells but

equipment, as well as better access to medical examination [1, 6].

**2. Detection of specific particles by liquid biopsy**

drugs in individual patient can be analyzed [9, 10].

patients.

88 Liquid Biopsy

of the disease [9].

purposes [9, 10].

The large increase in the incidence of thyroid cancer is seen in papillary thyroid cancer (PTC) which represents the major histological type [12]. PTC accounts for 85% of thyroid malignancy [13]. World Health Organization has defined PTC as a malignant epithelial tumor showing follicular cell differentiation and a specific signs of nuclear features which include nuclear enlargement and overlapping, irregular nuclear contours, and nuclear pseudoinclusions or nuclear grooves, as well as optically clear nuclei [14]. PTC measuring 1 cm or smaller in the greatest dimension is defined as papillary thyroid microcarcinoma (PTMC). It is suggested that incidence of PTC increased largely due to an increase in the incidence of PTMC, probably due to thyroid ultrasound screening with improved technical performance of the equipment, as well as better access to medical examination. Foci of PTMC have been reported in up to 22% of surgical thyroid specimens and up to 36% of autopsy series [6, 15].

The main therapeutic method which is used after the diagnosis of PTC is a total of subtotal thyroidectomy with or without radioactive iodine (RAI) and thyroid hormone suppression. Afterward monitorization of disease status is necessary for all the PTC patients which is carried out by measuring levels of serum thyroid-stimulating hormone (TSH) and serum thyroglobulin (Tg) in the blood. Neck ultrasonography is also performed to detect persistent or recurrent PTC nodules in the thyroid gland after treatment [16]. However, if thyroglobulin antibodies (TgAb) are found in the blood, serum thyroglobulin could not be used as a reliable tumor marker because of false negative rate. Furthermore, long time period is needed to observe the changes in the levels of serum TgAb, and this may lead to late diagnosis [17]. Therefore, other biomarkers need to be discovered and used to monitor persistent or recurrent disease.

A new diagnostic tool—liquid biopsy—can be used to analyze circulating tumor cells (CTCs) or circulating epithelial cells (CECs) and circulating cell-free tumor DNA (ctDNA) in the blood of thyroid cancer patients. This minimally invasive diagnostic method has received a lot of attention over the past years and can also be used to analyze thyroid cancer patients [18]. However, in the case of thyroid carcinoma, only a few studies have been exploring the significance of CTCs in the blood. CTCs are malignant epithelial cells which can separate from primary tumor, invade blood and lymph vessels, and travel through the body to form distant metastases [19]. Salvianti with colleagues proved that quantity of cfDNA with integrity index 180/67 in thyroid cancer patients was higher than in those who had benign thyroid nodules. Therefore, cfDNA could be a suitable marker to diagnose thyroid cancer [20]. On the surface of CTC, epithelial cell adhesion molecule (EpCAM) is found in overexpressed state and therefore can be used for malignant cell visualization from a sample taken by liquid biopsy. Usually EpCAM is overexpressed on tumor cells. The visualization of CTCs can be performed with different antibodies, which allows visualize cells under a fluorescence microscope. In other studies, quantification of various messenger RNAs (mRNAs) is detected in the blood [19].

Not only mRNA but also microRNA could be detected in CTCs [21]. Biochemical alterations of cancer cells are largely supported by noncoding RNA (ncRNA) dysregulation in the tumor site. Noncoding RNAs lack an open reading frame and do not have protein-coding ability. Based on the size of the functional RNA molecule, regulatory ncRNAs are classified as long ncRNAs and small ncRNAs or microRNA (miRNA) [22]. miRNAs are small, evolutionary conserved, single-stranded, noncoding RNA molecules (approximately 22 nucleotides in length) that bind target mRNA to regulate gene expression [23, 24]. MicroRNAs are involved in various physiological and pathological functions, such as apoptosis, cell proliferation, and differentiation, which indicate their functionality in carcinogenesis as tumor suppressor genes or oncogenes [25]. Up- or downregulation of miRNA can influence the tumorigenic outcome depending on the role(s) of the target genes on vital signaling processes [26].

The most often upregulated miRNAs in papillary thyroid cancer (PTC) are miR-146b, miR-222, miR-221, and miR-181b. Overexpressed miR-146b targets retinoic acid receptor beta (RARβ) and causes reduced expression of this gene leading to increased tumor aggressiveness and extrathyroidal invasion. miR-221 and miR-222 target tumor suppressor and cell-cycle regulator p27. Reduced expression of p27 results in increased proliferation of tumor cells. These processes are related to aggressive behavior of tumor, extrathyroidal invasion, and the presence of lymph node invasion [21, 27–29]. miR-181b also is overexpressed in PTC compared to normal thyroid tissue. miR-181b inhibits expression of cylindromatosis (CYLD) gene which acts as tumor suppressor and normally induces cellular apoptosis [28, 30].

**4. Follicular thyroid cancer and liquid biopsy**

**Table 1.** Expression of microRNA in PTC.

**Diagnosis Type of** 

Papillary thyroid cancer **miRNA**

Follicular thyroid carcinoma (FTC) is the second most common type of thyroid cancer, comprising 10–15% of all thyroid carcinomas [4, 13, 31]. Although FTC is the second most common type, its incidence has decreased over the past few years [31]. World Health Organization has defined FTC as a malignant epithelial tumor showing follicular cell differentiation in which the diagnostic nuclear features of PTC are absent. Lesions are usually encapsulated and show invasive growth pattern [14]. The diagnosis of FTC is a difficult dilemma in cases when capsular, vascular, or extrathyroidal invasion or metastasizing is not straightforward [32, 33]. A lot of studies have researched biomarkers in liquid biopsy for PTC; however, limited amount of information is found about FTC. One of those studies explored miRNA dysregulation and tried to found miRNA markers for diagnostic purposes in the case of FTC [34]. Dettmer with colleagues found upregulation of miR-182/-183/-221/-222/-125a-3p and a downregulation of miR-542-5p/-574-3p/-455/-199a. They concluded that distinction between FTC and hyperplastic nodules can be done by the use of dysregulated miRNA in the tissues. The miRNAs found

**Type of regulation Outcome References**

invasion, and lymph node metastasis

invasion, and lymph node metastasis

miR-181b Upregulated in cells Decreased apoptosis of cancer cells Boufraqech et al. [28] miR-145 Downregulated cells Regulates cancer growth Boufraqech et al. [28]

invasion, and migration

miR-451 Downregulated cells Tumor aggressiveness Rodriguez-Rodero et al. [27]

Rossi et al. [21]

Liquid Biopsy in Patients with Thyroid Carcinoma http://dx.doi.org/10.5772/intechopen.85356

Rossi et al. [21]

Rossi et al. [21]

Rodriguez-Rodero et al. [27] Boufraqech et al. [28] Chruscik et al. [29]

91

Rodriguez-Rodero et al. [27] Boufraqech et al. [28] Chruscik et al. [29]

Rodriguez-Rodero et al. [27] Boufraqech et al. [28] Chruscik et al. [29]

Boufraqech et al. [28]

Boufraqech et al. [28] Chruscik et al. [29]

Boufraqech et al. [28]

extrathyroidal invasion

miR-146b Upregulated in cells Aggressive behavior and

miR-222 Upregulated in cells Aggressive behavior, extrathyroidal

miR-221 Upregulated in cells Aggressive behavior, extrathyroidal

miR-613 Downregulated cells Increased cellular proliferation and invasion

miR-137 Downregulated cells Increased cellular proliferation,

The most often downregulated miRNAs in PTC are miR-145, miR-451, miR-613, and miR-137. miR-145 acts a tumor suppressor in thyroid cancer, and downregulation leads to cancer growth through several pathways [28]. miR-451 acts as a tumor suppressor by targeting the PI3/AKT pathway. Downregulation of miR-451a is associated with tumor aggressiveness and the presence of extrathyroidal invasion [27, 28]. miR-613 is involved in PTC cell proliferation and invasion [28, 29]. In PTC, miR-137 expression is downregulated leading to increased cellular proliferation, invasion, and migration [28] (**Table 1**).


**Table 1.** Expression of microRNA in PTC.

of thyroid cancer patients. This minimally invasive diagnostic method has received a lot of attention over the past years and can also be used to analyze thyroid cancer patients [18]. However, in the case of thyroid carcinoma, only a few studies have been exploring the significance of CTCs in the blood. CTCs are malignant epithelial cells which can separate from primary tumor, invade blood and lymph vessels, and travel through the body to form distant metastases [19]. Salvianti with colleagues proved that quantity of cfDNA with integrity index 180/67 in thyroid cancer patients was higher than in those who had benign thyroid nodules. Therefore, cfDNA could be a suitable marker to diagnose thyroid cancer [20]. On the surface of CTC, epithelial cell adhesion molecule (EpCAM) is found in overexpressed state and therefore can be used for malignant cell visualization from a sample taken by liquid biopsy. Usually EpCAM is overexpressed on tumor cells. The visualization of CTCs can be performed with different antibodies, which allows visualize cells under a fluorescence microscope. In other studies, quantification of various messenger RNAs (mRNAs) is detected in the blood [19].

Not only mRNA but also microRNA could be detected in CTCs [21]. Biochemical alterations of cancer cells are largely supported by noncoding RNA (ncRNA) dysregulation in the tumor site. Noncoding RNAs lack an open reading frame and do not have protein-coding ability. Based on the size of the functional RNA molecule, regulatory ncRNAs are classified as long ncRNAs and small ncRNAs or microRNA (miRNA) [22]. miRNAs are small, evolutionary conserved, single-stranded, noncoding RNA molecules (approximately 22 nucleotides in length) that bind target mRNA to regulate gene expression [23, 24]. MicroRNAs are involved in various physiological and pathological functions, such as apoptosis, cell proliferation, and differentiation, which indicate their functionality in carcinogenesis as tumor suppressor genes or oncogenes [25]. Up- or downregulation of miRNA can influence the tumorigenic outcome depending on the role(s) of the target genes on vital signaling

The most often upregulated miRNAs in papillary thyroid cancer (PTC) are miR-146b, miR-222, miR-221, and miR-181b. Overexpressed miR-146b targets retinoic acid receptor beta (RARβ) and causes reduced expression of this gene leading to increased tumor aggressiveness and extrathyroidal invasion. miR-221 and miR-222 target tumor suppressor and cell-cycle regulator p27. Reduced expression of p27 results in increased proliferation of tumor cells. These processes are related to aggressive behavior of tumor, extrathyroidal invasion, and the presence of lymph node invasion [21, 27–29]. miR-181b also is overexpressed in PTC compared to normal thyroid tissue. miR-181b inhibits expression of cylindromatosis (CYLD) gene which acts as tumor suppressor and normally induces cel-

The most often downregulated miRNAs in PTC are miR-145, miR-451, miR-613, and miR-137. miR-145 acts a tumor suppressor in thyroid cancer, and downregulation leads to cancer growth through several pathways [28]. miR-451 acts as a tumor suppressor by targeting the PI3/AKT pathway. Downregulation of miR-451a is associated with tumor aggressiveness and the presence of extrathyroidal invasion [27, 28]. miR-613 is involved in PTC cell proliferation and invasion [28, 29]. In PTC, miR-137 expression is downregulated leading to increased cel-

processes [26].

90 Liquid Biopsy

lular apoptosis [28, 30].

lular proliferation, invasion, and migration [28] (**Table 1**).
