Poorly differentiated carcinoma is a tumor of follicular cell origin that occupies a position both morphologically and biologically between well-differentiated papillary or follicular carcinoma and anaplastic thyroid carcinoma [1, 37, 38, 39]. These lesions behave in an aggressive fashion and are often lethal. They do not respond well to treatment with radioactive iodine, since their uptake of this targeted therapy is reduced. This is the lesion that most often is identified as “widely invasive follicular carcinoma” [40]. Vascular invasion and distant metastases are frequent at the time of diagnosis. On complete histological evaluation, there is often a focus of well-differentiated carcinoma (either papillary or follicular) with progression to dedifferentiation; however, some tumors are entirely composed of a poorly differentiated lesion. These tumors may have a central encapsulated nidus, and smaller lesions may not be widely invasive, but usually, the lesion exhibits frank capsular invasion and forms satellite nodules in the surrounding thyroid.

The majority of these lesions have an architectural growth pattern that is characterized by large, well-defined solid nests (Fig. 11.13,
e-Fig. 11.11) that mimics neuroendocrine tumors such as medullary carcinoma; this architecture has given rise to the terminology “insular” carcinoma. Other tumors have trabecular growth patterns. They are largely devoid of follicular architecture or colloid. The tumor cells are usually small and uniform in size (Fig. 11.14, e-Fig. 11.12), and there is mitotic activity with 3 or more mitoses per 10 high-power fields [41, 42] (Fig. 11.15, e-Fig. 11.13). Tumor necrosis is usually identified as single cell necrosis rather than the geographic necrosis that is characteristic of anaplastic carcinoma. In contrast to anaplastic carcinomas, there is little pleomorphism, and no bizarre, giant, or multinucleated cells are found.

FNA of these lesions yields extremely cellular smears that are devoid of colloid [43, 44, 45, 46]. The tumor is composed of small- to medium-sized epithelial cells seen individually and in small groups and solid clusters (Figs. 11.16, 11.17, 11.18, 11.19, e-Figs. 11.14 and 11.15). Occasionally, a necrotic background is present. The cytoplasm is pale and may contain fine vacuoles. Nuclei are round and monomorphic with fine, hyperchromatic chromatin and variable but often small nucleoli. Although demonstrating a “neoplastic” appearance, there is only mild nuclear atypia. The nuclei tend to be oriented around the periphery of the tumor cell clusters, and there may be basement membrane-like material, transgressing vessels, and endothelial wrapping of cell clusters [47]. In some cases, nuclear inclusions and grooves may be seen and indicate dedifferentiation of a papillary carcinoma.

The differential diagnosis includes medullary carcinoma of the thyroid and low-grade lymphoma. Sclerosis can mimic amyloid; however, Congo red stains are negative, and immunohistochemical stains for calcitonin, chromogranin, and CEA are negative. Markers of hematologic

differentiation are negative. In contrast, the tumors are positive for keratins, TTF-1, and Pax8 (Fig. 11.20), and staining for thyroglobulin, although often weak and sometimes focal, confirms the follicular cell differentiation of this neoplasm [48].

Molecular studies have identified a high incidence of ras mutations in these lesions [49], and up to 25% harbor mutations of the CTNNB1 gene, resulting in nuclear translocation of β-catenin and activation of a number of downstream targets of the WNT signaling pathway [50]. These mutations are not found in well-differentiated thyroid carcinomas and are more common in anaplastic carcinomas, suggesting that they play a role in progression of these lesions [51]. APC mutations, another cause of nuclear translocation of β-catenin, are not reported in thyroid carcinomas [51]. The loss of membranous staining for β-catenin can be seen by immunohistochemistry, and nuclear translocation is a marker of dedifferentiation. E-cadherin is also reduced or lost [52]. The loss of β-catenin and E-cadherin in these tumors may account for the dehiscence that is characteristic of poorly differentiated carcinoma.

Poorly differentiated carcinomas often express HBME-1 [53, 54, 55, 56], but the diagnosis of malignancy that is supported by this stain is not usually controversial in this entity. The expression of CK7, CK18, and CK19 is reduced in poorly differentiated carcinomas [57].

The molecular basis for dedifferentiation is postulated to be due to multiple genetic events. These tumors may have mutations of BRAF or RAS that are found in differentiated thyroid cancers [51, 58]. They have been reported to exhibit a low prevalence of expression of RET rearrangements [51, 54], a finding that has been used as evidence that RET/PTC rearrangements predict indolent behavior; however, it is known that the promoters of the upstream genes involved in the translocations determine variable levels of expression and dedifferentiation results in down-regulation of expression with loss of RET/PTC gene expression by RT-PCR as well as protein expression by immunohistochemistry. In addition to the mutations and rearrangements that occur in differentiated thyroid cancer, they often also harbor additional events, including mutations in PIK3CA [52, 59, 60], CTNNB1 [61], PTEN [61], the CDKI family of cell cycle regulators and p53 [61], AKT [58], TERT [62], and an STRN-ALK rearrangement [63].

Medullary thyroid carcinoma is a tumor of parafollicular C cells of the thyroid that synthesize and secrete calcitonin. C cells were initially described by Karl Hürthle [69] whose name has mistakenly been associated with oncocytes. The function of C cells only became apparent with the discovery of the hormone calcitonin and the description of medullary thyroid carcinoma [70].

Medullary carcinoma comprises approximately 5% of all thyroid carcinomas [20] but is responsible for 13.4% of the total deaths [71]. This lesion is usually readily recognized because of its unusual cytologic and histologic features, but it is also frequently misdiagnosed [1, 72]. Sometimes special investigation is required to distinguish it from follicular lesions or other tumors, including lymphomas and/or anaplastic carcinomas. The importance of distinguishing this tumor from follicular lesions is twofold. The first is for diagnostic classification and management considerations in the individual patient. These tumors do not preferentially take up iodine, and therapy with radioactive iodine is not indicated; in contrast, expression of somatostatin receptors by some of these tumors [73] makes somatostatinlabeled imaging a feasible diagnostic tool to localize the primary lesion and to identify metastatic deposits [74, 75], and somatostatin analogues as well as somatostatin-based peptide receptor radiotherapy (PRRT) may have applications in the management of disseminated disease [76, 77, 78]. The other aspect of management involves the implications for both the patient and members of his/her family, since many of these tumors are hereditary [79, 80].

The inherited forms of medullary carcinoma are of two major types [80]: multiple endocrine neoplasia (MEN) type IIA in which MTC may be associated with pheochromocytomas or may occur alone (also known as familial medullary thyroid carcinoma, FMTC) and MEN IIB in which the thyroid and adrenal proliferative disorders are associated with mucosal ganglioneuromas and a Marfanoid habitus. Other variants of MEN2A include associations with cutaneous lichen amyloidosis (CLA) and with Hirschsprung’s disease [80]. The inheritance of these syndromes was mapped to the pericentromeric region of chromosome 10 by linkage analysis [81, 82, 83]. Subsequently, mutations in the RET proto-oncogene in
exon 10 (codons 609, 611, 618, and 620), exon 11 (codons 630 and 634), exons 8, 13, 14, 15, and 16 have been identified in patients with MEN IIA and at codon 918 in exon 16 or rarely at codon A883F in exon 15 in MEN IIB [80, 84, 85]; these mutations have provided a more accurate marker of germ-line mutation and predisposition to this disease [71, 86, 87]. Current recommendations suggest that family members of known kindreds have genetic screening early in life and affected members should undergo prophylactic thyroidectomy in childhood [71, 80]. The ages recommended vary depending on the mutation and family history; the goal is to prevent the earliest possible onset of medullary thyroid carcinoma in these familial forms of the disease, since metastatic tumor has been found in patients as young as 6 years of age. Children affected with MEN IIB undergo surgery even earlier than those with MEN IIA and FMTC [88, 89].

Familial forms of medullary thyroid carcinoma usually result in multicentric disease as well as multicentric C-cell hyperplasia [90, 91]. C cells are usually limited to the central portion of the junction between the upper and middle thirds of the lateral lobes where they are generally distributed singly rather than in clusters. Increased numbers of C cells (greater than 7 cells per cluster), complete follicles surrounded by C cells, and distribution of cells beyond this geographic location are indicative of C-cell hyperplasia (Fig. 11.23, e-Figs. 11.17 and 11.18). The assessment of C-cell hyperplasia should only be performed on the lobe opposite a large tumor since infiltrating tumor can mimic this entity. The presence of C-cell hyperplasia
usually indicates an inherited disorder rather than a sporadic lesion; however, C-cell hyperplasia can also be associated with chronic hypercalcemia, thyroid follicular nodular disease, and thyroiditis [92, 93, 94, 95]. Patients with PTEN hamartoma tumor syndrome (PHTS), characterized by a predominance of nonthyroidal tumors, have a predisposition to develop multiple adenomatous follicular nodules but have also been reported to have a diffuse form of C-cell hyperplasia [96], but this has not been associated with medullary carcinoma. Drugs, specifically antidiabetic incretins (glucagon-like peptide-1 analogs including exenatide, liraglutide, and taspoglutide), cause C-cell hyperplasia and medullary thyroid carcinoma in rodents [97, 98] where GLP-1 receptors are expressed by C cells; although human medullary thyroid carcinomas may express GIP and GLP-1, normal human C cells do not express their receptors[99]; nevertheless, it has been suggested that patients be monitored with calcitonin measurements during GLP-1 analog administration [99].