Andreas Vesalius (1514 -1564) first formally described the thyroid in his anatomy manuscript, De humani corporis Fabrica Libri septem. Since then, we have come a long way in understanding the anatomy, physiology, and workings of this endocrine gland. The thyroid gland is a midline structure in the neck. Derived from the primitive pharynx and neural crest cells, embryologically, the tissue mass divides, forming the isthmus and the two lateral lobes of the thyroid. Bu the age of 2, the gland is already half the adult size. Developmental anomalies could result in aberrant masses of ectopic thyroid tissue, cysts, and sinuses. Apart from that, the thyroid gland is no stranger to neoplastic lesions. Follicular lesions of the thyroid include many subvariants from the benign follicular adenoma right up to malignant follicular carcinomas, follicular variants of other malignant thyroid lesions.
Follicular adenomas are one subset of benign neoplasms that can occur in the thyroid gland or ectopic thyroid tissue. They typically present as a solitary thyroid nodule or in association with nodular hyperplasia or thyroiditis. Thyroid nodules are palpable in 4 to 7 % of individuals, but the prevalence of nodules detected incidentally by ultrasound shows a higher prevalence of 19 to 67 percent. The majority of thyroid nodules are asymptomatic. Similar to worldwide incidence, 60 to 70% of the US population present with thyroid nodules. Most of these are benign, although 5% exhibit malignant features. Although the distinguishing line between the adenoma itself and its malignant counterpart is tricky, this is for all practical purposes a benign neoplasm.
Follicular adenomas usually present as a solitary thyroid nodule. They are benign neoplasms in nearly 2 to 4.3 % of the population. A study done on 300 consecutive autopsies revealed a 3% incidence of follicular adenomas compared to a 2.7% incidence for follicular carcinoma; small nodules, measuring less than 15 mm in diameter, have a prevalence of 5 to 10% (based on autopsy studies). The data vary between different geographic areas, Finland having the highest reported incidence of occult microcarcinomas . Thyroid adenomas are typically more common in females. Data in the US, more or less, reflect the same incidence for development.
During the past 30 years, the incidence of thyroid cancer has raised from 4.3 cases per 100,000 in 1980 to 12.9 cases per 100,000 in 2008 , and there is a strong debate in whether the increase in incidence should be considered an artifact of improved detection. The availability of ultrasound imaging, the technological improvement in medical equipment, the increased awareness in the general practice and among patients, the screening campaigns in higher-risk population are all factors that contributed to an increase in incidence rates.
The incidence rates for thyroid nodules are also increasing in the pediatric population; increased detection is surely a great component but can only explain a part of the cases . Birth cohort analyses showed the correlation with environmental exposures (such as diagnostic radiography, cosmic radiation, and other exposures). Studies on individuals exposed to I-131 radiation after Chernobyl's nuclear accident revealed an excess odds ratio per Grey of 2.22 equal for both sexes, with the odds ratio increasing with higher doses. Children aged less than two years were found to have the highest risks. Population studies indicate that when a specific etiology (i.e. radiation) is involved, the incidence differs from the normal population. The peak in incidence seen in the last 30 years cannot be fully explained by the increased detection, suggesting that there might be a true increase, but the specific causing agent has not been identified yet.
Iodine deficiency implicated in many studies for follicular lesions. Endemic goiter is a predisposing factor for follicular carcinoma with a higher rate of follicular carcinomas seen in low iodine areas. Studies show that 4 to 13% of follicular adenomas exhibit rearrangement of the PAX8-PPAR. PAX8 helps follicular cell differentiation by encoding a nuclear protein product necessary for transcription of thyroid-specific factors. Martelli ML determined mutations in PAX8 that led to dysfunction and loss of optimal follicular growth inhibition. A mutation causing inactivation of the PTEN tumor suppressor gene causes PTHS. Likewise, mutations in BRAF, NRAS, RET, and KRAS can explain aberrant neoplasms, including the thyroid parenchyma.
Functioning follicular adenomas arise as a result of a monoclonal increase of thyroid follicular cells with a predominance of activating mutations in the gene for the TSH receptor and less frequently in the adenylate cyclase-stimulating G alpha protein gene that results in increased thyroid hormone secretion independent of TSH. A monoclonal follicular cell expansion with activating mutations on the TSH receptor or in the adenylate cyclase-G protein mostly explains functioning follicular adenomas. 20% of nonfunctioning follicular adenomas that have oncogene mutations can later progress to follicular carcinoma.
Follicular adenoma is grossly described as a solitary, encapsulated nodule; the size can be extremely variable, ranging from a few millimeters to 10-15 cm. The color vary from tan to light brown with solid and fleshy appearance. It can resemble multinodular goiter due to secondary changes in hemorrhage and cystic degeneration.
Histological examination of the nodule reveals a follicular architecture present in the entire or nearly entire lesion. The nodule can be described as either microfollicular or macrofollicular growth pattern, and the thyrocytes have a normal cytological appearance. Follicular adenoma is usually a solitary encapsulated lesion and does not have any features suggestive of vascular or/and invasion of the adjoining capsule or to the neighboring thyroid tissue. Degenerative changes within the nodule may be seen in cases of prior FNA (fine needle aspiration performed for cytological diagnosis), which could result in degenerative changes. The only way to determine whether a follicular neoplasm is a carcinoma is after histopathological examination.
The two key characteristics that make the follicular lesion malignant is the evidence of capsular invasion and angioinvasion. There is much debate about the extent to which tumor cells need to invade the capsule to determine it's malignant potential. However, in a follicular adenoma, this is not the case. If the neoplasm only enters into the capsule without passing through the entirety of the capsule, then it is still an adenoma. When tumor cells invade a large vessel having an endothelial lining and attached to the wall, that is taken as a reliable sign of malignancy. Many studies suggest a minimum of 10 tissue blocks with tumor capsule and thyroid tissue; this method has a better success rate in ruling out follicular carcinoma before definitely labeling the neoplasm as a follicular adenoma.
Most patients with a follicular adenoma present with solitary thyroid nodule in an otherwise normal thyroid gland, however, it may occur in association with thyroiditis or nodular hyperplasia. Although most solitary nodules are asymptomatic and euthyroid, there is a <1% chance of hyperthyroidism. So while taking history and performing a physical of a patient with neck swelling, it is imperative to keep in mind the features of hyperthyroidism or hypothyroidism that could accompany the presentation. Thyroid medication history could help determine the etiology of many of these nodules.
Family history of autoimmune disease (Hashimoto disease, Grave disease) thyroid carcinoma or familial syndromes ( like Gardners) all are valid points to consider. Commonly patients present with and visually describe a slowly growing mass in the neck, pressure sensation over the neck. Pain seldom accompanies a thyroid nodule unless spontaneous hemorrhage or cystic degeneration has occurred within the nodule. Some patients may even complain of the cosmetic appearance of the mass. Pressure symptoms could cause dyspnea due to tracheal compression, increased coughing, voice hoarseness, and choking spells due to recurrent laryngeal nerve irritation and dysphagia secondary to esophagus compression.
On physical examination, a diligent head to toe examination is imperative to assess if any signs are suggestive of a clinically non-euthyroid state. Patients with a follicular adenoma present with a thyroid nodule that's palpable on examination or identified on an imaging study. Nodules less than 1 cm are usually challenging to palpate unless located anteriorly on the gland. Careful consideration should be taken to assess the size, location, shape, borders, and consistency of the nodule. There may be more than one nodule that is palpated. However, even after neck palpation, nearly half of these nodules go undetected and can only be picked up on ultrasonography.
Thyroid nodules are evaluated according to the American Thyroid Association Guidelines. The four main parameters to assess in a thyroid nodule evaluation are detailed patient history, physical examination, baseline serum TSH assay followed by an ultrasound. The ultrasound examination provides important informations regarding size and feature of the nodule so it determines the following steps of evaluation. In general, follicular adenomas are benign but could have characteristics akin to follicular carcinoma; also an important differential diagnosis is with the non-invasive follicular thyroid neoplasm with papillary-like nuclear features or NIFT. 5% of microfollicular adenomas, when subjected to histopathological examination, are reported as follicular cancers. Follicular carcinoma has a worse prognosis and hence should be carefully ruled out after thorough history, examination and investigations. Nodules with a size >1 cm should be completely evaluated since they have the potential to be, or evolve to, cancer. Occasionally nodules <1 cm require evaluation is symptomatic or associated with lymphadenopathy. Preliminary laboratory assessment, including a baseline thyroid function test, helps determine the status of the gland (euthyroid, or hyper/hypothyroidism). When indicated, aspiration by a fine-needle (FNA) to obtain a cytological sample can aid in narrowing down to a diagnosis.
Sonographic features of both follicular adenoma and follicular carcinoma are similar and careful examination can help distinguish the two entities. An extensive lesion size, hypoechogenicity, mixed or solid echotexture, absence of sonographic halo, micro/rim calcifications favor the malignant counterpart. The lack of internal flow, or a predominantly peripheral flow are associated with a reduced probability of thyroid follicular malignancy. A neck US should be performed during the thyroid evaluation. It is a time-efficient manner to evaluate all patients with a thyroid nodule, nodular goiter, or in cases of a thyroid nodule incidentally detected in other ways. The presence of a solid hypoechoic component in nodules with irregular margins, microcalcifications, taller than wide, rim calcifications are strongly suspicious and should be evaluated with FNA if the size is at least 1 cm. Nodules that are isoechoic or hyperechoic solid or partially cystic without the suspicious feature of irregular margins, microcalcifications, taller than wide, rim calcifications, should be evaluated with FNA only if bigger than 1,5 cm. Purely cystic nodules are considered not at risk and do not need evaluation with cytology.
In thyroid nodules >1 cm (in any diameter) it is recommended to measure serum thyrotropin (TSH) during the initial evaluation. If the TSH is low a I thyroid scan should be performed, if TSH is normal or elevated the radionuclide scan is not recommended. Radionuclide scanning can be evaluated together with US findings, FNA reports and clinical information. Simple follicular adenomas show less uptake on radioiodine scintigraphy comparing with functioning follicular adenomas, which increase absorption and concentrate radioiodine within the nodule; the internal control is the neighboring tissue of the gland showing a suppressed uptake.
Serum Tg levels should not be measured in the initial workup of a thyroid nodule because has a low specificity rate in the general evaluation but should be monitored in selected cases (i.e. after total thyroidectomy). Laboratory screening for calcitonin is neither recommended nor inappropriate: serum calcitonin can be evaluated for screening purposes because it may detect incidentally C-cell hyperplasia or medullary thyroid cancer at an earlier stage, improving overall survival.
CT scan and MRI have a limited role in the initial evaluation f solitary thyroid nodule. Indications for these imaging techniques include suspected tracheal involvement, either by invasion or compression, extension into the mediastinum, or recurrent disease.
FNA is performed to provide a cytological examination of the nodule, and it remains the mainstay for assessing these lesions, although it may not provide a diagnosis in all cases. The success rate of FNA is improved when the procedure is done under ultrasound guidance. The cytopathological findings are reported using one of the three major international nomenclatures: the British Thyroid Association and Royal College of Pathologists (Thy), the Italian Consensus (TIR) and the Bethesda System for Reporting Thyroid Cytopathology. Thyroid nodule fine-needle aspiration (FNA) washout may be examined for calcitonin in the preoperative evaluation in patients with elevated serum calcitonin (20–100 pg/mL). In patients with follicular adenoma the cytological sample has abundant follicular epithelial cells organized in sheets with crowding and overlapping of cells, microfollicle formation with scant or absent colloid. Some patients have follicular cells with abnormal architecture with atypia that is more significant than usually seen with benign lesions but not sufficient enough to call it a neoplasm. According to the Bethesda classification system, these patients are characterized as having "atypia of undetermined significance" or "follicular lesion of undetermined significance". Molecular assessment of indeterminate cytology can be helpful. A final diagnosis of follicular adenoma is made only after ruling out capsular and vessel invasion by standard nodulectomy or thyroidectomy with subsequent histological examination. Frozen section should not be requested in clinically benign nodules but is a common practice in cases of suspect papillary thyroid carcinoma hence its evaluation intraoperatively can guide in performing lymphadenectomy.
Main Advantages of Surgical Therapy
Follicular adenomas are benign neoplasms. They are slow-growing and can progress to a size that may cause compressive symptoms such as dyspnea, dysphagia, hoarseness. After due evaluation of symptoms, the patient should ideally be reassured that these do not signify a malignant process but rather that the mass is causing compression on another structure.
20% of nonfunctioning follicular adenomas have oncogene mutations that may progress to develop into a follicular carcinoma. N-RAS and K-RAS have been implicated in this transformation. If a follicular neoplasm is proven to be a carcinoma, then prompt oncological management is necessary. Patients with biopsy-confirmed follicular adenoma ideally do not need new therapy. Thyroxine supplementation is not recommended to suppress the gland unless hypothyroidism occurs after gland lobectomy. The risk of malignancy is more in the Chernobyl post-radiation studies.
Pressure symptoms are not usually complications but are a known effect once the nodule reaches a size where it can compress on adjacent structures.
When surgical intervention is done due to compressive symptoms, the following points should be taken care of in the postoperative period:
The management of follicular adenoma is a multidisciplinary approach, that's why liaison between the following departments is essential for a good outcome:
Thyroid nodules remain a challenge when it comes to diagnosis, evaluation, and clinical management. Usually, these neck swellings develop gradually as a solitary thyroid nodule, more often at the edge of the thyroid gland. These involve the isthmus or may be present over the lobes. Neck examination helps determine the location of these nodules that often are palpated or visualized over the neck. Follicular adenomas are usually the most common neoplasms that present as a solitary thyroid nodule. Adequate history and factors like age, gender, diet history( especially that of inadequate iodine supplementation), medical history, comorbidities, and radiation exposure must be considered.
While often these cases usually present to the endocrine or general surgeon, to ensure best patient outcomes, an interdisciplinary team approach must be performed. The careful gaze of a pathologist helps determine whether the neoplasm is benign or malignant. The expertise of a radiologist helps identify sonographic features of the nodule/s or if any suspicious features coexist. This enables the primary care provider to understand the disease process better and formulate a definitive plan for management.
Before surgery, routine clearances should be obtained depending on the comorbidities of the patient. Collaboration, teamwork, and careful decision making are paramount for a good outcome. Nurses assess the patient regularly and could identify surgical complications when they occur. Complications like bleeding, surgical site infection, thyroid crises, hypocalcemia may occur postoperatively. Scarring causing the patient distress, be it a hypertrophic scar or keloid formation, could be referred to as a plastic surgeon for further cosmetic management.
In an ideal scenario, the patient should be followed up until the biopsy returns with a report confirming a benign follicular adenoma. If a malignancy is determined, aggressive management is required. The oncologist, the oncologic surgeon, must be involved at this stage to better the prognosis of the patient. Integrated interprofessional care provided to the patient, combined with an evidence-based approach, helps achieve the best results.
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