Neoplasms of Follicular Cell Origin

Tumors of the thyroid gland most frequently present as asymptomatic nodules. With more widespread use of ultrasound, MRI, CT, and 18F-fluorodeoxyglucose (FDG) PET scanning, small, subclinical thyroid nodules are increasingly being detected. Fortunately, the vast majority of thyroid nodules are benign, but 5% to 10% of nodules prove to be primary thyroid cancer.

Initial evaluation of any thyroid nodule begins with a complete history and physical examination that focuses on the thyroid gland and surrounding cervical lymph nodes. Clinical features such as a history of childhood radiation, a family history of thyroid cancer, a genetic syndrome that could include thyroid cancer (e.g., Cowden syndrome, familial adenomatosis polyposis, Carney complex, multiple endocrine neoplasia syndrome, or Werner syndrome), rapid nodule growth, palpable cervical lymphadenopathy, or hoarseness of voice due to vocal cord paralysis all increase the likelihood of thyroid malignancy.

Following a complete history and physical examination, the next step in evaluation of a thyroid nodule is measurement of the serum thyroid-stimulating hormone (TSH) level. Even though thyroid function tests, including TSH, are almost always normal in the setting of primary thyroid cancers, a suppressed TSH would raise the possibility of an autonomously functioning nodule. Such nodules can be identified by radionuclide scanning and carry an extremely low risk of malignancy; therefore they do not require further workup, such as fine-needle aspiration biopsy. Depending on the degree of hyperthyroidism, observation or therapy may be indicated to treat the autonomous hyperfunctioning thyroid nodule. While not a clinically useful discriminator, several studies have shown that the risk of thyroid malignancy is positively correlated with the degree of TSH elevation, even if within the normal reference range; that is, the higher the TSH at presentation, the greater the chance that a nodule harbors malignancy.

Serum thyroglobulin values are not helpful in the evaluation of thyroid nodules, as benign nodules can also produce thyroglobulin values significantly above the normal range. There continues to be controversy about whether serum calcitonin values should be measured in all patients with clinically significant thyroid nodules. Based on the available evidence, the ATA guidelines do not have a specific recommendation for or against measurement of serum calcitonin in the workup of thyroid nodules. Since many patients with benign disease have mildly elevated calcitonin values, the concern is that these false-positive calcitonin values would lead to more surgeries than necessary. Conversely, several studies have shown that routine use of calcitonin in the evaluation of thyroid nodules does increase the sensitivity for detecting medullary thyroid cancer. Therefore further studies are needed to address this issue.

The ATA 2015 guidelines provide a rational and risk-adapted approach to the evaluation and management of thyroid nodules. After a complete history and physical, and confirmation of a nonsuppressed TSH, the next step in evaluation of a thyroid nodule is neck ultrasonography. Neck ultrasounds should routinely provide a description of the sonographic features of the nodule(s) to enable malignancy risk stratification (as discussed below) and evaluate cervical lymph nodes in the central and lateral neck ( Fig. 12.6 ).

Risk-based algorithm for workup of a thyroid nodule. (2015 American Thyroid Association guidelines.)

If very suspicious cervical lymph nodes are seen, then fine-needle aspiration of those lymph nodes can establish a diagnosis and lead to appropriate additional workup and treatment. If there are no suspicious lymph nodes identified, then the management algorithm for thyroid nodules relies on (1) sonographic features that define the risk of malignancy within the nodule and (2) the size of the nodule. This differs from previous approaches, where the size of the nodule was the primary factor influencing the decision to perform fine-needle aspiration biopsy ( Table 12.1 ).

As shown in Table 12.1 , nodules with sonographic patterns showing high suspicion features carry a risk of malignancy in over 70% to 90% of patients, while nodules with intermediate suspicious features carry a risk of malignancy of 10% to 20%, low suspicion features have a risk of 5% to 10%, and very low suspicion characteristics have a risk of malignancy in less than 3% of patients. Once these nodules have been risk stratified based on sonographic pattern, then the size of the nodule is used to recommend cutoff points for routine use of fine-needle aspiration biopsy ( Fig. 12.6 ). When multiple nodules are present, fine-needle aspiration should be preferentially directed toward the nodule with the highest risk of malignancy based on sonographic pattern and nodule size. In previous iterations of the ATA guidelines, essentially every nodule greater than 5 mm was considered for biopsy. However, in the 2015 edition of the ATA guidelines, nodules with low or very low suspicion are candidates for biopsy only if they are larger than 1.5 to 2 cm. Moreover, it is recommended that nodules with an intermediate- or high-suspicion pattern are considered for biopsy only if they are greater than 1 cm in size. This risk-stratified approach results in a significant number of sonographically detected thyroid nodules where routine use of fine-needle aspiration biopsy is not recommended. Using the same risk-stratified approach, thyroid nodules with a high suspicion pattern that are less than 1 cm can be followed with observation with repeat neck ultrasound in 6 to 12 months. Nodules with low to intermediate suspicion can be followed with repeat neck ultrasound in 12 to 24 months. Nodules greater than 2 cm with very low suspicion should have follow-up ultrasound no sooner than 24 months. Finally, nodules less than 1 cm with very-low-suspicion ultrasound pattern do not require routine sonographic follow-up.

These recommendations allow for observation rather than immediate fine-needle aspiration and surgery for highly suspicious subcentimeter nodules. This approach indirectly endorses an active surveillance management of such potentially malignant low-risk microcarcinomas. As noted in the ATA 2015 guidelines, while thyroid surgery is usually recommended for primary papillary thyroid cancer, active surveillance is now a reasonable alternative to immediate surgery, based largely on the experience published by Drs. Ito and Miyauchi from Kuma Clinic in Kobe Japan. Since cytologic confirmation of disease is not required for active surveillance, both the observation of biopsy-proven papillary thyroid cancer and observation of subcentimeter nodules that are highly suspicious for papillary thyroid cancer are appropriate within an active surveillance paradigm. Therefore an active surveillance option can be offered to patients with subcentimeter thyroid nodules, which are suspicious for or proven to be papillary thyroid carcinoma. However, this approach is recommended in a systematic active surveillance program with well-defined criteria and follow-up strategies. The usual observational approach includes a detailed neck ultrasound every 6 months for the first 2 years. The change in tumor size and volume during the first 2 years is used to establish the doubling time of the tumor. This doubling time is then used to plan the frequency of follow-up ultrasounds and the need for intervention. It is important to recognize that not every subcentimeter suspicious nodule is appropriate for observation. If the suspicious nodule has documented rapid growth, if there is evidence of metastatic disease outside the thyroid, if there is evidence of extrathyroidal extension, or if the tumor is sitting in a location where even minor extrathyroidal extension would be associated with neurovascular or tracheal compromise, then cytologic confirmation followed by surgery is usually recommended.

When fine-needle aspiration is indicated, the Bethesda classification system for cytology is very valuable in helping to risk stratify the various cytologic patterns into a risk of malignancy ( Box 12.1 ). If the cytology is nondiagnostic, a repeat fine-needle aspiration is usually warranted. For benign cytology, in the absence of other worrisome clinical features, a follow-up ultrasound done at an interval consistent with the overall suspicion of the nodule is appropriate. When appropriate nodules are biopsied, a malignant cytology (i.e., Bethesda VI) almost always leads to surgery. Likewise, cytologically suspicious nodules (i.e., Bethesda V lesions) usually require surgical resection for definitive diagnosis and therapy.

Despite many advances in the molecular biology of thyroid nodules, the cytologic classification of AUS/FLUS (atypia of undetermined significance or follicular lesion of undetermined significance) and FN/FSN (follicular neoplasm or suspicious for follicular neoplasm), Bethesda category III and IV, remain problematic and carry a risk of malignancy that approximates 5% to 15% and 15% to 30%, respectively. Multiple molecular markers have been developed for clinical use to further delineate the risk of malignancy of an indeterminate lesion. Therefore, depending on the clinical risk factors, sonographic features, availability of molecular testing, and patient preference, these molecular profiles may be useful in clinical decision-making.

Following the recommendations of the ATA 2015 guidelines, the interval for repeat ultrasonography following establishment of benign cytology is based on the sonographic pattern of the nodule. Even after a benign fine-needle aspiration, nodules that have a high-suspicion pattern on the ultrasound should probably have a repeat neck ultrasound and fine-needle aspiration within 12 months. However, nodules with low to intermediate suspicion can have a repeat neck ultrasound at 12 to 24 months, reserving a repeat biopsy for those nodules that exhibit evidence of growth of at least 2 to 3 mm, or more than 50% change in volume, or the development of new suspicious sonographic features. Overall, appropriate risk stratification for the management and follow up of thyroid nodules requires accurate initial characterization of the sonographic features of the nodule, proper selection of nodules to undergo fine-needle aspiration versus observation, and standardized communication of cytology results using Bethesda classification.

With regards to medical therapy for benign nodules, routine TSH suppressive therapy is not recommended. Although TSH suppression may lead to a modest deceleration of nodule growth, the potential adverse effects of long-term TSH suppression are thought to outweigh this minor treatment benefit. Iodine status should be assessed, and iodine deficiency should be treated with 150 µg of supplemental iodine daily.

Medullary Thyroid Cancer

Patients with MTC may present with a palpable mass in the thyroid or with cervical lymphadenopathy. In some patients, thyroid workup is undertaken because of the family history of medullary carcinoma, and in that setting, a clinically occult primary tumor may be identified. FNAC is usually sufficient to establish tissue diagnosis, but immunocytochemistry to determine the presence of calcitonin or serum calcitonin level may be helpful if the diagnosis is unclear. In addition to serum calcitonin, serum CEA is also a necessary part of the workup. All patients with a diagnosis of MTC should be counseled and tested for the presence of RET mutation, because absence of a family history is not sufficient to rule out inherited disease. Up to 7% of patients with apparently sporadic MTC harbor a germline mutation. This finding is especially true in persons with MEN 2B, for whom de novo germline RET mutation is seen in 50% of cases. Germline mutations are seen more commonly in younger patients or in those with multifocal disease, but they also may occur in older patients or in patients who present with a single thyroid nodule. Testing of all first-degree relative family members is recommended if the patient has a germline RET mutation. Additional workup includes contrast-enhanced CT scan of the neck and mediastinum to assess the presence and extent of regional lymph node metastasis to facilitate surgical planning. A whole-body FDG PET scan may be used to rule out distant metastases.

Neoplasms of Follicular Cell Origin

Benign adenomas confined to one lobe of the gland without any abnormality in the contralateral lobe are cured by an ipsilateral lobectomy. A total thyroidectomy is indicated for bilateral involvement. Patients with retrosternal extension require appropriate surgical intervention with a curative intent.

Management of patients with carcinomas of follicular cell origin is dictated by risk group stratification based on prognostic factors related to patient and tumor characteristics. The prognostic importance of age (≤55 versus >55 years), the size of the tumor (≤4 versus >4 cm), the extent of the tumor (i.e., the presence or absence of gross extrathyroid extension), the histologic differentiation (well versus poorly differentiated), and distant metastasis (present or absent) have been reported in several classification systems ( Table 12.3 ). Based on these prognostic factors, risk groups can be identified to facilitate selection of therapy ( Fig. 12.25 ). The intermediate-risk group consists of young patients with high-risk tumors or older patients with low-risk tumors.

Risk group categories. Dist. Mets., Distant metastases.

All surgical procedures for the treatment of thyroid carcinoma or for tumors suspected to be cancers should be extracapsular operations leaving no residual thyroid tissue in the surgical bed. Procedures commonly described as a “subtotal” and “near-total” thyroidectomy are incomplete operations for malignant disease and are discouraged. In performing a true extracapsular thyroidectomy, particular attention should be paid to the pyramidal lobe, the upper pole, and the region of the Berry’s ligament, where no thyroid tissue should be left behind. Following a “true extracapsular” total thyroidectomy, patients should not have any measurable serum Thyroglobulin (usually <1), thus avoiding the need for RAI ablation for “potential residual thyroid tissue (thyroid remnant).”

Low-risk patients with a unifocal, intrathyroidal tumor and a sonographically normal opposite lobe need an ipsilateral extracapsular lobectomy (including patients with tumors staged T1 and T2). Inasmuch as the primary tumor is intrathyroidal, the size difference between 1 cm and 4 cm has little impact on local control, regional lymph node metastasis, distant metastasis, or survival. An ipsilateral lobectomy is an adequate operation for definitive treatment in this setting. A total thyroidectomy should be considered for patients with bilateral nodularity (either clinically or sonographically identified thyroid abnormalities), regardless of the size of the primary cancer. Other indications for considering a total thyroidectomy in low-risk patients include a high-risk ipsilateral tumor with gross extrathyroidal extension, a history of radiation exposure, a strong family history of thyroid cancer, and extensive regional nodal metastases.

For high-risk patients, an extracapsular total thyroidectomy is the recommended surgical procedure. Minor extrathyroid extension (ETE) is no longer considered to upstage a tumor to T3. For a tumor to be staged T3, it has to be larger than 4 cm (T3a) or may have gross extrathyroid extension involving strap muscles (T3b). This degree of ETE is easily encompassed in a properly done total thyroidectomy with resection of the strap muscles, easily achieving an R0 resection. On the other hand, major or gross ETE to the posterior aspect of the thyroid gland is staged T4a with involvement of either the trachea, larynx, esophagus, or recurrent laryngeal nerve. These extensive tumors require adequate preoperative imaging for detailed assessment of the extent of the tumor to facilitate surgical treatment planning for complete resection. Preoperative CT scan with contrast is quite helpful in evaluating the extent of disease. An MRI may be complementary to give added information in a three-dimensional manner. The aim of surgical resection should be to achieve gross total clearance of all demonstrable disease (R0 resection). However, a primary total laryngectomy is required only rarely and is performed in highly selected patients based on histology and the probability of lack of iodine avidity of the cancer.

Patients in the intermediate-risk group require individualized treatment selection. Older patients with a low-risk, unifocal intrathyroidal tumor are equally well treated with a lobectomy. On the other hand, younger patients with high-risk tumors may require not only a total thyroidectomy but also more extensive operations based on the extent of their disease. Decisions about the extent of thyroidectomy are best made based on initial extent of disease, prognostic factors, risk group stratification, and anticipated need of RAI.

Completion total thyroidectomy is required in some patients who have undergone inadequate initial surgery, such as those who had an open biopsy or less than a lobectomy when a total thyroidectomy would have been indicated as the initial surgical procedure. Other indications for completion of a total thyroidectomy are patients who have undergone a lobectomy and (1) have indications for postoperative RAI, (2) have gross residual tumor that is resectable, or (3) have contralateral gross nodular disease that is suspicious for multifocal thyroid carcinoma.

Recurrent thyroid carcinoma poses specific challenges regarding preservation of the larynx and its function, the parathyroid glands, and the integrity of the esophagus and adjacent neurovascular structures. Historically, in the past the most common cause of mortality from carcinoma of the thyroid was uncontrolled local/regional disease leading to asphyxia, hemorrhage, and inanition. However, in the past three decades that scenario has changed due to appropriate selection of cases and aggressive initial surgical procedures achieving an R0 resection. Thus control of disease in the central compartment is of paramount importance because it improves longevity in many patients and quality of life in nearly all. The issues to be considered in resection include (1) the goal of surgical intervention (i.e., curative treatment versus symptomatic palliation), (2) the feasibility of (R0) gross total resection, (3) the availability and efficacy of alternate means of treatment, and (4) the sequelae of surgery.

Anaplastic thyroid carcinoma poses unique challenges for the surgeon. The role of the surgeon is generally to establish tissue diagnosis and management of the airway. In rare circumstances, anaplastic carcinoma may be surgically resectable, as in the case of anaplastic carcinoma developing in a preexisting nodular goiter and confined to the goiter or as a small component of a poorly differentiated resectable carcinoma. An elective tracheostomy for prevention of airway distress in most patients with an anaplastic carcinoma requires careful consideration of the overall treatment plan and prognosis and is rarely indicated unless the patient is in impending airway distress. Multidisciplinary discussion is required to inform the patient and the family of the dismal prognosis and the anticipated course of events. If a decision is made to perform a tracheostomy, it should be done after endotracheal intubation under general anesthesia in the operating room with all available support. Technically, tracheostomy may be very difficult due to the presence of gross disease in front of the trachea, and also, the potential of the tumor which may grow through the tracheostomy. Therefore, if possible, placing the tracheostomy in the usual suprasternal location should be avoided. It is desirable to perform a cricothyrotomy and use a long tracheostomy tube to provide a safe airway into the distal trachea.

Regional lymph node dissection is recommended for clinically palpable or radiologically identified metastatic lymph nodes on imaging studies (ultrasound or CT scan) before thyroidectomy. Routine elective dissection for removal of possible micrometastases in regional lymph nodes is not recommended, because it offers no benefit to the patient and may increase morbidity. Elective dissection of central compartment lymph nodes may be considered in patients undergoing thyroidectomy for advanced primary tumors. The surgical procedure for excision of gross metastases should be a systematic compartmental dissection of regional lymph node groups. Excision of isolated lymph nodes (“berry-picking”) is not recommended. The presence of lymph node metastases in the central compartment (N1a) requires a systematic dissection of lymph nodes from the hyoid bone cephalad to the innominate artery caudad, and between the two carotid sheaths (levels VI and VII). Lateral neck metastases (N1b) require a systematic dissection of lymph nodes from levels IIA to V. Metastatic disease at level I and level IIB is rare, and dissection of these regions is recommended only if contiguous gross nodal metastases are present. Involvement of mediastinal lymph nodes below the innominate artery is infrequent, and surgical resection should be considered carefully in the context of the overall status of the disease and the patient. On the other hand, dissection of anterosuperior mediastinal lymph nodes (level VII) is feasible through the cervical approach and should be included in central compartment node dissection. However, massive metastases or metastatic disease inferior to the innominate artery may require a sternotomy.

Medullary Thyroid Carcinoma

Surgery is the only effective treatment for MTC, and thus comprehensive surgical resection of the primary tumor and involved lymph nodes is crucial to achieve local/regional control and improve survival. Lobectomy for a small unifocal intrathyroidal primary tumor in a patient with sporadic MTC is acceptable. On the other hand, a total thyroidectomy with central compartment lymph node dissection is the recommended surgical procedure for most patients whose diagnosis is confirmed preoperatively. Elective dissection of lymph node groups at risk in the lateral neck is controversial. However, if metastatic disease is identified clinically or radiologically, a comprehensive systematic compartmental neck dissection is required. The decision about elective lateral neck dissection is also made based on the size of the primary tumor, presence of central compartment nodal metastases, and preoperative calcitonin level. Surgery on the thyroid gland and regional lymph nodes is recommended even in the presence of distant metastases, because control of disease in the neck directly affects the quality of life of these patients. When the diagnosis of MTC is made as an incidental finding in a thyroidectomy specimen, the patient should undergo studies for calcitonin levels, ultrasound of the neck, and RET mutation. If findings of these studies are normal, further surgery is not necessary.

Genetic testing is indicated in family members of a patient who tests positive for RET mutation. The timing of genetic testing and the treatment of family members is based on the type of mutation present in the patient. The ATA has classified mutations into four risk groups. Level A mutations include 768, 790, 791, and 891. Persons with these mutations generally have indolent, late-onset MTC. Testing for RET mutation in children of these patients is recommended at 3 to 5 years of age, and prophylactic surgical treatment may be deferred until an older age (>5 years) as long as thyroid ultrasound and serum calcitonin levels are normal. The rationale to delay treatment is to minimize the risk of permanent hypoparathyroidism in infants. ATA level B mutations include 609, 611, 618, 620, and 630. Patients with these mutations have slightly earlier onset of MTC, and a prophylactic thyroidectomy is recommended for their children before age 5 years who have the RET mutation. ATA level C includes patients with mutation 634. Elective thyroidectomy is recommended in children harboring this mutation before the age of 5 years, because MTC develops earlier and clinically is more aggressive. Finally, the ATA level D risk group, which includes mutations 883 and 918, is associated with very early onset of medullary thyroid cancer that often is aggressive. Elective treatment of children who test positive for these mutations is recommended as soon as possible, even before age 1 year.

Minimally Invasive, Endoscopic/Video-Assisted, and Remote Access/Robotic Techniques of Thyroidectomy

Over the course of the past two decades, there has been increasing interest in employing minimally invasive or remote access techniques for thyroidectomy to avoid a scar in the neck resulting from a “conventional thyroidectomy.” The explicit purpose for using these approaches is to minimize the length of the scar in the neck or to avoid an incision in the neck altogether for thyroid lobectomy or total thyroidectomy. These techniques have gained popularity among some surgeons largely because of the availability of endoscopic and robotic instrumentation and are fueled by technologic developments and industry. In general, the concept of minimally invasive surgery is gaining popularity in all specialties, largely because of the reduction of surgical morbidity associated with conventional open operations and improved aesthetic appeal of smaller scars or no visible scars as a result of incisions in remote locations. This is particularly true for surgical procedures in the abdomen and in the thorax. When resections of neoplasms, particularly malignant neoplasms, are dealt with, however, strict criteria for using minimally invasive procedures must be adhered to so as not to compromise an oncologically complete and safe surgical procedure. Clearly, thyroid surgery is no exception to these general guidelines. With increasing concern on the part of patients undergoing thyroid surgery, with reference to the aesthetic result of the surgical scar in the neck, thyroid surgeons have become sensitive to these concerns of the patients and have used smaller and smaller incisions, placed in natural skin creases, where appropriate, for thyroidectomy.

Minimally Invasive Thyroidectomy

In general, most patients with relatively small lesions (nodules or tumors) are suitable for using smaller incisions (2–2.5 cm) for performing a thyroid lobectomy or total thyroidectomy. It is crucial, however, that the incision be placed in a natural skin crease, closer to the cricoid cartilage. Thus progressively smaller incisions have been used over the course of the past several years. Not all patients, however, are suitable for surgery through small incisions, and strict criteria must be met to perform a satisfactory, safe, and oncologically uncompromised surgical procedure. Therefore the following are indications for minimally invasive thyroidectomy (using a small incision):

• 1.
  

  The thyroid nodule is benign.

  
  
• 2.
  

  The cancer is intrathyroidal.

  
  
• 3.
  

  The nodule or tumor is small (<3 cm in diameter).

  
  
• 4.
  

  The thyroid gland is small (5–6 cm).

  
  
• 5.
  

  There is no need for regional lymph node dissection.

  
  
• 6.
  

  The patient does not have Hashimoto’s thyroiditis.

  
  
• 7.
  

  The patient is not obese.

  
  
• 8.
  

  There is no previous surgery in the neck or superior mediastinum.

If these criteria are met, then minimally invasive thyroidectomy can be safely performed, either with or without the need for endoscopic or video-assisted techniques. Most patients undergoing a minimally invasive thyroidectomy do not need a drainage tube from the surgical field and can have a simple primary closure of the incision. An example of such a small incision and eventual aesthetic outcome from a minimally invasive thyroidectomy without endoscopic or video assistance is shown in Fig. 12.31 .

A , Planned incision for minimally invasive thyroidectomy in a natural skin crease close to the cricoid cartilage. B , Healed scar 1 year after surgery.

Excision of the Thyroglossal Duct Cyst

A thyroglossal duct cyst is a developmental anomaly that may manifest clinically as a cystic mass. It generally presents at a young age, but the appearance of a thyroglossal duct cyst in adults is not uncommon. In an adult, it usually is preceded by an episode of upper respiratory tract infection. The thyroglossal duct cyst may arise anywhere along the thyroglossal tract, which extends from the foramen cecum (on the dorsum of the tongue at the junction of its posterior and middle third) to the isthmus of the thyroid gland. The thyroglossal tract is invaginated during development by the hyoid bone, and therefore it curves behind the hyoid bone along its course. This location has specific surgical significance, because if a segment of the patent tract is left behind the hyoid, local recurrence of the cyst will take place. Therefore a segment of the central third of the hyoid bone should be excised to totally resect the entire thyroglossal tract (referred to as a Sistrunk operation ). An example of a thyroglossal duct cyst extending into the preepiglottic space posterior to the hyoid bone is shown in Fig. 12.32 . The surgical field demonstrating extension into the preepiglottic space and the specimen after a Sistrunk operation are shown in Fig. 12.33 .

An axial view of a contrast-enhanced computed tomography scan showing extension of the thyroglossal duct cyst into the posthyoid preepiglottic space.

The surgical field showing extension into the preepiglottic space and the specimen.

The cyst usually presents in the midline, but occasionally it may have a paramedian location. Most thyroglossal cysts do not have connections with a patent tract. The patient whose CT scan is shown in Fig. 12.34 has a 5-cm mass in the infrahyoid region overlying the thyrohyoid membrane. This patient also had a multinodular thyroid gland for which a total thyroidectomy was deemed appropriate. Patients whose thyroid glands are clinically and radiologically normal do not need a thyroidectomy, even in the presence of a well-differentiated carcinoma that is confined to the cyst.

An axial view of a computed tomography scan at the level of the thyrohyoid membrane showing the bilobulated mass.

The operative procedure is performed under general endotracheal anesthesia. The patient is placed in supine position on the operating table with the neck extended. The incision is outlined in relation to the location of the palpable mass along an upper neck skin crease. The incision should be placed so it is adequate for excision of the cyst; it also should provide access to the hyoid bone.

The clinically palpable mass is shown in Fig. 12.35 . An incision is made over the mass at the level of the thyrohyoid membrane. It is deepened through the platysma, and the upper and lower skin flaps are elevated with an electrocautery. In the left side of the exposed field, the cyst is located beneath the deep cervical fascia. The soft tissues surrounding the thyroglossal cyst are dissected with extreme care to avoid rupture of the cyst ( Fig. 12.36 ).

Outline of the incision and the clinically palpable mass overlying the thyrohyoid membrane.

The soft tissues surrounding the cyst are carefully dissected.

Large cysts have a thin wall and are particularly vulnerable to rupture during mobilization. Division of the infrahyoid strap muscles facilitates exposure ( Fig. 12.37 ). The hyoid bone adjacent to the cyst is denuded of its musculature, which is detached with the electrocautery ( Fig. 12.38 ). The central third of the hyoid bone is divided with a bone cutter, remaining medial to the lesser cornua on each side ( Fig. 12.39 ). The thyroglossal tract usually runs in the midline on the posterior aspect of the hyoid bone, as seen in the preoperative CT scan. After the hyoid is divided on both sides, it is grasped with an Ellis clamp and gently retracted to give a pull to the underlying soft-tissue attachments of the cystic mass.

The infrahyoid strap muscles are divided.

The mylohyoid and hyoglossus muscles are detached from the central third of the hyoid bone.

The hyoid bone is divided on both sides.

At this point a meticulous search for the thyroglossal duct tract should be undertaken, and it should be followed cephalad as far as it can be traced ( Fig. 12.40 ). After separation of the deeper soft-tissue attachments in the lower part, the specimen is retracted caudad, and the thyroglossal tract is followed further cephalad in the musculature of the base of the tongue if it continues toward the foramen cecum.

The cyst is retracted caudad.

Fig. 12.41 shows the surgical field after removal of the thyroglossal cyst, demonstrating the thyrohyoid membrane and the central part of the preepiglottic space, which are exposed because of the removal of the central segment of the hyoid bone. The wound is now irrigated with Bacitracin solution. A small Penrose drain placed in the field is brought out to the edge of the incision. Alternatively, a small, closed suction drain may be used. The incision is then closed in two layers using 3-0 chromic catgut interrupted sutures for platysma and 5-0 nylon for skin. The surgical specimen shows the intact cyst excised with the central third of the hyoid bone and the remnant of the thyroglossal tract ( Fig. 12.42 ).

The surgical field after excision of the cyst.

The surgical specimen consists of the thyroglossal cyst, the central third of the hyoid bone, and the entire thyroid gland. A total thyroidectomy usually is not indicated but was performed in this patient because of the presence of a multinodular goiter.

Postoperative care is minimal. The Penrose drain is removed when serosanguineous drainage is scanty. Primary wound healing should be expected, and the skin sutures may be removed at the end of 1 week. Recurrence of a thyroglossal duct cyst is rare and occurs only if a portion of the patent thyroglossal tract or a part of the cyst wall is left behind at the time of surgery.

Thyroid Lobectomy

A total extracapsular thyroid lobectomy is the operation performed most frequently on the thyroid gland for patients presenting with a solitary nodule. Often these are unifocal intrathyroidal papillary carcinomas. Solitary mass lesions of the thyroid gland that are confined to one lobe and are possibly neoplastic are best treated with a diagnostic as well as therapeutic thyroid lobectomy. The specimen that is removed contains the entire lesion, which provides accurate diagnosis and, in most instances, adequate treatment, if it proves to be a well-differentiated cancer and the opposite lobe is normal.

The patient shown in Fig. 12.43 has a 3-cm, smooth, fleshy lesion confined to the right lobe of the thyroid gland. The left lobe has no palpable abnormalities and preoperatively showed no abnormalities in the opposite lobe. The patient is placed under general endotracheal anesthesia in the supine position on the operating table with the neck extended. The palpable thyroid mass is shown. The skin incision should be placed in a natural skin crease. We generally prefer a smaller incision in a skin crease near the cricoid cartilage. Such an incision heals beautifully, with barely perceptible scar. However, in this patient the incision is lower and longer than usual for demonstration of surgical anatomy. In women with heavy breasts, the incision should be placed higher than usual, because in an upright position, the weight of the breasts results in a pull on the scar resulting in a hypertrophic scar. The skin incision is made with a scalpel, and the rest of the procedure is done with an electrocautery. The platysma is divided, and the upper and lower skin flaps are elevated, exposing the fascia over the strap muscles ( Fig. 12.44 ). The upper and lower skin flaps are shown retracted to expose the strap muscles covering the thyroid gland ( Fig. 12.45 ). The fascia over the strap muscles is incised in the midline, and the sternohyoid muscles are carefully dissected and retracted laterally to expose the underlying sternothyroid muscles and anterior surface of the thyroid gland ( Fig. 12.46 ).

A patient with a solitary lesion confined to the right lobe of the thyroid gland.

The skin incision.

The strap muscles covering the thyroid gland are exposed.

The anterior surface of the thyroid gland is exposed.

The entire thyroid gland and the central compartment is explored and examined by inspection and palpation before any decision is made regarding the extent of a thyroidectomy. Once the decision is made to proceed with ipsilateral lobectomy, the sternothyroid muscle is divided near its upper end to gain exposure of the upper pole of the thyroid lobe. The middle thyroid vein is divided and ligated first. The capsular vessels on the anterior surface of the thyroid gland at its upper pole are then individually dissected, divided, and ligated. Each of the branches of the superior thyroid artery is individually clamped and divided as close to the capsule of the upper pole as possible to avoid injury to the external laryngeal branch of the superior laryngeal nerve. The nerve is located posteromedial to the superior thyroid artery and curves medially to enter the cricothyroid muscle near the upper pole of the thyroid gland. Therefore the terminal branches of the superior thyroid artery should be divided as close to the upper pole as possible without leaving remnants of upper pole thyroid tissue behind. Mass ligature of the vascular pedicle at the upper pole is hazardous and should not be undertaken. Thus the upper pole is mobilized in an extracapsular plane. The upper pole is now rotated medially, exposing its posterior surface, where the superior parathyroid gland is located. The parathyroid is carefully dissected off the thyroid capsule by blunt and sharp dissection, preserving its blood supply. The dissection now proceeds caudad, over the posterior capsule of the thyroid gland, toward its lower pole. The next step in the operation is to find the lower parathyroid gland. Meticulous dissection should be undertaken to preserve the integrity of both the parathyroid glands and their blood supply coming from the inferior thyroid artery. Ligation of the inferior thyroid artery should never be done at its main trunk, since that will devascularize the parathyroid glands. Only the terminal branches of the inferior thyroid artery entering the thyroid gland, distal to the blood supply to the parathyroid glands, are divided and ligated. The blood supply to the parathyroid glands is through very delicate branches of the inferior thyroid artery. Rough handling and inadvertent clamping during this dissection can traumatize these vessels and jeopardize the vascularity of the parathyroid glands and their function.

The veins emanating from the lower pole of the thyroid gland are carefully divided and ligated, permitting its medial rotation.

The dissection now proceeds medially toward the tracheoesophageal groove to identify the recurrent laryngeal nerve. Once identified, it is traced cephalad until it enters the cricothyroid membrane ( Fig. 12.47 ).

The recurrent laryngeal nerve is traced cephalad until it enters the cricothyroid membrane.

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