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Thyroid, Anaplastic Carcinoma
Article Last Updated: Apr 18, 2006
AUTHOR AND EDITOR INFORMATION
Section 1 of 10  
Author: Anastasios K Konstantakos, MD, Clinical Associate Surgeon, Brigham and Women's Hospital, Harvard University
Coauthor(s):
Debra J Graham, MD, Director of Surgical Specialties Service, Cleveland Louis Stokes VA Medical Center, Associate Program Director, Assistant Professor, Department of Surgery, Case Western Reserve University
Editors: Lodovico Balducci, MD, Professor of Oncology and Medicine, University of South Florida College of Medicine; Division Chief, Senior Adult Oncology Program, H Lee Moffitt Cancer Center and Research Institute; Francisco Talavera, PharmD, PhD, Senior Pharmacy Editor, eMedicine; Rajalaxmi McKenna, MD, FACP, Consulting Staff, Department of Medicine, Southwest Medical Consultants, SC, Good Samaritan Hospital, Advocate Health Systems; John S Macdonald, MD, Professor of Medicine, New York Medical College; Chief, Division of Medical Oncology, St Vincent's Hospital and Medical Center; Medical Director, Saint Vincent's Comprehensive Cancer Center
Author and Editor Disclosure
Synonyms and related keywords:
undifferentiated thyroid carcinoma, anaplastic carcinoma of the thyroid, anaplastic thyroid carcinoma, ATC, thyroid gland malignancy, anaplastic thyroid carcinoma, thyroid cancer, thyroid tumor, metastases, thyroid malignancy
Background
Anaplastic carcinoma of the thyroid (ATC) is the most aggressive thyroid gland malignancy. Although ATC accounts for less than 2% of all thyroid cancers, it causes up to 40% of deaths from thyroid cancer.
The aggressive nature of ATC makes treatment studies difficult to perform.
Pathophysiology
ATC generally occurs in people in iodine-deficient areas and in a setting of previous thyroid pathology (eg, preexisting goiter, follicular thyroid cancer, papillary thyroid cancer). Local invasion of adjacent structures (eg, trachea, esophagus) commonly occurs.
ATC has a rapid course and early dissemination. The most common sites of distant spread include (in descending order) lung, bone, and brain. Metastases (particularly in the lung) are likely to be present at diagnosis more than 50% of the time.
Frequency
United States
ATC comprises less than 2% of all thyroid malignancies. Fortunately, the incidence appears to be declining.
International
Worldwide frequency likely approximates that in the United States.
Mortality/Morbidity
ATC typically has a rapidly progressive course. The overall 5-year survival rate is reportedly less than 10%, and most patients do not live longer than a few months after diagnosis.
Sex
The female-to-male ratio is approximately 3:1.
Age
Peak incidence occurs during the sixth to seventh decades of life. The age range of affected patients reportedly is 15-90 years.
History
Patients with anaplastic thyroid carcinoma (ATC) typically present with a rapidly growing neck mass. Patients with metastases may also note bone pain, weakness, and cough. Neurologic deficits may be observed with brain metastases. The rapidly growing neck mass may produce the following symptoms:
- Dysphagia
- Cough
- Neck pain
- Dyspnea
Physical
Physical examination typically reveals a dominant neck mass. More than 40% of affected patients have lymph node enlargement, indicating local metastases. Pleural effusions may lead to decreased breath sounds on auscultation. With metastases, the physician may note bone pain and neurologic deficits.
Causes
ATC is believed to occur from a terminal dedifferentiation of previously undetected long-standing thyroid carcinoma (eg, papillary, follicular). ATC has a genetic association with oncogenes C-myc, H-ras, and Nm23.
Goiter
Hyperthyroidism
Hypothyroidism
Parathyroid Carcinoma
Thyroid Lymphoma
Thyroid Nodule
Thyroid, Follicular Carcinoma
Thyroid, Medullary Carcinoma
Thyroid, Papillary Carcinoma
Thyroiditis, Subacute
Other Problems to be Considered
Thyroid, adenoma
Lab Studies
- Anaplastic thyroid carcinoma (ATC) cannot be definitively diagnosed with laboratory examinations of the blood or urine.
- Obtain serum calcium levels to rule out medullary thyroid carcinoma or parathyroid neoplasms.
Imaging Studies
- Chest radiography may be used to determine the presence of lung metastases.
- Preoperative cervical ultrasonography can detect lymph node metastases.
- Cervical CT scanning can be used to define the local spread of disease. Detection of distant metastases to the mediastinum, liver, lung, bone, and brain is also possible via CT scanning or MRI.
- Bone scanning can be used to determine the presence of bone metastases.
Procedures
- Fine-needle aspiration often yields enough cytologic information to allow diagnosis; however, if fine-needle aspiration is inadequate, patients may require an open surgical biopsy.
Histologic Findings
Grossly, ATC is described as a large, fleshy, off-white tumor. Infiltration of adjacent structures can be observed grossly and microscopically. Histologically, observation of regions of spontaneous necrosis and hemorrhage may be observed. Typically, angioinvasion is detectable.
The main histologic variants include spindle cell, giant cell (osteoclastlike), squamoid, and paucicellular. The giant cell subtype typically exhibits local calcification with significant osteoid formation. The paucicellular subtype demonstrates rapid growth, intense fibrosis, focal infarction, diffuse calcification, and encroachment of adjacent vascular tissue by atypical spindle cells.
Thyroid lymphoma is the only curable condition that may be confused with ATC. Rule out lymphoma in the presence of a poorly differentiated large cell thyroid tumor. This investigation involves lymphoid tissue markers (eg, cytoplasmic immunoglobulin, immunoglobulin receptors, gene rearrangement studies).
Medical Care
- Treatment is mostly palliative.
- Phase I studies are as follows:
- Consider patients with unresectable tumors who are in good general condition for phase I studies.
- These studies are available in any major cancer center, are generally financed by the industry, and may help individual patients.
- Phase I trials represent the only opportunity to recognize drugs of some activity in this unusual disease.
Surgical Care
- Perform surgery in conjunction with radiation and chemotherapy.
- Use surgery to obtain a definitive diagnosis when fine-needle aspiration is unsuccessful.
- Protect the airway when performing surgery; thus, performing an early prophylactic tracheostomy may be required.
- Despite the typically large size of these tumors, the extent of resection is limited when the diagnosis is made.
- Rather than performing complete thyroidectomy, resect as much thyroid tissue as possible without attempting resection of all adjacent structures because of the high incidence of postoperative morbidity (eg, vocal cord paralysis, esophageal fistula). Although a greater extent of resection may be associated with slightly longer survival, this hypothesis is not confirmed.
Consultations
Involve a surgeon with experience in thyroid operations in the operative care of affected patients.
The goals of pharmacotherapy are to reduce morbidity and to prevent complications.
Drug Category: Antineoplastics
Chemotherapeutic agents that may be used in advanced disease include doxorubicin and cisplatin.
| Drug Name | Doxorubicin (Adriamycin, Rubex) |
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| Description | This is an antineoplastic agent of the anthracycline antibiotic class. Inhibits topoisomerase II and produces free radicals, which may cause the destruction of DNA. The combination of these 2 events can in turn inhibit the growth of neoplastic cells. In metastatic thyroid carcinoma, doxorubicin is probably the most effective antineoplastic agent. |
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| Adult Dose | Recommended dose can vary from 60-75 mg/m2 typically as a single rapid IV infusion; dose may be repeated after 21 d |
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| Pediatric Dose | Administer as in adults |
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| Contraindications | Documented hypersensitivity; severe heart failure; cardiomyopathy; impaired cardiac function; preexisting myelosuppression |
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| Interactions | May decrease phenytoin and digoxin plasma levels; phenobarbital may decrease plasma levels of doxorubicin; cyclosporine may induce coma or seizures; mercaptopurine increases toxicity of doxorubicin; cyclophosphamide increases cardiac toxicity of doxorubicin |
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| Pregnancy | D - Unsafe in pregnancy
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| Precautions | Myelosuppression is a major dose-limiting toxicity; leukopenia usually reaches a nadir by week 2 of therapy and recovers by week 4; stomatitis, alopecia, and gastrointestinal upset are common but usually reversible adverse effects; erythematous streaking near the site of infusion; facial flushing; conjunctivitis; lacrimation; local toxicity may occur in irradiated tissues (eg, skin, heart, lung, esophagus, gastrointestinal mucosa)
Cardiomyopathy is a well known adverse effect of anthracycline antibiotics; acute and chronic heart failure may occur; mortality rate may exceed 50%; a dose as small as 250 mg/m2 can cause myocardial toxicity; cardiac irradiation or other concomitant anthracycline administration may increase risk of cardiotoxicity; late-onset cardiac toxicity, manifesting as congestive heart failure years after treatment, may occur in both children and adults |
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| Drug Name | Cisplatin (Platinol) |
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| Description | Inhibits DNA synthesis and, thus, cell proliferation by causing DNA crosslinks and denaturation of double helix. |
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| Adult Dose | Average dose: 20 mg/m2 IV qd for 5 d or 100 mg/m2 as single dose q4wk |
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| Pediatric Dose | Administer as in adults |
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| Contraindications | Documented hypersensitivity; preexisting renal insufficiency; myelosuppression; hearing impairment |
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| Interactions | Increases toxicity of bleomycin and ethacrynic acid |
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| Pregnancy | D - Unsafe in pregnancy
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| Precautions | Administer adequate hydration before and 24 h after cisplatin dosing to reduce risk of nephrotoxicity; myelosuppression, ototoxicity, nausea, and vomiting may occur; ototoxicity can be unilateral or bilateral and may be more severe in children; marked nausea and vomiting occurs in almost all patients; at high doses or after several treatment cycles, cisplatin causes peripheral neuropathy; mild-to-moderate myelosuppression may occur transiently; electrolyte disturbances, particularly hypomagnesemia secondary to renal wasting, may occur |
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Further Inpatient Care
- Role of adjuvant therapy
- Radiotherapy: Despite the fact that anaplastic thyroid carcinoma (ATC) is largely radioresistant, use external beam radiotherapy for local control. Some evidence shows that hyperfractionation may lead to better success at local control by permitting delivery of higher doses of total radiation with less toxicity.
- Chemotherapy: Currently, no available chemotherapeutic agent or combination of chemotherapeutic agents shows sufficient antineoplastic activity to prevent death; yet in rare instances, chemotherapy may prolong life by a few weeks or perhaps months. Doxorubicin and cisplatin are the 2 most common agents used; however, resistance from cellular extrusion of the drugs occurs.
- Since ATC is a relatively uncommon disease, large phase III clinical trials of systemic therapies are not possible to perform. For that reason, the value of newer therapies, such as taxanes, gemcitabine, and irinotecan, and targeted therapies, such as receptor tyrosine kinase inhibitors, is unknown.
Complications
- Risk of complications from a thyroid disease operation (eg, permanent hypoparathyroidism, recurrent laryngeal nerve palsy) may be increased with ATC if an aggressive surgical attempt is made.
- With limited thyroid resection, incidence of these local complications should not be significantly greater.
Prognosis
- ATC typically has a rapidly progressive course. The overall 5-year survival rate is reportedly less than 10%, and most patients do not live longer than a few months after diagnosis.
- A recent study has shown that patients younger than 60 years who have intrathyroidal ATC have a better prognosis compared with patients who are older and have distant metastases.
- While some studies have suggested that postoperative radiotherapy may be of benefit in terms of survival, definitive prospective trials are lacking.
Patient Education
Medical/Legal Pitfalls
- Failure to diagnose anaplastic thyroid carcinoma (ATC) at an early stage before it spreads both locally and distantly, which underscores the importance of meticulous history and physical examination assessment
- Failure to perform fine-needle aspiration for any suspicious thyroid mass; an equivocal or indeterminate mass should be re-aspirated or surgically excised if any question remains as to the histology of the lesion
- Failure to assess airway patency, which is foremost in the physician's treatment plan
- Failure to seriously consider intubation and/or tracheostomy if cancer is producing local airway compromise
Special Concerns
- Because ATC tends to occur in areas of previous thyroid pathology, consider the diagnosis in patients with a medical history of thyroid disease who present with a recently enlarging neck mass.
- If metastases are found, aggressive surgical therapy is not warranted.
- While recent trials of immunotherapy and gene therapy have been postulated, no definitive evidence suggests any benefit from these modalities; they should be considered experimental at best.
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Thyroid, Anaplastic Carcinoma excerpt Article Last Updated: Apr 18, 2006
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