Thyroid cancer

Thyroid Cancer

Micrograph (high power view) of papillary thyroid carcinoma demonstrating diagnostic features (nuclear clearing and overlapping nuclei). H&E stain.
Classification and external resources
Specialty Oncology
ICD-10 C73
ICD-9 193
MedlinePlus 001213
eMedicine ent/646
NCI Thyroid cancer
MeSH D013964

Thyroid cancer is a cancer originating from follicular or parafollicular thyroid cells. These cells give rise to both well-differentiated cancers (i.e., papillary and follicular) and anaplastic thyroid cancer. The second cell type, the C or parafollicular cell, produces the hormone calcitonin and is the cell of origin for medullary thyroid carcinoma (MTC).[1]

The most effective management of aggressive thyroid cancers is surgical removal of thyroid gland (thyroidectomy) followed by radioactive iodine ablation and TSH-suppression therapy. Chemotherapy or radiotherapy may also be used in cases of distant metastases or advanced cancer stage.[2] Five year survival rates are 97.8% in the United States.[3]

Signs and symptoms

Micrograph of a lymph node with papillary thyroid carcinoma.

Most often the first symptom of thyroid cancer is a nodule in the thyroid region of the neck.[4] However, many adults have small nodules in their thyroids, but typically under 5% of these nodules are found to be cancerous. Sometimes the first sign is an enlarged lymph node. Later symptoms that can be present are pain in the anterior region of the neck and changes in voice due to an involvement of the recurrent laryngeal nerve.

Thyroid cancer is usually found in a euthyroid patient, but symptoms of hyperthyroidism or hypothyroidism may be associated with a large or metastatic well-differentiated tumor.

Thyroid nodules are of particular concern when they are found in those under the age of 20. The presentation of benign nodules at this age is less likely, and thus the potential for malignancy is far greater.

Causes

Thyroid cancers are thought to be related to a number of environmental and genetic predisposing factors, but significant uncertainty remains regarding its causes.

Environmental exposure to ionizing radiation from both natural background sources and artificial sources are suspected to play a significant role, and there are significant increased rates of thyroid cancer rates in those exposed to mantlefield radiation for lymphoma, and those exposed to iodine-131 following the Chernobyl disaster.[5] Thyroiditis and other thyroid disease also predispose to thyroid cancer.[6]

Genetic causes include Multiple endocrine neoplasia type 2 which markedly increases rates, particularly of the rarer medullary form of the disease.[7]

Diagnosis

Further information: Thyroid nodule

After a thyroid nodule is found during a physical examination, a referral to an endocrinologist, or a thyroidologist may occur. Most commonly an ultrasound is performed to confirm the presence of a nodule, and assess the status of the whole gland. Measurement of thyroid stimulating hormone and anti-thyroid antibodies will help decide if there is a functional thyroid disease such as Hashimoto's thyroiditis present, a known cause of a benign nodular goiter.[8] Measurement of calcitonin is necessary to exclude the presence of medullary thyroid cancer. Finally, to achieve a definitive diagnosis before deciding on treatment, a fine needle aspiration cytology test is usually performed and reported according to the Bethesda system.

Classification

Thyroid cancers can be classified according to their histopathological characteristics.[9][10] The following variants can be distinguished (distribution over various subtypes may show regional variation):

The follicular and papillary types together can be classified as "differentiated thyroid cancer".[13] These types have a more favorable prognosis than the medullary and undifferentiated types.[14]

Staging

Detection of metastases

Detection of any metastases of thyroid cancer can be performed with a full body scintigraphy using iodine-131.[19][20]

Treatment

Thyroidectomy and dissection of central neck compartment is initial step in treatment of thyroid cancer in majority of cases.[4] Thyroid-preserving operation may be applied in cases, when thyroid cancer exhibits low biological aggressiveness (e.g. well-differentiated cancer, no evidence of lymph node metastases, low MIB-1 index, no major genetic alterations like BRAF mutations, RET/PTC rearrangements, p53 mutations etc.) in patients younger than 45 years.[21] If the diagnosis of well-differentiated thyroid cancer (e.g. papillary thyroid cancer) is established or suspected by FNA the surgery is indicated, whereas watchful waiting strategy is not recommended in any evidence-based guidelines.[21][22] Watchful waiting reduces overdiagnosis and overtreatment of thyroid cancer among old patients.[23] Radioactive Iodine-131 is used in patients with papillary or follicular thyroid cancer for ablation of residual thyroid tissue after surgery and for the treatment of thyroid cancer. Patients with medullary, anaplastic, and most Hurthle cell cancers do not benefit from this therapy.[4]

External irradiation may be used when the cancer is unresectable, when it recurs after resection, or to relieve pain from bone metastasis.[4]

Sorafenib and sunitinib, approved for other indications show promise for thyroid cancer and are being used for some patients who do not qualify for clinical trials.[24] Numerous agents are in phase II clinical trials and XL184 has started a phase III trial.[24]

Prognosis

The prognosis of thyroid cancer is related to the type of cancer and the stage at the time of diagnosis. For the most common form of thyroid cancer, papillary, the overall prognosis is excellent. Indeed, the increased incidence of papillary thyroid carcinoma in recent years is likely related to increased and earlier diagnosis. One can look at the trend to earlier diagnosis in two ways. The first is that many of these cancers are small and not likely to develop into aggressive malignancies. A second perspective is that earlier diagnosis removes these cancers at a time when they are not likely to have spread beyond the thyroid gland, thereby improving the long-term outcome for the patient. There is no consensus at present on whether this trend toward earlier diagnosis is beneficial or unnecessary.

The argument against early diagnosis and treatment is based on the logic that many small thyroid cancers (mostly papillary) will not grow or metastasize. This viewpoint holds the overwhelming majority of thyroid cancers are overdiagnosed (that is, will never cause any symptoms, illness, or death for the patient, even if nothing is ever done about the cancer). Including these overdiagnosed cases skews the statistics by lumping clinically significant cases in with apparently harmless cancers.[25] Thyroid cancer is incredibly common, with autopsy studies of people dying from other causes showing that more than one third of older adults technically has thyroid cancer, which is causing them no harm.[25] It is easy to detect nodules that might be cancerous, simply by feeling the throat, which contributes to the level of overdiagnosis. Benign (non-cancerous) nodules frequently co-exist with thyroid cancer; sometimes, it is a benign nodule that is discovered but surgery uncovers an incidental small thyroid cancer. Increasingly, small thyroid nodules are discovered as incidental findings on imaging (CT scan, MRI, ultrasound) performed for another purpose ; very few of these people with accidentally discovered, symptom-free thyroid cancers will ever have any symptoms, and treatment in such patients has the potential to cause harm to them, not to help them.[25][26]

Thyroid cancer is three times more common in women than in men, but according to European statistics,[27] the overall relative 5-year survival rate for thyroid cancer is 85% for females and 74% for males.[28]

The table below highlights some of the challenges with decision making and prognostication in thyroid cancer. While there is general agreement that stage I or II papillary, follicular or medullary cancer have a good prognosis, it is not possible when evaluating a small thyroid cancer to determine which ones will grow and metastasize and which will not. As a result once a diagnosis of thyroid cancer has been established (most commonly by a fine needle aspiration), it is likely that a total thyroidectomy will be performed.

This drive to earlier diagnosis has also manifest itself on the European continent by the use of serum calcitonin measurements in patients with goiter to identify patients with early abnormalities of the parafollicular or calcitonin-producing cells within the thyroid gland. As multiple studies have demonstrated, the finding of an elevated serum calcitonin is associated with the finding of a medullary thyroid carcinoma in as high as 20% of cases.

In Europe where the threshold for thyroid surgery is lower than in the United States, an elaborate strategy that incorporates serum calcitonin measurements and stimulatory tests for calcitonin has been incorporated into the decision to perform a thyroidectomy; thyroid experts in the USA, looking at the same data sets have, for the most part, not incorporated calcitonin testing as a routine part of their evaluation, thereby eliminating a large number of thyroidectomies and the consequent morbidity. The European thyroid community has focused on prevention of metastasis from small medullary thyroid carcinomas; the North American thyroid community has focused more on prevention of complications associated with thyroidectomy (see American Thyroid Association guidelines below). It is not clear at this time who is correct.

As demonstrated in the Table below, individuals with stage III and IV disease have a significant risk of dying from thyroid cancer. While many present with widely metastatic disease, an equal number evolve over years and decades from stage I or II disease. Physicians who manage thyroid cancer of any stage recognize that a small percentage of patients with low-risk thyroid cancer will progress to metastatic disease.

Fortunately for those with metastatic thyroid cancer, the last 5 years has brought about a renaissance in thyroid cancer treatment. The identification of some of the molecular or DNA abnormalities for thyroid cancer has led to the development of therapies that target these molecular defects. The first of these agents to negotiate the approval process is vandetanib, a tyrosine kinase inhibitor that targets the RET proto-oncogene, 2 subtypes of the vascular endothelial growth factor receptor, and the epidermal growth factor receptor.[29] More of these compounds are under investigation and are likely to make it through the approval process. For differentiated thyroid carcinoma, strategies are evolving to use selected types of targeted therapy to increase radioactive iodine uptake in papillary thyroid carcinomas that have lost the ability to concentrate iodide. This strategy would make it possible to use radioactive iodine therapy to treat "resistant" thyroid cancers. Other targeted therapies are being evaluated, making it possible that life will be extended over the next 5–10 years for those with stage III and IV thyroid cancer.

Prognosis is better in younger people than older ones.[28]

Prognosis depends mainly on the type of cancer and cancer stage.

 
Thyroid cancer type
5-year survival 10-year survival
Stage I Stage II Stage III Stage IV Overall Overall
Papillary 100%[30] 100%[30] 93%[30] 51%[30] 96%[31] or 97%[32] 93%[31]
Follicular 100%[30] 100%[30] 71%[30] 50%[30] 91%[31] 85%[31]
Medullary 100%[30] 98%[30] 81%[30] 28%[30] 80%,[31] 83%[33] or 86%[34] 75%[31]
Anaplastic (always stage IV)[30] 7%[30] 7%[30] or 14%[31] (no data)

Epidemiology

Thyroid cancer, in 2010, resulted in 36,000 deaths globally up from 24,000 in 1990.[35] Obesity may be associated with a higher incidence of thyroid cancer, but this relationship remains the subject of much debate.[36]

Thyroid cancer accounts for less than 1% of cancer cases and deaths in the UK. Around 2,700 people were diagnosed with Thyroid cancer in the UK in 2011, and around 370 people died from the disease in 2012.[37]

Notable cases

See also

References

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  23. Welch, H. Gilbert; Schwartz, Lisa; M.D., Lisa M. Schwartz,; Steve Woloshin (2011-01-18). Overdiagnosed: Making People Sick in the Pursuit of Health. Beacon Press. pp. 138–143. ISBN 9780807022009. Retrieved 7 October 2012.
  24. 24.0 24.1 Sherman (2009). "Advances in Chemotherapy of Differentiated Epithelial and Medullary Thyroid Cancers". Journal of Clinical Endocrinology & Metabolism 94 (5): 1493–1499. doi:10.1210/jc.2008-0923.
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  28. 28.0 28.1 Numbers from EUROCARE, from Page 10 in: F. Grünwald; Biersack, H. J.; Grںunwald, F. (2005). Thyroid cancer. Berlin: Springer. ISBN 3-540-22309-6.
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  30. 30.0 30.1 30.2 30.3 30.4 30.5 30.6 30.7 30.8 30.9 30.10 30.11 30.12 30.13 30.14 cancer.org Thyroid Cancer By the American Cancer Society. In turn citing: AJCC Cancer Staging Manual (7th ed).
  31. 31.0 31.1 31.2 31.3 31.4 31.5 31.6 Numbers from National Cancer Database in the US, from Page 10 in: F. Grünwald; Biersack, H. J.; Grںunwald, F. (2005). Thyroid cancer. Berlin: Springer. ISBN 3-540-22309-6. (Note:Book also states that the 14% 10-year survival for anaplastic thyroid cancer was overestimated)
  32. Rounded up to nearest natural number from 96.7% as given by eMedicine Thyroid, Papillary Carcinoma Author: Luigi Santacroce. Coauthors: Silvia Gagliardi and Andrew Scott Kennedy. Updated: Sep 28, 2010
  33. By 100% minus cause-specific mortality of 17% at 5 yr, as given by Barbet J, Campion L, Kraeber-Bodéré F, Chatal JF (2005). "Prognostic Impact of Serum Calcitonin and Carcinoembryonic Antigen Doubling-Times in Patients with Medullary Thyroid Carcinoma". Journal of Clinical Endocrinology & Metabolism 90 (11): 6077–6084. doi:10.1210/jc.2005-0044. PMID 16091497.
  34. National Cancer Institute, Medullary Thyroid Cancer Last Modified: 12/22/2010
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  37. "Thyroid cancer statistics". Cancer Research UK. Retrieved 28 October 2014.
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  39. "Survivors". Retrieved 2013-08-11.

External links