Hashimoto's thyroiditis

HLA genes

The first gene locus associated with autoimmune thyroid disease was the major histocompatibility complex (MHC) region on chromosome 6p21. It encodes human leukocyte antigens (HLAs). Specific HLA alleles have a higher affinity to auto-antigenic thyroidal peptides and can contribute to autoimmune thyroid disease development. Specifically, in Hashimoto's disease, aberrant expression of HLA II on thyrocytes has been demonstrated. They can present thyroid autoantigens and initiate autoimmune thyroid disease.^[26] Susceptibility alleles are not consistent in Hashimoto's disease. In Caucasians, various alleles are reported to be associated with the disease, including DR3, DR5, and DQ7.^[27][28]

CTLA-4 genes

CTLA-4 is the second major immune-regulatory gene related to autoimmune thyroid disease. CTLA-4 gene polymorphisms may contribute to the reduced inhibition of T-cell proliferation and increase susceptibility to autoimmune response.^[29] CTLA-4 is a major thyroid autoantibody susceptibility gene. A linkage of the CTLA-4 region to the presence of thyroid autoantibodies was demonstrated by a whole-genome linkage analysis.^[30] CTLA-4 was confirmed as the main locus for thyroid autoantibodies.^[31]

PTPN22 gene

PTPN22 is the most recently identified immune-regulatory gene associated with autoimmune thyroid disease. It is located on chromosome 1p13 and expressed in lymphocytes. It acts as a negative regulator of T-cell activation. Mutation in this gene is a risk factor for many autoimmune diseases. Weaker T-cell signaling may lead to impaired thymic deletion of autoreactive T cells, and increased PTPN22 function may result in inhibition of regulatory T cells, which protect against autoimmunity.^[32]

Immune-related genes

IFN-γ promotes cell-mediated cytotoxicity against thyroid mutations causing increased production of IFN-γ were associated with the severity of hypothyroidism.^[33] Severe hypothyroidism is associated with mutations leading to lower production of IL-4 (Th2 cytokine suppressing cell-mediated autoimmunity),^[34] lower secretion of TGF-β (inhibitor of cytokine production),^[35] and mutations of FOXP3, an essential regulatory factor for the regulatory T cells (Tregs) development.^[36] Development of Hashimoto's disease was associated with mutation of the gene for TNF-α (stimulator of the IFN-γ production), causing its higher concentration.^[37]

Sex

Study of healthy Danish twins divided to three groups (monozygotic and dizygotic same sex, and opposite sex twin pairs) estimated that genetic contribution to thyroid peroxidase antibodies susceptibility was 61% in males and 72% in females, and contribution to thyroglobulin antibodies susceptibility was 39% in males and 75% in females.^[38]

The high female predominance in thyroid autoimmunity may be associated with the X chromosome. It contains sex and immune-related genes responsible for immune tolerance.^[39] A higher incidence of thyroid autoimmunity was reported in patients with a higher rate of X-chromosome monosomy in peripheral white blood cells.^[40] Another potential mechanism might be skewed X-chromosome inactivation.^[5]

Pregnancy

In one population study, two or more births were a risk factor for developing autoimmune hypothyroidism in pre-menopausal women.^[41]

Medications

Certain medications or drugs have been associated with altering and interfering with thyroid function. There are two main mechanisms of interference:^[42]

• Altering thyroid hormone serum transfer proteins.^[42] Estrogen, tamoxifen, heroin, methadone, clofibrate, 5-fluorouracil, mitotane, and perphenazine all increase thyroid binding globulin (TBG) concentration.^[42] Androgens, anabolic steroids such as danazol, glucocorticoids, and slow release nicotinic acid all decrease TBG concentrations. Furosemide, fenoflenac, mefenamic acid, salicylates, phenytoin, diazepam, sulphonylureas, free fatty acids, and heparin all interfere with thyroid hormone binding to TBG and/or transthyretin.^[42]
• Altering extra-thryoidal metabolism of thyroid hormone. Propylthiouracil, glucocorticoids, propranolol, iondinated contrast agents, amiodarone, and clomipramine all inhibit conversion of T₄ and T₃.^[42] Phenobarbital, rifampin, phenytoin and carbamazepine all increase hepatic metabolism.^[42] Finally, cholestryamine, colestipol, aluminium hydroxide, ferrous sulphate, and sucralfate are all drugs that decrease T₄ absorption or enhance excretion.^[42]

Iodine

Both excessive and insufficient iodine intake has been implicated in developing antithyroid antibodies.^[43][44] Thyroid autoantibodies are found to be more prevalent in geographical areas after increasing iodine levels.^[44] Several mechanisms by which excessive iodine may promote thyroid autoimmunity have been proposed:^[43]

• Via thyroglobulin iodination: Iodine exposure leads to higher iodination of thyroglobulin, increasing its immunogenicity^[43] by creating new iodine-containing epitopes or exposing cryptic epitopes.^[45]
• Via thyrocyte damage: Iodine exposure has been shown to increase the level of reactive oxygen species. They enhance the expression of the intracellular adhesion molecule-1 on the thyrocytes, which could attract the immuno-competent cells into the thyroid gland.^[43] Iodine also promotes thyrocyte apoptosis.^[43]
• Via immune cell behaviour: Iodine has an influence on immune cells.^[43]

Comorbidities

Comorbid autoimmune diseases are a risk factor for developing Hashimoto's thyroiditis, and the opposite is also true.^[3] Another thyroid disease closely associated with Hashimoto's thyroiditis is Graves' disease.^[16] Autoimmune diseases affecting other organs most commonly associated with Hashimoto's thyroiditis include celiac disease, type 1 diabetes, vitiligo, alopecia,^[46] Addison disease, Sjogren's syndrome, and rheumatoid arthritis^[14][47] Autoimmune thyroiditis has also been seen in patients with autoimmune polyendocrine syndromes type 1 and 2.^[16]

Other

Other environmental factors include selenium deficiency,^[8] infectious diseases such as hepatitis C, rubella, and possibly Covid-19,^[48][49][50] toxins,^[5] dietary factors,^[16] radiation exposure,^[5] and gut dysbiosis.^[51]

Physical exam

Physicians will often start by assessing reported symptoms and performing a thorough physical exam, including a neck exam.^[10] Patients may have a "firm, bumpy, symmetric, painless goiter", however, up to 10% of patients may have an atrophied thyroid.^[5]

Antithyroid antibodies tests

Tests for antibodies against thyroid peroxidase, thyroglobulin, and thyrotropin receptors can detect autoimmune processes against the thyroid. 90% of hashimoto's patients have elevated levels of thyroid peroxidase antibodies.^[5] However, seronegative (without circulating autoantibodies) thyroiditis is also possible.^[58] There may be circulating antibodies before the onset of any symptoms.^[10]

Ultrasound

An ultrasound may be useful in detecting Hashimoto thyroiditis, especially in those with seronegative thyroiditis,^[13] or when patients have normal laboratory values but symptoms of autoimmune thyroiditis.^[47] Key features detected in the ultrasound of a person with Hashimoto's thyroiditis include "echogenicity, heterogeneity, hypervascularity, and presence of small cysts."^[13] Images obtained with ultrasound can evaluate the size of the thyroid, reveal the presence of nodules, or provide clues to the diagnosis of other thyroid conditions.^[47]

Nuclear medicine

Nuclear imaging showing thyroid uptake can also be helpful in diagnosing thyroid function, particularly differential diagnosis.^[5]

TSH levels test

Elevated Thyroid-stimulating hormone (TSH) levels may indicate hypothyroidism (underpeforming thyroid).^[47] Hypothyroidism is a common symptom and potential indication of hashimoto's disease.^[5] As blood levels of thyroid hormones fall due to hypothyroidism, the anterior pituitary gland increases production of TSH, which stimulates increased production of thyroid hormones in the thyroid.^[20] The elevation is usually a marked increase over the normal range.^[14] TSH is the preferred initial test of thyroid function as it has a higher sensitivity to changes in thyroid status than free T₄.^[59]

Biotin can cause this test to read "falsely low".^[20] Time of day can affect the results of this test; TSH peaks early in the morning and slumps in the late afternoon to early evening,^[60] with "a variation in TSH by a mean of between 0.95 mIU/mL to 2.0 mIU/mL".^[61] Hypothyroidism is diagnosed more often in samples taken soon after waking.^[62]

T₃ or T₄ levels test

These tests detect levels of two thyroid hormones: Thyroxine (T₄) and Tri-iodothyronine (T₃). Low levels of these hormones (hypothyroidism) may indicate autoimmune damage to the thyroid due to hashimotos, while elevated levels may indicate an attack of destructive thyrotoxicosis.^[5] Hashimotos with normal levels is possible however.

Free or total levels can be measured. Typically, Free T₄ is the preferred test for hypothyroidism,^[63] as Free T₃ immunoassay tests are less reliable at detecting low levels of thyroid hormone,^[64] and they are more susceptible to interference.^[63] Both immunoassay tests of Free T₄ and Free T₃ may overestimate concentrations, particularly at low thyroid hormone levels, which is why results are typically read in conjunction with TSH, a more sensitive measure.^[65] LC-MSMS assays are rarer, but they are "highly specific, sensitive, precise, and can detect hormones found in low concentrations."^[65]

Muscle Biopsy

Muscle biopsy is not necessary for diagnosis of myopathy due to hypothyroid muscle fibre changes, however it may reveal confirmatory features.^[15]

Side Effects

Side effects of thyroid replacement therapy are associated with "inadequate or excessive doses."^[20] Symptoms to watch for include, but are not limited to, anxiety, tremor, weight loss, heat sensitivity, diarrhea, and shortness of breath. More worrisome symptoms include atrial fibrillation and bone density loss.^[20] Long term over-treatment is associated with increased mortality and dementia.^[21]

Monitoring

Thyroid Stimulating Hormone (TSH) is the laboratory value of choice for monitoring response to treatment with levothyroxine.^[74] When treatment is first initiated, TSH levels may be monitored as often as a frequency of every 6–8 weeks.^[74] Each time the dose is adjusted, TSH levels may be measured at that frequency until the correct dose is determined.^[74] Once titrated to a proper dose, TSH levels will be monitored yearly.^[74] The target level for TSH is the subject of debate, with factors like age, sex, individual needs and special circumstances such as pregnancy being considered.^[75] Recent studies suggest that adjusting therapy based on thyroid hormone levels (T₄ and/or T₃) may be important.^[20]

Monitoring liothyronine treatment or combination treatment can be challenging.^[75][70][76] Liothyronine can suppress TSH to a greater extent than levothyroxine.^[77] Short-acting Liothyronine's short half-life can result in large fluctuations of free T₃^[76] over the course of 24 hours.^[78]

Patients may have to adjust their dosage several times over the course of the disease. Endogenous thyroid hormone levels may fluctuate, particularly early in the disease.^[79] Patients may sometimes develop hyperthyroidism, even after long-term treatment.^[5] This can be due to a number of factors including acute attacks of destructive thyrotoxicosis (autoimmune attacks on the thyroid resulting in rises in thyroid hormone levels as thyroid hormones leak out of the damaged tissues).^[18][5] This is usually followed by hypothyroidism.^[5]

Reverse T₃

Measuring reverse tri-iodothyronine (rT₃) is often mentioned in the lay (non-medical) press as a possible marker to inform T₄ or T₃ therapy, "however, there is currently no evidence to support this application" as of 2023.^[63] Although cited in the lay press as a possible competitor to T₃, it is unlikely that rT₃ causes hypothyroid symptoms by out-competing T₃ for thyroid hormone receptors, as it has a binding affinity 200 times weaker.^[80] It is also unlikely that rT₃ causes poor T₄ to T₃ conversion; despite being demonstrated in vivo to have the potential to inhibit DIO-mediated T₄ to T₃ conversion, this is considered improbable at normal body hormone concentrations.^[80]

Low tissue tri-iodothyronine (T₃) hypothesis

Peripheral tissue T₄ to T₃ conversion may be inadequate: Some patients on LT₄ monotherapy may have blood T₃ levels low or below the normal range,^[20][75] and/or may have local T₃ deficiency in some tissues.^[83] Although both molecules can have biological effects, thyroxine (T₄) is considered the "storage form" of thyroid hormone with much less effect, while tri-iodothyronine (T₃) is considered the active form used by body tissues.^[84][85] Thus the body must convert thyroxine into tri-iodothyronine.^[85] Tri-iodothyronine is produced primarily by conversion in the liver, kidney, skeletal muscle and pituitary gland.^[86]

Adequate conversion requires sufficient levels of the micronutrients zinc,^[87] selenium,^[8] iron,^[88] and possibly vitamin A.^[89] Conversion rates may decline with age.^[90] Since deiodinase type 2 is necessary for T₄ to T₃ conversion in some peripheral tissues, "patients with DIO2 gene polymorphisms may have variable peripheral T₃ availability", leading to localised hypothyroidism in some tissues.^[69][13][8] The Thr92Ala DIO2 polymorphism is present in 12–36% of the population.^[69]

For the latter patients, levothyroxine monotherapy may not be sufficient^[69] and patients may have improvement on combination therapy of T₄ and T₃.^[20][8][91] As standard immunoassay tests can overestimate blood T₄ and T₃ levels, Ultrafiltration LC-MSMS T₄ and T₃ tests may help to identify patients who would benefit from additional T₃.^[65]

Inadequate markers hypothesis

There is ongoing debate about how to define euthyroidism and whether TSH is its best indicator.^[81] TSH may be useful to detect poor thyroid output and may reflect the state of thyroid hormones in the hypothalamic-pituitary-thyroid axis, but not the presence of hormones in other body tissues.^[21][75][83] As a result, LT₄ monotherapy may not result in a "truly biochemically euthyroid state."^[69] Patients may express a preference for "low normal or below normal TSH values"^[83] and/or T₄ and T₃ monitoring. The monitoring of other biomarkers that reflect the action of thyroid hormone on tissues has also been proposed.^[13][92][21]

As immunoassay Free T₃ and Free T4 tests can overestimate levels, particularly at low thyroid hormone levels, hypothyroidism may be undertreated.^[65] LC-MSMS tests may provide more reliable measures.^[65]

Extra-thyroidal effects of autoimmunity hypothesis

It is hypothesised that autoimmunity may play some role in euthyroid symptoms.^[75][93][69] Hypothesised mechanisms include the proposal that TPO-antibody-producing lymphocytes may travel out of the thyroid to other tissue, creating symptoms and inflammation due to cross-reaction,^[69][94] or "the inflammatory nature of [...] persistently increased circulating cytokine levels."^[75] Multiple studies find that antibodies coincide with symptoms even in euthyroid patients,^[5][69] and higher levels are associated with increased symptoms,^[20] however "the found association does not prove a causality".^[69] No treatment currently exists for Hashimoto's autoimmunity, although observed wellbeing improvements after surgical thyroid removal are hypothesised to be due to removing the autoimmune stimulus.^[13][94]

Physical and psychosocial co-morbidities hypothesis

It is hypothesised that euthyroid symptoms may not be due to Hashimoto's or hypothyroidism, but some other "physical and psychosocial co-morbidities".^[82][21]

Anti-thyroid antibodies in pregnancy

The presence of Thyroid peroxidase antibodies at the outset of pregnancy are associated with a greater risk to the mother of hypothyroidism and thyroid impairment in the first year after delivery.^[126]

The presence of antibodies is also associated with "a 2 to 4-fold increase in the risk of recurrent miscarriages, and 2 to 3-fold increased risk of preterm birth", however the reason why is unclear. Thyroid peroxidase antibodies are speculated to indicate other autoimmune processes against the placental-fetal unit.^[13]

Levothyroxine treatment in euthyroid women with thyroid autoimmunity does not significantly impact the relative risk of miscarriage and preterm delivery, or outcomes with live birth. "Therefore, no strong recommendations regarding the therapy in such scenarios could be made, but consideration on a case-by-case basis might be implemented."^[13]

Hypothyroidism in pregnancy.

Women who have low thyroid function that has not been stabilized are at greater risk of complications for both parent and child. Risks to the mother include gestational hypertension including preeclampsia and eclampsia, gestational diabetes, placental abruption, and postpartum hemorrhage.^[13] Risks to the infant include miscarriage, preterm delivery, low birth weight, neonatal respiratory distress, hydrocephalus, hypospadias, fetal death, infant intensive care unit admission, and neurodevelopmental delays (lower child IQ, language delay or global developmental delay).^{[125][123][13]}

Successful pregnancy outcomes are improved when hypothyroidism is treated.^[123] Levothyroxine treatment may be considered at lower TSH levels in pregnancy than in standard treatment.^[13] Liothyronine does not cross the fetal blood-brain barrier, so liothyronine (T₃) only or liothyronine + levothyroxine (T₃ + T₄) therapy is not indicated in pregnancy.^[13]

Close cooperation between the endocrinologist and obstetrician benefits the woman and the infant.^{[125][127][128]}

Immune changes during pregnancy

Hormonal changes and trophoblast expression of key immunomodulatory molecules lead to immunosuppression and fetal tolerance. The main players in regulation of the immune response are Tregs. Both cell-mediated and humoral immune responses are attenuated, resulting in immune tolerance and suppression of autoimmunity. It has been reported that during pregnancy, levels of thyroid peroxidase and thyroglobulin antibodies decrease.^[129]