Graves' ophthalmopathy

A 40-year-old woman who recently received a diagnosis of Graves' disease comes for a follow-up visit. She has been taking methimazole, at a dose of 10 mg daily, and is now euthyroid, but for the past 3 months, she has had bothersome eye symptoms, including redness, tearing, grittiness, photophobia, diplopia at the extremes of gaze, and ocular pain with eye movements. She smokes 10 cigarettes per day. Examination reveals exophthalmos, swelling of periorbital tissues, and limitation of eye movements. How should Graves' ophthalmopathy be managed

The onset time of amiodarone-induced thyrotoxicosis (AIT) depends on AIT type

Objective: Considering the different pathogenic mechanisms of the two main forms of amiodarone-induced thyrotoxicosis (AIT), we ascertained whether this results in a different onset time as well. Design and methods: We retrospectively analyzed the clinical records of 200 consecutive AIT patients (157 men and 43 women; mean age 62.2G12.6 years) referred to our Department from 1987 to 2012. The onset time of AIT was defined as the time elapsed from the beginning of amiodarone therapy and the first diagnosis of thyrotoxicosis, expressed in months. Factors associated with the onset time of AIT were evaluated by univariate and multivariate analyses. Results: The median onset time of thyrotoxicosis was 3.5 months (95% CI 2–6 months) in patients with type 1 AIT (AIT1) and 30 months (95% CI 27–32 months, P!0.001) in those with type 2 AIT (AIT2). Of the total number of patients, 5% with AIT1 and 23% with AIT2 (PZ0.007) developed thyrotoxicosis after amiodarone withdrawal. Factors affecting the onset time of thyrotoxicosis were the type of AIT and thyroid volume (TV). Conclusions:ThedifferentpathogenicmechanismsofthetwoformsofAITaccountfordifferentonsettimesofthyrotoxicosisin the two groups. Patients with preexisting thyroid abnormalities (candidate to develop AIT1) may require a stricter follow-up during amiodarone therapy than those usually recommended. In AIT1, the onset of thyrotoxicosis after amiodarone withdrawal is rare, while AIT2 patients may require periodic tests for thyroid function longer after withdrawing amiodarone

Continuation of amiodarone delays restoration of euthyroidism in patients with type 2 amiodarone-induced thyrotoxicosis treated with prednisone: a pilot study

Context: Type 2 amiodarone-induced thyrotoxicosis (AIT) is a destructive thyroiditis usually re- sponsive to glucocorticoids. Whether continuation of amiodarone affects treatment outcome is unsettled. Objective: The objective of the study was to compare the outcome of glucocorticoid treatment in type 2 AIT patients who continued or withdrew amiodarone. Design: This was a matched retrospective cohort study. Setting: The study was conducted at a university center. Patients: Eighty-three consecutive patients with untreated type 2 AIT participated in the study. After matching with patients continuing amiodarone (AMIO-ON, n 8), patients interrupting amiodarone were randomly selected in a 4:1 ratio (AMIO-OFF, n 32). Intervention: All patients were treated with oral prednisone. Patients whose thyrotoxicosis re- curred after glucocorticoid withdrawal were treated with a second course of prednisone. Main Outcome Measure: Time and rate of cure were measured. Results: Median time to the first normalization of serum thyroid hormone levels did not signifi- cantly differ in AMIO-ON and AMIO-OFF patients (24 and 31 d, respectively; P 0.326). Conversely, median time for stably restoring euthyroidism was 140 d in AMIO-ON patients and 47 d in AMIO- OFF patients (log rank, P 0.011). In fact, AIT recurred in five of seven AMIO-ON patients (71.4%) and in only three of 32 AMIO-OFF patients (9.4%, P 0.002), requiring readministration of pred- nisone. One AMIO-ON patient never reached thyroid hormone normalization during the study period. Factors associated with glucocorticoid failure were thyroid volume and amiodarone continuation. Conclusions: Prednisone restores euthyroidism in most type 2 AIT patients, irrespective of amio- darone continuation or withdrawal. However, continuing amiodarone increases the recurrence rate of thyrotoxicosis, causing a delay in the stable restoration of euthyroidism and a longer exposure of the heart to thyroid hormone exces

Simultaneous medullary and papillary thyroid cancer: two case reports

<p>Abstract</p> <p>Background</p> <p>Papillary thyroid carcinoma (PTC) and medullary thyroid carcinoma (MTC) have always been considered different from each other; in their incidence, their cell origin and their histopathological features.</p> <p>Case presentation</p> <p>This paper describes two rare cases of the simultaneous occurrence of MTC and PTC in the thyroid gland. Case 1 is unique for different reasons: (a) the patient was affected by both multicentric MTC and PTC; (b) a "composite thyroid carcinoma" with mixed feautures of MTC and PTC carcinomas was found in the istmus of the gland; and (c) these tumors were associated with diffuse lymphocytic-type thyroiditis (LT). Case 2 is notable for the long follow up: 16 years disease free.</p> <p>Conclusion</p> <p>There are only 16 reports in the English medical literature describing a total of 20 cases of concurrent occurrence of both PTC and MTC in the same thyroid gland. We discuss whether the finding of another cancer in these patients was coincidental or from possible activation of a common tumorigenic pathway for both follicular and parafollicular thyroid cells.</p

Regulatory T cells in the pathogenesis of graves' disease

Maintaining a delicate balance between the prompt immune response to pathogens and tolerance towards self-antigens and commensals is crucial for health. T regulatory (Treg) cells are pivotal in preserving self-tolerance, serving as negative regulators of inflammation through the secretion of anti-inflammatory cytokines, interleukin-2 neutralization, and direct suppression of effector T cells. Graves' disease (GD) is a thyroid-specific autoimmune disorder primarily attributed to the breakdown of tolerance to the thyroid-stimulating hormone receptor. Given the limitations of currently available GD treatments, identifying potential pathogenetic factors for pharmacological targeting is of paramount importance. Both functional impairment and frequency reduction of Tregs seem likely in GD pathogenesis. Genome-wide association studies in GD have identified polymorphisms of genes involved in Tregs' functions, such as CD25 (interleukin 2 receptor), and Forkhead box protein P3 (FOXP3). Clinical studies have reported both functional impairment and a reduction in Treg frequency or suppressive actions in GD, although their precise involvement remains a subject of debate. This review begins with an overview of Treg phenotype and functions, subsequently delves into the pathophysiology of GD and into the existing literature concerning the role of Tregs and the balance between Tregs and T helper 17 cells in GD, and finally explores the ongoing studies on target therapies for GD

Simultaneous medullary and papillary thyroid cancer: two case reports

<p>Abstract</p> <p>Background</p> <p>Papillary thyroid carcinoma (PTC) and medullary thyroid carcinoma (MTC) have always been considered different from each other; in their incidence, their cell origin and their histopathological features.</p> <p>Case presentation</p> <p>This paper describes two rare cases of the simultaneous occurrence of MTC and PTC in the thyroid gland. Case 1 is unique for different reasons: (a) the patient was affected by both multicentric MTC and PTC; (b) a "composite thyroid carcinoma" with mixed feautures of MTC and PTC carcinomas was found in the istmus of the gland; and (c) these tumors were associated with diffuse lymphocytic-type thyroiditis (LT). Case 2 is notable for the long follow up: 16 years disease free.</p> <p>Conclusion</p> <p>There are only 16 reports in the English medical literature describing a total of 20 cases of concurrent occurrence of both PTC and MTC in the same thyroid gland. We discuss whether the finding of another cancer in these patients was coincidental or from possible activation of a common tumorigenic pathway for both follicular and parafollicular thyroid cells.</p

Amiodarone and the thyroid

Lek antyarytmiczny — amiodaron, pochodna benzofuranu bogata w jod, wywołuje zaburzenia funkcji tarczycy w 15–20% przypadków. Amiodaron może powodować niedoczynność tarczycy (AIH) oraz nadczynność tarczycy (AIT). AIH jest leczona substytucyjnie lewotyroksyną, w jej przypadku nie jest konieczne odstawienie amiodaronu. Nadczynność tarczycy indukowaną amiodaronem dzielimy na dwa typy: typ 1 — nadczynność tarczycy związana z nadmierną produkcją hormonów tarczycowych, oraz typ 2, w której dominuje proces zapalenia tarczycy związanego z rozpadem gruczołu. Wyróżnia się również typ mieszany/nieokreślony, w którego patomechanizmie udział biorą oba powyżej opisane mechanizmy. Typ 1 AIT występuje zwykle na podłożu wcześniej występującej choroby tarczycy, zaś typ 2 w pierwotnie zdrowym gruczole tarczowym. Tionamidy są lekiem pierwszego rzutu w leczeniu typu 1 AIT, nadchloran sodowy/potasowy poprzez hamowanie wychwytu jodu może zwiększać odpowiedź na tionamidy. AIT typu 2 jest leczone głównie z zastosowaniem glikokortykosteroidów. Odpowiedź na leczenie zależy od wielkości gruczołu tarczowego i ciężkości tyreotoksykozy. Postaci mieszane mogą wymagać zastosowania złożonej terapii z użyciem tionamidów, nadchloranu sodowego/potasowego oraz steroidów. Leczenie radiojodem często jest niemożliwe z powodu zmniejszonego wychwytu jodu u pacjentów wcześniej leczonych amiodaronem. Zabieg usunięcia tarczycy jest bardzo pomocną formą leczenia nadczynności tarczycy indukowanej jodem, szczególnie w przypadkach opornych na leczenie farmakologiczne. Tyroidektomia wykonana przez doświadczony zespół chirurgów może być szczególnie pomocna u chorych z poważnymi zaburzeniami w układzie sercowo-naczyniowym. (Endokrynol Pol 2015; 66 (2): 176–196)Amiodarone, a benzofuranic iodine-rich antiarrhythmic drug, causes thyroid dysfunction in 15–20% of cases. Amiodarone can cause both hypothyroidism (AIH, amiodarone-induced hypothyroidism) and thyrotoxicosis (AIT, amiodarone-induced thyrotoxicosis). AIH is treated by L-thyroxin replacement and does not need amiodarone discontinuation. There are two main forms of AIT: type 1, a form of true iodineinduced hyperthyroidism; and type 2, a drug-induced destructive thyroiditis. However, mixed/indefinite forms exist, contributed to by both pathogenic mechanisms. Type 1 AIT usually occurs in diseased thyroid glands, whereas type 2 AIT develops in substantially normal thyroid glands. Thioamides represent the first-line treatment for type 1 AIT, but iodine-replete glands are poorly responsive; sodium/potassium perchlorate, by inhibiting thyroidal iodine uptake, may increase the response to thioamides. Type 2 AIT is best treated by oral glucocorticoids. Response depends on thyroid volume and severity of thyrotoxicosis. Mixed/indefinite forms may require a combination of thioamides, potassium perchlorate, and steroids. Radioiodine treatment is usually not feasible because amiodarone-related iodine load decreases thyroidal radioiodine uptake. Thyroidectomy represents an important and helpful option in cases resistant to medical therapy. Surgery performed by a skilled surgeon may represent an emergent treatment in patients who have severe cardiac dysfunction. (Endokrynol Pol 2015; 66 (2): 176–196

Vitreous Substitutes: The Present and the Future

Vitreoretinal surgery has advanced in numerous directions during recent years. The removal of the vitreous body is one of the main characteristics of this surgical procedure. Several molecules have been tested in the past to fill the vitreous cavity and to mimic its functions. We here review the currently available vitreous substitutes, focusing on their molecular properties and functions, together with their adverse effects. Afterwards we describe the characteristics of the ideal vitreous substitute. The challenges facing every ophthalmology researcher are to reach a long-term intraocular permanence of vitreous substitute with total inertness of the molecule injected and the control of inflammatory reactions. We report new polymers with gelification characteristics and smart hydrogels representing the future of vitreoretinal surgery. Finally, we describe the current studies on vitreous regeneration and cell cultures to create new intraocular gels with optimal biocompatibility and rheological properties

The 2021 European group on graves’ orbitopathy (EUGOGO) clinical practice guidelines for the medical management of graves’ orbitopathy

Graves’ orbitopathy (GO) is the main extrathyroidal manifestation of Graves’ disease (GD). Choice of treatment should be based on the assessment of clinical activity and severity of GO. Early referral to specialized centers is fundamental for most patients with GO. Risk factors include smoking, thyroid dysfunction, high serum level of thyrotropin receptor antibodies, radioactive iodine (RAI) treatment, and hypercholesterolemia. In mild and active GO, control of risk factors, local treatments, and selenium (selenium-deficient areas) are usually sufficient; if RAI treatment is selected to manage GD, low-dose oral prednisone prophylaxis is needed, especially if risk factors coexist. For both active moderate-to-severe and sight-threatening GO, antithyroid drugs are preferred when managing Graves’ hyperthyroidism. In moderate-to-severe and active GO i.v. glucocorticoids are more effective and better tolerated than oral glucocorticoids. Based on current evidence and efficacy/safety profile, costs and reimbursement, drug availability, long-term effectiveness, and patient choice after extensive counseling, a combination of i.v. methylprednisolone and mycophenolate sodium is recommended as first-line treatment. A cumulative dose of 4.5 g of i.v. methylprednisolone in 12 weekly infusions is the optimal regimen. Alternatively, higher cumulative doses not exceeding 8 g can be used as monotherapy in most severe cases and constant/inconstant diplopia. Second-line treatments for moderate-to-severe and active GO include (a) the second course of i.v. methylprednisolone (7.5 g) subsequent to careful ophthalmic and biochemical evaluation, (b) oral prednisone/prednisolone combined with either cyclosporine or azathioprine; (c) orbital radiotherapy combined with oral or i.v. glucocorticoids, (d) teprotumumab; (e) rituximab and (f) tocilizumab. Sight-threatening GO is treated with several high single doses of i.v. methylprednisolone per week and, if unresponsive, with urgent orbital decompression. Rehabilitative surgery (orbital decompression, squint, and eyelid surgery) is indicated for inactive residual GO manifestations

Immunomodulatory role of vitamin D and selenium supplementation in newly diagnosed Graves’ disease patients during methimazole treatment

IntroductionMethimazole (MMI) represents the conventional therapeutic agent for Graves’ disease (GD) hyperthyroidism, but MMI efficacy is limited since it marginally affects the underlying autoimmune process. In a previous study, we randomly assigned 42 newly diagnosed GD patients with insufficient vitamin D (VitD) and selenium (Se) levels to treatment with MMI alone (standard) or combined with selenomethionine and cholecalciferol (intervention) and observed a prompter resolution of hyperthyroidism in the intervention group.MethodsIn the present study, we aimed to explore changes in peripheral T regulatory (Treg) and circulating natural killer (NK) cell frequency, circulating NK cell subset distribution and function, during treatment.ResultsAt baseline, circulating total CD3-CD56+NK cells and CD56bright NK cells were significantly higher in GD patients than in healthy controls (HC) (15.7 ± 9.6% vs 9.9 ± 5.6%, p=0.001; 12.2 ± 10.3% vs 7.3 ± 4.1%, p=0.02, respectively); no differences emerged in Treg cell frequency. Frequencies of total NK cells and CD56bright NK cells expressing the activation marker CD69 were significantly higher in GD patients than in HC, while total NK cells and CD56dim NK cells expressing CD161 (inhibitory receptor) were significantly lower. When co-cultured with the K562 target cell, NK cells from GD patients had a significantly lower degranulation ability compared to HC (p&lt;0.001). Following 6 months of treatment, NK cells decreased in both the intervention and MMI-alone groups, but significantly more in the intervention group (total NK: -10.3%, CI 95% -15.8; -4.8% vs -3.6%, CI 95% -9; 1.8%, p=0.09 and CD56bright NK cells: -6.5%, CI 95% -10.1; -3 vs -0.9%, CI 95% -4.4; 2%, p=0.03). Compared to baseline, CD69+ NK cells significantly decreased, while degranulation ability slightly improved, although no differences emerged between the two treatment groups. Compared to baseline, Treg cell frequency increased exclusively in the intervention group (+1.1%, CI 95% 0.4; 1.7%).DiscussionThis pilot study suggested that VitD and Se supplementation, in GD patients receiving MMI treatment, modulates Treg and NK cell frequency, favoring a more pronounced reduction of NK cells and the increase of Treg cells, compared to MMI alone. Even if further studies are needed, it is possible to speculate that this immunomodulatory action might have facilitated the prompter and better control of hyperthyroidism in the supplemented group observed in the previous study