Planning and diagnostic nursing strategy in the clinical management of the patient with hyperthroidism

Hyperthyroidism is a common disease that affects 0.8% of the population in Europe. It occurs when the thyroid gland produces more thyroid hormones than your body needs. There are several types of treatment, such as antithyroid drugs, treatment with radioactive iodine (131I) and finally surgery, in addition to these treatments, reference is made to a good hygienic-dietary orientation. Objective: to assess from the nursing field the safest and most effective type of hyperthyroidism treatment, including the risk factors to take into account when carrying out these. Methodology: systematic searches were carried out in bibliographic sources of trials and articles published between 2015 and 2021. Including studies that contained data on risk factors for hyperthyroidism. Results: of 426 related articles found, 13 met the inclusion criteria. Total thyroidectomy surgery induced a 26% therapeutic failure rate and 95% radioactive iodine treatment compared to the 19.1% therapeutic failure in antithyroid drug treatment. Conclusion: Despite the verification of the efficacy of all existing hyperthyroidism treatments, antithyroid drugs have greater efficacy and safety than the rest of the treatments studied, in relation to the time and rate of remission. On the other hand, risk factors such as tobacco and female sex are evidenced, which are negative factors when carrying out treatment for hyperthyroidism.

2022 European Thyroid Association Guideline for the management of pediatric Graves’ disease

Hyperthyroidism caused by Graves’ disease (GD) is a relatively rare disease in children. Treatment options are the same as in adults – antithyroid drugs (ATD), radioactive iodine (RAI) or thyroid surgery, but the risks and benefits of each modality are different. The European Thyroid Association guideline provides new recommendations for the management of pediatric GD with and without orbitopathy. Clinicians should be alert that GD may present with behavioral changes or declining academic performance in children. Measurement of serum TSH receptor antibodies is recommended for all pediatric patients with hyperthyroidism. Management recommendations include the first-line use of a prolonged course of methimazole/carbimazole ATD treatment (3 years or more), a preference for dose titration instead of block and replace ATD, and to avoid propylthiouracil use. Where definitive treatment is required either total thyroidectomy or RAI is recommended, aiming for complete thyroid ablation with a personalized RAI activity. We recommend avoiding RAI in children under 10 years of age but favor surgery in patients with large goiter. Pediatric endocrinologists should be involved in all cases.

Weight Gain after Treatment of Thyroid Dysfunction and Thyroid Surgery

Thyroid surgery is generally recommended for malignant conditions and for some benign thyroid disorders. Many patients report weight gain after thyroidectomy especially during the first months following surgery. Studies on patients with Graves’ disease treated either with antithyroid drugs or radioiodine confirm that these patients frequently gain weight after restoration of thyroid function. Other studies have also shown that there is considerable weight gain after thyroidectomy for both nodular goiter and thyroid cancer. Transient hypothyroidism during the postoperative period is often thought to be associated with weight gain after thyroidectomy. The role of a number of adipocytokines and their interaction with the thyroid function has been investigated in the pathogenesis of weight changes. Levothyroxine replacement or suppressive therapy after thyroidectomy has a different impact on the metabolic parameters independent of TSH levels. The long-term effects of the impaired T3/T4 ratio are not fully understood as there are no sensitive markers to assess the biological response of target organs and tissues. Future studies are needed to identify such parameters, provide new considerations for the treatment of patients after total thyroidectomy, and help determine individual target hormone levels to ensure a sustained euthyroid state.

The Differential Effects of Propylthiouracil and Methimazole as Graves’ Disease Treatment on Vascular Atherosclerosis Markers: A Randomized Clinical Trial

BackgroundHyperthyroidism is related to vascular atherosclerosis. Propylthiouracil (PTU) and methimazole, other than their antithyroid effects, may have different mechanisms in preventing atherogenesis in Graves’ disease.ObjectiveThis study aimed to investigate the effect of antithyroid drugs on markers of vascular atherosclerosis in Graves’ hyperthyroidism.MethodsThis study was a single-blind, randomized clinical trial conducted on 36 patients with Graves’ disease in Cipto Mangunkusumo General Hospital, Jakarta, Indonesia, from June 2019 until July 2020. Graves’ disease was diagnosed from clinical manifestation of hyperthyroidism with diffuse goiter and then confirmed by thyroid stimulation hormone (TSH), free T4 (fT4), and TSH-receptor antibody (TRAb) measurements. Participants were randomly assigned to either a PTU or a methimazole treatment group and followed up for 3 months. Markers of vascular atherosclerosis were represented by adhesion molecules [intercellular adhesion molecule-1 (ICAM-1), vascular cell adhesion molecule-1 (VCAM-1), and E-selectin], carotid artery stiffness [pulse wave velocity (PWV)], and thickness [carotid intima media thickness (cIMT)].ResultsBy the end of the study, 24 participants reached euthyroid condition (13 from the PTU group and 11 from the methimazole group). After 3 months of follow-up, in the PTU group, we noticed an improvement of ICAM-1 [pretreatment: 204.1 (61.3) vs. posttreatment: 141.6 (58.4) ng/ml; p = 0.001], VCAM-1 [837 (707–977) vs. 510 (402–630) ng/ml; p < 0.001] and E-selectin [32.1 (24.1–42.7) vs. 28.2 (21.6–36.8) ng/ml; p = 0.045] in the PTU group. In the methimazole group, only VCAM-1 improvement [725 (565–904) vs. 472 (367–590); p = 0.001] was observed. Meanwhile, we found no significant changes in PWV or cIMT in either group.ConclusionAntithyroid treatment in Graves’ disease leads to improvement in adhesion molecules, with a lesser effect on methimazole, whereas there were no significant changes in PWV or cIMT. PTU may have a better mechanism compared with methimazole in terms of improving adhesion molecules.

Ipertiroidismo e tiroidite autoimmune in età evolutiva

Hyperthyroidism is a rare clinical entity in paediatric age. In most cases the etiology is autoimmune and goiter represents the typical presentation. Ophthalmopathy is rare and can precede the diagnosis of autoimmune hyperthyroidism. Thyrotoxicosis caused by the hyperthyroid phase of Hashimoto’s thyroiditis must be carefully distinguished from Graves’ disease (GD), since the first condition has a better prognosis for spontaneous remission. Three treatment options are currently available for the management of paediatric GD. First-line therapy is antithyroid drugs, while thyroidectomy and radioiodine are considered on relapse. A lower remission rate and a higher risk of adverse events are observed after the first course of methimazole in childhood with respect to adulthood. Children and adolescents may require a prolonged antithyroid treatment, but an overall consensus regarding the optimal regimen is lacking.

Aeromedical Decision Making for Military Aircrew with Graves’ Disease

BACKGROUND: Graves’ Disease (GD) is a common cause of hyperthyroidism. Although definitive treatment with radioactive iodine (RAI) is preferred for military aircrew, there are cultural and individual differences in receptivity toward RAI, and clinical guidelines that recommend antithyroid drugs (ATD) as the first line therapy. We examined a case series of Republic of Singapore Air Force (RSAF) aviators with GD treated with ATD and the impact of their condition on aeromedical disposition.CASE SERIES: All RSAF aircrew diagnosed with GD and treated with ATD over a 15-yr period were retrospectively identified and analyzed to determine the impact on their fitness for flying duties. The mean age of the 13 aircrew was 33 ± 7.1 yr (range, 25–47 yr), with 11 (84.6%) being males. There were 10 (76.9%) who had ATD as the only treatment while 3 (23.1%) were initially treated with ATD but subsequently underwent RAI or surgery. Of the 10 treated with only ATD, 3 (30.0%) were returned to restricted flying, 6 (60.0%) were returned to unrestricted flying, and 1 (10.0%) is still undergoing ATD titration. There were 10 (76.9%) aircrew who were returned to some form of flying duties while on low doses of ATD.DISCUSSION: This case series suggests that ATD is a viable treatment modality in the aeromedical management of military aviators with GD and it is possible to return military aircrew on a stable maintenance dose of ATD to flying duties. A framework is proposed to support the aeromedical decision-making process for military aircrew in the treatment of GD.Loh EH-T, Soh FW, See B, Tan BBC. Aeromedical decision making for military aircrew with Graves’ disease. Aerosp Med Hum Perform. 2021; 92(12):980–986.

Graves’ Disease

Graves’ disease (GD) is an autoimmune disorder characterized by presence of TSH receptor autoantibody. It is most common cause of hyperthyroidism worldwide. Though GD can occur any age but peak incidence is seen during adulthood in between 20 to 50 years of age. GD is more commonly seen in female. GD is primarily disease of thyroid gland but affects multi organ system i.e. heart, liver, muscle, eye and skin. Symptoms and signs are result from hyperthyroidism or a consequence of underlying autoimmunity. Weight loss, fatigue, heat intolerance, tremor, and palpitations are the most common symptoms. Diffuse goiter presents in most of younger patients with thyrotoxicosis but less common in older patients. Graves’ ophthalmopathy and pretibial myxedema are extrathyroidal manifestations of GD which results from action of TSHR autoantibodies on TSHR present onfibroblast, adipocyte and T cells in extrathyroidal tissue. Treatment of GD remains in between antithyroid drugs, radioiodine or surgery. In this review we discuss the diagnosis and management of GD.

Subacute thyroiditis post-Pfizer-BioNTech mRNA vaccination for COVID-19

Summary There is emerging evidence of an association between COVID-19 vaccination and subacute thyroiditis. We present the case of a 42-year-old female healthcare worker who was diagnosed with subacute thyroiditis 4 days after receiving her second dose of Pfizer-BioNTech vaccine. Her clinical course followed the classical pattern for thyroiditis with spontaneous return to euthyroidism at 6 months post-presentation. The autoimmune/inflammatory syndrome induced by adjuvants has been implicated as a cause of autoimmune conditions post-vaccination and is a potential mechanism for subacute thyroiditis in our case. Learning points Subacute thyroiditis should be considered in all patients who receive any kind of vaccine for COVID-19 and subsequently develop symptoms or signs of hyperthyroidism or neck pain. Subacute thyroiditis is a self-limiting condition, and recognising it is important as no specific thyroid treatment (antithyroid drugs or thyroid hormone replacement) is necessary for most patients. The autoimmune/inflammatory syndrome induced by adjuvants may be an under-recognised cause of endocrinopathies and should particularly be considered post-vaccination.

Graves’ Disease

Graves’ disease (GD) is an autoimmune thyroid disorder where autoantibodies are produced against TSH (Thyroid Stimulating Hormone) receptor causing thyrotoxicosis. It is characterized by goiter, ophthalmopathy, and occasionally pretibial myxedema. The autoimmune mechanism causing disease is not well understood and it is complex. It involves multifactorial etiology involving environmental and genetic factors. Smoking and positive family history contributing to the development of GD. GD can be diagnosed based on the clinical manifestation and demonstrating low concentration of TSHs, high TRab (Thyroid Stimulating Hormone receptor autoantibodies), and high FT4 (Free thyroxine) concentration. Current treatment options aimed at stable restoration of euthyroidism by following different modalities of suppressing thyroid gland using antithyroid drugs, removing/ablating thyroid gland by surgery, and radioactive iodine treatment with iodine- 131.