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Clinical Trial Summary

Hypothyroidism is a thyroid disorder and one of the most common endocrine disorders. Hypothyroidism can have multiple causes; most patients suffer from primary autoimmune hypothyroidism (Hashimoto's disease), but also central hypothyroidism, hypothyroidism after total thyroidectomy due to thyroid carcinoma, or hypothyroidism due to therapy of Graves' disease occur. Most patients with hypothyroidism are treated with levothyroxine (L-T4) to supplement the lack of thyroxine (T4) produced by their own thyroid. Serum thyroid-stimulating hormone (TSH) and/or free T4 (fT4) are currently measured to assess the efficacy of this therapy and to establish euthyroidism. It is known that fT4 concentrations in patients using L-T4 can be above the upper limit of the reference interval, while their TSH is not (completely) suppressed. This raises the question whether fT4 is an accurate reflection of thyroid hormone status in patients using L-T4. TSH is considered a reliable parameter of thyroid hormone status; however, TSH cannot be used to assess thyroid function in specific hypothyroid patient groups (e.g. central hypothyroidism). Free triiodothyronine (fT3), the active thyroid hormone, has been suggested to be an interesting alternative of fT4 to assess thyroid function. Previously, the methods to measure fT3 were not that robust; however, methods to determine fT3 have been improved, are currently reliable and not susceptible to changes due to L-T4 intake. In addition, the fT3/fT4 ratio is thought to be an interesting candidate in assessing thyroid hormone status as well. The aim of this study is to improve laboratory diagnostics of thyroid hormone status in patients with hypothyroidism receiving L-T4 in whom TSH cannot be used as a reflection of thyroid hormone status. We will primarily investigate the additional already available laboratory tests fT3 and fT3/fT4 ratio. We hypothesize that treated hypothyroid participants who are assumed euthyroid based on TSH (e.g. patients with Hashimoto's hypothyroidism) but have fT4 concentrations above the upper reference limit will more often have a fT3 level or a fT3/fT4 ratio within the reference interval. Concentrations of alternative markers in healthy controls and patients with Hashimoto's hypothyroidism with 'normal' TSH concentrations can, thus, be used to predict thyroid hormone status in patients using L-T4 in whom TSH cannot be used to assess thyroid hormone status.


Clinical Trial Description

Hypothyroidism is a thyroid disorder and one of the most common endocrine disorders. Hypothyroid patients have a thyroid hormone deficiency characterized by a shortage of thyroid hormone (TH) in the circulation and at the organ level and are normally treated with a synthetic form of thyroid hormone (L-T4 or levothyroxine). Thyroxine (T4) is a prohormone, produced by the thyroid gland and converted into the active hormone triiodothyronine (T3) in peripheral tissues. A minor percentage (20%) of circulating T3 is directly produced by the thyroid gland. Although L-T4 treatment accounts for all patients with hypothyroidism, the pathogenesis of hypothyroidism differs. Most patients suffer from primary hypothyroidism (Hashimoto's disease), which is an auto-immune disorder, but also central hypothyroidism, hypothyroidism after total thyroidectomy due to thyroid carcinoma or hypothyroidism due to therapy of Graves' disease are commonly seen. Currently, thyroid-stimulating hormone (TSH) and/or free T4 (fT4) are measured in serum to monitor the treatment efficacy of L-T4. TSH is produced by the pituitary to stimulate the production of thyroid hormones by the thyroid gland and due to the negative feedback loop considered as a good reflection of thyroid hormone status. Target concentrations of TSH and fT4 differ depending on the cause of hypothyroidism. In patients with Hashimoto's hypothyroidism, TSH concentrations are measured to monitor treatment and TSH levels within the reference intervals are pursued. TSH is measured to monitor treatment in patients with hypothyroidism after total thyroidectomy due to thyroid carcinoma as well, although a suppressed TSH is warranted in this group. The extent of TSH suppression is determined based on the type and stage of the carcinoma. In patients who are hypothyroid due to therapy of Graves' disease, other target values apply. Patients who are just diagnosed with Graves' disease start with thyroid suppressive therapy together with thyroid hormone supplementation (L-T4) and show a prolonged suppressed TSH; therefore, fT4 is initially used to monitor therapy. TSH is used to monitor treatment again when TSH starts to normalize. Nevertheless, TSH shall always be slightly suppressed due to the TSH receptor antibodies produced during Graves' disease, which means fT4 concentration is still taken into account during follow-up. Finally, it is not possible to monitor treatment by using TSH concentrations in patients with central hypothyroidism, which means fT4 concentrations are leading in this group. In conclusion, TSH cannot always be used to assess thyroid function in which cases fT4 is assessed as well. It is known that patients using L-T4 can show a combination of fT4 values above the upper reference limit and non-suppressed or only slightly suppressed TSH levels. The most likely explanation for this is twofold. First, thyroid hormones are supplemented by L-T4, which only replaces T4, whereas the production of the active thyroid hormone T3 by the thyroid gland is lacking and the patients depend on peripheral conversion of T4. Literature showed that these patients need a higher L-T4 dosage to obtain a normal, or even somewhat lower, concentration of T3. TSH is regulated by changes in T3 rather than T4, clarifying the lack of pituitary feedback to increased fT4 concentrations if fT3 concentrations are not increased simultaneously. Second, previous studies showed that fT4 levels peak two until four hours after L-T4 intake and gradually decline until the next dosage is taken. Sometimes, this peak increases above the upper limit of the reference interval. This pattern is not seen for TSH levels. Looking at aforementioned outcomes, it seems that fT4 levels are higher in patients using L-T4 compared to healthy controls, thus not reflecting thyroid hormone status adequately. In clinical practice, the largest group of hypothyroid patients are monitored by measuring TSH as mentioned above. Therefore, these high fT4 levels will only rarely cause problems. However, these high fT4 levels can have treatment consequences in patient groups wherein therapy is monitored via fT4 levels (e.g. central hypothyroidism), which could lead to unwarranted dose adjustments (leading to a too low dose of L-T4). Free T3 (fT3) concentrations can be measured but are used only rarely in clinical practice. Previously, the fT3 measurement using immunoassay techniques was troublesome and, therefore, considered as unreliable. However, the quality of the currently used immunoassay has been substantially improved resulting in the availability of reliable fT3 immunoassays. Furthermore, in contrast to fT4, fT3 is not subject to change after L-T4 intake. Consequently, fT3 might be an interesting parameter to assess thyroid hormone status in L-T4 users along with TSH. In addition, literature suggested that the ratio between fT3 and fT4 might be worthwhile investigating as an indicator of peripheral conversion. The fT3/fT4 ratio is thought to be lower in L-T4 users compared to euthyroid controls and could, therefore, be used to evaluate to what extent T4 is converted to T3. A decline might represent insufficient availability of thyroid hormone throughout the body. Thyroid hormone markers as total T4 (TT4) and total T3 (TT3) were used as thyroid hormone parameters before the free fractions of both thyroid hormones (fT4 and fT3) could be used. They lost ground as traditional thyroid hormone biomarkers but still provide relevant information about general thyroid hormone status. Degradation of T4 results in the formation of reversed T3 (rT3). This thyroid hormone biomarker can be measured in serum and has already proven to be of significance in the diagnosis of non-thyroidal illness syndrome (NTIS). However, it might also be useful as biomarker in patients using L-T4. Furthermore, several biomarkers have been proposed to evaluate tissue thyroid hormone status and to provide a better insight into thyroid hormone status in peripheral tissues, such as sex-hormone binding globulin (SHBG), acylcarnitines and several amino acids. Although these biomarkers are not directly proposed as better suitable biomarkers than fT4 in patients using L-T4, it will be interesting to assess their contribution and relevance in this specific patient group. Deiodinases (DIO1, DIO2 and DIO3) greatly contribute to the conversion of inactive T4 to active T3 and to the degradation of thyroid hormones. DIO polymorphisms are common in the general population and might influence the treatment efficacy of certain patients using L-T4 and could, thus, be interesting to take into account. As previously mentioned, some biomarkers indicating thyroid hormone status show a shifted normal distribution compared to healthy controls. To assess to what extent other biomarkers contribute to indicate thyroid status, it is necessary to know what the normal distributions of these biomarkers are in the healthy population. After that, results in patient groups using L-T4 can be assessed and compared to results of healthy controls. Therefore, healthy controls must be included to obtain valid results. The aim of this study is to investigate whether a variety of additional markers can improve laboratory diagnostics in patients with hypothyroidism receiving L-T4 in whom TSH cannot be used as a reflection of thyroid hormone status (e.g. central hypothyroidism). Alternatives could be fT3 and the derived fT3/fT4 ratio but TT4, TT3, rT3, SHBG, acylcarnitines and several amino acids might be interesting parameters as well. We hypothesize that treated hypothyroid participants who are assumed euthyroid based on TSH (e.g. patients with Hashimoto's hypothyroidism) but have fT4 concentrations above the upper reference limit will more often have a fT3 level or a fT3/fT4 ratio within the reference interval. TSH is considered to reflect thyroid hormone status reliably. Concentrations of alternative markers in healthy controls and patients with Hashimoto's hypothyroidism with 'normal' TSH concentrations can, thus, be used to predict thyroid hormone status in patients using L-T4 in whom TSH cannot be used to assess thyroid hormone status. Therefore, outcomes of this study will particularly benefit the follow-up of patients with central hypothyroidism in whom TSH cannot be used to monitor thyroid hormone status. After informed consent is provided, participation to the study entails a single blood draw (3 tubes, 20 mL) and a single questionnaire (ThyPRO-39), the study is thus of cross-sectional design. Blood draw from hypothyroid patients using L-T4 is performed at the same time as regular blood draw. Therefore, no extra blood draw is necessary. Healthy controls will undergo one blood withdrawal. All data are stored pseudo-anonymously. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT06083636
Study type Observational
Source Academisch Medisch Centrum - Universiteit van Amsterdam (AMC-UvA)
Contact Heijboer
Phone +31205665940
Email a.heijboer@amsterdamumc.nl
Status Recruiting
Phase
Start date July 26, 2022
Completion date June 2025

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