Thyroid's secretory capacity
Thyroid's secretory capacity | |
---|---|
Synonyms | SPINA-GT, GT, T4 output, thyroid hormone output, thyroid's incretory capacity, functional thyroid capacity[1] |
Reference range | 1.41–8.67 pmol/s |
Test of | Maximum amount of T4 produced by the thyroid in one second |
MeSH | D013960 |
LOINC | 82368-2 |
Thyroid's secretory capacity (GT, also referred to as thyroid's incretory capacity, maximum thyroid hormone output, T4 output or, if calculated from serum levels of thyrotropin and thyroxine, as SPINA-GT[a]) is the maximum stimulated amount of thyroxine that the thyroid can produce in a given time-unit (e.g. one second).[2][3]
How to determine GT
Experimentally, GT can be determined by stimulating the thyroid with a high thyrotropin concentration (e.g. by means of rhTSH, i.e. recombinant human thyrotropin) and measuring its output in terms of T4 production, or by measuring the serum concentration of protein-bound iodine-131 after administration of radioiodine.[4] These approaches are, however, costly and accompanied by significant exposure to radiation.[5]
In vivo, GT can also be estimated from equilibrium levels of TSH and T4 or free T4. In this case it is calculated with
or
[TSH]: Serum thyrotropin concentration (in mIU/L or μIU/mL)
[FT4]: Serum free T4 concentration (in pmol/L)
[TT4]: Serum total T4 concentration (in nmol/L)
: Theoretical (apparent) secretory capacity (SPINA-GT)
: Dilution factor for T4 (reciprocal of apparent volume of distribution, 0.1 L−1)
: Clearance exponent for T4 (1.1e-6 sec−1), i. e., reaction rate constant for degradation
K41: Binding constant T4-TBG (2e10 L/mol)
K42: Binding constant T4-TBPA (2e8 L/mol)
DT: EC50 for TSH (2.75 mU/L)[2][6]
The method is based on mathematical models of thyroid homeostasis.[2][3] Calculating the secretory capacity with one of these equations is an inverse problem. Therefore, certain conditions (e.g. stationarity) have to be fulfilled to deliver a reliable result.
Specific secretory capacity
The ratio of SPINA-GT and thyroid volume VT (as determined e.g. by ultrasonography)
,
i.e.
or
is referred to as specific thyroid capacity (SPINA-GTs).[7] It is a measure for how much one millilitre of thyroid tissue can produce under conditions of maximum stimulation. Thereby, SPINA-GTs is an estimate for the endocrine quality of thyroid tissue.[citation needed]
Reference Range
Lower limit | Upper limit | Unit |
1.41[2] | 8.67[2] | pmol/s |
The equations and their parameters are calibrated for adult humans with a body mass of 70 kg and a plasma volume of ca. 2.5 L.[2]
Clinical significance
Validity
SPINA-GT is elevated in primary hyperthyroidism[8][9] and reduced in both primary hypothyroidism[10][11][12][9] and untreated autoimmune thyroiditis.[13] It has been observed to correlate (with positive direction) to resting energy expenditure,[14] resting heart rate,[15] the colour Doppler ultrasound pattern[16] and thyroid volume,[2][7] and (with negative direction) to thyroid autoantibody titres, which reflect organ destruction due to autoimmunity.[17] Elevated SPINA-GT in Graves' disease is reversible with antithyroid treatment.[14] While SPINA-GT is significantly altered in primary thyroid disorders, it is insensitive to disorders of secondary nature (e.g. pure pituitary diseases).[3]
Reliability
In silico experiments with Monte Carlo simulations demonstrated that both SPINA-GT and SPINA-GD can be estimated with sufficient reliability, even if laboratory assays have limited accuracy.[3] This was confirmed by longitudinal in vivo studies that showed that GT has lower intraindividual variation (i.e. higher reliability) than TSH, FT4 or FT3.[18]
Clinical utility
In clinical trials SPINA-GT was significantly elevated in patients with Graves' disease and toxic adenoma compared to normal subjects.[2][8] It is also elevated in diffuse and nodular goiters, and reduced in untreated autoimmune thyroiditis.[2][13] In patients with toxic adenoma it has higher specificity and positive likelihood ratio for diagnosis of thyrotoxicosis than serum concentrations of thyrotropin, free T4 or free T3.[2] GT's specificity is also high in thyroid disorders of secondary or tertiary origin.[3]
Calculating SPINA-GT has proved to be useful in challenging clinical situations, e.g. for differential diagnosis of subclinical hypothyroidism and elevated TSH concentration due to type 2 allostatic load (as it is typical for obesity and certain psychiatric diseases). For this purpose, its usage has been recommended in sociomedical assessment.[19]
Pathophysiological and therapeutic implications
Correlation of SPINA-GT with creatinine clearance suggests a negative influence of uremic toxins on thyroid biology.[20][21] In the initial phase of major non-thyroidal illness syndrome (NTIS) SPINA-GT may be temporarily elevated.[22][23] In chronic NTIS[24] as well as in certain non-critical chronic diseases, e.g. chronic fatigue syndrome[25][26] or asthma[27] SPINA-GT is slightly reduced.
According to the results of a community-based study in China it was associated to sleep duration and exercise habits.[28] With respect to iodine supply, it showed a complex U-shaped pattern, being reduced in subjects consuming iodine-rich food, but elevated in situations of iodine excess.[28] In two other studies from China, SPINA-GT correlated with negative direction to markers of obesity including body mass index, waist circumference and waist to hip ratio.[29][30] This doesn't seem to be the case, however, in Western populations.[31]
In women, therapy with Metformin results in increased SPINA-GT, in parallel to improved insulin sensitivity.[32] This observation was reproducible in men with hypogonadism, but not in men with normal testosterone concentrations,.[33] In postmenopausal women this effect was only observed in subjects on oestradiol replacement therapy.[34] Therefore, the described phenomenon seems to depend on an interaction of metformin with sex hormones.[33][35] In hyperthyroid[8] men both SPINA-GT and SPINA-GD negatively correlate to erectile function, intercourse satisfaction, orgasmic function and sexual desire. Likewise, in women with thyrotoxicosis elevated thyroid's secretory capacity predicts depression and sexual dysfunction.[36] Conversely, in androgen-deficient men with concomitant autoimmune thyroiditis, substitution therapy with testosterone leads to a decrease in thyroid autoantibody titres and an increase in SPINA-GT.[37]
In patients with autoimmune thyroiditis a gluten-free diet results in increased SPINA-GT (in parallel to sinking autoantibody titres).[38] Statin therapy has the same effect, but only if supply with vitamin D is sufficient.[39] Accordingly, substitution therapy with 25-hydroxyvitamin D leads to rising secretory capacity.[40][41][42][43] This effect is potentiated by substitution therapy with myo-inositol[44] and selenomethionine[40][41][45] or, in women, with dehydroepiandrosterone,[46] but impaired in males with early-onset androgenic alopecia.[47] The effects of vitamin D and selenomethionine are attenuated in hyperprolactinaemia, suggesting an inhibitory effect of prolactin.[48] Although both vitamin D supplementation and gluten-free diet result in increased SPINA-GT, there seems to be a complex interaction between both therapeutic measures, since vitamin D treatment is only able to elevate the thyroid's secretory capacity in subjects not following any dietary recommendation.[49]
On the other hand, men treated with spironolactone are faced with decreasing SPINA-GT (in addition to rising thyroid antibody titres).[50] It has, therefore, been concluded that spironolactone may aggravate thyroid autoimmunity in men.[50]
In subjects with type 2 diabetes, treatment with beta blockers resulted in decreased SPINA-GT, suggesting sympathetic innervation to contribute to the control of thyroid function.[51] In diabetic women, but not in men, SPINA-GT shows a positive correlation to the β-C-terminal cross-linked telopeptides of type I collagen (β-CTX), a marker of bone resorption.[52] In both diabetic and non-diabetic persons it correlates (negatively) with age and (positively) with the concentrations of troponin T and HbA1c.[53]
A study in euthyroid subjects with structural heart disease found that increased SPINA-GT predicts the risk of malignant arrhythmia including ventricular fibrillation and ventricular tachycardia.[54] This applies to both incidence and event-free survival.[54] Likewise, SPINA-GT is elevated in a significant subgroup of patients with takotsubo syndrome.[55] On the other hand, two studies found negative correlation between SPINA-GT and markers of dispersion in cardiac repolarisation, including Tp-e interval, JT interval, Tp-e/ QT ratio and Tp-e/QTc ratio. These results suggest that reduced thyroid function may trigger cardiovascular mortality as well.[56][9]
Among subjects with Parkinson's disease, SPINA-GT is significantly elevated in tremor-dominant and mixed subtypes compared to the akinetic-rigid type.[57]
Specific secretory capacity (SPINA-GTs) is reduced in obesity[2] and autoimmune thyroiditis.[7][58]
Endocrine disruptors may affect stimulated thyroid output, as demonstrated by a positive correlation of SPINA-GT with exposure to 2-hydroxynaphthalene (2-NAP),[59] urinary mercury concentration[60] and the excretion of certain phthalate metabolites,[61] and negative correlation with combined exposure to polycyclic aromatic hydrocarbons (PAHs)[59] and nickel.[62]
See also
- Thyroid function tests
- Sum activity of peripheral deiodinases
- Jostel's TSH index
- Thyrotroph Thyroid Hormone Sensitivity Index
- Thyroid Feedback Quantile-based Index
- SimThyr
- SPINA-GBeta
- SPINA-GR
Notes
- ^ SPINA is an acronym for "structure parameter inference approach".
References
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External links
- SPINA Thyr: Open source software for calculating GT and GD
- Package "SPINA" for the statistical environment R