Thyroid Hormones

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References

Drug Evaluations Subscription. Chicago, IL: American Medical Association, Vol. II, Section 10, Chapter 2, Summer, 1993.

Adlin EV, Maurer AH, Marks AD, Channick BJ. Bone mineral density in postmenopausal women treated with L-thyroxine. Am J Med 1991 Mar;90(3):360-366.
Abstract: PURPOSE: To determine if bone mineral density is decreased in postmenopausal women treated with 1-thyroxine, and, if any decrease is observed, whether it is related to overtreatment with thyroid hormone, to deficiency of calcitonin, or to other factors. PATIENTS AND METHODS: The study consisted of 19 postmenopausal women between 50 and 75 years of age treated with 1-thyroxine for 5 years or longer, and 19 matching control subjects with no thyroid disease. Bone mineral density of the spine and hip was measured by dual-photon absorptiometry. Plasma calcitonin concentrations and serum thyroid hormone levels were determined by radioimmunoassays. RESULTS: The 1-thyroxine-treated women had lower bone density in the lumbar spine (1.013 g/cm2 [95% confidence interval, 0.945 to 1.081] versus 1.134 g/cm2 [1.026 to 1.242], p = 0.043); in the femoral neck (0.736 g/cm2 [0.694 to 0.778] versus 0.809 g/cm2 [0.747 to 0.872], p = 0.040); in Ward's triangle (0.576 g/cm2 [0.530 to 0.623] versus 0.694 g/cm2 [0.617 to 0.770], p = 0.011); and in the trochanteric area (0.626 g/cm2 [0.581 to 0.672] versus 0.722 g/cm2 [0.651 to 0.794], p = 0.027). The maximal increase in calcitonin following calcium infusion was 1.37 ng/L (95% confidence interval, -0.44 to 3.17) in the 1-thyroxine-treated patients versus 18.8 ng/L (95% confidence interval, 10.0 to 27.5) in normal women, p less than 0.001. The average dose of 1-thyroxine was 120 micrograms/day; 16 of the 19 patients had normal serum thyroxine levels. However, TSH levels were low in 13 of the 19, suggesting that 1-thyroxine treatment was supraphysiologic. Seven of the 19 patients had a history of hyperthyroidism in the distant past; these patients, considered separately, had significantly reduced bone density in the hip. The other 12 patients, considered separately, did not have a statistically significant loss of bone density. CONCLUSIONS: Long-term 1-thyroxine therapy is associated with decreased density of the spine and hip. Since subclinical hyperthyroidism, decreased calcitonin responsiveness, and a history of hyperthyroidism were demonstrated in some or all of these patients, these factors must be considered as possible causes of the decreased bone density.

Beard J, Borel M, Peterson FJ. Changes in iron status during weight loss with very-low-energy diets. Am J Clin Nutr 1997 Jul;66(1):104-110.
Abstract: For several decades, very-low-energy diets (VLEDs) have been used by obese individuals to achieve weight loss. During the weight loss, patients often have dramatic drops in circulating thyroid hormone concentrations and experience cold intolerance. Because poor iron status is known to alter thermogenesis, we investigated the possibility that iron intake interacts with energy intake during weight loss in obese individuals. The effects on indicators of iron and thyroid status of increasing the iron content of a VLED from 18 to 27 mg/d during 12 wk of a VLED were compared with the effects on the same indicators of increasing energy intake from 1752 kJ(420 kcal) to 3347 kJ(800 kcal)/d. Although all VLED groups initially had 30% declines in plasma transferrin saturation, increases in plasma ferritin concentrations, and decreases in plasma thyroid hormone concentrations, patients who received iron supplementation had significantly higher circulating concentrations of triiodothyronine and thyroxine at the end of the VLED than did patients who received only the recommended dietary allowance of iron. The patients who received iron supplementation also had a more rapid return of iron indicators to normal values over the course of the VLED. The transitory fall in iron delivery to bone marrow was not associated with anemia. These data suggest that higher thyroid hormone concentrations can be maintained during VLEDs that provide higher iron intakes.

Beard JL, Borel MJ, Derr J. Impaired thermoregulation and thyroid function in iron-deficiency anemia. Am J Clin Nutr 1990 Nov;52(5):813-819.
Abstract: Ten women with iron-deficiency anemia, 8 with depleted iron stores (nonanemic), and 12 control women, all of similar body fatness, were exposed to a 28 degrees C water bath to test the hypothesis that iron-deficiency anemia impairs thermoregulatory performance. The anemic women had lower rectal temperatures than did control women (36.0 +/- 0.2 vs 36.2 +/- 0.1 degree C, respectively, P = 0.001) and a lower rate of oxygen consumption (5.28 +/- 0.26 vs 5.99 +/- 0.29 mL.min-1.kg body wt-1, respectively, P = 0.04) at 100 min of cold exposure. Plasma thyroxine and triiodothyronine concentrations were significantly (P less than 0.002) lower in anemic than in control women at baseline and during cold exposure. Responses of iron-depleted subjects were similar to those of control subjects. Iron supplementation corrected the anemia, significantly (P = 0.03) improved rectal temperature at 100 min, and partially normalized plasma thyroid hormone concentrations. Plasma catecholamines were unaffected by iron status. This experiment demonstrates a functional consequence of iron-deficiency anemia in the balance of heat production and loss and suggests that thyroid-hormone metabolism may be responsible.

Beard JL, Brigham DE, Kelley SK, Green MH. Plasma thyroid hormone kinetics are altered in iron-deficient rats. J Nutr 1998 Aug;128(8):1401-1408.
Abstract: Iron deficiency anemia is associated with lower plasma thyroid hormone concentrations in rodents and, in some studies, in humans. The objective of this project was to determine if plasma triiodothyronine (T3) and thyroxine (T4) kinetics were affected by iron deficiency. Studies were done at a near-thermoneutral temperature (30 degrees C), and a cool environmental temperature (15 degrees C), to determine plasma T3 and T4 kinetics as a function of dietary iron intake and environmental need for the hormones. Weanling male Sprague-Dawley rats were fed either a low Fe diet [iron-deficient group (ID), <5 microg/g Fe] or a control diet [control group (CN), 35 microg/g Fe] at each temperature for 7 wk before the tracer kinetic studies. An additional ID group receiving exogenous thyroid hormone replacement was also used at the cooler temperature. For T4, the disposal rate was >60% lower (89 +/- 6 vs. 256 +/- 53 pmol/h, P < 0.001) in ID rats than in controls at 30 degrees C, and approximately 40% lower (192 +/- 27 vs. 372 +/- 26 pmol/h, P < 0.01) in ID rats at 15 degrees C. Exogenous T4 replacement in a cohort of ID rats at 15 degrees C normalized the T4 concentration and the disposal rate. For T3, the disposal rate was significantly lower in ID rats in a cool environment (92 +/- 11 vs. 129 +/- 11 pmol/h, P < 0.01); thyroxine replacement again normalized the T3 disposal rate (126 +/- 12 pmol/h). Neither liver nor brown fat thyroxine 5'-deiodinase activities were sufficiently different to explain the lower T3 disposal rates in iron deficiency. Thus, plasma thyroid hormone kinetics in iron deficiency anemia are corrected by simply providing more thyroxine. This suggests a central regulatory defect as the primary lesion and not peripheral alterations.

Campbell NR, Hasinoff BB, Stalts H, Rao B, Wong NC. Ferrous sulfate reduces thyroxine efficacy in patients with hypothyroidism. Ann Intern Med 1992 Dec 15;117(12):1010-1013.
Abstract: OBJECTIVE: To determine whether simultaneous ingestion of ferrous sulfate and thyroxine reduces the efficacy of thyroid hormone in patients with primary hypothyroidism. DESIGN: Uncontrolled clinical trial. SETTING: Outpatient research clinic of a tertiary care center. PATIENTS: Fourteen patients with established primary hypothyroidism on stable thyroxine replacement. INTERVENTION: All patients were instructed to ingest simultaneously, a 300-mg ferrous sulfate tablet and their usual thyroxine dose every day for 12 weeks. RESULTS: After 12 weeks of ferrous sulfate ingestion with thyroxine, the mean level of serum thyrotropin (thyroid stimulating hormone, TSH) rose from 1.6 +/- 0.4 to 5.4 +/- 2.8 mU/L (P < 0.01), but the free thyroxine index did not change significantly. Subjective evaluation using a clinical score showed that nine patients had an increase in symptoms and signs of hypothyroidism; the mean score for the 14 patients changed from 0 to 1.3 +/- 0.4 (P = 0.011). When iron and thyroxine were mixed together in vitro, a poorly soluble purple complex appeared that indicated the binding of iron to thyroxine. CONCLUSIONS: Simultaneous ingestion of ferrous sulfate and thyroxine causes a variable reduction in thyroxine efficacy that is clinically significant in some patients. The interaction is probably caused by the binding of iron to thyroxine.

Campbell NR, Hasinoff BB. Iron supplements: A common cause of drug interactions. Brit J Clin Pharmacol 1991 Mar;31(3):251-255. (Review)

Franklyn J, Betteridge J, Holder R, Daykin J, Lilley J, Sheppard M. Bone mineral density in thyroxine treated females with or without a previous history of thyrotoxicosis. Clin Endocrinol (Oxf) 1994 Oct;41(4):425-432.
Thyroxine therapy alone does not represent a significant risk factor for loss of bone mineral density but there is a risk of bone loss in post-menopausal (but not premenopausal) females with a previous history of thyrotoxicosis treated with radioiodine.
Abstract: OBJECTIVE: The results of studies examining the influence of T4 therapy upon bone mineral density (BMD) are conflicting. This conflict may, in part, reflect inclusion of patients with varying thyroid disorders. We have therefore examined the influence of preceding thyroid history and T4 therapy on BMD. DESIGN: Case-control studies of patients on long-term T4 therapy who have or have not previously received radioiodine treatment for thyrotoxicosis, as well as previously thyrotoxic patients who have not required T4 replacement. PATIENTS: Twenty-seven premenopausal and 60 postmenopausal females with a past history of thyrotoxicosis and subsequent T4 treated hypothyroidism (group 1), 39 post-menopausal females with a past history of radioiodine treated thyrotoxicosis not receiving T4 (group 2) and 22 post-menopausal females with primary hypothyroidism on T4 (group 3). Female controls individually matched to patients by age and menopausal status. MEASUREMENTS: BMD measured by dual-energy X-ray absorptiometry. Serum biochemistry and tests of thyroid function. RESULTS: No significant differences were found in femoral or lumbar spine BMD measurements between premenopausal patients and controls in group 1 or between group 2 patients and controls. Measurements of BMD at all sites were lower in post-menopausal patients in groups 1 and 2 than in controls; when allowance was made for differences in BMD due to body mass index by analysis of variance, significant reductions in femoral trochanter BMD (3.9%, P < 0.05) and lumbar spine (5.6-8.5%, P < 0.01) BMD results were found in post-menopausal females in group 1 and reductions in femoral trochanter (3.9%, P < 0.01), Ward's triangle (5.6%, P < 0.05) and lumbar spine (8.5%, P < 0.01) BMD results in group 2. Separate analysis of BMD results of those with normal or reduced serum TSH did not affect outcome. BMD measurements were not significantly correlated with duration of T4 therapy, T4 dose, or serum free T4 or TSH in any patient group. CONCLUSIONS: Thyroxine therapy alone does not represent a significant risk factor for loss of bone mineral density but there is a risk of bone loss in post-menopausal (but not premenopausal) females with a previous history of thyrotoxicosis treated with radioiodine.

Franklyn JA, Betteridge J, Daykin J, Holder R, Oates GD, Parle JV, Lilley J, Heath DA, Sheppard MC. Long-term thyroxine treatment and bone mineral density. Lancet 1992 Jul 4;340(8810):9-13.
Abstract: Studies of the effect of thyroxine replacement therapy on bone mineral density have given conflicting results; the reductions in bone mass reported by some have prompted recommendations that prescribed doses of thyroxine should be reduced. We have examined the effect of long-term thyroxine treatment in a large homogeneous group of patients; all had undergone thyroidectomy for differentiated thyroid cancer but had no history of other thyroid disorders. The 49 patients were matched with controls for age, sex, menopausal status, body mass index, smoking history, and calcium intake score; in all subjects bone mineral density at several femoral and vertebral sites was measured by dual-energy X-ray absorptiometry. Despite long-term thyroxine therapy (mean duration 7.9 [range 1-19] years) at doses (mean 191 [SD 50] micrograms/day) that resulted in higher serum thyroxine and lower serum thyrotropin concentrations than in the controls, the patients showed no evidence of lower bone mineral density than the controls at any site. Nor was bone mineral density correlated with dose, duration of therapy, or cumulative intake, or with tests of thyroid function. There was a decrease in bone density with age in both groups. We suggest that thyroxine alone does not have a significant effect on bone mineral density and hence on risk of osteoporotic fractures.

Greenspan SL, Greenspan FS, Resnick NM, Block JE, Friedlander AL, Genant HK. Skeletal integrity in premenopausal and postmenopausal women receiving long-term L-thyroxine therapy. Am J Med 1991 Jul;91(1):5-14.
Abstract: PURPOSE: The impact of long-term L-thyroxine replacement therapy on skeletal integrity is a growing concern because of the large number of women receiving thyroid hormone therapy. The purpose of this study was to examine the hypothesis that long-term L-thyroxine therapy in which the free thyroxine index (FT4I) is maintained within a physiologic range has minimal impact on vertebral or femoral bone mineral density in both premenopausal and postmenopausal women. PATIENTS AND METHODS: We measured hip integral and spinal trabecular and integral bone densities in 28 premenopausal and 28 postmenopausal women who had been receiving L-thyroxine therapy for a median of 12 and 15 years, respectively, and in whom therapy was titrated to keep the FT4I within the normal range. The relationship between bone density parameters and thyroid hormone status was examined using univariate and multivariate statistical methods. RESULTS: Seventy-nine percent of the premenopausal women and 86% of the postmenopausal women had FT4I values in the normal range at the time of bone density determination. Moreover, throughout the study's duration, the majority of annually measured values were in the normal range for more than 80% of subjects. Premenopausal women had slightly lower bone density than would be expected for age: -6.7% (z = -0.39 +/- 0.74 [mean +/- SD], p less than 0.01), -3.1% (z = -0.22 +/- 0.78, p = 0.15), and -5.1% (z = -0.36 +/- 0.74, p less than 0.02) for spinal trabecular, spinal integral, and hip integral bone density, respectively. Postmenopausal women likewise had slightly lower bone density values that were significant only at the hip: -0.2% (z = -0.01 +/- 1.01, p = 0.95), -1.0% (z = -0.05 +/- 1.11, p = 0.80), and -6.2% (z = -0.39 +/- 0.80, p less than 0.02) for spinal trabecular, spinal integral, and hip integral bone density, respectively. When patients with previously treated Graves' disease (n = 4 in each group) were eliminated, the differences in bone density at the hip were no longer seen. Correlation analysis revealed only weak and generally nonsignificant relationships between parameters of thyroid hormone status and bone density at any site in either subgroup. Results of multiple regression analysis among the pooled data of all subjects showed that age provided a consistently significant contribution (R2 = 0.18 to 0.66) to the variability in bone density at the spine and the hip, but parameters of thyroid hormone status did not. CONCLUSION: These data provide the first supportive evidence that long-term L-thyroxine therapy that maintains the FT4I in the physiologic range is associated with a statistically significant, but clinically minimal, decrement in spinal and hip bone density in both premenopausal and postmenopausal women. The decrement at the hip was entirely due to the inclusion of patients with treated Graves' diseases. Thus, the changes in bone density in women receiving long-term L-thyroxine therapy are minimal at most and should not be a contraindication to therapy.

Hanna FW, Pettit RJ, Ammari F, Evans WD, Sandeman D, Lazarus JH. Effect of replacement doses of thyroxine on bone mineral density. Clin Endocrinol (Oxf) 1998 Feb;48(2):229-234.
Abstract: INTRODUCTION: Hyperthyroidism is associated with a reduction in bone mineral density (BMD). Suppressive doses of thyroxine (T4), inducing subclinical hyperthyroidism, have been reported by some investigators to reduce BMD. Little work has been done on replacement doses of T4. AIM: The aim was to investigate the effect of replacement doses of T4 on BMD. STUDY DESIGN: Cross-sectional study of hypothyroid patients on long-term T4 replacement doses, comparing those who had primary hypothyroidism with those who were previously hyperthyroid. PATIENTS: Fifty women on replacement doses of T4 for more than 5 years were recruited. Twenty-five were treated for primary (group 1) and 25 for radioiodine-induced hypothyroidism (group 2). They were well matched for age, menstrual status, smoking history, body mass index (BMI), dose and duration of T4 replacement as well as thyroid status. MEASUREMENTS: BMD was assessed by dual energy X-ray absorptiometry. Free T4 (FT4), FT3 as well as ultrasensitive TSH assays were used to assess thyroid status. RESULTS: The two groups showed no difference in BMD (g/cm2) of the lumbar spine (1.008 vs. 0.957, P = 0.25), femoral neck (0.745 vs. 0.735, P = 0.79) and total hip (0.878 vs. 0.837, P = 0.24). When the two groups were pooled, there was no significant difference between the patients and a reference population with femoral neck and total hip BMD expressed as a standard deviation (Z) score. However, the lumbar spine mean Z score was significantly greater than zero. For each site, there was a negative correlation of BMD with age in at least one group but, in general, BMI, FT4, FT3 and duration of T4 replacement did not correlate with BMD. T4 dose, however, had a consistent positive correlation with BMD in the spine, femoral neck and the hip (P = 0.01, 0.04 and 0.02, respectively) in group 2 but not group 1. CONCLUSION: In this study, there is no evidence for a difference in bone mineral density in patients receiving replacement doses of thyroxine irrespective of the aetiology of their hypothyroidism. The reduced bone mineral density associated with hyperthyroidism appears to be restored, maintained and in some cases possibly improved while on long-term thyroxine replacement post-radioiodine.

Kleiner J, Altshuler L, Hendrick V, Hershman JM. Lithium-induced subclinical hypothyroidism: review of the literature and guidelines for treatment. J Clin Psychiatry 1999 Apr;60(4):249-255. (Review)
Abstract: BACKGROUND: This review addresses the definition, prevalence, etiology, and clinical significance of lithium-associated subclinical hypothyroidism and offers guidelines for evaluation and treatment of this condition. DATA SOURCES: MEDLINE was used to search all articles written in English from 1964-present that included the words lithium and thyroid; lithium and subclinical hypothyroidism; mood and thyroid function; and bipolar illness and thyroid function. STUDY FINDINGS: Lithium interferes with thyroid metabolism and increases the incidence of overt and subclinical hypothyroidism. Subclinical hypothyroidism may be associated with the presence of somatic and neuropsychiatric symptoms and interfere with treatment responsiveness. CONCLUSION: A careful assessment of thyroid function is recommended prior to initiating lithium treatment and during maintenance treatment. Recommendations regarding the threshold for initiation of thyroxine supplementation in patients with lithium-associated subclinical hypothyroidism are discussed in relationship to the degree of detrimental effects potentially associated with thyroid dysfunction.

Kung AWC, Pun KK. Bone mineral density in premenopausal women receiving long-term physiological doses of levothyroxine. JAMA May 22-29;265(20):2688-2691.
Abstract: Total body and regional bone mineral density (BMD) levels were determined in 26 premenopausal women with Hashimoto's thyroiditis receiving long-term physiological doses of levothyroxine sodium replacement therapy. The BMD levels of each patient were compared with the mean of the BMD levels of age-matched normal controls. The mean levothyroxine sodium dose was 111 +/- 6 micrograms/d, and the mean duration of treatment was 7.5 +/- 5.3 years (range, 1 to 24 years). Dietary calcium intake was similar in both groups, as were serum thyroxine, triiodothyronine, free thyroxine index, and thyrotropin levels. Women receiving the levothyroxine treatment had normal total body BMD levels but had significantly lower BMD levels at the femoral neck (-5.7%), femoral trochanter (-7.0%), Ward's triangle (-10.6%), both arms (right, -7.8%; left, -8.9%), and pelvis (-4.9%). In contrast, lumbar spine BMD levels were similar in the two groups. There was no correlation between the total body or different regional BMD levels and the duration or dosage of levothyroxine treatment or thyroid function test results. However, the z score of the femoral neck of these patients showed a significant negative correlation with their serum free thyroxine index levels. We conclude that patients receiving physiological doses of levothyroxine may have decreased bone density. Thyroid functions in patients receiving long-term levothyroxine treatment should be closely monitored and bone densitometry should be performed in patients at risk for osteoporosis.

Kung AW, Lorentz T, Tam SC. Thyroxine suppressive therapy decreases bone mineral density in post-menopausal women. Clin Endocrinol (Oxf) 1993 Nov;39(5):535-540.
Abstract: OBJECTIVE: Hyperthyroidism is associated with increased bone turnover and decreased bone mass. This study aimed to evaluate the bone mineral density (BMD) of post-menopausal women on long-term thyroxine suppressive therapy. DESIGN: An age and sex-matched cross-sectional study. PATIENTS: Thirty-four post-menopausal women with carcinoma of thyroid, post total thyroidectomy and 131I ablation, on L-T4 for 12.2 +/- 6.6 years (mean +/- SD). Controls were 34 age-matched healthy Southern Chinese women. MEASUREMENTS: Total body and regional BMDs were determined by dual-energy X-ray absorptiometry. Bone turnover was assessed by biochemical markers. RESULTS: In the thyroxine treated group, total body mineral content was significantly lower than the controls (1652 +/- 356 vs 1994 +/- 270 g mean +/- SD, P < 0.005). They also had lower BMDs in the lumbar spine, femoral neck, trochanter and Ward's triangle (0.75 +/- 0.15 vs 0.92 +/- 0.16 g/cm2, P < 0.005; 0.62 +/- 0.12 vs 0.70 +/- 0.12 g/cm2, P < 0.01; 0.55 +/- 0.14 vs 0.63 +/- 0.15 g/cm2, P < 0.001; 0.55 +/- 0.14 vs 0.63 +/- 0.14 g/cm2, P < 0.005 respectively.) The thyroxine treated group also had higher serum alkaline phosphatase and osteocalcin levels as well as urinary hydroxyproline excretion, suggesting that they had high turnover bone loss. However, the Z-scores of the various regional BMDs were correlated only with the serum osteocalcin level and showed no correlation with the serum thyroxine level or with the dosage or duration of thyroxine treatment. CONCLUSION: Long-term thyroxine suppressive therapy was associated with bone loss and preventive therapy may be indicated in these post-menopausal women at risk of osteoporosis.

Leedman PJ, Stein AR, Chin WW, Rogers JT. Thyroid hormone modulates the interaction between iron regulatory proteins and the ferritin mRNA iron-responsive element. J Biol Chem 1996 May 17;271(20):12017-12023.
Abstract: The cytoplasmic iron regulatory protein (IRP) modulates iron homeostasis by binding to iron-responsive elements (IREs) in the transferrin receptor and ferritin mRNAs to coordinately regulate transferrin receptor mRNA stability and ferritin mRNA translational efficiency, respectively. These studies demonstrate that thyroid hormone (T3) can modulate the binding activity of the IRP to an IRE in vitro and in vivo. T3 augmented an iron-induced reduction in IRP binding activity to a ferritin IRE in RNA electrophoretic mobility shift assays using cytoplasmic extracts from human liver hepatoma (HepG2) cells. Hepatic IRP binding to the ferritin IRE also diminished after in vivo administration of T3 with iron to rats. In transient transfection studies using HepG2 cells and a human ferritin IRE-chloramphenicol acetyltransferase (H-IRE-CAT) construct, T3 augmented an iron-induced increase in CAT activity by approximately 45%. RNase protection analysis showed that this increase in CAT activity was not due to a change in the steady state level of CAT mRNA. Nuclear T3-receptors may be necessary for this T3-induced response, because the effect could not be reproduced by the addition of T3 directly to cytoplasmic extracts and was absent in CV-1 cells which lack T3-receptors. We conclude that T3 can functionally regulate the IRE binding activity of the IRP. These observations provide evidence of a novel mechanism for T3 to up-regulate hepatic ferritin expression, which may in part contribute to the elevated serum ferritin levels seen in hyperthyroidism.

Lopez Alvarez MB, Hawkins F, Rigopoulou D, Martinez G, Jodar E, Estenoz J, Ortuno B, Arnaiz F. [The risk factors and bone mineral density in women on long-term levothyroxine treatment]. Med Clin (Barc) 1999 Jan 30;112(3):85-89. [Article in Spanish]
Abstract: BACKGROUND: It is controversial if the long-term treatment with thyroid hormone given at substitutive or suppressive doses has a negative effect on bone metabolism. In previous reports the lack of ultrasensitive TSH assays and densitometers with adequate precision, and the heterogeneity of the patients analyzed could explain these discordant results. PATIENTS AND METHODS: We have assessed bone mineral density (BMD) in 43 premenopausal and 53 postmenopausal women, who underwent near total thyroidectomy and I-131 ablation due to differentiated thyroid cancer, that have been followed up (mean duration, 75.5 [43] months) with suppressive thyroid hormone treatment (mean dose, 170 [42] micrograms) in our hospital. Patients with history of hyperthyroidism were excluded. Lumbar BMD (L2-L4) and BMD in three different sites of hip were measured (dual X-ray densitometry) to determine the contribution of several clinical and risk factors associated with thyroid hormone therapy given to BMD. RESULTS: We have not found significant decrease in BMD at spine or hip when patients were compared with healthy, age and sex matched. Age (inverse correlation) and weight (direct correlation) were the variables mostly influencing BMD). Histologic type of thyroid neoplasia, doses of thyroid hormones, thyroid hormone levels and duration of follow-up, were not associated with changes in BMD. A decrease in calcium intake in postmenopausal and less physical activity in premenopausal women were related with a decreased lumbar BMD. CONCLUSIONS: During long-term treatment of female patients with thyroid hormones, other risk factors should be studied in order to prevent possible loss of bone mass.

Nuzzo V, Lupoli G, Esposito Del Puente A, Rampone E, Carpinelli A, Del Puente AE, Oriente P. Bone mineral density in premenopausal women receiving levothyroxine suppressive therapy. Gynecol Endocrinol 1998 Oct;12(5):333-337.
Abstract: Osteoporosis is a well-known complication of thyrotoxicosis. Prolonged subclinical hyperthyroidism due to L-thyroxine treatment has been associated with reduced bone mass and thus with the potential risk of premature development of osteoporosis. The aim of this study was to assess the effect of a chronic L-thyroxine suppressive treatment on bone mineral density (BMD) in a group of premenopausal women. Forty consecutive patients (mean age +/- SE = 40.95 +/- 1.56 years) affected by non-toxic goiter underwent bone mineral densitometry (dual energy X-ray absorptiometry; DEXA) of the lumbar spine (L1-L4) and right femoral neck. At the time of the study the patients had been under thyroid stimulating hormone (TSH) suppressive therapy for 74.95 +/- 10.34 months (range 17-168 months). Baseline levels of free thyroxine (fT4), free triiodothyronine (fT3), TSH, calcium and phosphorus were measured and correlated with BMD. The age of starting, duration of treatment, main daily dose, cumulative dose of treatment and body mass index (BMI) were also correlated with BMD. Statistical analysis was performed by multiple linear regression. BMD among female patients was not significantly different from that of the general population matched for age and sex. With the use of the regression model, no significant correlation was found between BMD and the variables considered. In conclusion, our data suggest that L-thyroxine suppressive therapy, if carefully carried out and monitored, has no significant effect on bone mass.

Paul TL, Kerrigan J, Kelly AM, Braverman LE, Baran DT. Long-term L-thyroxine therapy is associated with decreased hip bone density in premenopausal women. JAMA 1988 Jun 3;259(21):3137-3141.
Abstract: The effect of long-term L-thyroxine (L-T4) therapy on axial skeleton bone density was studied in 31 premenopausal women; the bone densities of these women were compared with the bone densities of 31 age- and weight-matched women without thyroid or bone abnormalities. The women receiving L-T4 therapy had been receiving the medication for a minimum of five years. There was no difference in calcium intake or excretion between the L-T4-treated women and the controls. Women receiving L-T4 had increased serum thyroxine concentrations (134 +/- 5 vs 95 +/- 3 nmol/L [10.4 +/- 0.4 vs 7.4 +/- 0.2 micrograms/dL]), an increased free thyroxine index (9.4 +/- 0.4 vs 6.8 +/- 0.2), and decreased serum thyroid-stimulating hormone concentrations (0.9 +/- 0.2 mU/L vs 2.1 +/- 0.3 mU/L [0.9 +/- 0.2 vs 2.1 +/- 0.3 microU/mL]). Serum triiodothyronine concentrations were normal and were similar in both groups. Women treated with L-T4 had a 12.8% lower bone density at the femoral neck and a 10.1% lower bone density at the femoral trochanter compared with matched controls. In contrast, lumbar spine bone density was similar in the two groups. The data suggest that long-term L-T4 therapy, which is often given at supraphysiologic dosages, may predispose patients to decreased bone density in the hip and may increase the risk of age-related bone loss. It is advisable, therefore, to employ a dosage of L-T4 that is carefully monitored to avoid the long-term use of dosages that are excessive for the thyroid condition being treated.

Schneider DL, Barrett-Connor EL, Morton DJ. Thyroid hormone use and bone mineral density in elderly men. Arch Intern Med 1995 Oct 9;155(18):2005-2007.
Abstract: BACKGROUND: Excessive thyroid hormone use reduces bone density in women. Thyroid hormone use is much less common in men, who also have less osteoporosis. We examined bone mineral density in a community-based sample of elderly men who reported long-term thyroid hormone use. METHODS: All 685 white men aged 50 to 98 years from a Southern California community who participated in a study of osteoporosis were examined. Medication use was validated. Height and weight were measured. Bone mineral density was measured at the ultradistal radius and midshaft radius using single photon absorptiometry and at the hip and lumbar spine using dual energy x-ray absorptiometry. RESULTS: Thirty-three men taking a mean thyroxine-equivalent dose of 130 micrograms daily for an average of 15.5 years were compared with 653 nonusers. There were no significant differences in bone density at any site between users and nonusers, before or after controlling for age, body mass index, smoking, thiazide diuretics, and oral corticosteroid use. Bone density also did not differ according to thyroid hormone type, duration of use, or use of suppressive dose adjusted for body weight. CONCLUSIONS: Long-term thyroid hormone use was not associated with adverse effects on bone mineral density in men.

Shakir KM, Chute JP, Aprill BS, Lazarus AA. Ferrous sulfate-induced increase in requirement for thyroxine in a patient with primary hypothyroidism. South Med J 1997 Jun;90(6):637-639.
Abstract: Recent studies have shown that under experimental conditions ferrous sulfate may reduce the gastrointestinal absorption of orally administered levothyroxine sodium in patients with primary hypothyroidism. We describe a patient who became hypothyroid while taking ferrous sulfate. The hypothyroid status was corrected by increasing the dose of levothyroxine. Subsequently, when ferrous sulfate was discontinued, the patient became hyperthyroid while taking the higher dose of thyroid hormone preparation. Since both hypothyroidism and iron deficiency anemia may coexist, additional thyroid function testing is recommended in patients treated concurrently with ferrous sulfate and L-thyroxine.

Tellian FF, Rueda-Vasquez E. Effect of serum lithium levels on thyrotropin levels. South Med J 1993 Oct;86(10):1182-1183.
Abstract: Previous research has demonstrated laboratory-detected hypothyroidism as a consequence of lithium usage in 3% to 30% of all recipients and abnormal TSH secretion in up to 15%. This has generally been considered a non-dose-related consequence of lithium therapy. This study examined whether serum levels of lithium are related directly to changes in thyroid function. In a retrospective review, data from 39 cases were analyzed for correlations between serum lithium level, TSH, T3 RU, and T4 by RIA. A positive correlation was found between changes in serum lithium concentration and changes in TSH level. None of the other variables measured showed any correlation. Results of this study suggest that lithium-induced changes in TSH are serum level dependent. Possible mechanisms and clinical implications have been discussed.

Threlkeld DS, ed. Hormones, Thyroid Hormones. In: Facts and Comparisons Drug Information. St. Louis, MO: Facts and Comparisons, Jun 1991.