Thyroxine (T4)

CPT Test code: 84436

Related Documents:	Thyroid Testing: Assessing Thyroid Disease in Your Patients
Specimen:	Serum
Volume:	1 mL (adult), 0.8 mL (pediatric)
Minimum Volume:	0.5 mL (adult), 0.3 mL (pediatric) (Note: This volume does not allow for repeat testing.)
Container:	Red-top tube or gel-barrier tube
Collection:	If a red-top tube is used, transfer separated serum to a plastic transport tube.
Storage Instructions:	Refrigerate
Reference Interval:	4.5-12.0 μg/dL^1,2
Use:	Thyroid function test. Decreased in hypothyroidism and in the third stage of (painful) subacute thyroiditis; increased with hyperthyroidism, with subacute thyroiditis in its first stage and with thyrotoxicosis due to Hashimoto disease.³ Used to diagnose T₄ toxicosis.
Limitations:	T₄ may be increased with excess intake of iodine or with surreptitious use of thyroxine.³ T₄ levels may be abnormal in the presence of systemic nonthyroidal disease. Alterations in binding capacity or quantity of TBG may increase or decrease total thyroxine without causing symptoms. A common cause of elevated T₄ in nonthyroidal disease is said to be liver disease. Serum thyroxine and free thyroxine index (FTI) are increased in familial dysalbuminemic hyperthyroxinemia, a euthyroid syndrome in which an abnormal binding site has affinity for thyroxine.⁴ The T₃ is usually normal in this entity, as is T₃ uptake (THBR). Thus, T₃ uptake is commonly ordered with T₄.
Additional Information:	The combination of the serum T₄ and T₃ uptake (THBR) as an indirect assessment of TBG, helps to determine whether an abnormal T₄ value is due to alterations in serum thyroxine-binding globulin or to changes of thyroid hormone levels. Deviations of both tests in the same direction usually indicate that an abnormal T₄ is due to abnormalities in thyroid hormone. Deviations of the two tests in opposite directions provide evidence that an abnormal T₄ may relate to alterations in TBG. *Causes of increased TBG binding* include neonatal state, molar and conventional pregnancy, estrogens, oral contraceptives, heroin, methadone, 5-fluorouracil, clofibrate, infectious hepatitis, chronic active hepatitis, and primary biliary cirrhosis, acute intermittent porphyria, lymphoma, and hereditary TBG increase. Amphetamines, iopanoic acid, ipodate, and amiodarone increase thyroxine.^5,6 High dose propranolol may elevate T₄ and FTI levels.⁷ *Causes of decreased TBG binding* include abnormal protein states especially nephrotic syndrome, androgens, anabolic steroids, prednisone, acromegaly, liver or other systemic illness, severe stress or hereditary TBG deficiency. Salicylates and diphenylhydantoin may lower T₄ significantly. Amiodarone may cause increased thyroxine levels and can cause hypothyroidism or hyperthyroidism. Lithium carbonate may cause goiter with or without hypothyroidism. Carbamazepine (Tegretol®) is reported to cause decreased values in thyroid function tests.
Footnotes:	1. Soldin SJ, Hicks JM, eds, Pediatric Reference Ranges, Washington, DC: AACC Press, 1995, 141. 2. Murthy JN, Hicks JM, Soldin SJ, “Evaluation of the Technicon Immuno I Random Access Immunoassay Analyzer and Calculation of Pediatric Reference Ranges for Endocrine Tests, T-Uptake, and Ferritin,” Clin Biochem, 1995, 28(2):181-5. PubMed 7628078 3. Klein I, Levey GS, “Silent Thyrotoxic Thyroiditis,” Ann Intern Med, 1982, 96(2):242-4. PubMed 7059071 4. Ruiz M, Rajatanavin R, Young RA, et al, “Familial Dysalbuminemic Hyperthyroxinemia: A Syndrome That Can Be Confused With Thyrotoxicosis,” N Engl J Med, 1982, 306(11):635-9. PubMed 6173750 5. Borst GC, Eil C, Burman KD, “Euthyroid Hyperthyroxinemia,” Ann Intern Med, 1983, 98(3):366-78. PubMed 6187257 6. Chopra IJ, Hershman JM, Pardridge MD, et al, “Thyroid Function in Nonthyroidal Illnesses,” Ann Intern Med, 1983, 98(6):946-57 (review). PubMed 6407376 7. Cooper DS, Daniels GH, Ladenson PW, et al, “Hyperthyroxinemia in Patients Treated With High-Dose Propranolol,” Am J Med, 1982, 73(6):867-71.PubMed 6816067
References:	Franklyn JA, Davis JR, Ramsden DB, et al, “Phenytoin and Thyroid Hormone Action,” J Endocrinol, 1985, 104(2):201-4. PubMed 3918137 Gharib H, Klee GG, “Familial Euthyroid Hyperthyroxinemia Secondary to Pituitary and Peripheral Resistance to Thyroid Hormones,” Mayo Clin Proc, 1985, 60(1):9-15. PubMed 2981377 Gruhn JG, Barsano CP, and Kumar Y, “The Development of Tests of Thyroid Function,” Arch Pathol Lab Med, 1987, 111(1):84-100. PubMed 3541847 Surks MI, Chopra IJ, Mariash CN, et al, “American Thyroid Association Guidelines for the Use of Laboratory Tests in Thyroid Disorders,” JAMA, 1990, 263(11):1529-32.PubMed 2308185