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Outcome of a Baby Born from a Mother with Acquired Juvenile Hypothyroidism Having Undetectable Thyroid Hormone Concentrations¹

Department of Pediatrics, Chiba University School of Medicine, Chiba 260-8670, Japan

Address correspondence and requests for reprints to: Toshiyuki Yasuda, M.D., Department of Pediatrics, Chiba University School of Medicine, 1–8-1 Inohana, Chuo-ku, Chiba 260-8670, Japan. E-mail: toshi{at}med.m.chiba-u.ac.jp

	Abstract

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We report a baby born from a mother with strongly positive thyroid stimulation blocking antibody (TSBAB) and nearly undetectable T₄ level. This case is a unique model of nearly complete absence of thyroid hormones during fetal and early neonatal life in humans. The infant girl was born by cesarean section, because of fetal bradycardia, after 41 weeks gestation and received mechanical ventilation for 3 days. The TSH level was more than 120 µU/mL in the neonatal thyroid screening. At age 17 days, the results of a thyroid function study showed undetectable free T₃ and free T₄ concentrations, TSH 550 µU/mL, and TSH receptor antibody (TRAB) 87%. Thyroxine at a dose of 30 µg/day was started at age 17 days. The patient required thyroxine treatment until age 8 months. The brain magnetic resonance image at age 2 months revealed reduced brain size. Her auditory brain stem response was absent at age 2 months. The audiogram at age 4 yr revealed sensorineural deafness of 70 dB. When she was 6 yr of age, motor development remained the same as that at age 4 months. Her height was 106 cm (-1.5 SD). The results of thyroid function study of the mother 23 days after delivery showed undetectable free T₃ and free T₄, TRAB 84%, and TSBAB 83%. In conclusion, the outcome of severe thyroid hormone deficiency in utero and early in human neonatal life was normal physical growth, fetal distress resulting in cesarean section, difficulty in the onset of breathing, permanent deficit in auditory function, brain atrophy, and severely impaired neuromotor development despite the start of an adequate dose of thyroxine replacement during the neonatal period.

	Introduction

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THE OUTCOME of transient hypothyroidism in infants born to mothers with chronic thyroiditis is usually good, but some are mentally retarded despite early neonatal treatment (1, 2). Maternal hypothyroidism during pregnancy is thought to contribute to the poor prognosis in these infants (3). We report a baby born from a mother with a high thyroid stimulation blocking antibody (TSBAB) titer and a nearly undetectable T₄ level. This is a unique model of the nearly complete absence of thyroid hormones during fetal and early neonatal life in humans.

	Subjects and Methods

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Serum free T₄, free T₃, T₄, and TSH concentrations were measured with a Nippon DPC RIA kit (Nippon DPC Corp., Tokyo, Japan), Daiichi RIA kit (Daiichi Pharmaceutical Company, Ltd.), and Dainabott immunoradiometric assay kit (Dainbbott Co. Ltd., Tokyo, Japan), respectively. TSH receptor antibody (TRAB) was measured with a Cosmic radio-receptor assay kit (Cosmic Corp., Tokyo, Japan). TSBAB was measured using the rat FRTL-5 cell line. In brief, we determined cAMP production of the cells in the presence of 100 µU/mL bovine TSH with an immunoglobulin preparation of the patient’s serum or of control serum, and TSBAB was expressed by percent inhibition of cAMP production by an immunoglobulin preparation of the patient’s serum compared with the control, as previously described (4).

Case report

Infant. The girl was born by cesarean section because of fetal bradycardia after 41 weeks gestation. She was intubated because of poor spontaneous respiration and received mechanical ventilation for 3 days. Cord arterial blood gas analysis was normal. Her body weight and length were 2640 gm (-1.5 SD) and 49 cm (-1 SD), respectively. The TSH level was more than 120 µU/mL in the neonatal thyroid screening performed at age 8 days, and the patient was referred to the Chiba University Hospital at the age of 17 days. Thyroxine at a dose of 30 µg/day was started at that time. The epiphysis of the distal femur was not visible on the knee x-ray film. The patient was inactive and had generalized edema, peripheral coldness, and jaundice. The thyroid gland size was +1.5 SD by echosonography. The results of a thyroid function study on admission were undetectable free T₃, free T₄, and T₄ concentrations, TSH 550 µU/mL, and TRAB 87%. Both T₄ and free T₄ levels normalized at age 24 days and have remained so since then. She received medication until age 8 months. At that time, the patient’s TRAB became negative (2.1%).

The brain magnetic resonance image (MRI) at age 2 months revealed reduced brain size, most notably around the operculum (Fig. 1). The auditory brain stem response was less than 100 dB at age 2 months. The audiogram at age 4 yr revealed sensorineural deafness of 70 dB. Her motor development at the age of 6 yr remained the same as that at age 4 months (head control and roll-over). Her height was 106 cm (-1.5 SD).

View larger version (74K): [in this window] [in a new window]   Figure 1. Brain T1-weighted MRI images at age 2 months. Three consecutive sections of brain MRI images are shown. There is fluid accumulation in the bifrontal areas indicating mild brain atrophy, which is most prominently noted around the operculum. There is no significant ventricular enlargement.

	Discussion

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Because T₄ crosses the placenta, hypothyroid fetuses that cannot synthesize the hormone at all usually receive T₄ (5, 6). Thus, maternal T₄ may partially compensate for the fetal thyroid deficiency, and the effect of thyroid hormone deficiency on human fetal brain development in these babies may be difficult to assess. Because, in this case, the mother’s thyroid hormone concentration was nearly undetectable, transfer of maternal thyroxine to the fetus was likely to be absent. The baby had received TRAB with the property of the TSH blocking type to give rise to inhibition of the biological actions of TSH that synthesize thyroid hormones. As a consequence, this patient is a unique model of nearly complete absence of thyroid hormones during fetal and early neonatal life in humans.

The role of maternal thyroid hormones in fetal brain development is an important but complex issue (7). The placental permeability to thyroid hormones and the degree of development in the nervous system and the TSH-thyroid axis during fetal life vary among species. Dussault and Coulombe (8) estimated that placental transfer of maternal T₄ is less than 1% of the fetal T₄ production rate in the rat. Subsequent studies, also in rats, revealed that T₄ and T₃ are in fact transferred to the fetus from the earliest stages of gestation, but at this time the physiological significance remains unknown (9). A recent study by Vulsma et al.(5) suggested that in human fetuses with congenital hypothyroidism, maternal-fetal transfer of T₄ may result in neonatal plasma levels of 25–50% of those in normal infants. Because type II 5'-deiodinase activity in the brain increases in response to lowered concentrations of T₄, these levels of T₄ might suffice as a substrate to maintain a normal or near normal T₃ concentration in brain (10). In contrast, our patient did not receive or produce any significant amount of thyroid hormone at all.

Severe hypothyroidism early in pregnancy is reported to be complicated by fetal distress in labor, leading to cesarean section in most cases (11), as in this report. The cause may be that inadequate thyroid hormone levels early in pregnancy produce irreversible changes in the fetoplacental vascular beds, impairing subsequent circulatory responses to the stress of labor. As for the roles of thyroid hormones in brain development, thyroid hormones appear to regulate those processes associated with terminal differentiation such as dendritic and axonal growth, synaptogenesis, neuronal migration, and myelination (7). Thyroid hormone deprivation in neonatal rats has long been known to result in a diminished rate of myelin production and the concentration of each of its component proteins, which is associated with reduced levels of mRNA for myelin-associated genes (7, 12). These rats have reduced brain size. Thus, the brain atrophy in our patient may be due to extreme thyroid hormone deficiency or fetal distress probably induced by maternal hypothyroidism early in pregnancy. Cord blood gas analysis was normal, therefore the contribution of the fetal distress to brain atrophy may be minor. Thyroid hormones, as well as glucocorticoids, promote pulmonary surfactant production (13). A deficiency in the surfactant causes neonatal respiratory distress syndrome. However, our patient did not suffer from respiratory distress syndrome, despite severe thyroid hormone deficiency in utero.

Hearing problems are a feature of endemic goiter, and of some patients with thyroid hormone resistance due to the thyroid hormone receptor (TR)ß gene deletion (Reffetoff syndrome) (14), but are rarely found in congenital hypothyroidism (15). TRß knockout mice have a functional cochlear defect (14). Evidence in rats suggests that cochlear development occurs early in gestation (16), so it is possible that, in humans, similarly, deafness is a feature of babies in whom the hypothyroidism was present earlier in gestation.

The birth weight and length in this patient were normal, which may indicate that thyroid hormone is not essential for physical growth during human fetal life and also that maternal hypothyroidism does not impair physical growth of the fetus (1).

In conclusion, the outcome of severe thyroid hormone deficiency in humans in utero and early in neonatal life was fetal distress resulting in cesarean section, difficulty in the onset of breathing, a permanent deficit in auditory function, brain atrophy, and severely impaired neuromotor development despite starting thyroxine replacement during the neonatal period.

	Acknowledgments

 
The authors would like to thank Drs. A. Honda, Asahi General Hospital, A. Suzuki, Chiba Rehabilitation Center, and Y. Kobayashi, Kobayashi Clinic, for initial management and later follow-up of this patient.

	Footnotes

 
¹ This study was supported by grants from the Ministry of Health and Welfare, Japan.

Received May 27, 1998.

Revised August 8, 1998.

Revised April 28, 1999.

Accepted May 5, 1999.

	References

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