Hypopituitarism following Radiotherapy Revisited

Neuroendocrine disturbances in anterior pituitary hormone secretion are common following radiation damage to the hypothalamic-pituitary (H-P) axis, the severity and frequency of which correlate with the total radiation dose delivered to the H-P axis and the length of follow-up. The somatotropic axis...

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Bibliographic Details
Published inEndocrine development Vol. 15; p. 1
Main Authors Darzy, Ken H, Shalet, Stephen M
Format Journal Article
LanguageEnglish
Published Switzerland 2009
Subjects
Adrenocorticotropic Hormone - deficiency
Adrenocorticotropic Hormone - metabolism
Brain Neoplasms - radiotherapy
Child
Cranial Irradiation - adverse effects
Gonadotropins - deficiency
Gonadotropins - metabolism
Human Growth Hormone - deficiency
Human Growth Hormone - metabolism
Humans
Hypopituitarism - diagnosis
Hypopituitarism - etiology
Hypopituitarism - physiopathology
Pituitary Diseases - etiology
Pituitary Diseases - metabolism
Prolactin - deficiency
Prolactin - metabolism
Radiation Injuries - diagnosis
Radiation Injuries - etiology
Radiobiology - methods
Thyrotropin - deficiency
Thyrotropin - metabolism
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Summary:Neuroendocrine disturbances in anterior pituitary hormone secretion are common following radiation damage to the hypothalamic-pituitary (H-P) axis, the severity and frequency of which correlate with the total radiation dose delivered to the H-P axis and the length of follow-up. The somatotropic axis is the most vulnerable to radiation damage and GH deficiency remains the most frequently seen endocrinopathy. Compensatory hyperstimulation of a partially damaged somatotropic axis may restore normality of spontaneous GH secretion in the context of reduced but normal stimulated responses in adults. At its extreme, endogenous hyperstimulation may limit further stimulation by insulin-induced hypoglycaemia resulting in subnormal GH responses despite the normality of spontaneous GH secretion. In children, failure of the hyper-stimulated partially damaged H-P axis to meet the increased demands for GH during growth and puberty may explain what has previously been described as radiation-induced GH neurosecretory dysfunction and, unlike in adults, the insulin tolerance test remains the gold standard for assessing H-P functional reserve. With low radiation doses (<30 Gy) GH deficiency usually occurs in isolation in about 30% of patients, while with radiation doses of 30-50 Gy, the incidence of GH deficiency can reach 50-100% and long-term gonadotropin, TSH and ACTH deficiencies occur in 20-30, 3-9 and 3-6% of patients, respectively. With higher dose cranial irradiation (>60 Gy) or following conventional irradiation for pituitary tumours (30-50 Gy), multiple hormonal deficiencies occur in 30-60% after 10 years of follow-up. Precocious puberty can occur after radiation doses of <30 Gy in girls only, and in both sexes equally with a radiation dose of 30-50 Gy. Hyperprolactinaemia, due to hypothalamic damage is mostly seen in young women after high dose cranial irradiation and is usually subclinical. H-P dysfunction is progressive and irreversible and can have an adverse impact on growth, body image, sexual function and quality of life. Regular testing is advised to ensure timely diagnosis and early hormone replacement therapy.
ISSN:1421-7082
DOI:10.1159/000207607