Quality of survival assessment in European childhood brain tumour trials, for children below the age of 5 years.

The highest incidence rate of childhood brain tumours is in children below the age of five years, who are particularly vulnerable to the effects of treatments. The assessment of quality of survival (QoS) in multiple domains is essential to compare the outcomes for different tumour types and treatment regimens. The aim of this position statement is to present the domains of health and functioning to be assessed in children from birth to five years, to advance the collection of a common QoS data set in European brain tumour trials. The QoS group of the European Society of Paediatric Oncology (SIOP-E) Brain Tumour group conducted consensus discussions over a period of six years to establish domains of QoS that should be prioritised in clinical trials involving children under 5 years. The domains of health and functioning that were agreed to affect QoS included: medical outcomes (e.g. vision, hearing, mobility, endocrine), emotion, behaviour, adaptive behaviour, and cognitive functioning. As for children aged five years and older, a 'core plus' approach is suggested in which core assessments are recommended for all clinical trials. The core component for children from birth to three years includes indirect assessment which, in this age-group, requires proxy assessment by a parent, of cognitive, emotional and behaviour variables and both direct and indirect endocrine measures. For children from four years of age direct cognitive assessment is also recommended as 'core'. The 'plus' components enable the addition of assessments which can be selected by individual countries and/or by, age-, treatment-, tumour type- and tumour location-specific trials.

The role of the sonic hedgehog signalling pathway in patients with midline defects and congenital hypopituitarism.

INTRODUCTION: The Gli family of zinc finger (GLI) transcription factors mediates the sonic hedgehog signalling pathway (HH) essential for CNS, early pituitary and ventral forebrain development in mice. Human mutations in this pathway have been described in patients with holoprosencephaly (HPE), isolated congenital hypopituitarism (CH) and cranial/midline facial abnormalities. Mutations in Sonic hedgehog (SHH) have been associated with HPE but not CH, despite murine studies indicating involvement in pituitary development. OBJECTIVES/METHODS: We aimed to establish the role of the HH pathway in the aetiology of hypothalamo-pituitary disorders by screening our cohort of patients with midline defects and/or CH for mutations in SHH, GLI2, Shh brain enhancer 2 (SBE2) and growth-arrest specific 1 (GAS1). RESULTS: Two variants and a deletion of GLI2 were identified in three patients. A novel variant at a highly conserved residue in the zinc finger DNA-binding domain, c.1552G > A [pE518K], was identified in a patient with growth hormone deficiency and low normal free T4. A nonsynonymous variant, c.2159G > A [p.R720H], was identified in a patient with a short neck, cleft palate and hypogonadotrophic hypogonadism. A 26·6 Mb deletion, 2q12·3-q21·3, encompassing GLI2 and 77 other genes, was identified in a patient with short stature and impaired growth. Human embryonic expression studies and molecular characterisation of the GLI2 mutant p.E518K support the potential pathogenicity of GLI2 mutations. No mutations were identified in GAS1 or SBE2. A novel SHH variant, c.1295T>A [p.I432N], was identified in two siblings with variable midline defects but normal pituitary function. CONCLUSIONS: Our data suggest that mutations in SHH, GAS1 and SBE2 are not associated with hypopituitarism, although GLI2 is an important candidate for CH.

Hypothalamo-pituitary-adrenal axis integrity after cranial irradiation for childhood posterior fossa tumours.

BACKGROUND: The evolution of anterior pituitary deficits after treatment for pituitary tumours has been largely attributed to local irradiation, but may be influenced as much by tumour mass or surgery. Other than growth hormone (GH) insufficiency, the late endocrinopathies after survival from non-central brain tumours have been little documented. The aim of this study was to investigate the hypothalamic-pituitary-adrenal (HPA) axis in long-term survivors of cranial irradiation for childhood posterior fossa tumours. PROCEDURE: We studied long-term data in patients treated prepubertally for posterior fossa brain tumours and systematically referred by radiation oncologists for growth and pubertal monitoring to the London Centre for Paediatric Endocrinology over the last 25 years. They must have undergone HPA axis assessment twice, first prepubertally at documentation of growth failure, and second at completion of growth and puberty. Data on sixteen patients (12 males, 4 females; median age: 5.7 years, range: 2.5-8.8 years), who had undergone excision surgery with high dose cranial irradiation and/or chemotherapy for childhood posterior fossa tumours, were examined. Patients were followed for a median of 11.0 (range: 6.8-21.4) years after radiotherapy. HPA axis assessment was undertaken with the insulin-induced hypoglycaemia test (ITT). Basal thyroid, cortisol and gonadal function tests were undertaken annually throughout the follow-up period and any deficits replaced. RESULTS: At each ITT, all patients mounted an inadequate GH response. By the end of the follow-up period all patients remained severely GH deficient, two (12.5%) had partial ACTH insufficiency, one (6.3%) had secondary hypothyroidism but none were gonadotropin deficient or hyperprolactinaemic. CONCLUSIONS: Unlike the severe, evolving multiple pituitary deficits after treatment of pituitary or central tumours in adults, these findings in children with posterior fossa tumours suggest that, with the exception of GH, neurotoxicity due to irradiation per se is associated with a low prevalence of anterior pituitary hormone deficiencies, even at a long follow-up. Since the children in this study were selected for assessment on the basis of growth failure, the high prevalence of GH insufficiency at first testing is to be expected; however, the early onset (within 1-3 years of irradiation) and permanence we have identified supports the view that GH is the most sensitive hormone to radiation injury.

Growth hormone treatment of children with brain tumors and risk of tumor recurrence.

GH is increasingly used for treatment of children and adults. It is mitogenic, however, and there is therefore concern about its safety, especially when used to treat cancer patients who have become GH deficient after cranial radiotherapy. We followed 180 children with brain tumors attending three large hospitals in the United Kingdom and treated with GH during 1965-1996, and 891 children with brain tumors at these hospitals who received radiotherapy but not GH. Thirty-five first recurrences occurred in the GH-treated children and 434 in the untreated children. The relative risk of first recurrence in GH-treated compared with untreated patients, adjusted for potentially confounding prognostic variables, was decreased (0. 6; 95% confidence interval, 0.4-0.9) as was the relative risk of mortality (0.5; 95% confidence interval, 0.3-0.8). There was no significant trend in relative risk of recurrence with cumulative time for which GH treatment had been given or with time elapsed since this treatment started. The relative risk of mortality increased significantly with time since first GH treatment. The results, based on much larger numbers than previous studies, suggest that GH does not increase the risk of recurrence of childhood brain tumors, although the rising trend in mortality relative risks with longer follow-up indicates the need for continued surveillance.

Treatment of achondroplasia with growth hormone: six years of experience.

We describe the effects of recombinant hGH (r-hGH) therapy for up to 6 y on stature and body proportions of 35 children with achondroplasia (Ach). Consecutive height (Ht) measurements were plotted on disease-specific Ach growth curves, but age and sex SD scores (SDS) of Ht, sitting Ht, subischial leg length, and Ht velocity were made with respect to Tanner normal standards. r-hGH was administered by daily subcutaneous injections at a median (range) dose of 30 (15.8-40) U/m2 per week [0.06 (0.04-0.08) mg.kg(-1).24 h(-1)]. Patients were treated for 3 (1-6) y from age 2.25 (1.2-9.3) y. Before treatment, Ht SDS was -4.6 (-6.5 to -3.24). Treatment caused a significant increase in Ht SDS year to year until y 4 (ANOVA F = 46.94; p < 0.01) that was subsequently sustained with no significant further change (y 5 and 6 versus y 4, p > 0.05). When the response to r-hGH was also expressed as a change in Ht velocity, there was a significant increase in the first year of therapy that was maintained over subsequent treatment years (ANOVA = 4.28, p = 0.001). Age was the most important variable accounting for the first-year response in Ht SDS (r2 = 0.41, p < 0.001), and dose of r-hGH did not influence this. Increments in sitting Ht SDS were greater than subischial leg length SDS (F = 26.25, p < 0.001; F = 9.04, p < 0.001, respectively). r-hGH treatment improved the Ht position of Ach children relative to their normal and Ach peers without obvious side effects. A young age at initiation of therapy prevented the characteristic Ht deficit from accumulating. The greater increase in spinal Ht accentuated the existing disproportion. The addition of later surgical leg lengthening could offer the possibility of proportionate adult stature just within the normal range.

Evolution of growth hormone neurosecretory disturbance after cranial irradiation for childhood brain tumours: a prospective study.

To determine the aetiopathology of post-irradiation growth hormone (GH) deficiency, we performed a mixed longitudinal analysis of 56 24 h serum GH concentration profiles and 45 paired insulin-induced hypoglycaemia tests (ITT) in 35 prepubertal children, aged 1.5-11.8 years, with brain tumours in the posterior fossa (n = 25) or cerebral hemispheres (n = 10). Assessments were made before (n = 16), 1 year (n = 25) and 2 to 5 years (n = 15) after a cranial irradiation (DXR) dose of at least 30 Gy. Fourier transforms, occupancy percentage, first-order derivatives (FOD) and mean concentrations were determined from the GH profiles taken after neurosurgery but before radiotherapy (n = 16) and in three treatment groups: Group 1: neurosurgery only without DXR (n = 9); Group 2: > or = 30 Gy DXR only (n = 22); Group 3: > or = 30 Gy DXR with additional chemotherapy (n = 9). Results were compared with those from 26 short normally growing (SN) children. Compared with SN children, children with brain tumours had faster GH pulse periodicities (200 min vs 140 min) and attenuated peak GH responses to ITT (24.55 (19.50-30.20) vs 8.32 (4.57-15.14) mU/l) after neurosurgery, before radiotherapy. However, spontaneous GH peaks (19.05 (15.49-23.44) vs 14.13 (9.12-21.38) mU/l), 24 h mean GH (5.01 (4.37-5.62) vs 3.98 (2.63-5.89) mU/l) and FODs (1.43 (1.17-1.69) vs 1.22 (0.88-1.56) mU/l per min) were similar. The abnormalities present before radiotherapy persisted in group 1 children at 1 year when 24 h mean GH (2.45 (1.17-5.01) mU/l) and FODs (0.73 (0.26-1.20) mU/l per min) were additionally suppressed, although partial recovery was evident by 2 years. With time from radiotherapy, there was a progressive increase in GH pulse periodicity (Group 2: 200 min at 1 year, 240 min at > or = 2 years; Group 3: 140 min at 1 year, 280 min at > or = 2 years) and a decrease in 24 h mean GH (Group 2 vs Group 3 at > or = 2 years: 2.45 (1.70-3.47) vs 1.86 (1.32-2.69) mU/l) and FODs (Group 2 vs Group 3 at > or = 2 years; 0.56 (0.44-0.69) vs 0.44 (0.27-0.61) mU/l per min). Initial discrepancies between measures of spontaneous and stimulated (ITT) GH peaks were lost by 2 or more years (spontaneous vs ITT; Group 2: 7.76 (5.89-9.77) vs 3.80 (0.91-15.84) mU/l; Group 3: 6.03 (4.27-8.32) vs 3.80 (0.31-46.77) mU/l). After cranial irradiation, a number of changes evolved within the GH axis: faster GH pulse periodicities and discordance between physiological and pharmacological tests of GH secretion before irradiation gave way to a slow GH pulse periodicity, decreased GH pulse amplitude and rate of GH change (FOD) and, with time, eventual concordance between physiological and pharmacological measures. The evolution of these disturbances may well reflect differential pathology affecting hypothalamic GH-releasing hormone and somatostatin.

Low-dose growth hormone-releasing hormone tests: a dose-response study.

We have evaluated parameters of the serum growth hormone (GH) concentration response to saline and 1-, 10- and 100-micrograms intravenous bolus doses of amide analogue of GH-releasing hormone (GHRH (1-29)NH2) given in random order to 10 adult male volunteers of median body weight 68 (60-90)kg. Compared with saline, both 10- and 100-micrograms GHRH(1-29)NH2 doses (but not 1 microgram) resulted in significant peak GH responses (means and 95% confidence intervals: 24.03 (11.22-51.29) vs 26.09 (16.40-41.50) mU/l, respectively). Although the average rate of serum GH rise was similar after both 10 micrograms (2.05 (1.13-2.97) mU.l-1.min-1) and 100 micrograms of GHRH(1-29)NH2 (1.52 (0.69-2.35) mU.l-1.min-1; ANOVA F = 0.93, p = 0.35), the average rate of serum GH decline after peak GH was slower after the higher dose (10 micrograms vs 100 micrograms: 0.65 (0.40-0.90) vs 0.37 (0.23-0.50) mU.l-1.min-1; ANOVA F = 5.14, p = 0.04), suggesting continued GH secretion. Increasing GHRH(1-29)NH2 doses delayed the time to peak GH (1 microgram: 7.00 (3.50-10.52) min; 10 micrograms: 15.80 (13.62-17.98) min; 100 micrograms: 24.80 (18.40-31.12) min) and serum GH levels were still elevated significantly 2 h after injection of 100 micrograms GHRH(1-29)NH2 compared with other doses (saline: 0.98 (0.48-2.04) mU/l; 1 microgram: 0.68 (0.48-0.93) mU/l; 10 micrograms: 1.07 (0.56-2.04) mU/l; 100 micrograms: 5.01 (2.34-10.86) mU/l; ANOVA F = 11.10, p < 0.001). In a second study we tested five adult male volunteers with lower doses (0.5-10 micrograms) of GHRH(1-29)NH2.(ABSTRACT TRUNCATED AT 250 WORDS)

Deoxycorticosterone, 11 beta-hydroxylase and the adrenal cortex.

We report a child in whom DOC excess secondary to congenital adrenal hyperplasia (CAH, 11 beta-hydroxylase deficiency) caused malignant hypertension. Clinical and metabolic control could be achieved only by replacement of both glucocorticoid and mineralocorticoid, thus confirming in clinical practice the hypothesis that DOC is produced from both the zonae fasciculata and glomerulosa of the adrenal cortex under the independent control of the ACTH and renin-angiotensin systems respectively.

Short-term endocrine consequences of total body irradiation and bone marrow transplantation in children treated for leukemia.

We studied 24-h hormone profiles and hormonal responses to insulin-induced hypoglycaemia prospectively in 23 children of similar age and pubertal stage, nine of whom had received prior cranial irradiation (group 1) and fourteen of whom had not (group 2), before and 6-12 months after total body irradiation (TBI) for bone marrow transplantation in leukaemia. Fourier transformation demonstrated that group 1 children had a faster periodicity of GH secretion before TBI than group 2 children (160 vs 200 min) but the amplitude of their GH peaks was similar. There were no differences between the groups in circadian cortisol rhythm, serum concentrations of insulin-like growth factor-I (IGF-I), sex steroids and basal thyroxine (T4). The peak serum GH concentrations observed after insulin-induced hypoglycaemia were similar between the two groups but the majority of patients had blunted responses. TBI increased the periodicity of GH secretion in both groups (group 1 vs group 2; 140 vs 180 min), but the tendency to attenuation of amplitude was not significant. There were no significant changes in the peak serum GH concentration response to insulin-induced hypoglycaemia which remained blunted. Serum IGF-I, sex steroid, cortisol or T4 concentrations were unchanged. Low-dose cranial irradiation has an effect on GH secretion affecting predominantly frequency modulation leading to fast frequency, normal amplitude GH pulsatility. This change is accentuated by TBI. In patients with leukemia, there is a marked discordance between the peak serum GH response to insulin-induced hypoglycaemia compared with the release of GH during 24-h studies, irrespective of the therapeutic regimen used.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of changing somatostatin tone on the pituitary growth hormone and thyroid-stimulating hormone responses to their respective releasing factor stimuli.

Somatostatin (SS) inhibits GH and TSH secretion, but its role in modulating their pulsatility is unclear. We studied GH and TSH responses to GH-releasing hormone (GHRH) and TRH stimulation upon a variable background infusion of saline, SS-(1-14) at 20 and 100 micrograms/m2.h, and oral pyridostigmine (30 and 60 mg) in six adult males. Basal GH levels were unaffected by SS-(1-14). Deconvolution analysis of serum GH values demonstrated that the pituitary responded to two GHRH stimuli 90 min apart without attenuation of the second response. The higher dose of SS-(1-14) significantly blunted the first GH response; second GH responses were further attenuated by both SS-(1-14) doses. Maximum GH release and "switch-off" rates for both stimuli were reduced without changes in the 50% secretion time. Pyridostigmine enhanced the first GH response to GHRH with an increase in the GH release rate; second GH responses were not augmented. GH secretion was prolonged by pyridostigmine, although the 50% secretion time remained unchanged. Peak stimulated serum TSH was attenuated by both SS-(1-14) doses, but pyridostigmine had no effect. All other TSH parameters examined were unaffected. We conclude that the GH response to GHRH is dependent on SS tone, but that the thyrotroph is not tonically inhibited by SS. SS attenuates the rate of GH release without changing the duration of secretion and appears important in terminating GH secretion.