What Is Hidden Behind Growth Hormone Deficiency? The Neuroradiologist's Perspective.

SAT-LB19 Is There a Need to Use Gadolinium Contrast for Pituitary MRI in the Evaluation of Pediatric Short Stature and Growth Hormone Deficiency?

Reassessment of GH status after the attainment of adult height has important clinical implications in the diagnosis and prognosis of GH deficiency (GHD) in adulthood. The current GH threshold for biochemical definition of GHD in young adults is still a subject of debate. To investigate the role of pharmacological stimulation tests compared with spontaneous 12-h nocturnal GH secretion in the diagnosis of permanent GHD in young adults with childhood-onset GHD. Forty-five young adults (25 males, 20 females) with childhood-onset GHD, height standard deviation score (SDS) -1.1 +/- 1.3 and body mass index (BMI) SDS 1.0 +/- 1.6, were re-evaluated at the age of 19.8 +/- 2.7 years. Sixteen subjects showed a normal pituitary gland on magnetic resonance imaging (MRI), while in 29, consistent structural hypothalamic-pituitary abnormalities were found. GH secretion was assessed by means of an insulin tolerance test (ITT) and a 12-h spontaneous nocturnal profile as well as by IGF-I assessment. The results were compared with those of 43 healthy controls. Mean 12-h spontaneous nocturnal GH secretion was < 3.1 microg/l (the lowest limit of the normal range) in 36 (80%) of the subjects and > 3.1 microg/l in nine (20%). Of these 36 patients, 29 (80%) had abnormal MRI findings and 20 (55%) had multiple pituitary hormone deficiencies (MPHD). All nine subjects with mean spontaneous GH secretion > 3.1 microg/l had a normal pituitary MRI, isolated GHD and a peak GH response to ITT > 5 microg/l. There was a discordance in 14 patients (31%), who showed a peak GH response to ITT > 5 microg/l but a reduced spontaneous GH secretory capacity; 10 had structural hypothalamic-pituitary abnormalities on MRI. Although the ITT provides valuable information and proves to be a sensitive index of permanent GHD, the results of this study emphasize the potential diagnostic value of assessment of 12-h spontaneous GH secretion in young adults with childhood-onset GHD.

Background/Aims: The diagnosis of growth hormone (GH) deficiency (GHD) in infancy and early childhood is not straightforward. GH stimulation tests are unsafe and unreliable in infants, and normative data are lacking. This study aims to investigate whether brain magnetic resonance imaging (MRI) may replace GH stimulation tests in the diagnosis of GHD in children younger than 4 years. Methods: We examined a retrospective cohort, with longitudinal follow-up, of 68 children consecutively diagnosed with GHD before the age of 4 years. The prevalence of hypothalamic-pituitary (HP) alterations at MRI and the associations with age and either isolated GHD (IGHD) or multiple pituitary hormone deficiency (MPHD) were assessed. Results: The prevalences of IGHD and MPHD were 54.4 and 45.6%, respectively. In the first group, brain MRI showed abnormalities in 83.8%: isolated pituitary hypoplasia in 48.7% and complex defects in 35.1%. In patients with MPHD, MRI showed complex alterations in 100%. All children younger than 24 months showed HP MRI abnormalities, regardless of the diagnosis. Complex defects were found in 94% of patients younger than 12 months and in 75% of patients between 13 and 24 months. Conclusion: Our data suggest that brain MRI may represent the first-line investigation for diagnosing GHD in infancy and early childhood.

GH secretion was reevaluated after completion of GH treatment at a mean age of 19.2 +/- 3.2 yr in 35 young adults with childhood-onset GH deficiency (GHD). The patients were subdivided into 4 groups according to their first pituitary magnetic resonance imaging (MRI) findings: group I, 11 patients with isolated GHD (IGHD) and normal pituitary volume (280 +/- 59.4 mm3); group II, 7 patients with IGHD and small pituitary gland (163.1 +/- 24.4 mm3; P = 0.0009 vs. group I); group III, 13 patients (5 with IGHD and 8 with multiple pituitary hormone deficiency) with congenital hypothalamic-pituitary abnormalities such as pituitary hypoplasia (95.8 +/- 39.3 mm3; P < 0.00001 vs. group I and P = 0.003 vs. group II), pituitary stalk agenesis, and posterior pituitary ectopia; and group IV, 4 patients with multiple pituitary hormone deficiency secondary to craniopharyngioma. Pituitary MRI and GH secretory status were reevaluated after GH withdrawal using arginine, insulin induced-hypoglycemia, and sequential arginine-insulin tests. Serum insulin-like growth factor I (IGF-I) and IGF-binding protein-3 (IGFBP-3) were determined at the time of retesting and 6, 12, and 24 months after discontinuation of treatment in the patients with permanent GHD and after 6 months in those with normal GH responses to stimulation. The patients in groups I and II showed a normal response to stimulation after completion of GH treatment regardless of pituitary size, whereas all patients in groups III and IV still had a GH response of less than 3 microg/L to any of the tests. Pituitary volume normalized in 6 of 7 patients in group II, whereas in all patients in group III MRI studies confirmed the initial findings. Mean IGF-I and IGFBP-3 concentrations at the time of retesting were significantly higher in groups I and II than in groups III and IV. In patients of groups III and IV, mean IGF-I was significantly decreased after 6 and 12 months, whereas IGFBP-3 was significantly decreased 12 months after treatment withdrawal. Our results confirm that a high proportion of children with IGHD and normal or small pituitary show normalization of GH secretion at the completion of GH treatment, whereas GHD is permanent in all patients with pituitary hypoplasia, pituitary stalk agenesis, and posterior pituitary ectopia. IGF-I and IGFBP-3 determinations shortly after GH withdrawal had limited value in the diagnosis of GHD of childhood onset associated with congenital hypothalamic-pituitary abnormalities, but became accurate after 6-12 months. We suggest that patients with GHD and congenital hypothalamic-pituitary abnormalities do not require further investigation of GH secretion, whereas patients with IGHD and normal or small pituitary gland should be retested well before the attainment of adult height.

GH secretion was reevaluated after completion of GH treatment at a mean age of 19.2 ± 3.2 yr in 35 young adults with childhood-onset GH deficiency (GHD). The patients were subdivided into 4 groups according to their first pituitary magnetic resonance imaging (MRI) findings: group I, 11 patients with isolated GHD (IGHD) and normal pituitary volume (280 ± 59.4 mm3); group II, 7 patients with IGHD and small pituitary gland (163.1 ± 24.4 mm3; P = 0.0009 vs. group I); group III, 13 patients (5 with IGHD and 8 with multiple pituitary hormone deficiency) with congenital hypothalamic-pituitary abnormalities such as pituitary hypoplasia (95.8 ± 39.3 mm3; P < 0.00001 vs. group I and P = 0.003 vs. group II), pituitary stalk agenesis, and posterior pituitary ectopia; and group IV, 4 patients with multiple pituitary hormone deficiency secondary to craniopharyngioma. Pituitary MRI and GH secretory status were reevaluated after GH withdrawal using arginine, insulin induced-hypoglycemia, and sequential arginine-insulin tests. Serum insulin-like growth factor I (IGF-I) and IGF-binding protein-3 (IGFBP-3) were determined at the time of retesting and 6, 12, and 24 months after discontinuation of treatment in the patients with permanent GHD and after 6 months in those with normal GH responses to stimulation. The patients in groups I and II showed a normal response to stimulation after completion of GH treatment regardless of pituitary size, whereas all patients in groups III and IV still had a GH response of less than 3 μg/L to any of the tests. Pituitary volume normalized in 6 of 7 patients in group II, whereas in all patients in group III MRI studies confirmed the initial findings. Mean IGF-I and IGFBP-3 concentrations at the time of retesting were significantly higher in groups I and II than in groups III and IV. In patients of groups III and IV, mean IGF-I was significantly decreased after 6 and 12 months, whereas IGFBP-3 was significantly decreased 12 months after treatment withdrawal. Our results confirm that a high proportion of children with IGHD and normal or small pituitary show normalization of GH secretion at the completion of GH treatment, whereas GHD is permanent in all patients with pituitary hypoplasia, pituitary stalk agenesis, and posterior pituitary ectopia. IGF-I and IGFBP-3 determinations shortly after GH withdrawal had limited value in the diagnosis of GHD of childhood onset associated with congenital hypothalamic-pituitary abnormalities, but became accurate after 6–12 months. We suggest that patients with GHD and congenital hypothalamic-pituitary abnormalities do not require further investigation of GH secretion, whereas patients with IGHD and normal or small pituitary gland should be retested well before the attainment of adult height.

The pituitary origin of ACTH secretion in ACTH-dependent hypercortisolism can be difficult to assess, as magnetic resonance imaging (MRI) frequently fails to identify ACTH-secreting microadenomas or, on the contrary, may give false positive images of microadenomas. The choice of therapeutic option for patients with such normal MRI findings is controversial. Some groups propose routinely pituitary surgery, whereas others consider that neurosurgical exploration may be less successful and more harmful, and therefore prefer other types of management. The aim of this study was to compare surgical outcomes between patients with Cushing's disease (CD) and normal vs. positive pituitary MRI findings. Fifty-four patients (44 women and 10 men) with CD, operated on after 1996 in two centers (Kremlin-Bicêtre and Bordeaux) and followed postoperatively during a mean period of 19.9 +/- 22.7 months (range, 1-89 months), were enrolled in this retrospective study. Twenty-eight patients had normal pituitary MRI findings, and the pituitary origin of ACTH was established by bilateral petrosal sinus sampling in all of these cases. Twenty-six patients had positive MRI findings clearly showing a microadenoma. The two groups were not significantly different in terms of the sex ratio, age, frequency of hypertension, or diabetes, basal 24-h urinary free cortisol levels and follow-up. All of the patients were operated on by two experienced neurosurgeons using the same surgical protocol. Selective adenomectomy was performed when a tumor was identified, and subtotal hypophysectomy was performed when the lesion was uncertain or when no tumor was found during surgical exploration. Respectively, 50% and 84% of patients with normal and positive MRI results underwent adenomectomy (P < 0.05). A pituitary adenoma (confirmed by pathological examination) was found at surgery in 53% and 88% of patients in the normal and positive MRI groups, respectively (P < 0.05). The early surgical success rate (combining patients with corticotropic deficiency and patients with eucortisolism) was similar in the normal and positive MRI groups (78% and 88%, respectively; P = 0.85). The recurrence rate was lower in the normal MRI group, but the difference did not reach statistical significance (9% vs. 30%; P = 0.07). The final remission rate at the last visit was similar in the normal and positive MRI groups (72% and 61%, respectively; P = 0.29). Postoperative complications were also similar: 10 patients (36%) with normal MRI and five patients (20%) with positive MRI had at least one postoperative complication (surgical and/or pituitary deficiency; P = 0.12). Thus, the outcome of pituitary surgery in CD appears to be similar regardless of whether pituitary MRI shows a microadenoma. We recommend neurosurgical pituitary exploration as the first-line treatment of CD, provided that the pituitary origin of ACTH secretion is confirmed by bilateral petrosal sinus sampling in patients with normal pituitary MRI findings.

Introduction: Short stature is a common concern that necessitates pediatric endocrinology evaluation. Growth hormone deficiency (GHD) is a commonly considered etiology. Brain and pituitary magnetic resonance imaging (MRI) with gadolinium-based contrast agents (GBCAs) is the most widely used imaging in assessing patients with GHD. Given the significant strides made in MRI technology, the need for contrast material should be reassessed. Method: We performed a retrospective review of healthy patients with short stature and/or GHD who underwent brain and pituitary MRI with and without contrast to assess the added value of contrast administration. Results: 227/318 identified patients underwent growth hormone (GH) stimulation testing; 28 (12.3%) with normal GH response and 62 (27.3%) with severe GHD. We found a low incidence of sellar and suprasellar pathologies. When comparing noncontrast and contrast MRI, we found perfect agreement in detecting abnormal posterior pituitary bright spots (kappa:1.0) and substantial agreement in detecting pars intermedia cysts and posterior superior sellar cysts (kappa: 0.74 and 0.71, respectively). Initially, only moderate agreement was found in detecting infundibular abnormalities (kappa: 0.51), although a revised noncontrast MRI protocol with high-resolution 3D images enabled visualization of the infundibulum. Conclusion: The MRI evaluation of healthy patients with short stature and/or isolated GHD may be completed without the use of GBCAs. The slight overestimation of pituitary stalk interruption by noncontrast images can be overcome by adding newer high-resolution sequences.

Neck MR Imaging Anatomy

BackgroundNumerous short-statured children are evaluated for growth hormone (GH) deficiency (GHD). In most patients, GH provocative tests are normal and are thus in retrospect unnecessary.MethodsA retrospective cohort study was conducted to identify predictors of growth hormone (GH) deficiency (GHD) in children seen for short stature, and to construct a very sensitive and fairly specific predictive tool to avoid unnecessary GH provocative tests. GHD was defined by the presence of 2 GH concentration peaks < 10 ng/ml. Certain GHD was defined as GHD and viewing pituitary stalk interruption syndrome on magnetic resonance imaging. Independent predictors were identified with uni- and multi-variate analyses and then combined in a decision rule that was validated in another population.ResultsThe initial study included 167 patients, 36 (22%) of whom had GHD, including 5 (3%) with certain GHD. Independent predictors of GHD were: growth rate < -1 DS (adjusted odds ratio: 3.2; 95% confidence interval [1.3–7.9]), IGF-I concentration < -2 DS (2.8 [1.1–7.3]) and BMI z-score ≥ 0 (2.8 [1.2–6.5]). A clinical decision rule suggesting that patients be tested only if they had a growth rate < -1 DS and a IGF-I concentration < -2 DS achieved 100% sensitivity [48–100] for certain GHD and 63% [47–79] for GHD, and a specificity of 68% [60–76]. Applying this rule to the validation population (n = 40, including 13 patients with certain GHD), the sensitivity for certain GHD was 92% [76–100] and the specificity 70% [53–88].ConclusionWe have derived and performed an internal validation of a highly sensitive decision rule that could safely help to avoid more than 2/3 of the unnecessary GH tests. External validation of this rule is needed before any application.

Until the advent of magnetic resonance imaging (MRI), only small advances were made in the field of pituitary imaging. MRI, however, led to an enormous increase in our detailed knowledge of pituitary morphology, thus improving the differential diagnosis of hypopituitarism. Indeed, MRI represents the examination method of choice for evaluating hypothalamic-pituitary-related endocrine diseases thanks to its ability to provide strongly contrasted high-resolution multiplanar and spatial images. Specifically, MRI allows for a detailed and precise anatomical study of the pituitary gland by differentiating between the anterior and posterior pituitary lobes. The MRI identification of pituitary hyperintensity in the posterior part of the sella, now considered a marker of neurohypophyseal functional integrity, has been the most striking finding for the diagnosis and understanding of some forms of “idiopathic” and permanent growth hormone deficiency (GHD). Published data show a number of correlations between pituitary abnormalities as observed on MRI and a patient’s endocrine profile. Indeed, several trends have emerged and have been confirmed: (1) normal MRI or anterior pituitary hypoplasia generally indicates isolated GHD which is transient and not confirmed after adult height achievement; (2) patients with MPHD seldom show a normal pituitary gland; (3) the classic triad of ectopic posterior pituitary gland, pituitary stalk hypoplasia/agenesis, and anterior pituitary gland hypoplasia is more frequently reported in MPHD patients and is generally associated with permanent GHD. Pituitary abnormalities have been reported in patients with GHD carrying mutations in several genes encoding transcription factors such as POU1F1, PROP1, HESX1, LHX3, LHX4, GLI2, PITX1, PITX2, SOX3, SOX2, and OTX2. Establishing endocrine and MRI phenotypes is extremely helpful in the selection and management of patients with hypopituitarism, both in terms of possible genetic counseling, as well as that of early diagnosis of evolving anterior pituitary hormone deficiencies.

We analyzed the final height of 146 short children with either nonacquired GH deficiency or idiopathic short stature. Our purpose was 1) to assess growth according to the pituitary magnetic resonance imaging findings in the 63 GH-treated children with GH deficiency and 2) to compare the growth of the GH-deficient patients with normal magnetic resonance imaging (n = 48) to that of 32 treated and 51 untreated children with idiopathic short stature (GH peak to provocative tests >10 microg/liter). The mean GH dose was 0.44 IU/kg.wk (0.15 mg/kg.wk), given for a mean duration of 4.6 yr. Among the GH-deficient children, 15 had hypothalamic-pituitary abnormalities (stalk agenesis), all with total GH deficiency (GH peak <5 microg/liter). They were significantly shorter and younger at the time of diagnosis than those with normal magnetic resonance imaging, had better catch-up growth (+2.7 +/- 0.9 vs. +1.3 +/- 0.8 SD score; P < 0.01), and reached greater final height (-1.1 +/- 1.0 vs. -1.7 +/- 1.0 SD score; P < 0.05). Among patients with normal magnetic resonance imaging, there was no difference in catch-up growth and final height between partial and total GH deficiencies. GH-deficient subjects with normal magnetic resonance imaging and treated and untreated patients with idiopathic short stature had comparable auxological characteristics, age at evaluation, and target height. Although they had different catch-up growth (+1.3 +/- 0.8, +0.9 +/- 0.6, and +0.7 +/- 0.9 SD score, respectively; P < 0.01, by ANOVA), these patients reached a similar final height (-1.7 +/- 1.0, -2.1 +/- 0.8, and -2.1 +/- 1.0 SD score, respectively; P = 0.13). Pituitary magnetic resonance imaging findings show the heterogeneity within the group of nonacquired GH deficiency and help to predict the response to GH treatment in these patients. The similarities in growth between the GH-deficient children with normal magnetic resonance imaging and those with idiopathic short stature suggest that the short stature in the former subjects is at least partly due to factors other than GH deficiency.

Recombinant hGH (rhGH) therapy may unmask central hypoadrenalism in adults with organic GH deficiency (GHD), likely by normalizing 11beta-hydroxysteroid dehydrogenase type 1 isoenzyme (11betaHSD1) activity and reducing cortisone to cortisol conversion. The aim of the present study was to evaluate the hypothalamic-pituitary-adrenal (HPA) axis in children with idiopathic isolated GHD and normal pituitary magnetic resonance imaging (MRI) both before and during rhGH therapy. This was a single-centre study of 10 consecutive children [five males and five females, mean age: 12.2 +/- 1.0 year]. Evaluation was performed at baseline and on rhGH (mean duration: 10.9 +/- 2.9 months, mean dose: 0.030 +/- 0.002 mg/kg bw/day). HPA function was assessed by serum cortisol levels before and after appropriate provocative stimuli, that is, 1 microg ACTH test (N = 5 patients) or insulin tolerance test (ITT, N = 5 patients), evaluating all children with the same stimulation test both before and during rhGH therapy. Central hypoadrenalism was excluded by the presence of either a peak of > 500 nmol/l or a rise in cortisol levels of > 200 nmol/l, after both tests. On rhGH therapy, serum IGF-I levels normalized, while serum cortisol and ACTH levels did not significantly differ from those recorded at baseline. The mean serum cortisol peak after both provocative tests was not significantly different on rhGH therapy and at baseline (498 +/- 41 vs. 580 +/- 35 nmol/l, respectively, P = 0.06), the mean cortisol rise being 280 +/- 45 and 270 +/- 36 nmol/l on rhGH and at baseline, respectively. According to the diagnostic criteria, no child became hypoadrenal on rhGH, contrary to what observed in patients with organic GHD, further supporting the view that only in patients with organic multiple pituitary hormone deficiency GHD masks the presence of a hidden central hypoadrenalism.

There is controversy as to whether brain magnetic resonance imaging (MRI) should be performed on all children with growth hormone deficiency (GHD) including those judged to have mild GHD. This study was aimed to determine the frequency of pituitary or intracranial abnormalities in pediatric GHD and to identify risk factors that may predict pituitary or intracranial abnormalities. A total of 95 pediatric GHD patients were included. Their medical records and brain magnetic resonance (MR) images were reviewed retrospectively. Abnormal pathogenic MR images were found in 14 patients (14.7%), including 10 (10.5%) with pituitary hypoplasia and 4 (4.2%) with pituitary stalk interruption syndrome. Serum levels of insulin-like growth factor-I (IGF-I), IGF-I standard deviation score (SDS), insulin-like growth factor binding protein 3 (IGFBP3), and growth hormone (GH) peak level of GH stimulation test were statistically significantly lower in the group with abnormal brain MRI. The frequency of abnormal MRI was statistically significantly higher in the complete GHD group. IGF-1 SDS showed the highest area under the curve which can predict the presence of brain abnormality with a sensitivity of 85% and a specificity of 71.4%, if IGF-1 SDS was less than -1.365. IGF-1, IGFBP3, and GH peak levels also showed good sensitivity of over 80% for predicting brain abnormalities with cutoff values of 70.285 ng/mL, 1,604 ng/mL, and 4.205 ng/mL, respectively. The sensitivity and specificity of each cutoff value of IGF-1, IGF-1 SDS, IGFBP3, and GH peak levels were good and statistically significant in predicting brain MRI abnormalities. However, it was insufficient to predict all brain abnormalities with these variables. Therefore, we would like to recommend performing a brain MRI if a child is diagnosed with GHD.

The aim of this study was to verify the persistence in adulthood of GH deficiency diagnosed in childhood and treated with hGH in childhood and to study whether anatomical hypothalamic-pituitary alterations evaluated by magnetic resonance (MR) imaging could predict it. To this goal, in six GHD adults (3 males and 3 females aged 17.2-24.5 yr, BMI 21.8 +/- 1.3), we studied anterior pituitary hormone response to GHRH (1 microgram/kg iv)+pyridostigmine (120 mg po)+ GnRH (100 micrograms iv) +TRH (400 micrograms iv)+hCRH (100 micrograms iv) as well as brain MR imaging. In childhood, the diagnosis of severe isolated GHD had been done based on auxological findings as well as on GH response < 7 micrograms/L after two classical provocative stimuli. In the present study, hormonal responses showed the persistence of severe isolated GHD in 4 out of 6 patients (peak, mean +/- SEM: 3.8 +/- 0.6, range 2.6-4.8 micrograms/L). In these patients, IGF-I levels were found low or low-normal. In other 2 patients, a clear GH response to stimulation (peak: 51.3 and 43.0 micrograms/L, respectively) together with normal IGF-I levels were found. No other anterior pituitary hormone deficiency was present in all subjects. MR imaging showed pituitary hypoplasia in all patients with persistent GHD; in 2 out of them, pituitary stalk interruption and ectopic neurohypophysis was also present. On the other hand, MR imaging showed normal hypothalamo-pituitary morphology in the 2 subjects with normal somatotrope response. In conclusion, our present data indicate that testing with a potent stimulus such as GHRH+pyridostigmine is a reliable method to assess the persistence of GH deficiency which associates with anatomical hypothalamic-pituitary alterations at the MR imaging. Patients with transient GH deficiency in childhood and normal pituitary GH reserve in adulthood have normal hypothalamic-pituitary MR imaging.

Growth hormone deficiency (GHD) is a key differential diagnosis in children with proportionate short stature. While brain magnetic resonance imaging (MRI) is recommended for all confirmed GHD cases to rule out hypothalamic-pituitary anomalies, its universal application remains debated We conducted a retrospective, single-center study including 84 pediatric patients diagnosed with isolated GHD Brain MRI revealed hypothalamic-pituitary abnormalities in 27.4%. Compared to those with normal MRIs, patients with abnormalities were younger (6.78 ± 2.72 vs 8.34 ± 3.38 years, P = .038), shorter (height SDS −2.83 ± 0.58 vs −2.56 ± .64, P = .032), and had lower IGF-1 SDS (−1.07 ± .66 vs −.78 ± .70, P = .041). Multivariate logistic regression confirmed age, height SDS, and IGF-1 SDS as independent predictors of MRI anomalies. ROC analysis identified cutoff values with moderate predictive accuracy: age <7.1 years, height SDS <−2.7, and IGF-1 SDS <−.9.