G. Corneli

Diagnostic reliability of a single IGF-I measurement in 237 adults with total anterior hypopituitarism and severe GH deficiency

objective Within an appropriate clinical context, GH deficiency (GHD) in adults must be demonstrated biochemically by a single provocative test. Insulin‐induced hypoglycaemia (ITT) and GH‐releasing hormone (GHRH) + arginine (ARG) are indicated as the tests of choice, provided that appropriate cut‐off limits are defined. Although IGF‐I is the best marker of GH secretory status, its measurement is not considered a reliable diagnostic tool. In fact, considerable overlap between GHD and normal subjects is present, at least when patients with suspected GHD are considered independently of the existence of other anterior pituitary defects. Considering the time and cost associated with provocative testing procedures, we aimed to re‐evaluate the diagnostic power of IGF‐I measurement.

Usefulness of IGF-I assay for the diagnosis of GH deficiency in adults

IGF-I is the best marker of GH secretory status but it also depends on the nutritional status and peripheral hormones such as insulin, glucocorticoids, thyroid hormones and gonadal steroids. Though monitoring IGF-I levels is the best way for evaluating appropriate GH replacement, the usefulness of IGF-I assay in the diagnosis of adult GH deficiency (GHD) is still matter of debate. To clarify this point in a large population of GHD adults (no.=135, 61 women and 74 men; age, mean±SE: 43.8±1.4 yr, range 20–80 yr) we studied IGF-I levels, their reproducibility and association to peak GH response to GHRH+arginine (GHRH+ARG) test and insulin tolerance test (ITT). The results in GHD were compared with those in a large population of normal subjects (no.=336, 233 women and 103 men, aged 20–80 yr). Mean IGF-I levels in GHD (77.8±4.9 µg/l) were clearly lower (p<0.001) than those in normal subjects (170.2±4.7 µg/I). In Childhood Onset GHD (CO-GHD; no.=40; age, mean±SE: 27.8±1.5 yr) IGF-I levels were lower than those in Adult Onset GHD (AO-GHD; no.=95, age, mean±SE: 50.7±1.4 yr) (56.6±9.7 vs 87.1 ±5.4 µg/l, p<0.0003). In both GHD and normal subjects IGF-I levels showed good, reproducibility (r=0.92, p<0.00001 and r=0.62, p<0.00001, respectively). In GHD, but not in normal subjects, IGF-I levels were positively associated to peak GH responses to GHRH+ARG (r=0.57, p<0.00001); on the other hand, the GH peak after ITT was not associated to IGF-I in GHD. In normal subjects, but not in GHD, IGF-I levels were negatively associated to age (r=−0.60, p<0.00001). Considering individual IGF-I levels there was a clear overlap between GHD and normal subjects. However, this overlap was strongly dependent on age. In fact, in the third and fourth decade of life 83.6% of GHD had IGF-I levels below the 3rd centile of normal values; on the other hand, in the fifth-sixth decade and in ageing 47% and only 12% of GHD, respectively, had IGF-I levels low for age. In conclusion, our results demonstrate that IGF-I levels represent a reproducible marker of GH status and are reduced more in CO-GHD than in AO-GHD adults. An overlap exists between GHD and normal subjects, however this is small up to the 4th decade of life. Thus, though normal IGF-I levels do not rule out the existence of GHD, up to 40 yr low IGF-I levels strongly point to GHD if malnutrition and liver disease have been ruled out.

Pituitary imaging abnormalities in patients with and without hypopituitarism after traumatic brain injury

Recent evidence suggests that patients with traumatic brain injury (TBI) are at substantial risk of hypopituitarism. The pathomechanisms, however, are not completely understood yet. Little is known about the association of morphological changes in the sella region with pituitary function in TBI. In this study, we assessed morphological abnormalities of the sella region in patients with TBI and their relation to endocrine function. We studied magnetic resonance (MR) or computed tomography (CT) scans of 22 patients with TBI [17 men, 5 women, age (mean±SD) 43.5±10.6 yr, time after trauma 17.4 ±15.0 yr]. Of these, 15 patients had some degree of hypopituitarism. We found abnormalities of the sella region in 80% of the patients with hypopituitarism and 29% of those without hypopituitarism (Fisher’s exact test, p=0.032). The most common abnormality was loss of volume or empty sella, followed by native signal inhomogeneities, perfusion deficit, and lack of neurohypophyseal signal. Our results indicate that pituitary imaging abnormalities are more common in TBI patients with hypopituitarism than those without. Both immediate trauma-induced pathology as necrosis and hemorrhage as well as multifactorial mid- to long-term changes may underlie these abnormalities.

Endocrine responses to ghrelin in adult patients with isolated childhood-onset growth hormone deficiency

objective Ghrelin, a 28 amino acid acylated peptide, is a natural ligand of the GH secretagogues (GHS) receptor (GHS‐R), which is specific for synthetic GHS. Similar to synthetic GHS, ghrelin strongly stimulates GH secretion but also displays significant stimulatory effects on lactotroph and corticotroph secretion. It has been hypothesized that isolated GH deficiency (GHD) could reflect hypothalamic impairment that would theoretically involve defect in ghrelin activity.

Diagnosis of GH deficiency in adults.

Within an appropriate clinical context, growth hormone deficiency (GHD) in adults must be demonstrated biochemically. The assays of insulin-like growth factor-I (IGF-I) and IGF binding protein-3 (IGFBP-3) per se do not establish the diagnosis of adult GHD. Similarly, the evaluation of spontaneous growth hormone (GH) secretion over 24 h has no diagnostic value in adulthood even when an ultra-sensitive GH assay is used. The diagnosis of adult GHD is established by provocative testing of GH secretion, and insulin-induced hypoglycaemia using the insulin tolerance test (ITT) is indicated as the test of choice. Alternative provocative tests of GH secretion have been proposed and have to be used with appropriate cut-off limits. Testing with GH releasing hormone (GHRH) alone has no diagnostic value, but when GHRH is given in combination with arginine or pyridostigmine it becomes the most potent and reproducible provocative test to evaluate the maximal secretory capacity of somatotrope cells. The potentiating effect of arginine on the GHRH-induced GH response is fully preserved while the stimulatory effect of GHRH + pyridostigmine is reduced in ageing. The GHRH + arginine test is well tolerated and reproducibly distinguishes between normal and GHD adult and elderly subjects. Thus, the GHRH + arginine test is the most promising alternative to the ITT provided that cut-off limits appropriate to its potent stimulatory effect are considered.

Insulin-Like Growth Factor I Levels and the Diagnosis of Adult Growth Hormone Deficiency

The current guidelines state that, within the appropriate clinical context, the diagnosis of adult growth hormone (GH) deficiency must be made biochemically using provocative tests. Measurement of insulin-like growth factor I (IGF-I) and binding protein 3 (IGFBP-3) levels cannot always distinguish between healthy and GH-deficient individuals. In particular, IGFBP-3 as a marker of GH status is clearly less sensitive than IGF-I and there is general agreement that its measurement does not provide useful diagnostic information. However, the diagnostic value of measuring IGF-I levels has been revisited recently. It has been confirmed that normal IGF-I levels do not rule out severe GH deficiency (GHD) in adults, in whom the diagnosis has therefore to be based on the demonstration of severe impairment of the peak GH response to provocative tests. It has also been emphasized that very low IGF-I levels in patients with high suspicion of GHD could be considered to be definite evidence for severe GHD. This assumption particularly applies to patients with childhood-onset, severe GHD or with multiple hypopituitary deficiencies acquired in adulthood. In addition, the use of IGF-I levels to monitor the efficacy and adequacy of recombinant human GH replacement remains widely accepted.

Both fasting-induced leptin reduction and GH increase are blunted in Cushing's syndrome and in simple obesity.

background  Simple obesity and Cushings syndrome (CS) are two clinical models of leptin hypersecretion coupled with GH hyposecretion. Fasting inhibits leptin while stimulating GH secretion in normal human subjects.

Occurrence of GH deficiency in adult patients who underwent neurosurgery in the hypothalamus–pituitary area for non-functioning tumour masses

Hypothalamus-pituitary tumours and their treatments (neurosurgery and/or radiotherapy) are major causes of acquired hypopituitarism. Scientific and clinical evidences show the positive effect of GH replacement therapy in severe adult GH deficiency (GHD) pointed toward the need of diagnostic screening of conditions at high risk for GHD. We screened 152 adults (82 males, 70 females; age: 52.3+/-1.2 years, age-range: 20-80 years, BMI: 26.4+/-0.8 kg/m(2)) in order to disclose the presence of GHD after neurosurgery for hypothalamus-pituitary tumours. The whole group (studied at least 3 months after neurosurgery) included: 111 non-functioning pituitary adenomas and 41 peri-pituitary tumours (24 craniopharyngiomas, 7 meningiomas, 5 cysts, 2 chondrosarcomas, 1 colesteatoma, 1 germinoma and 1 hemangiopericitoma). In 14 patients who underwent both neurosurgery and radiotherapy due to a tumour remnant, the somatotroph function was evaluated again 6 months after the end of radiotherapy. GHD was assumed to be shown by GH peak <5 microg/L (severe <3 microg/L) after Insulin Tolerance Test (ITT) or <16.5 microg/L (severe <9 microg/L) after GH-releasing hormone+arginine test (GHRH+ARG) (3rd and 1st centile limits of normality, respectively), two widely accepted provocative tests. Before neurosurgery GHD was present in 97/152 (63.8%) and resulted severe in 66/152 (43.4%) patients. After neurosurgery GHD was present in 122/152 (80.2%) and severe in 106/152 (69.7%). While 26 patients developed severe GHD (GHD) as consequence of neurosurgery, only one patient who had been classified as GHD before neurosurgery showed normal GH response after surgery. After neurosurgery, 91.0% (81/89) of the pan-hypopituitaric patients showed severe GHD. Considering the 14 patients who underwent also radiotherapy after neurosurgery, 7/14 had GHD before neurosurgery while 12/14 became severe GHD after radiotherapy in a context of pan-hypopituitarism. IGF-I levels below the 3rd age-related normal limits were present in 39.0% of patients in whom severe GHD was showed by provocative tests. In conclusion, this study shows that the occurrence of acquired severe GHD is extremely common in adult patients bearing non-functioning tumour masses in the hypothalamus-pituitary area and further increases after neurosurgery. All patients bearing non-functioning hypothalamus-pituitary tumours should undergo evaluation of their somatotroph function before and after neurosurgery that represents a condition at obvious more than high risk for hypopituitarism.

Short procedure of GHRH plus arginine test in clinical practice

Either in children or in adults, arginine (ARG) alone and combined with GHRH (GHRH + ARG) are reliable tests for the diagnosis of GH deficiency. The procedures of these tests generally include GH measurement every 15 min from baseline up to 90–120 min. Aim of our study was to verify if the procedure of these tests could be usefully shortened in clinical practice. To this goal we have studied 173 normally growing children and adolescents (C, 117 M and 56 F, age: 11.3 ± 0.4 yr.) and 125 young and middle aged normal adults (A, 68 M and 57 F, age: 30.0 ± 0.6 yr.). ARG alone test was performed by 81 C and 33 A (0.5 g/kg arginine, iv, from 0 to +30 min, up to a maximum of 30 g) while GHRH (1 μg/kg iv bolus at 0 min) + ARG test was performed by 92 C and 92 A. After ARG alone, taking into account data from +15 to +105 min, GH values above the 3rd centile limit of arbitrary cut-off (7 or 10 μg/1 in C and 5 μg/1 in A) occurred in 85% or 64% and 94% subjects, respectively. After GHRH + ARG test, taking into account only data at +30, +45, +60 min GH values above the 3rd centile limit (20 μg/1 in C and 16.5 μg/1 in A) occurred in 99% of subjects in both groups. Taking into account only these 3 timing points, the percentage of GH peak above the third centile limits after ARG alone was never higher than 60% in C and 85% in A. In conclusion, this study shows that single GHRH + arginine test can be reliably performed in a shortened procedure which makes easier the clinical practice and further reduces costs.

Different degrees of GH deficiency evidenced by GHRH+arginine test and IGF-I levels in adults with pituritary disease.

To verify if the entity of the peak GH responses to the GHRH+arginine (ARG) test is able to show different degree forms of GH deficiency (GHD), we linked these responses with the number of other anterior pituitary deficits. These anterior pituitary deficits were also related with IGF-I levels. To this purpose, we studied a large cohort of lean patients with pituitary disease of different etiologies [86 males and 68 females; age: mean±SEM 41.5±1.2 yr, body mass index (BMI) <25 kg/m2]. The patients were subdivided into 4 groups according to the increasing number of hormone deficiencies: isolated GHD (HYPO1, no.=28) or GHD plus one, two or three additional hormones (gonadotrophin, ACTH, and TSH) deficiencies (HYPO2, no.=20; HYPO3, no.=15; HYPO4, no.=91). Peak GH responses to the GHRH+ARG test and IGF-I levels showed a clear difference among the groups (p<0.01 and p<0.001, respectively). A significant difference was found between HYPO1 and HYPO4 for IGF-I levels (p<0.05), and between HYPO1 and HYPO4 and between HYPO2 and HYPO4 for the GHRH+ARG test (p<0.005). Considering only the patients who underwent both GHRH+ARG test and insulin tolerance test (ITT) (no.=70), the pattern of the peak GH responses to the GHRH+ARG test was the same of the whole group of patients, while no statistical difference was found with ITT. Our data show that the peak GH responses to the GHRH+ARG test and the IGF-I levels are linked to the severity of hypopituitarism, expressed by the number of increasing anterior pituitary deficits. This association is lost if the evaluation of the GH status is performed by the ITT. In all, the GHRH+ARG test and measurement of IGF-I are able to evidence different degrees of GHD in adult patients with pituitary disease.