Trends In Growth Hormone Stimulation Testing And Growth Hormone Dosing In Adult Growth Hormone Deficiency Patients: Results From The Answer Program

Objective: Adult growth hormone deficiency (AGHD) results in physiologic impairments that may reduce quality of life and negatively impact body composition. AGHD can be treated with recombinant human growth hormone (GH). This study analyzes AGHD patients enrolled in the American Norditropin® Studies: Web-Enabled-Research (ANSWER) Program/NovoNet, a U.S. observational noninterventional study of patients treated with Norditropin® (somatropin [recombinant DNA origin] injection) at the discretion of their physicians.Methods: Data were evaluated for GH stimulation test (GHST) usage and Norditropin® doses over 4 years.Results: Adults (N = 468) with isolated GHD (IGHD) or multiple pituitary hormone deficiency (MPHD) were evaluated. The most commonly used GHSTs were arginine + L-dopa (27%; mostly a single center) and glucagon (25%; most frequent test after 2009). The percent of patients meeting recommended test-specific cut points varied from 32 to 100%, depending on the GHST used. Mean baseline GH doses were higher for MPHD patients and for younger patients in both IGHD and MPHD groups.Conclusion: MPHD was more common than IGHD. Mean GH doses were higher in younger patients, consistent with a transition from higher pediatric to lower adult dosing. Over time, glucagon became the most popular GHST. The use, in some patients, of other GHSTs with cut points, as well as starting doses not consistent with current recommendations, highlights the need for continued education regarding treatment guidelines for AGHD.Abbreviations:AACE = American Association of Clinical EndocrinologistsAGHD = adult growth hormone deficiencyANSWER = American Norditropin® Studies: Web-Enabled-ResearchBMI = body mass indexGH = growth hormoneGHD = growth hormone deficiencyGHRH = growth hormone-releasing hormoneGHST = growth hormone stimulation testIGF-1 = insulin-like growth factor-1IGHD = isolated growth hormone deficiencyITT = insulin tolerance testKIMS = Pfizer International Metabolic DatabaseMPHD = multiple pituitary hormone deficiencyTES = The Endocrine Society     

American Association of Clinical Endocrinologists and American College of Endocrinology Guidelines for Management of Growth Hormone Deficiency in Adults and Patients Transitioning from Pediatric to Adult Care

Objective: The development of these guidelines is sponsored by the American Association of Clinical Endocrinologists (AACE) Board of Directors and American College of Endocrinology (ACE) Board of Trustees and adheres with published AACE protocols for the standardized production of clinical practice guidelines (CPG).Methods: Recommendations are based on diligent reviews of clinical evidence with transparent incorporation of subjective factors, according to established AACE/ACE guidelines for guidelines protocols.Results: The Executive Summary of this 2019 updated guideline contains 58 numbered recommendations: 12 are Grade A (21%), 19 are Grade B (33%), 21 are Grade C (36%), and 6 are Grade D (10%). These detailed, evidence-based recommendations allow for nuance-based clinical decision-making that addresses multiple aspects of real-world care of patients. The evidence base presented in the subsequent Appendix provides relevant supporting information for the Executive Summary recommendations. This update contains 357 citations of which 51 (14%) are evidence level (EL) 1 (strong), 168 (47%) are EL 2 (intermediate), 61 (17%) are EL 3 (weak), and 77 (22%) are EL 4 (no clinical evidence).Conclusion: This CPG is a practical tool that practicing endocrinologists and regulatory bodies can refer to regarding the identification, diagnosis, and treatment of adults and patients transitioning from pediatric to adult-care services with growth hormone deficiency (GHD). It provides guidelines on assessment, screening, diagnostic testing, and treatment recommendations for a range of individuals with various causes of adult GHD. The recommendations emphasize the importance of considering testing patients with a reasonable level of clinical suspicion of GHD using appropriate growth hormone (GH) cut-points for various GH–stimulation tests to accurately diagnose adult GHD, and to exercise caution interpreting serum GH and insulin-like growth factor-1 (IGF-1) levels, as various GH and IGF-1 assays are used to support treatment decisions. The intention to treat often requires sound clinical judgment and careful assessment of the benefits and risks specific to each individual patient. Unapproved uses of GH, long-term safety, and the current status of long-acting GH preparations are also discussed in this document.LAY ABSTRACTThis updated guideline provides evidence-based recommendations regarding the identification, screening, assessment, diagnosis, and treatment for a range of individuals with various causes of adult growth-hormone deficiency (GHD) and patients with childhood-onset GHD transitioning to adult care. The update summarizes the most current knowledge about the accuracy of available GH–stimulation tests, safety of recombinant human GH (rhGH) replacement, unapproved uses of rhGH related to sports and aging, and new developments such as long-acting GH preparations that use a variety of technologies to prolong GH action. Recommendations offer a framework for physicians to manage patients with GHD effectively during transition to adult care and adulthood. Establishing a correct diagnosis is essential before consideration of replacement therapy with rhGH. Since the diagnosis of GHD in adults can be challenging, GH–stimulation tests are recommended based on individual patient circumstances and use of appropriate GH cut-points. Available GH–stimulation tests are discussed regarding variability, accuracy, reproducibility, safety, and contraindications, among other factors. The regimen for starting and maintaining rhGH treatment now uses individualized dose adjustments, which has improved effectiveness and reduced reported side effects, dependent on age, gender, body mass index, and various other individual characteristics. With careful dosing of rhGH replacement, many features of adult GHD are reversible and side effects of therapy can be minimized. Scientific studies have consistently shown rhGH therapy to be beneficial for adults with GHD, including improvements in body composition and quality of life, and have demonstrated the safety of short- and long-term rhGH replacement.Abbreviations: AACE = American Association of Clinical Endocrinologists; ACE = American College of Endocrinology; AHSG = alpha-2-HS-glycoprotein; AO-GHD = adult-onset growth hormone deficiency; ARG = arginine; BEL = best evidence level; BMD = bone mineral density; BMI = body mass index; CI = confidence interval; CO-GHD = childhood-onset growth hormone deficiency; CPG = clinical practice guideline; CRP = C-reactive protein; DM = diabetes mellitus; DXA = dual-energy X-ray absorptiometry; EL = evidence level; FDA = Food and Drug Administration; FD-GST = fixed-dose glucagon stimulation test; GeNeSIS = Genetics and Neuroendocrinology of Short Stature International Study; GH = growth hormone; GHD = growth hormone deficiency; GHRH = growth hormone–releasing hormone; GST = glucagon stimulation test; HDL = high-density lipoprotein; HypoCCS = Hypopituitary Control and Complications Study; IGF-1 = insulin-like growth factor-1; IGFBP = insulin-like growth factor–binding protein; IGHD = isolated growth hormone deficiency; ITT = insulin tolerance test; KIMS = Kabi International Metabolic Surveillance; LAGH = long-acting growth hormone; LDL = low-density lipoprotein; LIF = leukemia inhibitory factor; MPHD = multiple pituitary hormone deficiencies; MRI = magnetic resonance imaging; P-III-NP = procollagen type-III amino-terminal pro-peptide; PHD = pituitary hormone deficiencies; QoL = quality of life; rhGH = recombinant human growth hormone; ROC = receiver operating characteristic; RR = relative risk; SAH = subarachnoid hemorrhage; SDS = standard deviation score; SIR = standardized incidence ratio; SN = secondary neoplasms; T3 = triiodothyronine; TBI = traumatic brain injury; VDBP = vitamin D-binding protein; WADA = World Anti-Doping Agency; WB-GST = weight-based glucagon stimulation test     

Clonidine Stimulation Test For Gh Deficiency: A New Look At Sample Timing

Objective: In the glucagon stimulation test (GST), the occurrence of peak growth hormone (GH) levels at typical times is an indication of normal secretion. This has not been studied for the clonidine stimulation test (CST). The 120-minute time is rarely the peak, and previous reports suggest it can be omitted. This study aimed to evaluate the meaning and utility of peak time in the CST and the significance of shortening the test.Methods: CSTs performed on 250 consecutive subjects in a single center were evaluated for results (GH sufficient or deficient) and result of confirmatory GST with respect to the peak time of the CST.Results: Peak GH occurred typically at 30, 60, and 90 minutes (91.6% of tests, versus 60% expected) (P<.001). A total of 132 of 155 (85.15%) sufficient tests occurred at typical times, versus 66 of 97 (68%) deficient tests (P<.05). Typicality of timing did not follow in the confirmatory GST and did not predict the final result of testing. Removal of the 120-minute sample affected the final result in 0.4% of evaluations.Conclusion: The timing of the GH peak is not useful when interpreting the CST. The CST is equally effective when terminated at 90 minutes from stimulation.Abbreviations:AST = arginine stimulation testCST = clonidine stimulation testGH = growth hormoneGST = glucagon stimulation test     

Serum Free Cortisol During Glucagon Stimulation Test In Healthy Short-Statured Children And Adolescents

Objective: The total cortisol (TC) response may be measured during the glucagon stimulation test (GST) for growth hormone (GH) reserve in order to assess the integrity of the hypothalamic-pituitary-adrenal (HPA) axis. Measurements of TC are unreliable in conditions of albumin and cortisol-binding globulin (CBG) alterations (e.g., hypoproteinemia or CBG deficiency). We aimed to measure the serum free cortisol (sFC) response to the GST in children and adolescents and determine whether it could predict the GH response to glucagon stimulation.Methods: Infants and children with either short stature or growth attenuation who were referred for evaluation of GH reserve underwent the GST.Results: The study population consisted of 103 subjects (62 females), median age 3.9 years (range, 0.5–14). The mean basal and peak TC levels were 13.3 ± 6.7 μg/dL and 29.6 ± 8.8 μg/dL, respectively. The mean basal and peak sFC levels were 0.7 ± 0.8 μg/dL and 1.7 ± 1.1 μg/dL, respectively. There was a negative correlation between peak TC and age (r = -0.3, P = .007) but not between peak sFC and age (r = -0.09, P = .36). Ninety-five percent of the patients had peak TC levels >15.8 μg/dL and peak sFC levels >0.6 μg/dL.Conclusion: Our results on a cohort of healthy short-statured children can serve as reference values for the sFC response during GST. Based on these results, we propose peak TC levels >15.8 μg/dL and peak sFC levels >0.6 μg/dL for defining normalcy of the HPA axis during the GST in children and adolescents.Abbreviations:ACTH = adrenocorticotrophic hormoneBMI = body mass indexCBG = cortisol-binding globulinGH = growth hormoneGST = glucagon stimulation testHPA = hypothalamic-pituitary-adrenalSDS = standard deviation scoresFC = serum free cortisolTC = total cortisol     

Similar clinical features among patients with severe adult growth hormone deficiency diagnosed with insulin tolerance test or arginine or glucagon stimulation tests

ObjectiveTo determine whether insulin tolerance tests (ITTs), arginine stimulation tests (ASTs), and glucagon stimulation tests (GST) identify patients who have similar clinical features of growth hormone (GH) deficiency when a diagnostic GH threshold of 3 μg/L is used.MethodsData were obtained from the KIMS database (Pfizer International Metabolic Database). Comparisons were made between patients who underwent ITT, AST, or GST for GH peak, body mass index, lipids, waist circumference, waist-to-hip ratio, and quality of life.ResultsA total of 5453 tests were available from 4867 patients registered in the database (ITT = 3111, AST To purchase reprints of this article, please visit: www.aace.com/reprints. Copyright © 2012 AACE = 1390, GST = 952). Significant (P < .001) intraindividual correlations were observed between the GH peaks for ITT vs AST (r = 0.655), ITT vs GST (r = 0.445), and AST vs GST (r = 0.632). GH peaks in response to all tests were negatively correlated to the number of additional pituitary hormone deficiencies and positively correlated to the insulinlike growth factor 1 standard deviation score. Body mass index had a negative influence on all 3 tests. Most clinical variables did not differ between the groups when comparing GH-deficient patients according to the diagnostic test used. The only exceptions that showed any difference were body mass index (slightly higher in the AST and GST groups), triglyceride levels (increased in the GST group), and insulinlike growth factor 1 (standard deviation score) (lower in the ITT and AST groups than in the GST group). Waist circumference was greater and quality of life was worse in the GST group than in the other groups.ConclusionsThe ITT, AST, and GST produce similar GH peaks, are influenced by similar clinical factors, and identify patients with similar features of GH deficiency at a diagnostic threshold of 3 μg/L. (Endocr Pract. 2012;18:325-334)     

Diagnosing Growth Hormone Deficiency: Can a Combined Arginine and Clonidine Stimulation Test Replace 2 Separate Tests?

ObjectiveGiven the large number of false-positive growth hormone deficiency (GHD) diagnoses from a single growth hormone (GH) stimulation test in children, 2 different pharmacologic tests, performed on separate days or sequentially, are required. This study aimed to assess the reliability and safety of a combined arginine-clonidine stimulation test (CACST).MethodsThis was a retrospective, single-center, observational study. During 2017-2019, 515 children aged >8 years underwent GH stimulation tests (CACST: n = 362 or clonidine stimulation test [CST]: n = 153). The main outcome measures used to compare the tests were GH response (sufficiency/deficiency) and amplitude and timing of peak GH and safety parameters.ResultsPopulation characteristics were as follows: median age of 12.2 years (interquartile range [IQR]: 10.7, 13.4), 331 boys (64%), and 282 prepubertal children (54.8%). The GHD rate was comparable with 12.7% for CACST and 14.4% for CST followed by a confirmatory test (glucagon or arginine) (P = .609). Peak GH was higher and occurred later in response to CACST compared with CST (14.6 ng/mL [IQR: 10.6, 19.4] vs 11.4 ng/mL [IQR: 7.0, 15.8], respectively, P < .001; 90 minutes [IQR: 60, 90] vs 60 minutes [IQR: 60, 90], respectively, P < .001). No serious adverse events occurred following CACST.ConclusionOur findings demonstrate the reliability and safety of CACST in detecting GHD in late childhood and adolescence, suggesting that it may replace separate or sequential GH stimulation tests. By diminishing the need for the second GH stimulation test, CACST saves time, is more cost-effective, and reduces discomfort for children, caregivers, and medical staff.     

Timing of GH Peak in Both Glucagon and Clonidine Tests is of Major Clinical Importance

Objective: To detect a possible correlation between timing of the peak value of growth hormone (GH) during stimulatory tests (STs) and the effectiveness of treatment with recombinant human growth hormone (rhGH) in children with idiopathic GH deficiency (iGHD).Methods: We retrospectively studied 92 patients with iGHD (57 boys; mean age at diagnosis: 9.93 years). Diagnosis was confirmed by 2 different STs, glucagon stimulation test (GST), and clonidine stimulation test (CST). Auxologic parameters were recorded, while observed and predicted (according to KIGS Prediction Model) height velocity during the first year of treatment and the index of responsiveness (IoR) were calculated for the prepubertal children (n = 65).Results: Atypical GST was defined as that with peak GH value at time 0 minutes, 30 minutes, 60 minutes, or 180 minutes, whereas atypical CST was defined as that with peak timing at 0 minutes, 30 minutes, or 120 minutes. Atypical GST was detected in 18 patients (19.57%). IoR was lower in the prepubertal children with atypical GST (-1.81 ± 0.67 versus -1.34 ± 0.85; P = .051). In the CST, the 18 children who had atypical timing, had significantly lower IoR (-1.86 ± 0.66 versus -1.35 ± 0.84; P = .047). When the patients were categorized according to the number of atypical tests, significant differences in the IoR were detected (-2.09 ± 0.68 with 2 atypical STs &lsqb;n = 6], -1.64 ± 0.61 with 1 atypical ST &lsqb;n = 16], and -1.29 ± 0.87 with no atypical ST &lsqb;n = 43], P = .045).Conclusion: The presence of atypical peak GH timing during ST may be a factor that predicts lower growth hormone velocity during the first year of rhGH treatment in prepubertal children with iGHD.Abbreviations: CST = clonidine stimulation test; GH = growth hormone; GHD = growth hormone deficiency; GST = glucagon stimulation test; iGHD = idiopathic growth hormone deficiency; IoR = index of responsiveness; rhGH = recombinant human growth hormone; SDS = standard deviation scores; ST = stimulatory test     

Growth hormone response to a growth hormone-releasing hormone stimulation test in a population-based study following cranial irradiation of childhood brain tumors

Children with brain tumors are at high risk of developing growth hormone deficiency (GHD) after cranial irradiation (CI) if the hypothalamus/pituitary (HP) axis falls within the fields of irradiation. The biological effective dose (BED) of irradiation to the HP region was determined, since BED gives a means of expressing the biological effect of various irradiation treatment schedules in a uniform way. Hypothalamic versus pituitary damage as cause of GHD was distinguished in 62 patients by comparing the growth hormone (GH) peak response to an insulin tolerance test (ITT)/arginine stimulation test and the GH response to a growth hormone-releasing hormone (GHRH) stimulation test. Peak GH response to a GHRH test was significantly higher (median 7.3 mU/l; range: 0.5--79.0 mU/l) than that of an ITT/arginine test (median 4.7 mU/l; range: 0.01--75.0 mU/l) (p = 0.017). Peak GH after a GHRH test was significantly inversely correlated to follow-up time (r(s) = -0.46, p < 0.0001) and to BED (R(s) = -0.28, p = 0.03), and both were found to be of significance in a multivariante regression analysis. We speculate that a significant number of patients developed hypothalamic radiation-induced damage to the GHRH secreting neurons, and secondary to this the pituitary gland developed decreased responsiveness to GHRH following CI in childhood.     

Higher Growth Hormone Levels are Associated with Erectile Dysfunction in Male Patients With Acromegaly

Objective: To investigate in vivo correlates of erectile dysfunction (ED) in male patients with acromegaly.Methods: Fifty-one male patients with acromegaly were assessed by the International Index of Erectile Function-5 and Acromegaly Quality of Life (Acro-QoL) questionnaires. The measurement of serum nitric oxide (NO) were performed in patients and age-matched nonacromegalic controls.Results: Among 51 patients analyzed, 32 (62.7%) had ED. Patients with ED showed lower Acro-QoL scores regarding global (69.8 ± 17.7 versus 79.4 ± 11.2; P = .035) and personal relationship dimensions (59.6 ± 22.1 versus 76.8 ± 17.6; P = .012) than non-ED patients. ED patients were older (44.5 ± 11.2 years versus 33.2 ± 8.5 years; P = .04) and showed higher growth hormone (GH) levels (15.5 μg/L &lsqb;interquartile range of 9.5 to 34.5 μg/L] versus 5.9 μg/L &lsqb;interquartile range of 3.4 to 13.9 μg/L]; P = .001) compared to non-ED patients. The cutoff values for identifying ED were 7.9 μg/L for random GH and 5.3 μg/L for GH nadir after oral administration of 75 g of glucose. There was no significant difference in total testosterone levels between the two groups (6.36 ± 4.24 nmol/L versus 9.54 ± 5.50 nmol/L; P = .299). The NO levels in patients with acromegaly were significantly lower than those in nonacromegalic controls (8.77 ± 1.78 μmol/L versus 19.19 ± 5.02 μmol/L, respectively; P = .049). Furthermore, the NO levels were even lower in ED patients than those in non-ED patients (5.14 ± 0.98 μmol/L versus 12.09 ± 3.44 μmol/L; P = .027).Conclusion: Our study showed that ED is prevalent in male acromegalic patients and may be associated with systemic endothelial dysfunction induced by excessive GH. Further studies investigating the mechanism of GH and ED are required.Abbreviations: Acro-QoL = Acromegaly Quality of Life; ED = erectile dysfunction; FSH = follicle-stimulating hormone; GH = growth hormone; IGF-1 = insulin-like growth factor 1; IIEF-5 = international index of erection function-5; LH = luteinizing hormone; MRI = magnetic resonance imaging; NO = nitric oxide; OGTT = oral glucose tolerance test; QoL = quality of life; ROC = receiver operating characteristic     

Significant Elevation of Growth Hormone Level Impacts Surgical Outcomes in Acromegaly

Objective: Transsphenoidal adenomectomy (TSA) is first-line treatment for acromegaly. Our aim was to determine the impact of pre-operative biochemical parameters on the outcomes of surgery.Methods: Retrospective case series of 79 consecutive acromegalics operated between 1994 and 2013. Inclusion criteria were: first TSA, pathology-confirmed growth hormone (GH) adenoma, and follow-up >3 months. Biochemical remission was defined as normal insulin-like growth factor 1 (IGF-1) without adjuvant therapy during follow-up.Results: Median follow-up was 35.4 months (range, 3 to 187 months). Logistic regression analysis showed that the best model to predict long-term remission included the following pre-operative markers: GH, tumor diameter, and cavernous sinus invasion (CSI) (area under the curve, 0.933). A threshold GH of 40 ng/mL was associated with long-term remission (sensitivity, 97%; specificity, 42%). Group A (GH >40 ng/mL) comprised 19 patients (9 men); age, 43 ± 13 years; tumor diameter, 2.7 ± 1.0 cm; 73.7% with CSI; and pre-operative median GH, 77.8 ng/mL (interquartile range [IQR], 66.7 to 107.0 ng/mL). Three patients (15%) in group A achieved remission at 3 months, but 2 patients recurred during follow-up. Group B (GH ≤40 ng/mL) comprised 60 patients (25 men); age, 47 ± 13 years; tumor diameter, 1.6 ± 1.0 cm; 35% with CSI, preoperative median GH, 6.9 ng/mL (IQR, 3.4 to 16.9 ng/mL). Thirty-five patients (58%) in group B achieved remission at 3 months without recurrence during follow-up. Group A had larger tumors and a higher proportion of tumors with CSI (P<.05).Conclusion: Both GH and IGF-1 should be measured pre-operatively, as highly elevated GH levels negatively impact long-term surgical remission. This strategy allows early identification of patients who require adjuvant therapy and may decrease time to biochemical control.Abbreviations: AUC = area under the curve CSI = cavernous sinus invasion GH = growth hormone ICA = internal carotid artery IGF-1 = insulin-like growth factor 1 MRI = magnetic resonance imaging OGTT = oral glucose tolerance test POD2 = postoperative day 2 TSA = transsphenoidal adenomectomy     

Trabecular Bone Score Change Differs with Regard to 25(OH)D Levels in Patients Treated for Adult-Onset Growth Hormone Deficiency

Objective: Vitamin D is important in bone health. However, potential relationships of concomitant vitamin D deficiency with growth hormone deficiency (GHD) and the possibility that vitamin D inadequacy may alter the skeletal effects of growth hormone (GH) replacement therapy have not been adequately evaluated.Methods: A prospective study was conducted in adult-onset GHD patients treated with recombinant human GH (rhGH) for 2 years. Trabecular bone score (TBS), lumbar spine (LS) bone mineral density (BMD), total hip (TH) BMD, and 25-hydroxyvitamin D (25(OH)D) levels were assessed at baseline and 24 months. The study cohort was divided based on 25(OH)D levels into 2 groups with the cutoff defined as the 50^th percentile at each follow-up time point.Results: Fifty-seven patients (29 males/28 females, mean age 34.4 years) were studied. After 24 months of GH replacement, LS BMD increased by 7.6% and TH BMD increased by 4.5% (both P<.05), with no difference according to 25(OH)D levels. TBS increased (+1.39 ± 3.6%) in those whose 25(OH)D was above the 50^th percentile but decreased (-1.36 ± 5.6%, P<.05) in the cohort below the 50^th percentile of 25(OH)D. Positive correlations were observed between baseline levels of IGF-1 and 25(OH)D (R = 0.37, P<.001) and between 24-month 25(OH)D and TBS (R = 0.25, P<.05).Conclusion: A differential effect of GH on TBS change was observed; TBS increased only in the cohort with 25(OH)D above the 50^th percentile. Vitamin D sufficiency may be required to obtain optimal effects of GH treatment on bone quality, as assessed by TBS, in GHD adults.Abbreviations:AO-GHD = adult-onset GHDBMD = bone mineral densityBMI = body mass indexCa = calciumCTx = carboxyterminal collagen crosslinksCV = coefficient of variationDXA = dual energy X-ray absorptiometryECLIA = enzyme-labeled chemiluminescent immunometric assayGH = growth hormoneGHD = growth hormone deficiencyIGF-1 = insulin-like growth factor 1LS BMD = lumbar spine BMDOC = osteocalcin25(OH)D = 25-hydroxyvitamin DP = phosphorusPTH = parathyroid hormonerhGH = recombinant human GHTBS = trabecular bone scoreTH BMD = total hip BMD     

Effect of Growth Hormone Replacement Therapy on the Quality of Life In Women with Growth Hormone Deficiency who Have A History of Acromegaly Versus Other Disorders

ObjectiveTo compare the response in quality of life (QoL) to growth hormone (GH) replacement in women with GH deficiency (GHD) and a history of acromegaly with that in women with GHD of other causes.MethodsFifty-five women with GHD were studied: 17 with prior acromegaly and 38 with other causes of GHD. We compared two 6-month, randomized, placebo controlled studies of GH therapy in women with hypopituitarism conducted with use of the same design—one in women with a history of acromegaly and one in women with no prior acromegaly. QoL was assessed with the following questionnaires: the QoL-Assessment of Growth Hormone Deficiency in Adults (AGHDA), the Symptom Questionnaire, and the 36-Item Short-Form Health Survey (SF-36).ResultsThe 2 groups had comparable mean pretreatment age, body mass index, and QoL scores and comparable mean GH dose at 6 months (0.61 ± 0.30 versus 0.67 ± 0.27 mg daily). After 6 months of GH replacement therapy, women with GHD and prior acromegaly demonstrated a greater improvement in AGHDA score, four SF-36 subscales (Role Limitations due to Physical Health, Energy or Fatigue, Emotional Well-Being, and Social Functioning), and the Somatic Symptoms subscale of the Symptom Questionnaire than did women with GHD of other causes. Poorer pretreatment QoL was associated with a greater improvement in QoL after administration of GH.ConclusionIn this study, GH replacement therapy improved QoL in women with GHD and a history of acromegaly but not in women with GHD due to other hypothalamic and pituitary disorders. Further studies are needed to determine the long-term risks versus benefits of GH replacement in patients who develop GHD after definitive treatment for acromegaly. (Endocr Pract. 2012;18:209-218)     

Morning Serum Cortisol Level After Transsphenoidal Surgery for Pituitary Adenoma Predicts Hypothalamic-Pituitary-Adrenal Function Despite Intraoperative Dexamethasone Use

Objective: Perioperative glucocorticoid (GC) is rarely needed in patients undergoing transsphenoidal surgery (TSS). We instituted a steroid-sparing protocol in the settings of intraoperative dexamethasone use. We evaluated the safety of using a cut off cortisol level of 14 μg/dL on postoperative day (POD)-1 and -6 after dexamethasone use during the surgery. We also analyzed the efficacy of serial morning cortisol levels for weaning GC replacement.Methods: The charts of 48 adult patients who received dexamethasone 4 mg intraoperatively were reviewed. Morning cortisol levels were measured on POD-1. Patients with cortisol ≥14 μg/dL were discharged without CG replacement. Morning cortisol level was checked routinely on POD-6, and GC replacement was initiated when the level was <14 μg/dL. Serial cortisol levels were measured in patients requiring GC after the first postoperative week.Results: Overall, 67% patients had POD-1 cortisol ≥14 μg/dL and did not require GC on discharge. After POD-6, 83% of patients were not on GC replacement. A cosyntropin stimulation testing (CST) was only performed in 3 patients. There were no hospital admissions for adrenal crisis during the postoperative period.Conclusion: A steroid-sparing protocol with POD-1 and -6 morning cortisol levels can be safely and effectively used in the settings of intraoperative dexamethasone administration. It leads to avoidance of GC in more than two-thirds of patients on discharge and more than 80% of patients after the first postoperative week. We found that dynamic adrenal testing could be omitted in the majority of patients by using serial morning cortisol levels to assess the hypothalamic-pituitary-adrenal (HPA) axis.Abbreviations: ACTH = adrenocorticotropic hormone AI = adrenal insufficiency CST = cosyntropin stimulation test ECLIA = electrochemiluminescence immunoassay GC = glucocorticoid HPA = hypothalamic-pituitary-adrenal ITT = insulin tolerance test POD = postoperative day TSS = transsphenoidal surgery     

Challenges of Securing Growth Hormone Coverage for Idiopathic Short Stature: Review of the 7-Year Experience at one Institution

Objective: Despite U.S. Food & Drug Administration (FDA) approval of growth hormone (GH) for idiopathic short stature (ISS), many providers face challenges obtaining insurance coverage. We reviewed the insurance coverage experience for ISS at our hospital to identify factors predictive of approval or denial.Methods: We reviewed charts of patients who underwent GH stimulation testing from July 1, 2009, to April 30, 2017, to identify ISS patients (height <-2.25 SD, subnormal predicted adult height (PAH) and peak GH >10 ng/mL).Results: Eighty-seven patients met ISS criteria, of whom 47 (29 male/18 female) had a GH request submitted to insurance. Mean age, height, and growth velocity were 8.6 ± 2.7 years, 2.83 ± 0.4 SD, and 4.4 ± 1.7 cm/year, respectively. Mean PAH based on bone age was -2.50 ± 0.9 SD, equaling 62 inches for males and 58 inches for females. Most had private managed care insurance (74%). Overall, 17/47 (36%) received treatment approval, 7 immediately and 10 more on appeal. There were no differences in age, height SD, growth rate, insurance type, or PAH between the 17 who were approved and the 30 denied. For 21 patients who were treated, a mean increase in 0.6 SD in height was seen after 1 year.Conclusion: At our institution, GH coverage requests for ISS included very short children mostly ages 6 to 11, with heights well below -2.25 SD and poor PAH. Only 36% were approved even after appeal. This highlights the challenge in our area to secure GH treatment for a FDA-approved indication. Collaboration between pediatric endocrinologists and insurers focusing on height SD and PAH, may improve cost-effective coverage to deserving short children who meet FDA guidelines for ISS treatment.Abbreviations: FDA = Food and Drug Administration; GH = growth hormone; IGF-1 = insulin-like growth factor 1; ISS = idiopathic short stature; PAH = predicted adult height     

Acylated ghrelin secretion is acutely suppressed by oral glucose load or insulin-induced hypoglycemia independently of basal growth hormone secretion in humans

BACKGROUND: Ghrelin has been reported to be the natural ligand of growth hormone (GH) secretagogue receptor, and it is known that exogenous ghrelin administration strongly stimulates GH release in humans. However, the effects of endogenous ghrelin on GH secretion and changes in ghrelin levels during dynamic changes in GH levels are not well understood. METHODS: Therefore, we measured circulating acylated ghrelin concentrations during oral glucose tolerance tests (OGTTs) in patients with active acromegaly (AA, n = 9) and in age/sex/BMI-matched group A controls (n = 12), and during insulin tolerance testing (ITT) in patients with GH deficiency (GHD, n = 10) and in group B controls (n = 10). Plasma acylated ghrelin, serum GH, insulin and glucose levels were measured during each test. RESULTS: Fasting plasma ghrelin levels correlated negatively with serum insulin levels in both group A and B controls (r = -0.665; p < 0.05) but not in patients with AA or GHD. During OGTTs, circulating ghrelin levels decreased significantly with a nadir at 30 min in both patients with AA (p < 0.05) and group A controls (p < 0.01). Also, ITTs were followed by a significant decrease in circulating ghrelin levels with a nadir at 30 min in patients with GHD (p < 0.05) and in group B controls (p < 0.05). CONCLUSION: The results of the study show that at baseline acylated ghrelin levels do not differ with respect to the GH status (GH excess or GH deficiency) and, furthermore, the suppression of acylated ghrelin levels during OGTT or ITT is independent of the GH response to the tests.     

Alterations In Thyroid Hormone Levels Following Growth Hormone Replacement Exert Complex Biological Effects

Objective: Alterations in the thyroid axis are frequently observed following growth hormone (GH) replacement, but uncertainty exists regarding their clinical significance. We aimed to compare fluctuations in circulating thyroid hormone levels, induced by GH, to changes in sensitive biological markers of thyroid hormone action.Methods: This was a prospective observational clinical study. Twenty hypopituitary men were studied before and after GH replacement. Serum thyroid-stimulating hormone (TSH), thyroid hormones, and insulin-like growth factor 1 were measured. Changes in thyroid hormone concentrations were compared to alterations in resting metabolic rate and cardiac time intervals. Health-related quality of life (QOL) was assessed by disease-sensitive and generic questionnaires.Results: Following GH replacement, free thyroxine concentration declined and free triiodothyronine level increased. Resting energy expenditure increased, particularly in subjects with profound hypopituitarism, including TSH deficiency (16.73 ± 1.75 kcal/kg/min vs. 17.96 ± 2.26 kcal/kg/min; P = .01). Alterations in the thyroid axis were more pronounced in subjects with a low/normal baseline respiratory quotient (RQ) who experienced a paradoxical rise in RQ (0.81 vs. 0.86; P = .01). Subjects with a high baseline RQ experienced a slight but nonsignificant fall in RQ without alteration in thyroid axis. The isovolumetric contraction time was shortened during the study; however, this did not reach statistical significance. Improvements in QOL were observed despite alterations in thyroid axis.Conclusion: Changes in the thyroid axis following GH replacement are associated with complex tissue-specific effects. These fluctuations may induce a hypothyroid phenotype in some tissues while appearing to improve the biological action of thyroid hormone in other organs.Abbreviations: AGHDA = Assessment of Growth Hormone Deficiency in Adulthood; CHOox = carbohydrate oxidation; ET = ejection time; fT3 = free triiodothyronine; fT4 = free thyroxine; GH = growth hormone; GHD = growth hormone deficiency; HB-RQ = high baseline respiratory quotient; HPT = hypothalamic-pituitary-thyroid; ICT = isovolumetric contraction time; IGF-1 = insulin-like growth factor 1; IRT = isovolumetric relaxation time; LB-RQ = low baseline respiratory quotient; LV = left ventricular; NHP = Nottingham Health Profile; QOL = quality of life; REE = resting energy expenditure; RQ = respiratory quotient; rT3 = reverse triiodothyronine; SF-36 = Short Form 36; TSH = thyroid-stimulating hormone; T3 = triiodothyronine; T4 = thyroxine; TT3 = total triiodothyronine; TT4 = total thyroxine     

可乐定联合精氨酸激发试验在矮小儿童生长激素缺乏症中的诊断价值及生长激素峰值的影响因素分析

目的:探讨可乐定联合精氨酸激发试验在矮小儿童生长激素缺乏症(GHD)中的诊断价值,并分析生长激素(GH)峰值的影响因素。方法:选取2016年5月到2018年7月期间因身材矮小来安徽理工大学附属亳州医院就诊的矮小儿童120例,所有儿童均进行可乐定、精氨酸激发试验,比较可乐定、精氨酸、可乐定联合精氨酸激发试验的阳性率,以可乐定联合精氨酸激发试验的结果为标准,将120例矮小儿童分为GHD组(76例)和非GHD组(44例),比较两组儿童的年龄、骨龄、体质量指数(BMI)、体重指数标准差积分(BMI SDS)、胰岛素样生长因子-1(IGF-1)、胰岛素样生长因子结合蛋白-3(IGFBP-3)、GH峰值,分析可乐定联合精氨酸激发试验中GH峰值与各临床指标的相关性,并采用多因素逐步回归分析法分析可乐定联合精氨酸激发试验中GH峰值的影响因素。结果:可乐定联合精氨酸激发试验的阳性率高于可乐定激发试验和精氨酸激发试验的阳性率(P0.05),可乐定激发试验的阳性率高于精氨酸激发试验的阳性率(P0.05)。GHD组儿童BMI、BMI SDS高于非GHD组,IGF-1、GH峰值低于非GHD组(P0.05)。经Pearson相关分析显示,可乐定联合精氨酸激发试验中儿童的BMI、BMI SDS与GH峰值呈负相关,IGF-1与GH峰值呈正相关(P0.05)。多因素逐步回归分析结果显示,可乐定联合精氨酸激发试验中儿童的BMI SDS和IGF-1是GH峰值的影响因素(P0.05)。结论:可乐定联合精氨酸激发试验在矮小儿童GHD诊断中具有较高的阳性率,其诊断价值高于两种药物单独进行激发试验,且儿童的BMI SDS和IGF-1是激发试验GH峰值的影响因素,在进行激发试验时需考虑儿童的BMI SDS和IGF-1水平对诊断结果造成的影响。     

Growth hormone (GH) secretion in patients with childhood-onset GH deficiency: retesting after one year of therapy and at final height

BACKGROUND: Recent studies have shown that many patients treated with growth hormone (GH) during childhood because of idiopathic GH deficiency (GHD) are no longer GH deficient when retested after cessation of GH therapy when final height is achieved. These patients are labelled as transient GHD. We hypothesized that normalization of GH secretion in transient GHD could occur earlier during the course of GH treatment, which could allow earlier cessation of GH treatment. METHODS: In a retrospective study, GH secretion was re-evaluated after cessation of GH treatment at final height in 43 patients diagnosed during childhood as idiopathic GHD (10 with multiple pituitary hormonal deficiencies (MPHD) and 33 with isolated GHD (IsGHD)). In a prospective study, GH secretion was re-assessed after interruption of GH treatment given for 1 year in 18 children with idiopathic GHD (2 MPHD, 16 IsGHD). GH secretion was evaluated by glucagon or insulin stimulation tests. RESULTS: In the retrospective study, all the 10 patients with MPHD and 64% of the 33 patients with IsGHD were still deficient at re-evaluation using the paediatric criteria to define GHD (GH peak <10 ng/ml at provocative test). The proportion of persisting deficiency was greater in patients with complete IsGHD (86%, 12/14 patients) than in patients with partial IsGHD (47%, 9/19 patients). With the criteria proposed in adulthood (GH peak <3 ng/ml), all the 10 patients with MPHD were still considered to be deficient. In contrast, only 15% (5/33 patients) with IsGHD had a maximal GH value <3 ng/ml (36% of the 14 patients with complete IsGHD and none of the 19 patients with partial IsGHD). In the prospective study, after interruption of GH therapy given for 1 year, the 2 patients with MPHD were still GHD at re-evaluation and they resumed GH treatment. Among the 16 patients with IsGHD, 13 (81%) were still deficient (peak response <10 ng/ml) after 1 year. Two of the 3 patients in whom GHD was not confirmed at retesting after 1 year GH showed again a deficient response at second retesting. CONCLUSIONS: Although many patients diagnosed with IsGHD during childhood have a normalized GH secretory capacity when retested during adulthood, early retesting after interruption of GH treatment given for 1 year during childhood does not enable to determine if GH therapy has to be discontinued before cessation of growth.     

Discordance Between Gh and Igf-1 Levels in Turkish Acromegalic Patients

Objective: Discordance between insulin-like growth factor-1 (IGF-1) and growth hormone (GH) levels is an important problem in the follow-up of patients diagnosed with acromegaly. Our aims were to evaluate the discordance between IGF-1 and GH levels and compare the performance of different cut-off levels for the nadir in GH (GHn) in acromegalic patients.Methods: The study included 63 acromegalic patients in a follow-up at a tertiary care university hospital facility. Levels of IGF-1, IGF binding protein-3 (IGFBP-3), and GH were investigated. The baseline GH and GHn levels were evaluated after an oral glucose tolerance test (cut-offs of 0.4 and 1 ng/mL, respectively). The discordance rates between GHn and IGF-1 levels, and IGF-1/IGFBP-3 ratios were determined.Results: We first adopted a GHn cut-off value of 1 ng/mL and found that 27 patients (42.9%) exhibited biochemical remission (BR) (IGF-1 <95^th percentile, GH <1), and 25 patients (39.7%) had no BR (NBR) (IGF-1 ≥95^th percentile, GH >1).Discordance in the presence of normal IGF-1 and nonsuppressed GH (DC1) occurred in 2 of 63 (3.2%) patients; discordance in the presence of high IGF-1 and suppressed GH (DC2) occurred in 9 of 63 (14.3%) patients. If the GHn cut-off value adopted was 0.4 ng/mL, the distributions were 17 of 63 (27.0%) patients in BR, 29 of 63 (46.0%) patients in NBR, 12 of 63 (19.0%) in DC1, and 5 of 63 (7.9%) patients in DC2. If only the baseline GH values were considered, the distributions were very similar to those with a GHn cut-off value of 0.4 ng/mL. The IGF-1/IGFBP-3 ratio was lowest in the BR group.Conclusion: Adopting a GHn cut-off value of 0.4 ng/mL did not increase the test performance compared with baseline GH only. In contrast, in the follow-up of acromegalic patients, the IGF-1/IGFBP-3 ratio might be a useful measurement when discordance between IGF-1 and GH levels occurs. We propose that these values be considered in clinical practice.Abbreviations:BR = biochemical remissionDC1 = discordance group 1DC2 = discordance group 2DM = diabetes mellitusGH = growth hormoneGHn = nadir in GHIGF-1 = insulin-like growth factor-1IGFBP-3 = IGF binding protein-3LAR = long-acting releaseNBR = not in biochemical remissionOGTT = oral glucose tolerance test