生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

生长激素缺乏但持续增高:垂体柄中断合并垂体多激素缺乏一例报告及文献复习

Normal function of growth hormone-insulin-like growth factor Ⅰaxis is essential for linear growth after birth. A case of continuous growth with undetectable growth hormone level even under insulinhypoglycemia stimulation was reported. The growth hormone deficiency was due to pituitary stalk interruption combined with deficiency of multiple pituitary hormones. Taken together with reviewed literature, this so-called nongrowth hormone-dependent linear growth was preconditioned by other hormones, especially gonadotropin deficiency,and the unclosed epiphysis.     

骨代谢调控的垂体-骨轴机制

近年来,垂体激素包括促甲状腺激素、FSH、促肾上腺皮质激素以及催产素等,相继被发现对骨代谢具有直接的调控作用.这一发现打破了垂体激素是通过作用于靶内分泌腺间接对骨代谢进行调节的传统观念,从而提出了骨代谢调控的垂体-骨轴(pituitary-bone axis)新概念.这些突破性研究进展使人们对垂体激素的功能有了全新的了解,并且对甲亢、绝经、妊娠等引起的骨质疏松症以及糖皮质激素引起的骨坏死的发病机制有了更深的认识,为相关骨代谢疾病的防治以及新药研发提供了新的科学思路和理论基础.

Abstract：

Recent studies have shown that pituitary hormones, including thyroid stimulating hormone (TSH), follicle stimulating hormone(FSH), adrenocorticotropic hormone(ACTH), and oxytocin(OT)may actually bypass their target endocrine organs and affect the skeleton directly. Therefore, a new conception, pituitary-bone axis is proposed. This breakthrough sheds a new light on the function of pituitary hormones and the pathogenesis of osteoporosis associated with hyperthyroidism, menopause or pregnancy, and even osteonecrosis after using glucocorticoids. In addition, it is conducive to give the reference guidance for clinical treatment of metabolic bone diseases and new drug development.     

Pubertal growth and growth hormone secretion

A dramatic increase in linear growth velocity, often referred to as the pubertal growth spurt, is a central feature of pubertal development. Despite the existence of numerous investigative attempts, a precise understanding of the hormonal events subserving this process has proved elusive. Nevertheless, evidence has gradually accumulated that indicates that sex steroid-induced modulation of growth hormone secretion is a central and critical feature of the pubertal growth spurt. As a result, disorders of either growth hormone or sex steroid hormone production may result in clinical growth disorders during puberty.     

The growth hormone receptor in growth.

The growth hormone receptor (GHR) is a major effector of Human growth. Functional variants of the GHR include very rare loss-of-function mutations (pathology) and very common polymorphisms (physiology). Recent experimental data have clarified the mechanisms through which mutations of the GHR or Stat5 lead to growth hormone insensitivity and major monogenic growth defects. Recent pharmacogenetic studies support that the response to growth-promoting administration of growth hormone is influenced by exon 3 polymorphism of the GHR.     

Normal growth and techniques of growth assessment

The shape of the human growth curve is described and illustrated. Growth studies may be longitudinal, cross-sectional, mixed longitudinal or linked-longitudinal; each has advantages and disadvantages, and each requires appropriate statistical methods for handling the data. Standards for height and height velocity for use in a clinical setting wherein follow-up over several years is presumed are described and illustrated. Such standards have to take into account tempo of growth at ages over nine years. Cross-sectionally derived standards do not do this and are not suitable for clinical use. The techniques of measurement of height, sitting height and skinfolds are described and illustrated. Growth and development during puberty is described; there are changes in body composition as well as in body size and shape. Standards for pubertal stages of breasts, pubic hair and genitalia are given and emphasis is laid on the great variation in both the timing and the duration of these pubertal changes. Measurement of developmental age is discussed. The Greulich-Pyle and Tanner-Whitehouse methods for skeletal age are described. These methods can be used for predicting adult height which is useful both in diagnosis and in following the effects of treatment. In diagnosis the predicted adult height is compared to the range of expected heights in the children of the particular pair of parents concerned (the so-called 'target' range of heights) to see if smallness is simply due to delay. Change in Tanner-Whitehouse predicted height occurs on successful treatment of, for example, growth hormone deficient short stature, and is thus a guide to the success of treatment. Standards are also given for height of children from age two to nine inclusive, with allowance for height of their parents.     

Mammalian epidermal growth factor promotes plant growth

Application of mouse submaxillary gland epidermal growth factor to young sorghum seedlings at low concentrations (≈0.4-4 μM) increased shoot growth significantly over 3- and 6-day periods. The effects were dose dependent.     

Predicting the growth response to growth hormone in patients with intrauterine growth retardation

OBJECTIVE Human GH treatment of short children who had intrauterine growth retardation (IUGR) results in a highly variable growth response. The object of this study was to test the hypothesis that differences in responsiveness to exogenously administered GH might reflect differences in endogenous GH secretion or sensitivity. DESIGN Prospective study evaluating the growth response to GH therapy in short individuals with prior IUGR. PATIENTS Ten short, prepubertal children with prior IUGR were studied. Mean age was 6 years (3.39–8.61). Mean bone age was 4.6 years (2.3–8.3). Mean body mass index was 13.2 kg/m² (9.9–14.0; normal 13.5–19.0). MEASUREMENTS Overnight spontaneous GH release was measured using a constant withdrawal pump and stimulated GH release was measured following clonidine (0.15 mg/m²) administration. IGF-I concentrations were measured at baseline and 12, 24, 36 and 48 hours after sequential doses of GH (0.05 and 0.2 mg/kg/dose) given 48 hour apart. Patients were treated with GH (0.125 mg/kg three times a week) and growth response was assessed. In the second and third year, attempts were made to improve the growth rate by nutritional supplementation and increasing the dose of GH to 0.25 mg/kg three times a week. RESULTS All patients had normal integrated nocturnal GH secretion (>3 μg/l, 6mU/l) and normal peak GH secretion in response to clonidine (>7 μg/l). In the first year of the trial, mean growth velocity (GV) increased from 5.39 cm/year ± 0.29 to 7.32 cm/year ± 0.39 (P = 0.004). Changes in GV correlated inversely with integrated GH (r = ? 0.69; P = 0038), baseline IGF-I concentration (r = ? 0.88; P = 0.002) and baseline GV-SDS (r = ? 0.68; P = 0.043). There was no correlation between change in GV and GH binding protein, baseline height SDS or age. The effect of GH waned in the second year, but tended to remain greater than the pretreatment growth rate (6.54 ± 0.49 vs 5.53 cm/year ± 0.29; P = 0.09). No significant advancement of bone age over chronological age was observed over the first 2 years. Increasing nutritional intake by 17% did not result in significant weight gain nor increase in height velocity. Doubling the dose of GH in the second or third year did not result in a significant increase in GV. CONCLUSION The variable response to GH therapy in short children with a history of intrauterine growth retardation may partly reflect relative sufficiency or insufficiency of GH. Baseline IGF-I levels and baseline growth velocity appear to be useful and practical predictors of response to GH.     

Interactions between growth hormone, insulin-like growth factor I, and basic fibroblast growth factor in melanocyte growth.

Melanocytes, highly differentiated neural crest-derived cells, are located in the basal layer of the epidermis, where they play a role in protecting against UV damage in the skin. Previous studies suggest that both growth hormone (GH) and the insulin-like growth factor I (GH/IGF-I) system may be important for melanocyte growth and function. We have therefore characterized the role of the GH/IGF system in melanocyte growth in vitro and its interaction with the local growth factor basic fibroblast growth factor (bFGF). Analysis of the effects of GH, IGF-I, and bFGF and combinations of these growth factors on melanocyte growth in vitro revealed that 1) GH stimulates the growth of melanocytes when combined with IGF-I, des(1-3)IGF-I [an analog of IGF-I that has a reduced binding affinity for IGF-binding proteins (IGFBPs)], or bFGF, either separately or in combination; 2) in contrast to the lack of effect of GH or bFGF alone, both IGF-I and des(1-3)IGF-I enhance melanocyte growth in a dose-dependent manner; and 3) IGF-I is more efficacious in eliciting a growth response at low concentrations compared to des(1-3)IGF-I. Using Western ligand blotting, affinity cross-linking, immunoprecipitation, RIA, and Northern analysis, we show that cultured human melanocytes synthesize and secrete minimal amounts of IGFBP. IGFBP-4 is the major IGFBP produced by these cells when cultured in complete growth medium or in the presence of either IGF-I or des(1-3)IGF-I alone. In conclusion, these studies provide support for a role for both GH and IGF-I in the growth of human melanocytes in vitro, involving synergy with bFGF. Low levels of melanocyte-derived IGFBP-4 may play a role in enhancing the modulation of IGF action.     

Growth cartilage expression of growth hormone/insulin-like growth factor I axis in spontaneous and growth hormone induced catch-up growth

IntroductionCatch-up growth following the cessation of a growth inhibiting cause occurs in humans and animals. Although its underlying regulatory mechanisms are not well understood, current hypothesis confer an increasing importance to local factors intrinsic to the long bones' growth plate (GP).AimThe present study was designed to analyze the growth-hormone (GH)-insulin-like growth factor I (IGF-I) axis in the epiphyseal cartilage of young rats exhibiting catch-up growth as well as to evaluate the effect of GH treatment on this process.Material and methodsFemale Sprague–Dawley rats were randomly grouped: controls (group C), 50% diet restriction for 3 days + refeeding (group CR); 50% diet restriction for 3 days + refeeding &; GH treatment (group CRGH). Analysis of GH receptor (GHR), IGF-I, IGF-I receptor (IGF-IR) and IGF binding protein 5 (IGFBP5) expressions by real-time PCR was performed in tibial growth plates extracted at the time of catch-up growth, identified by osseous front advance greater than that of C animals.ResultsIn the absence of GH treatment, catch-up growth was associated with increased IGF-I and IGFBP5 mRNA levels, without changes in GHR or IGF-IR. GH treatment maintained the overexpression of IGF-I mRNA and induced an important increase in IGF-IR expression.ConclusionsCatch-up growth that happens after diet restriction might be related with a dual stimulating local effect of IGF-I in growth plate resulting from overexpression and increased bioavailability of IGF-I. GH treatment further enhanced expression of IGF-IR which likely resulted in a potentiation of local IGF-I actions. These findings point out to an important role of growth cartilage GH/IGF-I axis regulation in a rat model of catch-up growth.     

Predicting growth in response to growth hormone treatment

The use of growth hormone (GH) to treat children who have disturbances of growth is complicated by variability both within and across diagnostic groups, and at the start of and throughout treatment. Growth prediction models are important tools in the effort to account for these sources of variability and tailor GH treatment to each patient’s needs. This review considers the methodological approach taken to the development of models from data in large databases such as the Pfizer International Growth Database (KIGS); it also assesses the limitations of these models and their data sources, and the potential for improvements. While all aspects of model development bear continued scrutiny and improvement, the incorporation of more predictors is key if treatment outcomes are to be optimized in terms of efficacy, safety and cost.