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Query: UMLS:C0011854 (
type 1 diabetes
)
20,749
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The IGF system has been associated with development and progression of diabetic retinopathy. We examined whether a simple measurement of the IGF system (serum total
IGF-I
) correlated with progression of diabetic retinopathy in pregnancy in
type 1 diabetes
. A prospective observational study was performed in 103 pregnant women with
type 1 diabetes
. Serum
IGF-I
was measured in maternal serum from week 14, every fourth week until week 30, and every second week until delivery. Twenty-four-hour blood pressure was measured with a portable oscillometry monitor. The women had visual acuity testing and fundus photography before pregnancy, once in each trimester, and 4 months after birth. Each eye was assigned an overall retinopathy grade on a scale from 1 to 6 independently by two experienced graders. During pregnancy, serum
IGF-I
increased with increasing gestational age until a plateau was reached in week 32. Progression of retinopathy was significantly associated with a higher level of
IGF-I
(P < 0.01). Serum
IGF-I
increased with increasing progression of retinopathy. Change of retinopathy was significantly associated with level of
IGF-I
(P < 0.01). During pregnancy, serum
IGF-I
increased with increasing birth weight until a plateau was reached in week 32. Birth weight was significantly associated with a higher level of serum
IGF-I
(P < 0.01).
...
PMID:Increased serum IGF-I during pregnancy is associated with progression of diabetic retinopathy. 1260 30
Anorexia nervosa is a syndrome with multifactorial etiology in which several genetic, biologic, psychological and social factors are involved. Patients affected by anorexia nervosa (AN) may develop multiple endocrine abnormalities, e.g. amenorrhea, hypothalamus-pituitary-adrenal axis hyperactivity, low T3 syndrome and peculiar changes of somatotroph axis function. These endocrine abnormalities are also found after prolonged starvation and may represent an adaptive response developed in order to save energy and proteins. It is still a matter of debate whether these endocrine changes are etiologic or secondary. In fact, several evidences suggest the existence in AN of hypothalamus functional alterations, which may be involved in the development and maintenance of the food intake disorder; on the other hand, the increased CRH secretion seems to be secondary to malnutrition as well as GH hypersecretion coupled to low
IGF-I
levels; the latter is a common finding in AN, as well as in other undernutrition and malabsorption conditions,
type 1 diabetes
mellitus, liver cirrhosis and catabolic states. Hypothalamic amenorrhea, which is one of the diagnostic criteria for AN, is not linked only to the reduction of body weight but reflects also deep alterations of gonadotropin secretory pattern. Low T3 syndrome is frequently found in AN; on the other hand, an iodide-induced hypothyroidism is quite uncommon. T3 reduction in AN seems to be an adaptive response to prolonged starvation; however the presence of a simultaneous central dysregulation cannot be excluded. Finally, AN patients frequently show defects in urinary concentration or dilution with inappropriate secretion of antidiuretic hormone, which may be due to intrinsic defects in the neurohypophysis or to abnormalities of its regulatory afferent neurons.
...
PMID:[Endocrine abnormalities in anorexia nervosa]. 1271 47
Human placental GH (hPGH) replaces pituitary GH during pregnancy. hPGH is correlated to serum
IGF-I
in normal pregnancies and in pregnancies complicated by fetoplacental disorders. In gestational diabetes and type 2 diabetes no correlation between hPGH and
IGF-I
has been found. The relationship between hPGH and
IGF-I
in
type 1 diabetes
mellitus has not been investigated thoroughly. Furthermore, hPGH may be involved in the development of insulin resistance during pregnancy. In this prospective, longitudinal study, 51 type 1 diabetic subjects were followed with repeated blood sampling during pregnancy (median, 14 blood samples/subject; range, 8-26). Maternal concentrations of serum hPGH,
IGF-I
, and IGF-II were measured and compared with insulin requirements and birth characteristics. hPGH was detected from as early as 6 wk gestation. In all subjects, a rise in serum hPGH was observed during pregnancy, and the rise between wk 16 and 25 was correlated to the rise between wk 26 and 35 (P < 0.001). From wk 26 onward, the increase in hPGH values was significantly correlated to the birth weight, expressed as a z-score (r(s) = 0.54; P < 0.001), as were the absolute hPGH values. Also, a positive influence of hPGH on placental weight was found. Serum
IGF-I
values decreased significantly from the first to the second trimester (P < or = 0.021). Serum hPGH correlated to serum
IGF-I
from wk 24- 35, and changes in
IGF-I
followed the increase in hPGH between wk 26-35 (r(s) = 0.53; P < 0.001), as did IGF-II (r(s) = 0.37; P = 0.008). Changes in
IGF-I
and IGF-II between wk 26-35 also correlated to the birth weight z-score (P < or = 0.020), but only hPGH remained significant in multiple regression analysis. Similar results were found in the subgroup delivering at term. Interestingly, the increase in hPGH was not correlated to the increase in insulin requirements, nor was any consistent relationship revealed during each gestational period. In conclusion, our study suggests a role for hPGH in the regulation of both IGFs and fetal growth in
type 1 diabetes
. In contrast, the increase in insulin requirements during pregnancy in type 1 diabetic subjects could not be related to hPGH levels.
...
PMID:Human placental growth hormone, insulin-like growth factor I and -II, and insulin requirements during pregnancy in type 1 diabetes. 1455 93
Human placental GH (hPGH) replaces pituitary GH during pregnancy. hPGH is correlated to serum
IGF-I
in normal pregnancies and in pregnancies complicated by fetoplacental disorders. In gestational diabetes and type 2 diabetes no correlation between hPGH and
IGF-I
has been found. The relationship between hPGH and
IGF-I
in
type 1 diabetes
mellitus has not been investigated thoroughly. Furthermore, hPGH may be involved in the development of insulin resistance during pregnancy. In this prospective, longitudinal study, 51 type 1 diabetic subjects were followed with repeated blood sampling during pregnancy (median, 14 blood samples/subject; range, 8-26). Maternal concentrations of serum hPGH,
IGF-I
, and IGF-II were measured and compared with insulin requirements and birth characteristics. hPGH was detected from as early as 6 wk gestation. In all subjects, a rise in serum hPGH was observed during pregnancy, and the rise between wk 16 and 25 was correlated to the rise between wk 26 and 35 (P < 0.001). From wk 26 onward, the increase in hPGH values was significantly correlated to the birth weight, expressed as a z-score (r(s) = 0.54; P < 0.001), as were the absolute hPGH values. Also, a positive influence of hPGH on placental weight was found. Serum
IGF-I
values decreased significantly from the first to the second trimester (P </= 0.021). Serum hPGH correlated to serum
IGF-I
from wk 24-35, and changes in
IGF-I
followed the increase in hPGH between wk 26 and 35 (r(s) = 0.53; P < 0.001), as did IGF-II (r(s) = 0.37; P = 0.008). Changes in
IGF-I
and IGF-II between wk 26 and 35 also correlated to the birth weight z-score (P </= 0.020), but only hPGH remained significant in multiple regression analysis. Similar results were found in the subgroup delivering at term. Interestingly, the increase in hPGH was not correlated to the increase in insulin requirements, nor was any consistent relationship revealed during each gestational period. In conclusion, our study suggests a role for hPGH in the regulation of both IGFs and fetal growth in
type 1 diabetes
. In contrast, the increase in insulin requirements during pregnancy in type 1 diabetic subjects could not be related to hPGH levels.
...
PMID:Human placental growth hormone, insulin-like growth factor I and -II, and insulin requirements during pregnancy in type 1 diabetes. 1297 Mar 10
IGF-I
regulates islet beta-cell growth, survival, and metabolism and protects against
type 1 diabetes
(T1D). However, the therapeutic efficacy of free
IGF-I
may be limited by its biological half-life in vivo. We investigated whether prolongation of its half-life as an
IGF-I
/IGF binding protein (IGFBP)-3 complex affords increased protection against T1D and whether this occurs by influencing T cell function and/or islet beta-cell growth and survival. Administration of
IGF-I
either alone or as an
IGF-I
/IGFBP-3 complex reduced the severity of insulitis and delayed the onset of T1D in nonobese diabetic mice, but
IGF-I
/IGFBP-3 was significantly more effective. Protection from T1D elicited by
IGF-I
/IGFBP-3 was mediated by up-regulated CCL4 and down-regulated CCL3 gene expression in pancreatic draining lymph nodes, activation of the phosphatidylinositol 3-kinase and Akt/protein kinase B signaling pathway of beta-cells, reduced beta-cell apoptosis, and stimulation of beta-cell replication. Reduced beta-cell apoptosis resulted from elevated Bcl-2 and Bcl-X(L) activity and diminished caspase-9 activity, indicating a novel role for a mitochondrial-dependent pathway of beta-cell death. Thus,
IGF-I
/IGFBP-3 affords more efficient protection from insulitis, beta-cell destruction, and T1D than
IGF-I
, and this complex may represent an efficacious therapeutic treatment for the prevention of T1D.
...
PMID:Insulin-like growth factor (IGF)-I/IGF-binding protein-3 complex: therapeutic efficacy and mechanism of protection against type 1 diabetes. 1461 76
The IGF system plays vital roles in neuronal development, metabolism, regeneration and survival. It consists of
IGF-I
, IGF-II, insulin,
IGF-I
-receptor, and those of IGF-II and insulin as well as IGF-binding proteins. In the last decades it has become clear that perturbations of the IGF system play important roles in the pathogenesis of diabetic neurological complications. In the peripheral nervous system
IGF-I
, insulin, and C-peptide particularly in
type 1 diabetes
participate in the development of axonal degenerative changes and contributes to impaired regenerative capacities. These abnormalities of the IGF system appear to be less pronounced in type 2 diabetes, which may in part account for the relatively milder neurological complications in this type of diabetes. The members of the IGF system also provide anti-apoptotic effects on both peripheral and central nervous system neurons. Furthermore, both insulin and C-peptide and probably
IGF-I
possess gene regulatory capacities on myelin constituents and axonal cytoskeletal proteins. Therefore, replenishment of various members of the IGF system provides a reasonable rational for prevention and treatment of diabetic neurological complications.
...
PMID:The insulin-like growth factor system and neurological complications in diabetes. 1466 47
In pregnancy, pituitary growth hormone (GH) is gradually replaced by placental growth hormone (hPGH). GH deficient pregnant women may take advantage of GH substitution during pregnancy, but this issue still remains unresolved. Also, in pregnancy diabetes may cause macrosomia. The combination of GH deficiency, GH substitution therapy and
type 1 diabetes
mellitus may influence pregnancy in unforeseen ways. We present a case of pregnancy in a GH deficient woman with
type 1 diabetes
who continued on GH replacement until week 21. In gestational week 37 a thin and mildly small-for gestational-age (length 55 cm, +3 SD, 99th centile and weight 2445 g., -1.4 SD, 10th centile) but otherwise healthy boy was born. The patient had levels of serum hPGH at the lower end of the range of values found in a matching group of diabetic women. Serum
IGF-I
levels were at the upper end of the range of values in the control group. A positive correlation between serum hPGH and
IGF-I
values was seen in the control group when using the area-under-the-curve (r=0.84; p<0.001). The patient's child had lower birth weight and ponderal index, but was otherwise healthy. Serum
IGF-I
, but not hPGH, correlated to the absolute birth weight (r=0.63; p=0.015) and the birth weight z-score (r=0.55; p=0.039) in the control group. Serum hPGH and
IGF-I
declined rapidly after delivery. In conclusion, hPGH correlated to
IGF-I
in
type 1 diabetes
mellitus (DM), and
IGF-I
values correlated to the birth weight. Both
type 1 diabetes
mellitus and GH deficiency (with GH substitution therapy) may influence fetal growth, and in combination, the net influence may be difficult to predict.
...
PMID:Placental growth hormone during pregnancy in a growth hormone deficient woman with type 1 diabetes compared to a matching diabetic control group. 1470 May 57
There is evidence of a metabolic role for
IGF-I
in
type 1 diabetes
, but it is unclear whether
IGF-I
acts indirectly by reducing GH secretion or has direct effects. Using stable isotopes we have investigated, on three separate occasions, the effect of a pulse of recombinant human GH, a sc injection of recombinant human
IGF-I
, and a placebo on glucose, lipid, and protein metabolism in subjects with
type 1 diabetes
during a basal insulin infusion and a hyperinsulinemic euglycemic clamp. Endogenous GH secretion was suppressed with octreotide.
IGF-I
reduced the hepatic glucose production rate (Ra), increased peripheral glucose uptake, and reduced protein breakdown during the basal insulin infusion (P < 0.05, P < 0.005, and P < 0.05, respectively, vs. placebo) and the hyperinsulinemic euglycemic clamp (P < 0.05, P < 0.005, and P < 0.05, respectively, vs. placebo).
IGF-I
had no effect on glycerol Ra, an index of lipolysis. GH increased glucose and glycerol Ra during the basal insulin infusion (P < 0.005 vs. placebo study), but the effects were no different from placebo during the clamp. In conclusion,
IGF-I
had a direct effect on glucose and protein metabolism, which was maintained during the hyperinsulinemic euglycemic clamp. This suggests that
IGF-I
acts in concert with insulin and may have an important role in maintaining glucose homeostasis and protein metabolism in
type 1 diabetes
.
...
PMID:Insulin-like growth factor I has a direct effect on glucose and protein metabolism, but no effect on lipid metabolism in type 1 diabetes. 1471 81
Genetic association with
type 1 diabetes
(T1D) has been established for two chromosomal regions: HLA DQ/DR (
IDDM1
) and INS VNTR (IDDM2). To identify additional genetic markers, we tested polymorphisms in regulatory regions of several cytokine and important metabolic genes. These polymorphisms exhibit functional consequences for expression and function. Functional genetic polymorphisms of proinflammatory (T-helper-1: IL-2, IL-12 and IFN-gamma), anti-inflammatory (T-helper-2: IL-4, IL-6 and IL-10) and metabolic (
IGF-I
, VDR and INS) genes were determined in 206 Dutch simplex families with juvenile onset T1D and the results were analysed using the transmission disequilibrium test. Significantly increased transmission to T1D probands was observed for the loci
IDDM1
, IDDM2 and the vitamin D receptor. Although none of the other individual polymorphisms was associated with disease individually, the combination of T-helper-2 and metabolic/growth alleles IL-10(*)R2, IL-4(*)C, VDR(*)C and
IGF-I
(*)wt was found to be transmitted more frequently than expected (67%, P(c)=0.015). We conclude that additional genetic predisposition to T1D is defined by combinations of markers (eg Th2 and metabolic) rather than by a single marker. The consequences of the increased transmission of a low Th2 expressing genotypes together with a normal Th1 profile may result in a net proinflammatory cytokine expression pattern.
...
PMID:Functional genetic polymorphisms in cytokines and metabolic genes as additional genetic markers for susceptibility to develop type 1 diabetes. 1473 47
Ghrelin is secreted primarily by the stomach, although other tissues such as the pancreas synthesize a minor proportion. The discovery of a new cell type that produces ghrelin in the human pancreas and that this organ expresses GHS-R opens new perspectives in the understanding of the control of glucose metabolism. We have studied 22 children with newly diagnosed
type 1 diabetes
mellitus at four different points: at diagnosis before insulin therapy, after 48-60 h of insulin therapy, and after 1 and 4 mo of insulin treatment. At each point circulating levels of ghrelin, leptin,
IGF-I
, IGF binding protein (IGFBP)-1, IGFBP-2, IGFBP-3, and glucose were determined. Ghrelin levels were significantly decreased at diagnosis (573 +/- 68 pg/mL, p < 0.01) compared with controls (867 +/- 38 pg/mL) and remained decreased after insulin therapy (d 2: 595 +/- 68 pg/mL; 1 mo: 590 +/- 61 pg/mL; 4 mo: 538 +/- 67 pg/mL) with no differences before or after insulin treatment. There was a negative correlation between ghrelin levels and body mass index at all of the study points, whereas a negative correlation between ghrelin and glucose concentrations was only observed after insulin therapy. No correlation between ghrelin and HbA1c was found at any point. A positive correlation between ghrelin and IGFBP-1 was found after insulin therapy, but no correlation with other members of the IGF system or leptin was found. In conclusion, these data could indicate a possible link between glucose concentrations and ghrelin; hence, the persisting low ghrelin levels in diabetic children may suggest a defensive mechanism against hyperglycemia.
...
PMID:Response of circulating ghrelin levels to insulin therapy in children with newly diagnosed type 1 diabetes mellitus. 1497 81
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