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Target Concepts:
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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 nomenclature of human diabetes mellitus (DM) has been revised, and this classification has been accepted throughout the medical world and literature. The major categories of diabetes are: insulin-dependent DM, type I or
IDDM
; noninsulin-dependent DM, type II or NIDDM; secondary DM or type S; impaired glucose tolerance, IGT; gestational diabetes; and previous abnormality of glucose tolerance, PrevAGT. A review of the literature has shown that over half of the documented diabetic dogs, with a single medical diagnosis, appear to be type I,
IDDM
, with a substantial proportion being type S, and the remainder being type II, NIDDM. Obesity is frequently associated with IGT and NIDDM. Diabetic cats most commonly have pancreatic islet destruction associated with pancreatic amyloidosis; they are insulin deficient,
IDDM
. The commonest causes of secondary diabetes in dogs are pancreatic damage, hyperadrenocorticism and hypersomatotropism secondary to persistent progesterone influence. Progestogen therapy is the most frequently reported cause of secondary diabetes in cats. Diabetes in horses is type S, usually secondary to a functional
pituitary tumor
but occasionally following chronic pancreatitis. The blood glucose ranges for normal, IGT and diabetic animals, and the normal serum insulin values of various species is tabulated.
...
PMID:Definition of diabetes mellitus. 351 69
GH hypersecretory states include organic and functional causes. Among functional GH hypersecretory states, enhanced somatotroph secretion physiologically occurs at birth associated with reduced IGF-I levels reflecting the still immature sensitivity of liver to circulating GH levels; this may also occur in women exposed to oral extrogens. Pathophysiological conditions of GH hypersecretion are generally associated with congenital or acquired/functional conditions of peripheral GH insensitivity. Genetic alterations of the GH receptor lead to the so called Laron's syndrome. On the other hand, a relevant number of clinical conditions (malnutrition, malabsorption, anorexia nervosa, liver cirrhosis, renal failure,
Type 1 diabetes mellitus
) are associated with acquired GH insensitivity and a more or less pronounced GH hypersecretion. Both organic and acquired conditions of GH insensitivity show low IGF-I synthesis and release and therefore lack the negative IGF-I feedback action on somatotroph function. GH hypersecretion may be associated with renal failure; however, in this case, the alteration in the metabolic clearance rate of GH would also have a role; moreover, IGF-I levels are generally normal in this condition. Hyperthyroidism is another condition connoted by elevated GH levels that reflects a true GH hypersecretory state and is, in fact, associated with high-normal IGF-I levels; this peculiar condition is likely to be reflecting the stimulatory effect of thyroid hormones on both GH and IGF-I secretion and is promptly reversed by treatment-induced euthyroidism. Apart from these "functional" hypersecretory state, the classic organic GH hypersecretory state is represented by acromegaly or giantism. In these conditions GH hypersecretion is generally sustained by a pituitary adenoma hypersecreting GH alone or together with another pituitary hormone, mostly PRL; less frequently GH hypersecretion may be due to ectopic GHRH hypersection. Exaggerated GH secretion elicits exaggerated IGF-I synthesis and secretion that is, in turn, responsible for the large majority of endocrine signs and symptoms. In the appropriate clinical context of acromegalic features, evidence of concomitant marked GH and IGF-I hypersecretion at baseline demonstrates active acromegaly or giantism and indicates the need for magnetic resonance imaging in order to verify the presence of a
pituitary tumor
. However, as random measurement of basal GH levels is not reliable for definite diagnosis of acromegaly, it is considered mandatory to rely on the lack of GH suppression below 1 microg/l during oral glucose tolerance test (OGTT) coupled with elevated IGF-I levels. The same criteria are assumed, at present, to define true cure of the disease after (or under) treatment. There is consensus about the assumption that concomitant normalization or persistent abnormality of both OGTT-induced GH nadir and IGF-I levels define a successfully or a poorly controlled disease status, respectively. On the other hand, acromegalic patients with GH nadir above 1 microg/l or IGF-I levels persistently elevated are inadequately controlled and their disease should not be considered inactive. It has been clearly demonstrated that an extended exposure to GH and IGF-I excess level, even if slight, has a very harmful effect on patients; therefore early diagnosis of acromegaly and appropriate definition of its cure are of fundamental extreme in order to plan a prompt and appropriate therapeutic intervention(s) guaranteed also by the continuous improvement in the therapeutic tools available to treat this systemic disease.
...
PMID:Hormonal diagnosis of GH hypersecretory states. 1549 57
We report a rare case of
type 1 diabetes
in a woman associated with acromegaly who was treated with surgery after pregnancy. An 18-year-old woman came to our hospital in April, 1998, complaining of thirst, polydipsia, polyuria, appetite loss, body weight loss of 8 kg in a month, and amenorrhea beginning 2 months earlier. Based on laboratory data, she was diagnosed as having
type 1 diabetes
mellitus. Although we suspected her of having acromegaly because of high growth hormone (GH) levels (6.9 or 8.5 ng/ml), blood levels of insulin-like growth factor 1 (IGF-1) and IGF-binding protein-3 (IGFBP-3) were within normal range and the circadian rhythm of her blood GH levels was normally maintained. Her blood GH level was elevated to 12.6 ng/ml 15 minutes after a TRH administration. Blood GH levels were suppressed from 49 ng/ml to 1.5 ng/ml 4 hours after an oral administration of 2.5 mg of bromocriptine. A magnetic resonance images (MRIs) showed pituitary swelling, but no nodules were found in the pituitary. Therefore, we diagnosed her as having acromegaly and observed her without surgery, while prescribing diet therapy and intensive insulin therapy for diabetes. We started a treatment of oral administration of 7.5 mg of bromocriptine per day for the acromegaly from April 28, 2000, because her elevated GH was suspected of causing her diabetes to be poorly controlled. During a pregnancy from October, 2000 to September, 2001, diabetic control was improved with increased administration of insulin under a constant dose of bromocriptine. She delivered a normal full-term infant. After the bromocriptine therapy was stopped as she hoped to breastfeed, blood levels of GH and IGF-1 became elevated and her diabetic control deteriorated. As her
pituitary tumor
observed in pituitary MRIs became larger during the course, a transsphenoidal surgery was performed on March 8, 2002. After the surgery, blood levels of GH and IGF-1 lowered and diabetic control improved again. We concluded as follows: to rule out acromegaly in patients with poorly controlled diabetes, 1) measurements of serum GH and IGF-1 should be performed, and 2) pituitary MRIs should be performed if blood levels of GH or IGF-1 are high.
...
PMID:Type 1 diabetes associated with asymptomatic acromegaly successfully treated with surgery after pregnancy: a case report. 1612 8
