Proinsulin, insulin, and C-peptide concentrations in human portal and peripheral blood.

Horwitz, David L.; Starr, J I; Mako, Mary E.; Blackard, William G.; Rubenstein, A. H.

doi:10.1172/jci108047

Cited by 476 publications

(247 citation statements)

References 32 publications

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“…Measures of pre-hepatic pancreatic insulin secretion were derived using C-peptide concentrations. C-peptide is secreted from the pancreas simultaneously and in equimolar quantities with insulin but is not taken up by the liver and, once in the peripheral circulation, has simpler distributional characteristics [29]. This has allowed effective working simplifications of C-peptide behaviour, which enable model-based estimates of the true pancreatic insulin secretion rate to be derived.…”

Section: Methodsmentioning

confidence: 99%

Loss of beta cell function as fasting glucose increases in the non-diabetic range

2004

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Aims/hypothesis. Our aim was to define the level of glycaemia at which pancreatic insulin secretion, particularly first-phase insulin release, begins to decline. Methods. Plasma glucose and insulin concentrations were measured during an IVGTT in 553 men with non-diabetic fasting plasma glucose concentrations. In 466 of the men C-peptide was also estimated. IVGTT insulin secretion in first and late phases was assessed by: (i) the circulating insulin response; (ii) population parameter deconvolution analysis of plasma C-peptide concentrations; and (iii) a combined model utilising both insulin and C-peptide concentrations. Measurements of insulin sensitivity and elimination were also derived by modelling analysis.Results. As fasting plasma glucose (FPG) increased, IVGTT first-phase insulin secretion declined by 73%, 71% and 68% for the three methods respectively. The FPG values at which this decline began, determined by change point regression, were 4.97, 5.16 and 5.42 mmol/l respectively. The sensitivity of late-phase insulin secretion to glucose declined at FPG concentrations above 6.0 mmol/l. Insulin elimination, but not insulin sensitivity, varied with FPG. IntroductionThe respective roles of insulin deficiency and insulin resistance in the development of Type 2 diabetes mellitus remain controversial [1,2]. In response to a glucose stimulus, two phases of insulin secretion may be distinguished [3]. The first occurs as an immediate response to a rise in blood glucose concentrations. Low first-phase insulin release is an early abnormality in deteriorating glucose homeostasis and predicts the subsequent development of Type 2 diabetes [4,5,6,7]. Late-phase insulin release is more prolonged, but of lesser amplitude. It includes the progressively increasing second phase of insulin secretion seen in response to sustained hyperglycaemia [3], and also the compensatory insulin secretion that is the feedback response to a continued increase in circulating glucose. This late-phase insulin secretion may seem to be preserved even when glucose metabolism is defective,In the course of this work, our colleague and co-author James Jeffs died unexpectedly after a short illness. His contribution will be greatly missed.

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Section: Methodsmentioning

confidence: 99%

Loss of beta cell function as fasting glucose increases in the non-diabetic range

2004

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“…Insulin and C-peptide are co-released in a 1 to 1 molar ratio [77]. Whereas insulin undergoes substantial (40±80 %) and variable [66, 78±80] hepatic-insulin extraction [81], C-peptide is presumably not cleared by the liver [82], which resulted in a predominance of the use of C-peptide when calculating the overall insulin secretory rates.…”

Section: Methods For Assessing Pulsatile Insulin Secretionmentioning

confidence: 99%

The in vivo regulation of pulsatile insulin secretion

2002

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In 1922, Karen Hansen [1] measured two series of blood glucose concentrations and reported oscillations in the peripheral concentrations of this substrate, results which were validated by simultaneous sampling from two sites to exclude the possibility that assay variability was a cause of the observed variations. Furthermore she studied the glucose concentrations in diabetic patients, and described both rapid and slower oscillations [1]. Half a century later the observation of rapid oscillations was shown to correlate with oscillations in the peripheral insulin concentrations [2±6], with glucose concentration increases slightly out of phase with insulin secretion pulses [7]. The pulsatile secretion of insulin was shown to coincide with islet pulsatile release of glucagon [4,6,8,9], and somatostatin [9±11]. A number of studies have reported importance of this release pattern for optimal insulin action [10, 12±21, 21±25], for overall insulin secretion [26±35], and for possible development of disease [36±43]. Studies on pulsatile insulin secretion could therefore be important for appreciating how insulin release is regulated overall and how Diabetologia (2002) 45: 3±20 ReviewsThe in vivo regulation of pulsatile insulin secretion

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“…Thus, patients with diabetes under insulin therapy show the highest insulin resistance and the highest insulin levels in the peripheral blood. Peripheral insulin concentrations do reflect those in the portal vein (8), even in patients under insulin therapy. In patients without diabetes, increasing peripheral insulin levels by exogenous insulin suppresses the hepatic glucose production but in diabetics under insulin therapy the hepatic glucose production cannot be inhibited by plasma insulin concentrations throughout the physiologic range.…”

Section: Introductionmentioning

confidence: 96%

Therapy of acromegalic patients exacerbated by concomitant type 2 diabetes requires higher pegvisomant doses to normalise IGF1 levels

Droste¹,

Domberg²,

Buchfelder

et al. 2014

European Journal of Endocrinology

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Objective: Acromegaly is associated with an increased prevalence of glucose metabolism disorders. Clinically confirmed diabetes mellitus is observed in approximately one quarter of all patients with acromegaly and is known to have a worse prognosis in these patients. Design: Of 514 acromegalic patients treated with pegvisomant and recorded in the German Cohort of ACROSTUDY, 147 had concomitant diabetes mellitus. We analysed these patients in an observational study and compared patients with and without concomitant diabetes. Results: Under treatment with pegvisomant, patients with diabetes mellitus rarely achieved normalisation (64% in the diabetic cohort vs 75% in the non-diabetic cohort, PZ0.04) for IGF1. Diabetic patients normalised for IGF1 required higher pegvisomant doses (18.9 vs 15.5 mg pegvisomant/day, P!0.01). Furthermore, those diabetic patients requiring insulin therapy showed a tendency towards requiring even higher pegvisomant doses to normalise IGF1 values than diabetic patients receiving only oral treatment (22.8 vs 17.2 mg pegvisomant/day, PZ0.11). Conclusions: Hence, notable interdependences between the acromegaly, the glucose metabolism of predisposed patients and their treatment with pegvisomant were observed. Our data support recent findings suggesting that intra-portal insulin levels determine the GH receptor expression in the liver underlined by the fact that patients with concomitant diabetes mellitus, in particular those receiving insulin therapy, require higher pegvisomant doses to normalise IGF1. It is therefore important to analyse various therapy modalities to find out whether they influence the associated diabetes mellitus and/or whether the presence of diabetes mellitus influences the treatment results of an acromegaly therapy.

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Proinsulin, insulin, and C-peptide concentrations in human portal and peripheral blood.

Cited by 476 publications

References 32 publications

Loss of beta cell function as fasting glucose increases in the non-diabetic range

Loss of beta cell function as fasting glucose increases in the non-diabetic range

The in vivo regulation of pulsatile insulin secretion

Therapy of acromegalic patients exacerbated by concomitant type 2 diabetes requires higher pegvisomant doses to normalise IGF1 levels

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