Atypical presentation of multiple evanescent white dot syndrome involving granular lesions of varying size.

PURPOSE: To report an atypical presentation of multiple evanescent white dot syndrome (MEWDS). DESIGN: Observational case report. METHODS: Review of the clinical, laboratory, photographic, and angiographic records of a patient with MEWDS. RESULTS: A 29-year-old woman presented with 20/400 vision in the right eye associated with multiple, granular lesions of varying sizes (100-1000 microm) in the outer retina, a prominent panuveitis, diffuse choroidal thickening and enlarged blindspot. The multiple lesions and visual disturbances resolved within 4 weeks with corticosteroid treatment, and the patient was diagnosed with MEWDS. CONCLUSIONS: Clinicians should be aware of atypical manifestations of MEWDS. The patient's unusual fundoscopic changes and prominent intraocular inflammatory reaction are findings that have not been reported in patients with MEWDS.

Molecular evidence supporting the portal theory: a causative link between visceral adiposity and hepatic insulin resistance.

The mechanism by which increased central adiposity causes hepatic insulin resistance is unclear. The "portal hypothesis" implicates increased lipolytic activity in the visceral fat and therefore increased delivery of free fatty acids (FFA) to the liver, ultimately leading to liver insulin resistance. To test the portal hypothesis at the transcriptional level, we studied expression of several genes involved in glucose and lipid metabolism in the fat-fed dog model with visceral adiposity vs. controls (n = 6). Tissue samples were obtained from dogs after 12 wk of either moderate fat (42% calories from fat; n = 6) or control diet (35% calories from fat). Northern blot analysis revealed an increase in the ratio of visceral to subcutaneous (v/s ratio) mRNA expression of both lipoprotein lipase (LPL) and peroxisome proliferator-activated receptor-gamma (PPARgamma). In addition, the ratio for sterol regulatory element-binding transcription factor-1 (SREBP-1) tended to be higher in fat-fed dogs, suggesting enhanced lipid accumulation in the visceral fat depot. The v/s ratio of hormone-sensitive lipase (HSL) increased significantly, implicating a higher rate of lipolysis in visceral adipose despite hyperinsulinemia in obese dogs. In fat-fed dogs, liver SREBP-1 expression was increased significantly, with a tendency for increased fatty acid-binding protein (FABP) expression. In addition, glucose-6-phosphatase (G-6-Pase) and phosphoenolpyruvate carboxykinase (PEPCK) increased significantly, consistent with enhanced gluconeogenesis. Liver triglyceride content was elevated 45% in fat-fed animals vs. controls. Moreover, insulin receptor binding was 50% lower in fat-fed dogs. Increased gene expression promoting lipid accumulation and lipolysis in visceral fat, as well as elevated rate-limiting gluconeogenic enzyme expression in the liver, is consistent with the portal theory. Further studies will need to be performed to determine whether FFA are involved directly in this pathway and whether other signals (either humoral and/or neural) may contribute to the development of hepatic insulin resistance observed with visceral obesity.

Mechanism of action in dogs of slow-acting insulin analog O346.

We compared metabolic effects as well as plasma and interstitial fluid kinetics of fatty acid-acylated insulin, Lys(B29)(N(epsilon)-omega-carboxynonadecanoyl)-des(B30) human insulin (O346), with previously determined kinetics of native insulin and insulin detemir. Euglycemic clamps with iv injection of O346 (90 pmol/kg) or saline control were performed in 10 male mongrel dogs under inhalant anesthesia. The t(1/2) for the clearance of O346 from plasma was 375.7 +/- 26.7 min; the t(1/2) for the appearance of O346 in interstitial fluid was 137 +/- 20 min (mean +/- SEM). Glucose disposal with O346 injection was increased 4-fold (t = 480 min, 8.3 +/- 1.42 mg/min/kg) compared with preinjection (t = 0 min, 2.1 +/- 0.13 mg/min/kg; P < 0.05) or saline control (t = 480 min, 2.09 +/- 0.22 mg/min/kg; P < 0.05). O346 plasma elimination and transendothelial transport were 0.3% and 3.5% of regular insulin and 3% and 50% of insulin detemir, respectively. Combination of in vivo results and compartmental modeling suggests that the duration of action of O346 after iv injection is about 25-fold and 10-fold longer compared with regular human insulin and insulin detemir, respectively. This study demonstrates that O346 stimulates glucose disposal very slowly, but when injected iv, its effect may be maintained for as long as 48 h as estimated from simulation analysis. The data suggest that O346 bound to albumin in plasma acts as a storage compartment for O346 from which the analog is slowly released to insulin-sensitive tissues. Reduced liver clearance of O346 is suggested to be the major mechanism for the protracted action.

Elevated glucagon-like peptide-1-(7-36)-amide, but not glucose, associated with hyperinsulinemic compensation for fat feeding.

We previously developed a canine model of central obesity and insulin resistance by supplementing the normal chow diet with 2 g cooked bacon grease/kg body weight. Dogs fed this fatty diet maintained glucose tolerance with compensatory hyperinsulinemia. The signal(s) responsible for this up-regulation of plasma insulin is unknown. We hypothesized that meal-derived factors such as glucose, fatty acids, or incretin hormones may signal beta-cell compensation in the fat-fed dog. We fed the same fat-supplemented diet for 12 wk to six dogs and compared metabolic responses with seven control dogs fed a normal diet. Fasting and stimulated fatty acid and glucose-dependent insulinotropic peptide concentrations were not increased by fat feeding, whereas glucose was paradoxically decreased, ruling out those three factors as signals for compensatory hyperinsulinemia. Fasting plasma glucagon-like peptide-1 (GLP-1) concentration was 2.5-fold higher in the fat-fed animals, compared with controls, and 3.4-fold higher after a mixed meal. Additionally, expression of the GLP-1 receptor in whole pancreas was increased 2.3-fold in the fat-fed dogs. The increase in both circulating GLP-1 and its target receptor may have increased beta-cell responsiveness to lower glucose. Glucose is not the primary cause of hyperinsulinemia in the fat-fed dog. Corequisite meal-related signals may be permissive for development of hyperinsulinemia.

Mode of transcapillary transport of insulin and insulin analog NN304 in dog hindlimb: evidence for passive diffusion.

A defect in transcapillary transport of insulin in skeletal muscle and adipose tissue has been proposed to play a role in the insulin resistance that leads to type 2 diabetes, yet the mechanism of insulin transfer across the capillary endothelium from plasma to interstitium continues to be debated. This study examined in vivo the interstitial appearance of insulin in hindlimb using the fatty acid acylated insulin analog Lys(B29)-tetradecanoyl des-(B30) human insulin, or NN304, as a marker for insulin transport. If the insulin transport were a saturable process, then "swamping" the capillary endothelial insulin receptors with native insulin would suppress the subsequent appearance in interstitial fluid of the insulin analog NN304. This analog binds to insulin receptors with an affinity of about 50% of native insulin. Experimental conditions established a physiologic NN304 dose in the absence or presence of pharmacologic and saturating concentrations of regular human insulin. Euglycemic clamps were performed in dogs under inhalant anesthesia with deep hindlimb lymphatic sampling, representative of skeletal muscle interstitial fluid (ISF). In group 1 (n = 8), NN304 alone was infused (3.6 pmol center dot min(-1) center dot kg(-1)) from 60 to 360 min. In group 2 (n = 6), starting at time 0, human insulin was infused at a pharmacologic dose (60 pmol center dot min(-1) center dot kg(-1)) with the addition of NN304 infusion (3.6 pmol center dot min(-1) center dot kg(-1)) from 60 to 360 min. In group 3 (n = 4), the human insulin infusion was increased to a saturating dose (120 pmol center dot min(-1) center dot kg(-1)). Pharmacologic insulin infusion (group 2) established steady-state human insulin concentrations of 6,300 plus minus 510 pmol/l in plasma and 5,300 plus minus 540 pmol/l in ISF. Saturating insulin infusion (group 3) achieved steady-state human insulin concentrations of 22,000 plus minus 1,800 pmol/l in plasma and 19,000 plus minus 1,500 pmol/l in ISF. Total (bound and unbound) NN304 plasma concentrations rose from a steady state of 1,900 plus minus 110 (group 1) to 2,400 plus minus 200 pmol/l (group 2) and 3,100 plus minus 580 pmol/l (group 3), consistent with a competition-driven decline in NN304 clearance from plasma as the human insulin level increased (P < 0.05 by ANOVA). Steady-state interstitial NN304 concentrations also rose with increasing human insulin levels but did not achieve significance in comparison with analog alone (162 plus minus 15 vs. 196 plus minus 22 and 241 plus minus 53 pmol/l for group 1 versus groups 2 and 3, respectively; P = 0.20), yet the steady-state plasma:ISF ratio for NN304 remained essentially unchanged in the absence and presence of elevated human insulin levels (12.6 plus minus 1.2 vs. 12.4 plus minus 0.5 and 13.1 plus minus 1.5 for group 1 versus groups 2 and 3, respectively; P = 0.93). Last, NN304 rate of appearance in interstitial fluid (i.e., half-time to steady state) was similar between groups; mean half-time of 92 plus minus 4 min (NS between groups). In conclusion, appearance of the insulin analog NN304 in skeletal muscle interstitial fluid was constant whether in the absence or presence of human insulin concentrations sufficient to saturate the endothelial insulin receptors. These findings support the hypothesis, provided that the mechanism of insulin and NN304 transcapillary transport is similar, that transcapillary transport of insulin in skeletal muscle occurs primarily via a nonsaturable process such as passive diffusion via a paracellular or transcellular route.

Albumin binding of acylated insulin (NN304) does not deter action to stimulate glucose uptake.

NN304 [Lys(B29)-tetradecanoyl des(B30) human insulin] is a potentially therapeutic insulin analog designed to exhibit protracted glucose-lowering action. In dogs with infusion rates similar to insulin itself, NN304 exhibits similar glucose uptake (R(d)) stimulation with delayed onset of action. This compartmental modeling study was to determine if NN304 action could be accounted for by the approximately 2% unbound NN304 concentration. NN304 (or human insulin) (n = 6 each) was infused at 10.2 pmol center dot min(-1) center dot kg(-1) under euglycemic clamp conditions in anesthetized dogs. NN304 appearance in lymph, representing interstitial fluid (ISF), was slow compared with insulin (t(1/2) = 70 +/- 7 vs. 14 +/- 1 min, P < 0.001). R(d) was highly correlated with the ISF concentration for insulin and NN304 (r = 0.86 and 0.93, respectively), suggesting that slow transendothelial transport (TET) is responsible for sluggish NN304 action. Insulin and NN304 concentration data were fit to a two-compartment (plasma and ISF) model. NN304 plasma elimination and TET were reduced to 10 and 7% of insulin, respectively. Thus, there was reduction of NN304 transport, but not to the degree expected. In ISF, there was no reduction in NN304 elimination. Thus, this acylated insulin analog demonstrates blunted kinetics in plasma, and full efficacy in the compartment of action, ISF.