Disposition of a mixed meal by the conscious dog

Moore, Mary Courtney; Pagliassotti, Michael J.; Swift, Larry L.; Asher, Jordan; Murrell, Joel; Neal, Doss W.; Cherrington, Alan D.

doi:10.1152/ajpendo.1994.266.4.e666

Cited by 35 publications

(36 citation statements)

References 20 publications

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“…The lower arterial glucose levels likely contributed to the lower insulin levels. Consistent with previous studies, only ϳ70% of the glucose given enterally is absorbed as glucose (8,17); the remaining 30% is metabolized by the intestine. A failure to absorb 100% of the enterally delivered glucose as glucose is likely not the sole explanation for the lower insulin concentration in TPNϩEG.…”

Section: Discussionsupporting

confidence: 90%

Route-dependent effect of nutritional support on liver glucose uptake

Chen¹,

Torres-Sanchez²,

Hosein³

et al. 2005

American Journal of Physiology-Regulatory, Integrative and Comp

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The liver is a major site of glucose disposal during chronic (5 day) total parenteral (TPN) and enteral (TEN) nutrition. Net hepatic glucose uptake (NHGU) is dependent on the route of delivery when only glucose is delivered acutely; however, the hepatic response to chronic TPN and TEN is very similar. We aimed to determine whether the route of nutrient delivery altered the acute (first 8 h) response of the liver and whether chronic enteral delivery of glucose alone could augment the adaptive response to TPN. Chronically catheterized conscious dogs received either TPN or TEN containing glucose, Intralipid, and Travasol for either 8 h or 5 days. Another group received TPN for 5 days, but ϳ50% of the glucose in the nutrition was given via the enteral route (TPNϩEG). Hepatic metabolism was assessed with tracer and arteriovenous difference techniques. In the presence of similar arterial plasma glucose levels (ϳ6 mM), NHGU and net hepatic lactate release increased approximately twofold between 8 h and 5 days in TPN and TEN. NHGU (26 Ϯ 1 vs. 23 Ϯ 3 mol ⅐ kg Ϫ1 ⅐ min Ϫ1 ) and net hepatic lactate release (44 Ϯ 1 vs. 34 Ϯ 6 mol ⅐ kg Ϫ1 ⅐ min Ϫ1 ) in TPNϩEG were similar to results for TPN, despite lower insulin levels (96 Ϯ 6 vs. 58 Ϯ 16 pM, TPN vs. TPNϩEG). TEN does not acutely enhance NHGU or disposition above that seen with TPN. However, partial delivery of enteral glucose is effective in decreasing the insulin requirement during chronic TPN.intestine; glycogen IN STRESSED STATES (trauma, injury, or infection) nutritional support is often provided to patients either via the parenteral (TPN) or enteral (TEN) route. Prior studies suggest that when the nutrition (either TPN or TEN) is given continuously for 5 days liver glucose uptake is markedly augmented; the liver removes ϳ45% of the exogenous glucose (1). Even more surprisingly, substantial liver glucose uptake occurred in the absence of hyperglycemia (ϳ6.7 mmol/l) and in only mild hyperinsulinemia (102 pmol/l) (1). Recently, our group (3) observed that the enhancement in the capacity of the liver to take up glucose (i.e., adaptive response) begins within 5 h after initiation of TPN and is nearly fully manifest by 24 h.The enteral route is the preferred route for delivery of exogenous nutrients (12,14). In postsurgical and stressed patients, isocaloric enteral nutrition can be given without significant accompanying hyperglycemia (22, 23) compared with that shown with TPN. A potential benefit of the enteral route is that when only glucose is delivered via the enteral route in the acute setting it enhances net hepatic glucose uptake (NHGU) to a greater extent than when glucose is delivered via a peripheral route; this route-dependent effect has been termed the "portal signal" (7,20). The portal signal can rapidly (Ͻ15 min) augment NHGU; it does not require the presence of hyperglycemia or hyperinsulinemia (11). Surprisingly, when TEN is administered chronically in unstressed animals, which should activate the portal signal, NHGU is not any greater than that seen with TPN...

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Section: Discussionsupporting

confidence: 90%

Route-dependent effect of nutritional support on liver glucose uptake

Chen¹,

Torres-Sanchez²,

Hosein³

et al. 2005

American Journal of Physiology-Regulatory, Integrative and Comp

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“…Knowing that the insulinbrain-liver signaling axis was intact in dogs, we undertook a second set of experiments to determine whether a physiologic increase in brain insulin could activate central signaling and thereby modify hepatic glucose metabolism in vivo. To this end, we brought about an increase in brain insulin that was physiologic in both its route of administration (infused into the arteries that perfuse the brain) and its magnitude (~10-fold increase), the latter being within the physiologic range of arterial hyperinsulinemia seen after a mixed meal (26). In order to allow the impact of such a change to be clearly seen, we maintained basal insulin and glucagon levels at the liver.…”

Section: Discussionmentioning

confidence: 99%

Brain insulin action augments hepatic glycogen synthesis without suppressing glucose production or gluconeogenesis in dogs

Ramnanan¹,

Saraswathi²,

Smith³

et al. 2011

J. Clin. Invest.

112

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In rodents, acute brain insulin action reduces blood glucose levels by suppressing the expression of enzymes in the hepatic gluconeogenic pathway, thereby reducing gluconeogenesis and endogenous glucose production (EGP). Whether a similar mechanism is functional in large animals, including humans, is unknown. Here, we demonstrated that in canines, physiologic brain hyperinsulinemia brought about by infusion of insulin into the head arteries (during a pancreatic clamp to maintain basal hepatic insulin and glucagon levels) activated hypothalamic Akt, altered STAT3 signaling in the liver, and suppressed hepatic gluconeogenic gene expression without altering EGP or gluconeogenesis. Rather, brain hyperinsulinemia slowly caused a modest reduction in net hepatic glucose output (NHGO) that was attributable to increased net hepatic glucose uptake and glycogen synthesis. This was associated with decreased levels of glycogen synthase kinase 3β (GSK3β) protein and mRNA and with decreased glycogen synthase phosphorylation, changes that were blocked by hypothalamic PI3K inhibition. Therefore, we conclude that the canine brain senses physiologic elevations in plasma insulin, and that this in turn regulates genetic events in the liver. In the context of basal insulin and glucagon levels at the liver, this input augments hepatic glucose uptake and glycogen synthesis, reducing NHGO without altering EGP.

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“…The liver is an important site of glucose removal after a meal (1,8,13,18,33,37,38). Several studies have demonstrated that the combination of hyperglycemia, hyperinsulinemia, and intraportal glucose infusion (portal signal) can produce rates of NHGU that are comparable with rates observed after glucose ingestion (32,39,40).…”

Section: Discussionmentioning

confidence: 99%

Comparison of the time courses of insulin and the portal signal on hepatic glucose and glycogen metabolism in the conscious dog.

Pagliassotti¹,

Holste²,

Moore³

et al. 1996

J. Clin. Invest.

124

181

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To investigate the temporal response of the liver to insulin and portal glucose delivery, somatostatin was infused into four groups of 42-h-fasted, conscious dogs ( n ϭ 6/group), basal insulin and glucagon were replaced intraportally, and hyperglycemia was created via a peripheral glucose infusion for 90 min (period 1). This was followed by a 240-min experimental period (period 2) in which hyperglycemia was matched to period 1 and either no changes were made (CON), a fourfold rise in insulin was created (

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Disposition of a mixed meal by the conscious dog

Cited by 35 publications

References 20 publications

Route-dependent effect of nutritional support on liver glucose uptake

Route-dependent effect of nutritional support on liver glucose uptake

Brain insulin action augments hepatic glycogen synthesis without suppressing glucose production or gluconeogenesis in dogs

Comparison of the time courses of insulin and the portal signal on hepatic glucose and glycogen metabolism in the conscious dog.

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